SYSTEM OF REGULATORY DOCUMENTS IN CONSTRUCTION

ESTIMATE STANDARDS
RUSSIAN FEDERATION

FERp 81-04-02-2001

Approved And introduced in de th action from 16 April l I 2003 G.
resolution Gosstroy Russia from 16 . 04 . 2003 G . № 35

FEDERAL
UNIT PRICES
ON START H A L A D O N T WORKS

FERp-2001

Collection No.2

AUTOMATED SYSTEMS
MANAGEMENT

State Committee of the Russian Federation
for construction and housing n o-comm al complex
(Gosstroy of Russia)

Moscow2003G.

Federal unit prices for commissioning about private work FERp- 2001-02 Automated control systems.

(Gosstroy of Russia) Moscow, 2003G.

Designed to determine direct costsT in the estimated cost, as well as for settlements for the completed commissioning automated systems management.

Compilation designed in price level1-th territorial region as of January 1, 2000.

DEVELOPEDFederal State Unitary Enterprise TsNIIEUS Gosstroy of Russia (Zh.G. Cherns shova, L.V. Razmadze), JSC "Association of Monta zhavtomatika "(B .Z . Barlasov, M.I. Logoiko), Coordinating Center for Pricing and Estimated Rationing in Construction LLC (A.N. Zhukov) with the participation of the Interregional Center for Pricing in Construction and Industry building materials(MTsTSS) Gosstroy of Russia (V.P. Shuppo).

CONSIDEREDDepartment of Pricing and Estimated Rationing of the Gosstroy of Russia (Editorial Commission: V.A. Stepanov - Head, V.G.Kozmodemyansk iy, T .L. Gri ischenkova).

INTRODUCEDDepartment of Pricing and Estimated Rationing of the Gosstroy of Russia.

APPROVED AND INTRODUCED from 16 . 04. 200316. 04. 2003 No. 35

FEDERAL UNIT RATES
ON PUSKON L ADDITIONAL WORKS

Collection № 2

Automated control systems

FERp-2001-02

TECHNICAL PART

1. General provisions

1. 1. These federal unit prices (hereinafter referred to as prices) are intended to determine direct costs in the estimated cost of the start-up palmar x works on automated control systems at commissioning under construction, as well as reconstructed, expanded and technically re-equipped operating enterprises, buildings and structures.

1. 2. Prices reflect the industry average level of technology and organization of commissioning th works.

The rates are obligatory for application by all enterprises and organizations, regardless of their departmental affiliation and forms of ownership, carrying out capital construction at the expense of the state budget of all levels and target off-budget funds.

For construction projects funded by own funds enterprises, organizations and individuals, the prices of this collection are advisory in nature.

1. 3. Rates are based on:

Collection of state elemental estimated norms for start-up l and daughters e work - GESNp-2001-02 "Automated control systems", approved and put into effect from July 15, 2001 by a resolution of the Gosstroy of Russia dated July 23, 2001 No. 84;

start-up pay levell recruiting personnel hired on the basis of the state statistical reporting in construction in the first territorial region as of January 1, 2000.

1. 4. When applying this collection, in addition to the provisions contained in this technical part, it is necessary to take into account the requirements general, given in the Guidelines for the use of federal unit prices for commissioning, approved and put into effect by the Gosstroy of Russia.

1. 5. This Collection applies to:

Automated process control systems (APCS);

Centralized operational dispatch control systems;

Automatic fire and security fire alarm systems;

Control systems and automatic control fire fighting and countersmoke protection;

telemechanical systems.

The collection is not intended to determine direct costs in the estimated cost of work:

For precision in-line analyzers of the physicochemical properties of media and products circulating in the technological process: refractometers, chromatographs, octane meters and other similar single-use analyzers;

For software and hardware complexes of computer centers for economic or other information not related to technological processes;

For video surveillance (security) systems using television installations, loud-speaking communications (alerts), etc., the direct costs of which are determined according to the Collection for the installation of equipment No. 10 "Communication equipment".

(Changed edition. Rev. No. 1)

1. 6. Rates are based on the following conditions:

Software and hardware complexes (KPTS) orto complexes of technical means ( TO Vehicles) transferred for adjustment - serial, complete, with loaded system and application software, provided with technical documentation (passports, certificates, etc.), their storage period in the warehouse does not exceed the standard;

Commissioning works are carried out by organizations licensed to carry out these types of work, when performing work at facilities supervised by authorities state supervision additionally licensed and/or approved by these agencies. Workers performing the work have qualifications corresponding to technical complexity automated systems, have passed the necessary training, attestation or certification, are provided with the necessary equipment, measuring instruments, control and test stands, instrumental software, programmers, calibrators, tools, tools personal protection etc.;

Puscona l hello The work is carried out on the basis of the working documentation approved by the customer, if necessary, taking into account the project for the production of works (P P P), programs and graphics;

By the start of the start-up worksd internal organization, the customer transferred the working project documentation, including parts of the APCS project: software (MS), information software (IS), software (SW), organizational software (OO);

To start-up production l adjective x works are started if the customer has documents on the completion of the installation work provided for by SNi P (acts, protocols, etc.). In the event of forced breaks between installation and adjustment work for reasons beyond the control of the contractor, to start-up palmar m work is started after checking the safety of previously assembled and installation of previously dismantled technical means (in this case, the act of completion of installation work is drawn up anew on the date of commencement of commissioning);

Switching of operating modes of technological equipment is carried out by the customer in accordance with the project, regulations and within the periods provided for by the agreed programs and work schedules;

Detected defects in the installation of software and hardware (PTS) or hardware (TS) are eliminated by the installation organization.

(Changed edition. Rev. No. 1)

1. 7. Prices are developed in accordance with the requirements state standards, in particular, GOST 34. 603- 92"Information technology. Types of testing of automated systems", standards " State system industrial devices and means of automation”, “State system for ensuring the uniformity of measurements”, 3-th part of SNiP "Organization, production and acceptance of work", Rules for the installation of electrical installations (PUE), Intersectoral rules for labor protection (safety rules) during the operation of electrical installations (POTRM- 016-2001) RD 153-34.0-03.150-00,"Safety Rules for Gas Distribution and Gas Consumption Systems" (PB-12-529-03. O general rules s safe for adults fire hazard x chemical, petrochemical and oil refining industries (PB 09-540-03) and other rules and norms of state supervision bodies, technical documentation manufacturers of TCP or TS, duly approved instructions, technical and technological regulations, guiding technical materials and other technical documentation for the installation, commissioning and operation of PTS and TS.

(Changed edition. Rev. No. 1)

1. 8. The prices take into account the costs for the production of a set of works of one technological cycle of commissioning for the commissioning of the process control system in accordance with the requirements of regulatory and technical documentation, including the following stages (stages):

1. 8.1.Preparatory work, verification of KTS (KTS) of automated systems:

Study of working and technical documentation, incl. pre-design stage materials ( technical requirements to the system, etc.), performance of other measures of engineering and technical preparation of work, examination of the technological control object, external inspection of equipment and installation work performed on the APCS, determination of the readiness of systems adjacent to the APCS (power supply, etc.), etc. d.

Verification of the compliance of the main technical characteristics of the equipment with the requirements established in the passports and instructions of manufacturers (the results of verification and adjustment are recorded in the act or passport of the equipment, faulty TCP or TS are transferred to the customer for repair and replacement).

(Changed edition. Rev. No. 1)

1. 8. 2. Autonomous adjustment of automated systems after completion of their installation:

Checking the installation of the PTS (TS) for compliance with the requirements of the instructions of manufacturers and working documentation;

Replacement of individual defective elements with serviceable ones issued by the customer;

Checking the correct marking, connection and phasing of electrical wiring;

Phasing and control of the characteristics of actuators (IM);

Setting up the logical and temporal relationships of signaling, protection, blocking and control systems, checking the correctness of the passage of signals;

Checking the functioning of application and system software;

Preliminary determination of the characteristics of the object, calculation and adjustment of the parameters of the equipment of automated systems, configuration of measuring transducers and software logic devices;

Preparation for inclusion and inclusion in the operation of measurement, control and management systems to ensure individual testing of process equipment and adjustment of the settings for the equipment of control systems in the process of their operation;

Preparation of production and technical documentation.

(Changed edition. Rev. No. 1)

1. 8. 3. Complex adjustment of automated systems:

Bringing the settingsP TS (TS), communication channels and application software to the values ​​(state) at which automated systems can be used in operation, while carried out in a complex:

Determining the compliance of the procedure for testing devices and elements of signaling, protection and control systems with the algorithms of working documentation, identifying the causes of failure or their “false” operation, setting the necessary values ​​for the operation of positional devices;

Definition of conformity bandwidth lock-regulatorcomfort her fittings requirements technological process, correct working out of limit and travel switches,position and status sensors;

Determination of the flow characteristics of regulatory bodies (RO) and bringing them to the required rate using the adjustment elements available in the design;

Clarification of the static and dynamic characteristics of the object, adjusting the values ​​of the system settings, taking into account their mutual influence in the process of work;

Preparation for the inclusion in the operation of systems to ensure the comprehensive testing of technological equipment;

Testing and determining the suitability of automated systems to ensure the operation of process equipment with a capacity that meets the standards for the development of design capacities in the initial period;

Analysis of the work of automated systems;

Registration of production documentation, act of acceptance into operation of systems in accordance with the requirements of SNiP;

Entry in one copy circuit diagrams from the set of working documentation of changes agreed with the customer, based on the results of the start-up production d eye work.

1.9. The prices of this Collection do not include the costs of:

Puscona l and daughters e works, prices for which are given in the relevant sections EPp-2001-01 "Electrical devices": on electric machines (motors) of electric drives, switching devices, static converters, power devices, measurements and tests in electrical installations;

Testing of automated systems over24hours of their work during the period of complex testing of technological equipment;

Drawing up a technical report and estimate documentation;

Delivery of measuring instruments to state verification;

Configuring components and screen forms, adjusting and finalizing the design mathematical, information and software, determined on the basis of standards for design work;

Audit of PTS (TS), elimination of their defects (repair) and installation defects, including bringing the insulation of electrical equipment, cable communication lines and parameters of installed fiber-optic and other communication lines to the standards;

Checking the compliance of wiring diagrams with circuit diagrams and making changes to wiring diagrams;

Preparation of principal, assembly, detailed diagrams and drawings;

Partial or complete reassembly of cabinets, panels, consoles;

Coordination of work performed with supervisory authorities;

Carrying out physical and technical and chemical analyzes, supply of exemplary mixtures, etc.;

Drawing up a program of complex testing of technological equipment;

Training of operating personnel;

Development of operational documentation;

Technical (service) maintenance and periodic checks of the KTS (KTS) during the operation period.

(Changed edition. Rev. No. 1)

1.10. The prices of this Collection are developed for automated systems (hereinafter referred to as systems) depending on the category of their technical complexity, characterized by the structure and composition of the KTS (KTS),taking into account the complexity factor.

table 1

	Characteristics of the system (structure and composition of the KTS or KTS)	System complexity factor
	Single-level information, control, information and control systems, characterized in that measuring and regulating devices are used as components of the CTS to perform the functions of collecting, processing, displaying and storing information and generating control commands. at communication devices, electromagnetic, semiconductor and other components, signal fittings, etc. instrumental or hardware types of execution
	Single-level information, control, information - control systems, characterized in that programmable logic controllers are used as components of the KPTS to perform the functions of collecting, processing, displaying and storing information and generating control commands ( PLC ), intercom devices, microprocessor-based operator interfaces (display panels)	1, 313
	Single-level systems with automatic mode of indirect or direct (direct) digital (digital-analog) control using object-oriented controllers with programming of settings parameters, the operation of which does not require the development of project MO and software
	Information, control, information and control systems in which the composition and structure of the CTS meet the requirements established for classifying systems as I category of complexity and in which fiber optics are used as communication channels to ne information transmission systems (VOTSI)
	Measurement and (or) automatic control systems chemical composition And physical properties substances
	Measuring systems (measuring channels) for which metrological certification (calibration) is required according to the project
	Multilevel distributed information, control, information and control systems, in which the composition and structure of the local level CPTS meet the requirements established for classifying the system as a II -th category of complexity and in which processes are used to organize subsequent levels of management s (PCS ) or operator ( OS ) stations; implemented on the basis of problem-oriented software, interconnected and with the local control level through local area networks	1, 566
	Information, control, information and control systems in which the composition and structure of the CPTS (CTS) meets the requirements established for classifying systems as II category of complexity and in which fiber-optic information transmission systems (FOTS) are used as communication channels
Notes : 1 . Systems II and III categories of technical complexity may have one or more features,given as a characteristic of the system. 2. In the event that a complex system contains systems (subsystems), according to the structure and composition of the KTS or KTS referred to different categories of technical complexity, the complexity coefficient of such a system is calculated in accordance with clause .

1.11.Rates designed for systems I, II and III category of technical complexity depending on the number of communication channels for the formation of input and output signals.

Under the communication channel for the formation of input and output signals (hereinafter - the channel) should be understood as a set of technical means and communication lines that provide the transformation, processing and transmission of information for use in the system.

The Collection takes into account the quantity:

Information channels (including channels for measurement, control, notifications x, address, state, etc.);

control channels.

The composition of information channels and control channels, in turn, takes into account the number of channels:

Discrete - contact and non-contact on AC and DC, pulsed from discrete (signaling) measuring transducers, for monitoring the status of various on-offs x devices, as well as for transmitting “on-off” signals, etc.;

Analog, which include (for the purposes of this Collection) all the rest - current, voltage, frequency, mutual inductance, natural or unified signals of measuring transducers (sensors) that change continuously, encoded (pulse or digital) signals for the exchange of information between various digital devices information processing etc.

In the following presentation, the symbols for the number of channels given in Table 1 are used. .

table 2

Symbol	Name
K a i	Number of information analogue channels
K d and	Number of information discrete channels
K a y	Number of analog control channels
K d y	Number of discrete control channels
To common and	The total number of information analog and discrete channels
To common	Total number of analog and discrete control channels
K total \u003d (K total and + K total y)	Total number of information and control channels analog and discrete

2. The procedure for applying unit prices

2.1.The collection price tables show base prices ( R b) for commissioning s e works for systems I, II and III category of technical complexity ( R Ib, R IIb, R IIIb), depending on the total number of information and control channels, analog and discrete(K total) in this system.

(Changed edition. Rev. No. 1)

2. 2. For a complex system consisting of subsystems of different categories of technical complexity, the components of the price - the amount of funds for wages (ZP) and the labor cost (H) - is calculated as follows:

at 1< С < 1,313 , where C is the coefficient of complexity, calculated by the formula:

where: - the total number of analog and discrete channels of information and control related to subsystems, respectively, I, II, III difficulty categories;

(1.1)

where is the base wage according to Table. 02-01-001 for the system I category of technical complexity (С=1);

The basic rate of labor costs according to table. 02-01-001.

at 1.313< С < 1,566

(2.1)

where is the base wage according to Table. 02-01-002 for the system II category of technical complexity (C=1.313).

where - the basic rate of labor according to table. 02-01-002.

(Changed edition. Change No. 1 )

2. 3. When compiling cost estimates (estimates) for start-up palmar e work to take into account the characteristics of a particular system to the base price ( R b) the following coefficients should be applied:

2. 3. 1 . Coefficient f m i, taking into account two factors: "metrological complexity" and "development» information functions" of the system

Coefficient f m icalculated by the formula:

f m i = 0 , 5 + K a i : K total × M × I, (3)

where M - the coefficient of "metrological complexity", determined by the table. ;

AND - the coefficient of "development of information functions", determined by the table. .

table 3

No. p.p.	Characteristics of the factors of "metrological complexity" ( M) systems		The coefficient of "metrological complexity" of the system ( M)
	Measuring transducers (sensors) and measuring instruments, etc., operating in normal environmental and technological environment, accuracy class:
	less than or equal to 1 , 0	K a uM1	1
	below 0 , 2 and above 1, 0	K a uM2	1, 14
	greater than or equal to 0 , 2	K a uM3	1, 51
Note : If the system has measuring transducers (sensors) and measuring instruments belonging to different accuracy classes, the coefficient M calculated by the formula: M = (1 +0.14×K a uM2: K a i) × (1 +0.51×K a uM3: K a i),(4) where: K a i = K a uM1 + K a uM2 + K a uM3 ;(4. 1)

table 4

no.	Characteristics of the factors of "development of information functions" ( AND) systems	Designation of the number of channels	Coefficient of "development of information functions" of the system ( AND)
1	Parallel or centralized control and measurement of the parameters of the state of the technological control object (TOU)	K total iI1	1
	The same as for p . ,including archiving, documenting data, compiling emergency and production (shift, daily, etc.) reports, presentation of parameter trends, indirect measurement (calculation) of individual integrated indicators functioning of TOU	K total uI2	1, 51
	Analysis and generalized assessment of the state of the process as a whole according to its model (recognition of the situation, diagnostics of emergency conditions, search for a bottleneck, forecast of the process)	K total iI3	2, 03
Note : If the system has different characteristics of "development of information functions", the coefficient AND calculated by the formula: And = (1+0.51× K total uI2: TOcommon) × ( 1+1.03 × K total iI3: TOcommon) ,(5) where: To common and = K bosch uI1 + K total uI2 + K total uI3; (5.1 )

(Changed edition. Rev. No. 1)

2. 3. 2. Coefficient Ugh, taking into account the "development of control functions", calculated by the formula:

Ugh= 1+ (1, 31 × K and at+ 0.95 × K y ) : K total × At,(6)

where: At- the coefficient of "development of control functions", is determined by the table.

table 5

no.	Characterization of the factors of "development of control functions" ( At) systems	Designation of the number of channels	Coefficient of "development of control functions" of the system(At)
	Single-circuit automatic control (AR) or automatic single-cycle logic control (switching, blocking, etc.).	K total yU1	1
	Cascade and (or) software AP or automatic software logic control (AP LU) according to a "hard" cycle, multiply connected AR or APLU according to a cycle with branches.	K total yU2	1, 61
	Management b fast leakage their processes in emergency conditions or control with adaptation (self-learning and changing the algorithms and parameters of systems) or optimal control (OC) of steady-state modes (in statics), OC of transients or the process as a whole (optimization in dynamics).	K total uU3	2, 39
Note : If the system has different characteristicsR development of control functions”, coefficient At calculated by the formula: Y = (1+0.61× K total yU2: To common) × (1+1.39× K total uU3: To common); (7) where: To common = K bosch yU1 + K total yU2 + K total yU3; (7.1)

2. 4. Estimated price ( R) for a specific system is calculated by applying to the base price established in accordance with paragraph .,coefficients f m i , Ugh, which are multiplied with each other I:

R = R b ×(F m and × F y).(8)

2. 5. When performing start-up la doch s x jobs in more complex working conditions, in comparison with those provided for in the collection, as a result of which labor productivity decreases, the coefficients given in the Instructions for the Application of Federal Unit Prices for Start-Up palm work.

2. 6. When performing repeated commissioning works (before putting the facility into operation), it is necessary to apply the coefficient to the prices 0, 537. Re-commissioning should be understood as work caused by the need to change the technological process, the mode of operation of technological equipment, in connection with a partial change in the design or forced replacement of equipment. The need to re-perform work must be confirmed by a reasonable task (letter) from the customer.

2. 7. In the event that the automated process control system is created as part of an automated technological complex (ATC) included in the pilot or experimental construction plan, or in the list of unique or especially important (most important) objects (constructions), or the automated process control system includes experimental or experimental software and hardware (technical) means, a coefficient is applied to the prices 1, 2.

2. 8. In the event that the launch palmar If the work is carried out under the technical supervision of the personnel of the manufacturer or supplier of the equipment, the coefficient should be applied to the prices 0, 8.

2. 9. Specified in paragraphs. ÷ the coefficients are applied to the cost of those stages of work (the corresponding number of information and control channels), which are subject to the above conditions. If multiple coefficients are used, they must be multiplied.

2. 10. Reducing factor for the same type of automated technological complexes (ATK) in accordance with clause 2.5. MDS 81-40.2006 is taken into account by the norms of this Collection, subject to a special calculation procedure, in which the price is initially determined as a whole for several of the same type of ATK in accordance with the project and, if necessary, a price is allocated for one of the same type of ATK.

It is not allowed, when determining estimated prices, artificial, contrary to the project, division of the automated system into separate measurement systems, control (regulation) loops, subsystems.

For example: For centralized system operational dispatch control of ventilation and air conditioning, including several subsystems of supply and exhaust ventilation, the estimated price is determined as a whole for the centralized control system, and the costs for individual subsystems, if necessary, are determined as part of the overall price for the whole system, taking into account the number of channels related to subsystems.

(Changed edition. Rev. No. 1)

2. 11. If it is necessary to make intermediate payments for the performed commissioning works, it is recommended to use approximate structure the cost of commissioning works for their main stages (unless the contract provides for other conditions for mutual settlements of the parties), given in Table. .

table 6

no.	Name of the stages of commissioning	Share in total cost works, %
	Preparatory work, verification of TCP (PS):	25
	including preparatory work	10
	Offline system tuning	55
	Complex adjustment of systems	20
	Total	100
Notes : 2. In the event that the customer engages one organization to perform commissioning work on software and hardware (for example, a project developer or equipment manufacturer that has the appropriate licenses for commissioning palmar x works), and for technical means - another start-up daughter organization, distribution of the volume of work performed by them (within the total cost of work on the system), including the stages of Table. , is produced, in agreement with the customer, taking into account about the total number of channels related to PTS and TS.

(Changed edition. Rev. No. 1)

3. The procedure for preparing initial data for budgeting

3.1.Preparation of initial data for budgeting is carried out on the basis of design and technical documentation for a specific system.

When preparing the initial data, it is recommended to use the "Scheme of an automated technological complex (ATC)» given in the appendix .

Preparation of initial data is carried out in the following sequence:

3.1.1.As part of the ATK, according to the scheme, the following groups of channels are distinguished according to Table. .

table 7

no.	Channel group symbol	Channel group content
1	CBTFROM→ TOU(KTS)	Control channels analog and discrete (K but at and K d )transfer of control actions from K P TS (KTS) at TOU . The number of control channels is determined in count actuators: membrane, piston, electric single- and multi-turn, non-engine (cut-off), etc.
2	TOU→KPTS (KTS)	but And and K d and )transformation of information (parameters) coming from the technological control object (TOU) to the KPTS (KTS) . The number of channels is determined quantity measuring transducers, contact and non-contact signaling devices, position sensors and equipment condition, limit and travel switches, etc. wherein combined fire protection sensorn noah signaling ( pic) is taken into account as one discrete channel
3	Op→K PTS (KTS)	Analogue and discrete information channels (K but And and K d and )used by the operator (Op) to influence the KTS (KTS) . The number of channels is determined the number of organs of influence, used by the operator ( buttons, keys, controls etc.) to implement the functioning of the system in the modes of automated (automatic) and manual remote control of actuators not counted as organ channels impact KPTS (KTS) used for tuning and other auxiliary functions (except for control): keyboard of terminal devices of information and control panels, buttons, switches, etc., panels of multifunctional or multi-channel devices of POS control panels, etc., as well as voltage switches, fuses and other auxiliary bodies for influencing the above and other technical meansthe adjustment of which is taken into account by the prices and norms of this Collection
4	KPTS→About n(KTS)	Channels analog and discrete (TO a and and K d i) displaying information coming from KTS (KTS) to Op when determining the number of system channels not taken into account, except when the project provides for the display of the same technological parameters (equipment status) on more than one terminal device (monitor, printer, interface panel, information board, etc.). The adjustment of information displays on the first terminal device is taken into account by the prices of this Collection. In this case, when displaying information on each terminal device beyond the first, the displayed parameters ( TO but And and K d and ) are taken into account TO but And with coefficient0, 025, K d and with coefficient0, 01 . Not taken into account as channels indicators (lamps, LEDs etc.) states and positions built into measuring transducers (sensors), contact or non-contact signaling devices, buttons, control keys, switches, as well as indicators of the presence of voltage of devices, recorders, terminal devices of panels, consoles, etc., the adjustment of which is taken into account by the prices of this Collection
5	sms № 1, № 2, … , № i	Communication channels (interactions) analog and discrete information (C a and C d and) with related systems, made on separate projects. “The number of physical channels through which communication signals (interaction) with adjacent systems are transmitted is taken into account: discrete - contact and non-contact direct and alternating current (with the exception of coded) and analog signals, the values ​​of which are determined on a continuous scale, as well as, for the purposes of this Collection, coded (pulse and digital)". Different kinds voltage electrical systems used as power sources for APCS equipment (shields, consoles, actuators, information converters, terminal devices, etc.) as communication channels (interactions) with adjacent systems are not taken into account.

(Changed edition. Rev. No. 1)

3. 1. 2. For each group of channels in Table. the number of information channels (analog and discrete) and control channels (analog and discrete) is counted, as well as e the total number of information and control channels ( TO common) for the system as a whole.

3.1. 3. Based on the table. the category of technical complexity of the system is established and, depending on TO commonaccording to the corresponding price table, the base price is determined (R b), if necessary, a base price is calculated for complex system (R sl b)- using formulas ( ) And ( ).

3. 1. 4. To link the base price to a specific system, correction factors are calculated F i mAnd F atin accordance with paragraphs. And , then the estimated price is calculated according to the formula ( ).

DEPARTMENT 01. AUTOMATED CONTROL SYSTEMS

Rate code	Name and technical specifications equipment	Direct costs (compensation of commissioning personnel), rub.	Labor costs, man-hour
Table 02-01-001 Automated control systems of the 1st category of technical complexity Meter : system (rates 1 , 3 , 5 , 7 , 9 , 11 , 13 , 15 , 19 ); channel (rates 2 , 4 , 6 , 8 , 10 , 12 , 14 , 16 , 18 , 20 )
02- 01- 001- 02	TO common ):	190, 07	13, 4
02- 01- 001- 02	for each channel 2before 9add to rate 1		6, 45
02- 01- 001- 03	10	921, 99	65
02- 01- 001- 04	for each channel 10before 19add to rate 3		6, 3
02- 01- 001- 05	20		128
02- 01- 001- 06	for each channel 20before 39add to rate 5	87, 23	6, 15
02- 01- 001- 07	40	3560, 31	251
02- 01- 001- 08	for each channel 40before 79add to rate 7		6, 03
02- 01- 001- 09	80	6978, 77	492
02- 01- 001- 10	for each channel 80before 159add to rate 9	83, 40	5, 88
02- 01- 001- 11	160	13645, 49	962
02- 01- 001- 12	for each channel 160before 319add to rate 11	78, 72	5, 55
02- 01- 001- 13	320	26241, 32
02- 01- 001- 14	for each channel 320before 639add to rate 13	73, 62	5, 19
02- 01- 001- 15	640	49787, 59
02- 01- 001- 16	for each channel 640before 1279add to rate 15	62, 55	4, 41
02- 01- 001- 17		89787, 88
02- 01- 001- 18	for each channel 1280before 2559add to rate 17	49, 50	3, 49
02- 01- 001- 19 2 , 4 , 6 , 8 , 10 , 12 , 14 , 16 , 18 , 20 )
02- 01- 002- 01	System with number of channels (TO common ):	260, 59	17, 6
02- 01- 002- 02	for each channel 2before 9add to rate 1	125, 41	8, 47
02- 01- 002- 03	10	1258, 51	85
02- 01- 002- 04	for each channel 10before 19add to rate 3	122, 89	8, 3
02- 01- 002- 05	20	2487, 41	168
02- 01- 002- 06	for each channel 20before 39add to rate 5	119, 93	8, 1
02- 01- 002- 07	40	4885, 98	330
02- 01- 002- 08	for each channel 40before 79add to rate 7	117, 12	7, 91
02- 01- 002- 09	80	9564, 68	646
02- 01- 002- 10	for each channel 80before 159add to rate 9		7, 71
02- 01- 002- 11	160	18699, 98
02- 01- 002- 12	for each channel 160before 319add to rate 11	107, 94	7, 29
02- 01- 002- 13	320	35978, 58
02- 01- 002- 14	for each channel 320before 639add to rate 13	100, 83	6, 81
02- 01- 002- 15	640	68255, 66
02- 01- 002- 16	for each channel 640before 1279add to rate 15		5, 78
02- 01- 002- 17		123037, 86
02- 01- 002- 18	for each channel 1280 Meter : system (rates 1 , 3 , 5 , 7 , 9 , 11 , 13 , 15 , 19 ); channel (rates 2 , 4 , 6 , 8 , 10 , 12 , 14 , 16 , 18 , 20 )
02- 01- 003- 01	System with number of channels (TO common ): 2	341, 85	21
02- 01- 003- 02	for each channel2before 9add to rate 1	164,41	10, 1
02- 01- 003- 03	10	1660, 41	102
02- 01- 003- 04	for each channel10before 19add to rate 3	159, 53	9, 8
02- 01- 003- 05	20	3255, 70	200
02- 01- 003- 06	for each channel20before 39add to rate 5	156, 76	9, 63
02- 01- 003- 07	40	6397, 45	393
02- 01- 003- 08	for each channel40before 79add to rate 7	153, 67	9, 44
02- 01- 003- 09	80	12534, 44	770
02- 01- 003- 10	for each channel80before 159add to rate 9	149, 76	9, 2
02- 01- 003- 11	160	24515, 42	1506
02- 01- 003- 12	for each channel160before 319add to rate 11	141, 62	8, 7
02- 01- 003- 13	320	47175, 09	2898
02- 01- 003- 14	for each channel320before 639add to rate 13	132, 18	8, 12
02- 01- 003- 15	640	89482, 91	5497
02- 01- 003- 16	for each channel640before 1279add to rate 15	112, 32	6, 9
02- 01- 003- 17	1280	161368, 77	9913
02- 01- 003- 18	for each channel1280before 2559add to rate 17	89, 04	5, 47
02- 01- 003- 19	2560	275350, 81	16915
02- 01- 003- 20	for each channel2560add to rate 19	72, 11	4, 43

Inactive

FERp 81-05-PR-2001

STATE ESTIMATE STANDARDS

FEDERAL UNIT PRICES FOR COMMISSIONING
FERp-2001

IV. Applications

State budget standards. Federal unit prices for commissioning (hereinafter referred to as FERp) are intended to determine the costs of commissioning and draw up, on their basis, estimates (estimates) for the performance of these works.

Approved and included in the federal register of estimated standards to be applied when determining the estimated cost of capital construction projects, the construction of which is financed with the attraction of funds federal budget Order of the Ministry of Construction and Housing and Communal Services of the Russian Federation of January 30, 2014 N 31 / pr (as amended by the Order of the Ministry of Construction of Russia of February 7, 2014 N 39 / pr).

Electrical devices

Electrical devices

Annex 1.1. Commissioning structure

Appendix 1.1

Stages of work	Share, %, in total costs (rate)
Preparatory work
Adjustment work carried out before individual testing of process equipment
Adjustment work during the period of individual testing of technological equipment
Complex testing
Preparation of working and acceptance documentation

Annex 1.2. Terms and definitions used in FERP Part 1

Appendix 1.2

Term	Definition
switching device	An electrical device that cuts off the load current or removes the mains voltage (circuit breaker, load switch, separator, disconnector, knife switch, package switch, fuse, etc.).
local government	Control, in which the controls and switching devices are structurally located on the same panel or shield.
Remote control	Control, in which the controls and switching devices are structurally located on different panels or boards.
Secondary switching connection	Secondary circuit of control, signaling, voltage transformers, etc., limited by one group of fuses or automatic switch, as well as secondary circuit of current transformers of the same purpose (protection, measurement).
Primary switching connection	An electrical circuit (equipment and tires) of the same purpose, name and voltage, connected to the buses of a switchgear, generator, switchboard, assembly and located within the power station, substation, etc. Electrical circuits of different voltages (regardless of the number) of one power transformer. All switching devices and busbars by means of which a line or transformer is connected to a switchgear.
	A section of a two-, three- or four-wire electrical network
Device	A set of elements in a product made in a single design (for example: cabinet or control panel, relay protection panel, cell, power supply, etc.). The device may not have a specific functional purpose in the product.
Signaling section	Signal implementation device.
	Any element of the electrical circuit (potentiometer, resistor, capacitor, etc.), the parameter value of which requires regulation according to the manufacturer's instructions.
Functional group	A set of elements that perform a specific function in an automatic control or regulation system and are not combined into a single design (for example: a relay-contactor control circuit for an electric drive, a task node, a controller node, a dynamic compensation node, a linearization node, a node for generating a parameter of a certain functional dependence, etc. ).
The control apparatus as part of the relay contactor functional group	A relay element that performs the function of setting a coordinate or changing it according to a given control law (for example: a button, a control key, limit and limit switches, a contactor, a magnetic starter, a relay, etc.).
Automatic control system	An automatic control system in which the goal of control in static and dynamic modes is achieved by optimizing closed control loops.
Automatic control system	A set of functional groups that provide automatic change of one or more coordinates of the technological control object in order to achieve the specified values ​​of controlled variables or optimize a certain criterion of control quality.
Element of an automatic control or regulation system	A component of the circuit, which has a single design, a detachable connection, performs one or more specific functions in the product (amplification, conversion, generation, signal shaping) and requires verification on a stand or in a specially assembled circuit for compliance with the specifications or requirements of the manufacturer.
Technological object	The set of technological and electrical equipment and the technological process of production implemented on it.
Technological complex	A set of functionally interconnected means of technological equipment (aggregates, mechanisms and other equipment) for performing specified technological processes and operations under production conditions in order to carry out all stages of obtaining the quantity and quality of the final product established by the project.
Mechanism	A set of movably connected parts that perform specified movements under the action of applied forces.
	A set of two or more mechanisms operating in a complex and providing a given technological process of production.
Dispatch department	A set of mechanisms or electrical devices connected by a single technological cycle and a common control scheme.
Trial	The application of current or voltage to the object for the duration of the test, regulated by a regulatory document.
Test object	Independent current-carrying part of a cable, busbar, apparatus, transformer, generator, electric motor and other devices.
cable penetration	A conductive device designed to transmit electrical energy through special power and control cables through hermetic rooms or tight boxes of nuclear power plants.

Automated control systems

Annex 2.1. Categories of technical complexity of systems, their characteristics and coefficients (part 2 section 1)

Appendix 2.1

	Characteristics of the system (structure and composition of the KTS or KTS)	Coefficient system complexity
	Single-level information, control, information and control systems, characterized in that measuring and control devices, electromagnetic, semiconductor and other components, signal fittings, etc. .P. instrumental or hardware types of execution.
	Single-level information, control, information and control systems, characterized in that programmable logic controllers (PLC), intrasystem communication devices, microprocessor operator interfaces (panels display).
	Single-level systems with automatic mode of indirect or direct (direct) digital (digital-analog) control using object-oriented controllers with programming of settings parameters, the operation of which does not require the development of project MO and software.
	Information, control, information and control systems in which the composition and structure of the CTS meet the requirements established for classifying systems as category I of complexity and in which fiber-optic information transmission systems (FOTSI) are used as communication channels.
	Systems for measuring and (or) automatic control of the chemical composition and physical properties of a substance.
	Measuring systems (measuring channels) for which metrological certification (calibration) is required according to the project.
	Multilevel distributed information, control, information and control systems, in which the composition and structure of the local level CPTS meet the requirements established for classifying the system to the second category of complexity and in which process (PCS) or operator (OS) are used to organize subsequent levels of control stations implemented on the basis of problem-oriented software, connected to each other and to the local control level via local area networks.
	Information, control, information and control systems in which the composition and structure of the CPTS (CTS) meets the requirements established for classifying systems as category II of complexity and in which fiber-optic information transmission systems (FOTSI) are used as communication channels.
Notes: 1. Systems of II and III categories of technical complexity may have one or more features given as a characteristic of the system. 2. In the event that a complex system contains in its composition systems (subsystems), according to the structure and composition of the CPTS or CTS, related to different categories of technical complexity, the complexity factor of such a system is calculated in accordance with clause 2.2. Estimates of the volume of work.

Annex 2.2. Symbols for the number of channels (part 2 department 1)

Appendix 2.2

Symbol	Name
	Number of information analogue channels
	Number of information discrete channels
	Number of analog control channels
	Number of discrete control channels
	The total number of information analog and discrete channels
	Total number of analog and discrete control channels
	Total number of information and control channels analog and discrete

Appendix 2.3

Annex 2.3. Coefficient of "metrological complexity" of the system (part 2 department 1)

	Characterization of the factors of "metrological complexity" (M) of the system	Designation quantity channels	Coefficient "metrological complexity" of the system (M)
	Measuring transducers (sensors) and measuring instruments, etc., operating in normal environmental and technological environment, accuracy class:
	less than or equal to 1.0
	below 0.2 and above 1.0
	greater than or equal to 0.2
Note. If the system has measuring transducers (sensors) and measuring instruments belonging to different accuracy classes, the coefficient is calculated by the formula: Where:

Annex 2.4. Coefficient of "development of information functions" of the system (part 2 department 1)

Appendix 2.4

	Characteristics of the factors of "development of information functions" (I) of the system	Designation quantity channels	Coefficient "development information- rational functions" of the system (I)
	Parallel or centralized control and measurement of the parameters of the state of the technological control object (TOU).
	The same as according to claim 1, including archiving, documenting data, compiling emergency and production (shift, daily, etc.) reports, presenting parameter trends, indirect measurement (calculation) of individual complex indicators of the functioning of the TOU.
	Analysis and generalized assessment of the state of the process as a whole according to its model (recognition of the situation, diagnostics of emergency conditions, search for a bottleneck, forecast of the process).
Note. If the system has different characteristics of "development of information functions", the coefficient is calculated by the formula: Where:

Annex 2.5. Coefficient of "development of control functions" (part 2 department 1)

Appendix 2.5

	Characteristics of the factors of "development of control functions" (U) of the system	Designation of the number of channels	Coefficient of "development of control functions" of the system (U)
	Single-circuit automatic control (AR) or automatic single-cycle logic control (switching, blocking, etc.).
	Cascade and (or) software AP or automatic program logic control (APLC) on a "hard" cycle, multi-connected AP or APLC on a loop with branches.
	Control of fast processes in emergency conditions or control with adaptation (self-learning and changing algorithms and system parameters) or optimal control (OC) of steady state (in statics), OC of transients or the process as a whole (optimization in dynamics).
Notes. If the system has different characteristics of "development of control functions", the coefficient is calculated by the formula: Where:

Annex 2.6. Structure of commissioning works (part 2 department 1)

Appendix 2.6

	Name of the stages of commissioning	Share in the total cost of work, %
	Preparatory work, verification of TCP (PS):
	including preparatory work
	Offline system tuning
	Complex adjustment of systems
Notes: 1. The content of the work execution stages corresponds to clause 1.2.4. general provisions FERp. 2. In the event that the customer engages one organization to carry out commissioning work on software and hardware (for example, a project developer or equipment manufacturer that has the appropriate licenses to perform commissioning work), and on technical means - another commissioning organization, the distribution of the volumes of work performed their work (within the total cost of work on the system), including the stages in Appendix 2.6, is carried out, in agreement with the customer, taking into account the total number of channels related to the MTS and TS.

Annex 2.7. Channel groups (part 2 department 1)

Annex 2.7

	Channel group symbol
	KPTSTOU (KTS)	Control channels are analog and discrete ( and ) transfers of control actions from KPTS (KTS) to TOU. The number of control channels is determined by the number of actuators: membrane, piston, electric single- and multi-turn, motorless (cut-off), etc.
	TOUKPTS (KTS)	Channels analog and discrete information ( and ) conversion of information (parameters) coming from the technological control object (TOU) to the KPTS (KTS). The number of channels is determined by the number of measuring transducers, contact and non-contact signaling devices, equipment position and status sensors, limit and limit switches, etc., while the combined fire alarm sensor (POS) is counted as one discrete channel.
	OpKPTS (KTS)	Analogue and discrete information channels ( and ) used by the operator (Op) to influence the KTS (KTS). The number of channels is determined by the number of influence elements used by the operator (buttons, keys, control devices, etc.) for the implementation of the system operation in the modes of automated (automatic) and manual remote control of actuators without taking into account the influence elements of the KTS (CTS) as channels, used for tuning and other auxiliary functions (except for control): keyboard of terminal devices of information and control displays, buttons, switches, etc., panels of multifunctional or multi-channel devices of control panels of POS, etc., as well as voltage switches, fuses and other auxiliary bodies of influence of the above and other technical means, the adjustment of which is taken into account by the prices of the FERp part 2.
	KPTSOp (KTS)	Analog and discrete channels ( and ) for displaying information coming from the KTS (KTS) to the OP when determining the number of system channels are not taken into account, except when the project provides for displaying the same technological parameters (equipment status) on more than one terminal device (monitor, printer, interface panel, information board, etc.). Adjustment of displaying information on the first terminal device is taken into account FERp part 2. In this case, when displaying information on each terminal device in addition to the first, the displayed parameters ( and ) are taken into account with a coefficient of 0.025, with a coefficient of 0.01. Indicators (lamps, LEDs, etc.) of status and position built into measuring transducers (sensors), contact or non-contact signaling devices, buttons, control keys, switches, as well as indicators of the presence of voltage of devices, recorders, terminals are not taken into account as channels. devices of panels, consoles, etc., the adjustment of which is taken into account FERp part 2.
	sms N 1, N 2, …, N	Communication channels (interactions) analog and discrete information ( and ) with related systems, made on separate projects. "The number of physical channels through which communication signals (interactions) with adjacent systems are transmitted is taken into account: discrete - contact and contactless direct and alternating current (with the exception of coded ones) and analog signals, the values ​​of which are determined on a continuous scale, as well as, for the purposes of FERp, the part 2 coded (pulse and digital)". Different types of electrical system voltage used as power sources for APCS equipment (shields, consoles, actuators, information converters, terminal devices, etc.), as communication channels (interactions) with adjacent systems are not taken into account.

Annex 2.8. Scheme of an automated technological complex (ATC)

Appendix 2.8

Annex 2.9. AS complexity categories, taking into account the number of AS software functions (part 2 section 2)

Appendix 2.9

Number of speaker functions
St. 1 to 10
St. 10 to 49
St. 49 to 99

Annex 2.10. Coefficients taking into account the number of remote nuclear power plants (part 2 department 2)

Appendix 2.10

Number of territorially remote NPP locations	Coefficient

Annex 2.11. Coefficients taking into account the specifics of the implementation of the NPP commissioning

Appendix 2.11

	Name	Table number (rates)	Coefficient
	Availability of individual external battery sources of emergency power supply.	02-02-004, 02-02-005
	Implementation of commissioning under the technical guidance of the chief personnel of enterprises - manufacturers of the AU.	02-02-006, 02-02-007
	Fault-tolerant speakers. In the case of performing commissioning work on computer systems that have a classification sign of complexity as fault-tolerant complexes.	02-02-004, 02-02-007
	Disaster resistant speakers. In the case of performing commissioning work on computer systems that have a classification sign of complexity as disaster-proof complexes.	02-02-004, 02-02-007
	When re-conducting preliminary tests after the modernization of the AU.
	NPP architecture accounting factor, taking into account the specifics of the commissioning: For commissioning of the AU, using two or more processor server based on any architecture;
	For commissioning of AS using a server cluster based on any architecture.
	AC architecture accounting coefficient - for AC commissioning performed on servers of the Risc architecture.

________________
* total share coefficient

Annex 2.12. Terms and definitions used in FERP Part 2

Appendix 2.12

	Conditional designation	Definition
Automated system		1. A system consisting of personnel and a set of means for automating its activities, implementing information technology performance of established functions. 2. A set of mathematical and technical means, methods and techniques that are used to facilitate and speed up the solution of time-consuming tasks associated with information processing.
Automated process control system		An automated system that ensures the operation of an object due to the appropriate choice of control actions based on the use of processed information about the state of the object.
Automated technological complex		A set of jointly functioning technological control object (TOU) and the APCS controlling it.
Automatic indirect control mode when performing the APCS function		The mode of execution of the APCS function, in which the APCS automation tool complex automatically changes the settings and (or) settings of the local automation systems of the technological control object.
Automatic mode of direct (immediate) digital (or analog-to-digital) control when performing the control function of the process control system		The mode of execution of the APCS function, in which the APCS automation tool complex generates and implements control actions directly on the actuators of the technological control object.
Autonomous adjustment of speakers		The process of bringing the functions of the AU as a whole, their quantitative and (or) qualitative characteristics, into line with the documentation for the commissioning.
Basic software configuration		The set of software functions, due to the requirements of design solutions.
Basic software setup		The process of bringing software to a base configuration.
Measuring transducer (sensor), measuring device		Measuring devices designed to obtain information about the state of the process, designed to generate a signal that carries measurement information both in a form accessible to the direct perception of the operator (measuring devices), and in a form suitable for use in the process control system for the purpose of transmission and (or ) transformation, processing and storage, but not amenable to direct perception by the operator. To convert natural signals into unified ones, various normalizing converters are provided. Measuring transducers are divided into main groups: mechanical, electromechanical, thermal, electrochemical, optical, electronic and ionization. Measuring transducers are divided into transducers with natural, unified and discrete (relay) output signal (signaling devices), and measuring instruments - into devices with natural and unified input signal.
installation		The process of installing (porting) software onto hardware.
Interface (or I/O pairing)		A set of unified constructive, logical, physical conditions that technical means must satisfy in order to be able to connect them and exchange information between them. In accordance with the purpose, the interface includes: List of interaction signals and rules (protocols) for the exchange of these signals; Modules for receiving and transmitting signals and communication cables; Connectors, interface cards, blocks. The interfaces unify information, control, notification, address and status signals.
Information function of the automated control system		ACS function, including receiving information, processing and transmitting information to the ACS personnel or outside the system about the state of the TOU or external environment.
Information Support automated system		A set of forms of documents, classifiers, regulatory framework and implemented decisions on the volume, placement and forms of existence of information used in the AS during its operation.
Executive device		Actuating devices (ID) are designed to influence the technological process in accordance with the command information KPTS (KTS). The output parameter of the IU in the automated process control system is the consumption of matter or energy entering the TOU, and the input is the signal of the KTS (KTS). IN general case IU contain an actuator (IM): electric, pneumatic, hydraulic and control body (RO): throttling, dosing, manipulating. There are complete DUTs and systems: with an electric drive, with a pneumatic drive, with a hydraulic drive and auxiliary devices of the DUT (power amplifiers, magnetic starters, positioners, position indicators and control devices). To control some electrical devices (electric baths, large electric motors, etc.), the controlled parameter is the flow of electrical energy, and in this case, the role of the DUT is performed by the amplification unit.
Actuating mechanism
Regulatory body
Disaster-proof speakers		AS, consisting of two or more remote server systems functioning as a single complex using clustering and / or load balancing technologies. The server and supporting equipment is located at a considerable distance from each other (from units to hundreds of kilometers).
Comprehensive adjustment of speakers		The process of bringing NPP functions, their quantitative and (or) qualitative characteristics in line with the requirements of the TOR and project documentation, as well as identifying and eliminating shortcomings in the operation of systems. Comprehensive adjustment of the AU consists in working out information exchange speakers with external objects.
Configuration (computer system)		The set of functional parts of a computer system and the connections between them, due to the main characteristics of these functional parts, as well as the characteristics of the data processing tasks being solved.
Configuration		Configuration setting.
Indirect measurement (calculation) of individual complex indicators of the functioning of TOU		Indirect automatic measurement (calculation) is performed by converting a set of partial measured values ​​into a resulting (complex) measured value using functional transformations and subsequent direct measurement of the resulting measured value, or by direct measurement of partial measured values, followed by automatic calculation of the values ​​of the resulting (complex) measured value by results of direct measurements.
Mathematical support of the automated system		A set of mathematical methods, models and algorithms used in AS.
Metrological certification (calibration) of measuring channels (MC) of APCS		MC must have metrological characteristics that meet the requirements of accuracy standards, the maximum permissible errors. IC APCS are subject to state or departmental certification. The type of metrological certification must correspond to that established in the terms of reference for the process control system. The IC APCS are subject to state metrological certification, the measurement information of which is intended for: Use in commodity-commercial transactions; Accounting material assets; Protecting the health of workers, ensuring safe and harmless working conditions. All other MCs are subject to departmental metrological certification.
Multilevel process control system		APCS, which includes APCS of different levels of hierarchy as components.
General automated system software		Part of the AS software, which is a collection software tools developed out of connection with the creation of this AS.
Single-level process control system		APCS, which does not include other, smaller APCS.
Optimal control		Control that provides the most advantageous value of a certain optimality criterion (OC), which characterizes the effectiveness of control under given constraints. Various technical or economic indicators: Transition time (performance) of the system from one state to another; Some indicator of product quality, the cost of raw materials or energy, etc. OU example: In furnaces for heating blanks for rolling, by optimally changing the temperature in the heating zones, it is possible to ensure the minimum value of the root-mean-square deviation of the heating temperature of the processed blanks with a change in the rate of their advancement, dimensions, and thermal conductivity.
Experimental operation of the AU		Putting the NPP into operation in order to determine the actual values ​​of the quantitative and qualitative characteristics of the NPP and the readiness of personnel to work in the conditions of the operation of the NPP, determine the actual efficiency of the NPP, and adjust (if necessary) documentation.
Failsafe AC		AS, providing the possibility of functioning of applied software and / or network services of systems with medium criticality, i.e. such systems, the maximum recovery time for which should not exceed 6-12 hours.
Parameter		An analog or discrete value that takes on various values ​​and characterizes either the state of the ATC, or the process of functioning of the ATC, or its results. Example: temperature in the working space of the furnace, pressure under the top, coolant flow rate, shaft rotation speed, terminal voltage, calcium oxide content in raw meal, signal for assessing the condition of the mechanism (unit), etc.
Preliminary tests of the AU		The processes of determining the operability of the NPP and making a decision on the possibility of accepting the NPP for trial operation. They are performed after the developer debugs and tests the supplied software and hardware of the system, as well as the NPP components and provides them with the relevant documents on their readiness for testing, as well as after familiarization of the NPP personnel with the operational documentation.
AC acceptance tests		The process of determining the compliance of the NPP with the terms of reference, assessing the quality of trial operation and deciding whether it is possible to accept the NPP for permanent operation, including checking: the completeness and quality of the implementation of functions at standard, limiting, critical values ​​of the parameters of the automation object and in other operating conditions of the NPP specified in TK; fulfilling each requirement related to the system interface; work of personnel in a dialogue mode; means and methods for restoring the operability of the AU after failures; completeness and quality of operational documentation. An error has occurred The payment was not completed due to a technical error, cash from your account were not written off. Try to wait a few minutes and repeat the payment again.

STATE ESTIMATE STANDARDS

FERp 81-05-2001-I2

FEDERAL UNIT RATES
FOR COMMISSIONING

FERp-2001

CHANGES,
WHICH ARE INCLUDED IN THE STATE ESTIMATES
REGULATIONS. FEDERAL UNIT RATES
FOR COMMISSIONING

Moscow 2010

“Changes that are being made to state budgeting standards. Federal unit prices for commissioning” contain changes and additions to the federal unit prices approved by order of the Ministry regional development Russian Federation dated August 4, 2009 No. 321 “On approval of state estimated standards for the installation of equipment, overhaul equipment and commissioning.

DEVELOPEDFederal Center for Pricing in Construction and Building Materials Industry

APPROVEDby order of the Ministry of Regional Development of the Russian Federation dated December 21, 2010 No.№ 747

CHANGES THAT ARE INTRODUCED TO THE STATE
ESTIMATE NORMATIVES. FEDERAL UNIT RATES
FOR COMMISSIONING

In the section " I . General Provisions" to make the following changes and additions:

Paragraphs 1.2, 1.2.1, 1.2.2, 1.2.3, 1.2.4, 1.2.5, 1.2.6, 1.2.7 shall be stated as follows:

1.2. FERP part 2 "Automated control systems" are designed to determine the cost of commissioning for the commissioning of automated control systems.

1.2.1. FERP Part 2 applies to:

automated process control systems (APCS);

centralized operational dispatch control systems;

automatic fire and security fire alarm systems;

control and automatic control systems for fire extinguishing and smoke protection;

telemechanical systems;

computer hardware and software, in terms of software installation and configuration.

FERP parts 2 of department 1 are not intended to determine direct costs in the estimated cost of work:

on precision in-line analyzers of physical and chemical properties of media and products circulating in the technological process: refractometers, chromatographs, octanometers and other similar single-use analyzers;

for video surveillance (security) systems using television installations, loud-speaking communications (alerts), etc., the direct costs of which are determined by FERm, Part 10 "Communication Equipment".

1.2.2. Part 2 pricing is based on the following conditions:

complexes of software and hardware tools (KHTS) or complexes of hardware (HH) transferred for adjustment - serial, complete, with loaded system and application software, provided with technical documentation (passports, certificates, etc.), their shelf life is warehouse does not exceed the standard;

commissioning works are carried out on the basis of the working documentation approved by the customer, if necessary, taking into account the project for the production of works (PP P ), programs and graphics;

by the start of the commissioning organization, the customer transferred the working design documentation, including parts of the APCS project:

mathematical software (MO), information software (IO), software (SW), organizational software (OO);

start-up and commissioning works are started if the customer has documents on the completion of installation work. In the event of forced breaks between installation and commissioning work for reasons beyond the control of the contractor, commissioning work is started after checking the safety of previously installed and installation of previously dismantled technical means (in this case, the act of completion of installation work is drawn up again on the start date of commissioning);

switching modes of operation of technological equipment are carried out by the customer in accordance with the project, regulations and within the periods provided for by the agreed programs and work schedules;

detected defects in the installation of software and hardware (PTS) or hardware (TS) are eliminated by the installation organization.

1.2.3. FERp part 2 are developed in accordance with the requirements of state standards, rules for the construction of electrical installations, intersectoral labor protection rules (safety rules) for the operation of electrical installations, safety rules for gas distribution and gas consumption systems, general explosion safety rules for explosive chemical, petrochemical and oil refining industries and other rules and norms of state supervision bodies, technical documentation of manufacturers of the TCP or TS, instructions, technical and technological regulations, guiding technical materials and other technical documentation for the installation, commissioning and operation of the TCP and TS.

1.2.4. Part 2 prices department 1 the costs for the production of a complex of works of one technological cycle of commissioning for the commissioning of the process control system in accordance with the requirements of regulatory and technical documentation, including the following stages (stages):

1.2.4.1. Preparatory work, verification of KTS (KTS) of automated systems:

study of working and technical documentation, incl. materials of the pre-project stage (technical requirements for the system, etc.), the implementation of other measures of engineering and technical preparation of work, inspection of the technological control object, external inspection of the equipment and installation work performed on the APCS, determination of the readiness of systems adjacent to the APCS (power supply, etc.). etc.), etc.

verification of compliance of the main technical characteristics of the equipment with the requirements established in the passports and instructions of manufacturers (the results of verification and adjustment are recorded in the act or passport of the equipment, faulty PTS or TS are transferred to the customer for repair and replacement).

1.2.4.2. Autonomous adjustment of automated systems after completion of their installation:

checking the installation of the PTS (TS) for compliance with the requirements of the instructions of manufacturers and working documentation;

replacement of individual defective elements with serviceable ones issued by the customer;

checking the correctness of marking, connection and phasing of electrical wiring;

phasing and control of the characteristics of actuators (IM);

setting up logical and temporal interconnections of signaling, protection, blocking and control systems, checking the correctness of the passage of signals;

checking the functioning of application and system software;

preliminary determination of the characteristics of the object, calculation and adjustment of the parameters of the equipment of automated systems, configuration of measuring transducers and software logic devices;

preparation for inclusion and inclusion in the operation of measurement, control systems And control to ensure individual testing of technological equipment and adjustment of the settings of the equipment of control systems in the course of their operation;

registration of production and technical documentation.

1.2.4.3. Complex adjustment of automated systems:

bringing the settings of the PTS (TS), communication channels and application software to values ​​(states) at which automated systems can be used in operation, while being carried out in a complex:

determination of the compliance of the procedure for testing devices and elements of signaling, protection and control systems with the algorithms of working documentation with the identification of the causes of failure or their “false” operation, setting the necessary values ​​for the operation of positional devices;

determination of the compliance of the flow capacity of the shut-off and control valves with the requirements of the technological process, the correct development of limit and limit switches, position and status sensors;

determination of the flow characteristics of regulatory bodies (RO) and bringing them to the required rate using the adjustment elements available in the design;

clarification of the static and dynamic characteristics of the object, adjustment of the values ​​of the system settings, taking into account their mutual influence in the process of work;

preparation for the inclusion in the operation of systems to ensure the comprehensive testing of technological equipment;

test and suitability automated systems to ensure the operation of process equipment with a capacity that meets the standards for the development of design capacities in the initial period;

analysis of the work of automated systems;

registration of production documentation, act of acceptance into operation of systems;

making changes in one copy of the circuit diagrams from the set of working documentation, agreed with the customer, based on the results of commissioning.

1.2.5. Part 2 prices department 1 costs for: commissioning works are not taken into account, the prices for which are given in

relevant sections of FERp Part 1 "Electrical Devices": on electric machines (motors) of electric drives, switching devices, static converters, power devices, measurements and tests in electrical installations;

testing of automated systems in excess of 24 hours of their operation during the period of complex testing of technological equipment;

drawing up a technical report and estimate documentation;

delivery of measuring instruments for state verification;

configuration of components and screen forms, correction and completion of design mathematical, information and software, defined on the basis of standards for design work;

revision of the TCP (TS), elimination of their defects (repair) and installation defects, including bringing the insulation of electrical equipment, cable communication lines and the parameters of the installed fiber-optic and other communication lines to the standards;

checking the compliance of wiring diagrams with circuit diagrams and making changes to wiring diagrams;

preparation of principal, assembly, detailed diagrams and drawings;

partial or complete reassembly of cabinets, panels, consoles;

carrying out physico-technical and chemical analyzes, supply of exemplary mixtures, etc.;

drawing up a program of complex testing of technological equipment;

training of operating personnel;

development of operational documentation;

technical (service) maintenance and periodic checks of the KPTS (KTS) during the operation period.

1.2.6. Part pricing 2 departments 1 developed for automated systems (hereinafter referred to as systems) depending on the category of their technical complexity, characterized by the structure and composition of the CPTS (CTS).

1.2.7. Part pricing 2 department 1 designed for systems I, II and III category of technical complexity depending on the number of communication channels for the formation of input and output signals.

The communication channel for the formation of input and output signals (hereinafter referred to as the channel) includes a set of technical means and communication lines that provide transformation, processing and transmission of information for use in the system.

The prices take into account the number of channels:

informational (including channels for measurement, control, notification, address, status, etc.);

management.

The composition of information and control channels, in turn, takes into account the number of channels:

discrete - contact and non-contact on alternating and direct current, pulsed from discrete (signaling) measuring transducers, for monitoring the status of various on-off devices, as well as for transmitting “on-off” signals, etc .;

analog, which include (for the purposes of FERP Part 2 department 1) all the rest - current, voltage, frequency, mutual inductance, natural or unified signals of measuring transducers (sensors) that change continuously, coded (pulse or digital) signals for information exchange between various digital information processing devices, etc.

In the following, the conventions for the number of channels given in Appendix 2.2 are used.

Add section " I . General Provisions” by paragraphs 1.2.8, 1.2.9, 1.2.10, 1.2.11 as follows:

1.2.8. The prices of part 2 of department 2 take into account the costs of the following independent completed commissioning processes:

installation and basic configuration of general and special AS software;

functional setting of general and special AS software;

autonomous adjustment of speakers;

complex adjustment of the AU;

carrying out preliminary and acceptance tests of the AU.

1.2.9. The prices of part 2 of department 2 do not include the costs of:

work on the revision of hardware, elimination of their defects and installation defects, imperfections in construction and installation works;

design work;

repeated tests;

development of operational and budget documentation;

trial operation;

delivery of measuring instruments for state verification;

coordination of work performed with supervisory authorities;

maintenance and Maintenance TS during the period of commissioning.

1.2.10. Division 2 Part 2 rates are designed for systems I, II, IIIAndIVcategory of technical complexity, depending on the number of software functions used to create the AS.

1.2.11. The terms and definitions used in FERP Part 2 are given in Annex 2.12.

The following amendments and additions shall be made to the Federal unit prices for commissioning:

Rate numbers	Name and technical characteristics of equipment		Direct costs (compensation of commissioning personnel), rub.	Labor costs man-hours
Part 2 "AUTOMATED CONTROL SYSTEMS" supplement with department 02 tables 02-02-001, 02-02-002, 02-02-003, 02-02-004,02-02-005,02-02-006, 02-02-007
DEPARTMENT 02. COMPUTER HARDWARE AND SOFTWARE Table 02-02-001. Installation and basic configuration of general and special software Meter: 1 installation
02-02-001-01		Installation and basic configuration of general and special software	39,10	2,49
Table 02-02-002. Functional setting of general AC software Meter: 1 function
02-02-002-01		Functional setting of general AC software, number of functions - 1	61,30
Table 02-02-003. Functional setting of the dedicated AC software Meter: 1 function
02-02-003-01		Functional setting of special AC software, number of functions - 1	43,39	2,76
Table 02-02-004. Autonomous adjustment of speakers Meter: 1 system
Autonomous adjustment of speakers:
02-02-004-01		I difficulty category	82,39	5,25
02-02-004-02		II difficulty category	371,67	23,63
02-02-004-03		III difficulty category	743,39	47,28
02-02-004-04		IV difficulty category	1486,84	94.56
Table 02-02-005. Comprehensive adjustment of speakers Meter: 1 system
Comprehensive adjustment of speakers:
02-02-005-01		I difficulty category	70,76
02-02-005-02		II difficulty category	353,78	22,5
02-02-005-03		III difficulty category	703,66	45,01
02-02-005-04		IV difficulty category	1415,77	90,04
Table 02-02-006. Preliminary tests of the AU Meter: 1 system
Preliminary tests of the AU:
02-02-006-01		I difficulty category	100,01	6,37
02-02-006-02		II difficulty category	500,56	31,85
02-02-006-03		III difficulty category	1000,78	63,68
02-02-006-04		IV difficulty category	1962,68	127,34
Table 02-02-007. AC acceptance tests Meter: 1 system
AC acceptance tests:
02-02-007-01		I difficulty category	189,84	12,07
02-02-007-02		II difficulty category	949,22	60,37
02-02-007-03		III difficulty category	1897,99	120,74
02-02-007-04		IV difficulty category	3796,30	241,45

In the section " IV . Applications" the following changes and additions were made:

Appendices 2.1-2.7 shall be stated as follows:

Automated control systems

Appendix 2.1

	Characteristics of the system (structure and composition of the KTS or KTS)	System complexity factor
	Single-level information, control, information and control systems, characterized in that measuring and control devices, electromagnetic, semiconductor and other components, signal fittings, etc. .P. instrumental or hardware types of execution
	Single-level information, control, information - control systems, characterized in that programmable logic controllers (PLC), intrasystem communication devices, microprocessor operator interfaces (panels display)
	Single-level systems with automatic mode of indirect or direct (direct) digital (digital-analog) control using object-oriented controllers with programming of settings parameters, the operation of which does not require the development of project MO and software
	Information, control, information and control systems in which the composition and structure of the CTS meet the requirements established for classifying systems as category I of complexity and in which fiber-optic information transmission systems (FOTS) are used as communication channels
	Measuring systems (measuring channels) for which metrological certification (calibration) is required according to the project
	Multi-level distributed information, control, information and control systems, in which the composition and structure of the local level CPTS meet the requirements established for classifying the system to the second category of complexity and in which process (PCS) or operator (OS) are used to organize subsequent levels of control stations implemented on the basis of problem-oriented software, interconnected and with the local control level via local area networks
	Information, control, information - control systems, in which the composition and structure of the CPTS (CTS) meets the requirements established for classifying systems as category II of complexity and in which fiber-optic information transmission systems (FOTSI) are used as communication channels

Notes:

2. In the event that a complex system contains in its composition systems (subsystems) that, according to the structure and composition of the CPTS or CTS, are attributed to different categories of technical complexity, the complexity factor of such a system is calculated in accordance with clause 2.2. Estimates of the volume of work

Appendix 2.2

Symbols for the number of channels (part 2 department 1)

Symbol	Name
	Number of information analogue channels
	Number of information discrete channels
	Number of analog control channels
	Number of discrete control channels
	The total number of information analog and discrete channels
	Total number of analog and discrete control channels
	Total number of information and control channels analog and discrete

Appendix 2.3

The coefficient of "metrological complexity" of the system (part of 2 department 1)

	Characteristics of the factors of "metrological complexity" (M) systems		The coefficient of "metrological complexity" of the system (M)
	Measuring transducers (sensors) and measuring instruments, etc., operating in normal environmental and technological environment, accuracy class:
	below or equal 1,0
	below 0,2 and higher 1,0
	greater than or equal 0,2

Note.

If the system has measuring transducers (sensors) and measuring instruments belonging to different accuracy classes, the M coefficient is calculated by the formula:

where:

(4.1)

Appendix 2.4

Coefficient of "development of information functions" of the system (part 2 department 1)

	Characteristics of the factors of "development of information functions" (I) of the system	Designation of the number of channels	Coefficient of "development of Information functions" of the system (AND)
	Parallel or centralized control and measurement of the parameters of the state of the technological control object (TOU)
	The same as according to clause 1, including archiving, documenting data, compiling emergency and production (shift, daily, etc.) reports, presenting parameter trends, indirect measurement (calculation) of individual complex indicators of the functioning of the TOU
	Analysis and generalized assessment of the state of the process as a whole according to its model (recognition of the situation, diagnostics of emergency conditions, search for a bottleneck, forecast of the process)

Notes.

If the system has different characteristics of the “development of information functions”, the I coefficient is calculated by the formula:

where:

(5.1)

Appendix 2.5

The coefficient of "development of control functions" (part 2 department 1)

	Characteristics of the factors of "development of control functions" (U) systems	Designation of the number of channels	Coefficient of "development of control functions" of the system (U)
	Single-circuit automatic control (AR) or automatic single-cycle logic control (switching, blocking, etc.).
	Cascade and (or) software AP or automatic program logic control (ALLU) on a "hard" cycle, multi-connected AP or APLU on a loop with branches.
	Control of fast processes in emergency conditions or control with adaptation (self-learning and changing algorithms and system parameters) or optimal control (OC) of steady state (in statics), OC of transients or the process as a whole (optimization in dynamics).

Notes.

If the system has different characteristics of "development of control functions", the Y coefficient is calculated by the formula:

where:

(7.1)

Appendix 2.6

Structure of commissioning works (part 2 department 1)

	Name of the stages of commissioning	Share in the total cost of work, %
	Preparatory work, verification of TCP (PS):
	including preparatory work
	Offline system tuning
	Complex adjustment of systems

Notes:

2. In the event that the customer engages one organization to carry out commissioning work on software and hardware (for example, a project developer or equipment manufacturer that has the appropriate licenses to perform commissioning work), and on technical means - another commissioning organization, the distribution of the volumes of work performed their work (within the total cost of work on the system), including the stages in Appendix 2.6, is carried out, in agreement with the customer, taking into account the total number of channels related to the MTS and TS.

Annex 2.7

Channel groups (part 2 department 1)

	Channel group symbol
	KPTS→TOU (KTS)	Control channels analog and discrete transmission of control actions from KPTS (KTS) to TOU. The number of control channels is determined by the number of actuators: membrane, piston, electric single- and multi-turn, motorless (cut-off), etc.
	TOU→KPTS (KTS)	Transformation of information (parameters) coming from the technological control object (TOU) to the KPTS (KTS). The number of channels is determined by the number of measuring transducers, contact and non-contact signaling devices, position and equipment status sensors, limit and travel switches, etc. in this case, the combined fire alarm sensor (POS) is counted as one discrete channel
	Op→KPTS (KTS)	Analogue and discrete information channels used by the operator (Op) to influence the KTS (KTS). The number of channels is determined by the number of influence elements used by the operator (buttons, keys, control devices, etc.) for the implementation of the system operation in the modes of automated (automatic) and manual remote control of actuators without taking into account the influence elements of the KTS (CTS) as channels, used for tuning and other auxiliary functions (except for control): keyboard of terminal devices of information and control displays, buttons, switches, etc., panels of multifunctional or multi-channel devices of control panels of POS, etc., as well as voltage switches, fuses and other auxiliary bodies of influence of the above and other technical means, the adjustment of which is taken into account by the prices of the FERp part 2.
	KPTS→Op (KTS)	Analogue and discrete channels for displaying information coming from the KTS (KTS) to the OP when determining the number of system channels are not taken into account, except when the project provides for the display of the same technological parameters (equipment status) on more than one terminal device (monitor, printer, interface panel, bulletin board, etc.). Adjustment of information displays on the first terminal device is taken into account by FERp of part 2. In this case, when displaying information on each terminal device in addition to the first, the displayed parameters are taken into account with a coefficient of 0.025, with a coefficient of 0.01. Indicators (lamps, LEDs, etc.) of status and position built into measuring transducers (sensors), contact or non-contact signaling devices, buttons, control keys, switches, as well as indicators of the presence of voltage of devices, recorders, terminals are not taken into account as channels. devices of panels, consoles, etc., the adjustment of which is taken into account by the FERp of part 2.
	sms № 1, № 2, ..., № i	Communication channels (interactions) analog and discrete information with related systems, made on separate projects. “The number of physical channels through which communication signals (interactions) with adjacent systems are transmitted is taken into account: discrete - contact and non-contact direct and alternating current (with the exception of coded ones) and analog signals, the values ​​​​of which are determined on a continuous scale, as well as, for the purposes of the FERp part 2, coded (pulse and digital)". Various types of electrical system voltage used as power sources for APCS equipment (shields, consoles, actuators, information converters, terminal devices, etc.) as communication channels (interactions) with adjacent systems are not taken into account.

Appendix 2.9 shall be stated as follows:

Appendix 2.9

Supplement with annexes 2.10-2.12:

Appendix 2.10

Coefficients taking into account the number of remote nuclear power plants (part 2 department 2)

Appendix 2.11

Coefficients taking into account the specifics of the implementation of the NPP commissioning

	Name	Table number (rates)	Coefficient
	Availability of individual external battery sources of emergency power supply.
	Implementation of commissioning activities under the technical supervision of the chief personnel of the AU manufacturers.
	Fault-tolerant speakers. In the case of performing commissioning work on computer systems that have a classification sign of complexity as fault-tolerant complexes.
	Disaster resistant speakers. In the case of performing commissioning work on computer systems that have a classification sign of complexity as disaster-proof complexes.
	When re-conducting preliminary tests after the modernization of the AU.
	Accounting factor for NPP architecture, taking into account the specifics of the commissioning For commissioning of the AU, using two or more processor server based on any architecture;
	For commissioning of AS using a server cluster based on any architecture
	AC architecture accounting coefficient, - for AC commissioning performed on Rise-architecture servers.	02-02-001(*)

(*) total share coefficient

Appendix 2.12

Terms and definitions used in FERP Part 2

	Symbol	Definition
Automated system	AC	1. A system consisting of personnel and a set of means for automating its activities, implementing information technology for performing established functions 2. A set of mathematical and technical means, methods and techniques that are used to facilitate and speed up the solution of time-consuming tasks associated with information processing.
Automated process control system	APCS	An automated system that ensures the operation of an object due to the appropriate choice of control actions based on the use of processed information about the state of the object
Automated technological complex		The set of jointly functioning technological control object (TOU) and the process control system that controls it
Automatic mode of indirect control when performing the APCS function		The mode of execution of the APCS function, in which the APCS automation tool complex automatically changes the settings and (or) settings of the local automation systems of the technological control object.
Automatic mode of direct (immediate) digital (or analog-to-digital) control when performing the control function of the process control system		The mode of execution of the APCS function, in which the APCS automation tool complex generates and implements control actions directly on the actuators of the technological control object.
Autonomous adjustment of speakers		The process of bringing the functions of the nuclear power plant as a whole, their quantitative and (or) qualitative characteristics, into line with the documentation for the commissioning.
Basic software configuration		The set of software functions, due to the requirements of design solutions
Basic software setup		The process of bringing the software to the base configuration
Measuring transducer (sensor), measuring device		Measuring devices designed to obtain information about the state of the process, designed to generate a signal that carries measurement information both in a form accessible to the direct perception of the operator (measuring devices), and in a form suitable for use in the process control system for the purpose of transmission and (or ) transformation, processing and storage, but not amenable to direct perception by the operator. To convert natural signals into unified ones, various normalizing converters are provided. Measuring transducers are divided into main groups: mechanical, electromechanical, thermal, electrochemical, optical, electronic and ionization. Measuring transducers are divided into transducers with natural, unified and discrete (relay) output signal (signaling devices), and measuring instruments - into devices with natural and unified input signal.
installation		The process of installing (porting) software onto hardware.
Interface (or input-output interface)		A set of unified constructive, logical, physical conditions that technical means must satisfy in order to be able to connect them and exchange information between them. In accordance with the purpose, the interface includes: a list of interaction signals and rules (protocols) for the exchange of these signals; modules for receiving and transmitting signals and communication cables; connectors, interface cards, blocks; The interfaces unify information, control, notification, address and status signals.
Information function of the automated control system		ACS function, including receiving information, processing and transmitting information to the ACS personnel or outside the system about the state of the TOU or the external environment
Information support of the automated system		A set of forms of documents, classifiers, regulatory framework and implemented decisions on the volume, placement and forms of existence of information used in the AS during its operation
Executive device Actuating mechanism Regulatory body	PS THEM RO	Actuating devices (ID) are designed to influence the technological process in accordance with the command information KPTS (KTS). The output parameter of the IU in the automated process control system is the consumption of matter or energy entering the TOU, and the input is the signal of the KTS (KTS). In the general case, MDs contain an actuator (IM): electric, pneumatic, hydraulic and control body (RO): throttling, dosing, manipulating. There are complete DUTs and systems: with an electric drive, with a pneumatic drive, from hydraulic drive and auxiliary devices of the IU (power amplifiers, magnetic starters, positioners, position indicators and control devices). To control some electrical devices (electric baths, large electric motors, etc.), the controlled parameter is the flow of electrical energy, and in this case, the role of the DUT is performed by the amplification unit.
Disaster-proof speakers		AS, consisting of two or more remote server systems functioning as a single complex using clustering and/or load balancing technologies. The server and supporting equipment is located at a considerable distance from each other (from units to hundreds of kilometers).
Comprehensive adjustment of speakers	book	The process of bringing NPP functions, their quantitative and (or) qualitative characteristics in line with the requirements of the TOR and project documentation, as well as identifying and eliminating shortcomings in the operation of systems. Comprehensive adjustment of the AU consists in working out the information interaction of the AU with external objects.
Configuration (computer system)		The totality of the functional parts of the computer system and the links between them, due to the main characteristics of these functional parts, as well as the characteristics of the data processing tasks being solved.
Configuration		Configuration setting.
Indirect measurement (calculation) of individual complex indicators of the functioning of TOU		Indirect automatic measurement (calculation) is performed by converting a set of partial measured values ​​into a resulting (complex) measured value using functional transformations and subsequent direct measurement of the resulting measured value, or by direct measurement of partial measured values, followed by automatic calculation of the values ​​of the resulting (complex) measured value by results of direct measurements.
Mathematical support of the automated system		A set of mathematical methods, models and algorithms used in AS
Metrological certification (calibration) of measuring channels (MC) APCS		MC must have metrological characteristics that meet the requirements of accuracy standards, the maximum permissible errors. IC APCS are subject to state or departmental certification. The type of metrological certification must correspond to that established in the terms of reference for the process control system. EC APCS are subject to state metrological certification, the measurement information of which is intended for: use in commodity-commercial transactions; accounting of material assets; protecting the health of workers, ensuring safe and harmless working conditions. All other MCs are subject to departmental metrological certification.
Multilevel process control system		APCS, which includes APCS of different levels of hierarchy as components.
General automated system software		Part of the AS software, which is a set of software developed outside of connection with the creation of this AS
Single-level process control system		A process control system that does not include other, smaller process control systems.
Optimal control	OU	Control that provides the most advantageous value of a certain optimality criterion (OC), which characterizes the effectiveness of control under given constraints. Various technical or economic indicators can be selected as KOs: transition time (performance) of the system from one state to another; some indicator of product quality, the cost of raw materials or energy resources, etc. DT example: In furnaces for heating workpieces for rolling, by optimally changing the temperature in the heating zones, it is possible to ensure the minimum value of the root-mean-square deviation of the heating temperature of the processed workpieces with a change in the rate of their advancement, size and thermal conductivity.
Experimental operation of the AU		AC input into action in order to determine the actual values ​​of the quantitative and qualitative characteristics of the NPP and the readiness of personnel to work in the conditions of the operation of the NPP, determine the actual efficiency of the NPP, and correct (if necessary) documentation.
Failsafe AC		AS, providing the possibility of functioning of applied software and / or network services of systems with medium criticality, i.e. such systems, the maximum recovery time for which should not exceed 6-12 hours.
Parameter		An analog or discrete value that takes on various values ​​and characterizes either the state of the ATC, or the process of functioning of the ATC, or its results. Example: temperature in the working space of the furnace, half-furnace pressure, coolant flow rate, shaft rotation speed, terminal voltage, calcium oxide content in raw meal, signal for assessing the condition of the mechanism (unit), etc.
Preliminary tests of the AU		The processes of determining the operability of the NPP and making a decision on the possibility of accepting the NPP for trial operation. They are carried out after the developer debugs and tests the supplied software and hardware of the system, as well as the NPP components and provides them with the relevant documents on their readiness for testing, as well as after familiarization of the NPP personnel with the operational documentation.
AC acceptance tests		The process of determining the compliance of the NPP with the terms of reference, assessing the quality of trial operation and deciding whether it is possible to accept the NPP for permanent operation, including checking: the completeness and quality of the implementation of functions at standard, limiting, critical values ​​of the parameters of the automation object and in other operating conditions of the NPP specified in TK; fulfilling each requirement related to the system interface; work of personnel in a dialogue mode; means and methods for restoring the operability of the AU after failures; completeness and quality of operational documentation.
Software		A set of programs on data carriers and program documents intended for debugging, operation and testing of the software.
Working software configuration		The set of software functions, due to the requirements of the agreed documentation
Software regulation		Regulation of one or more quantities that determine the state of the object, according to predetermined laws in the form of functions of time or some system parameter. Example. A hardening furnace in which the temperature, as a function of time, changes during the hardening process according to a predetermined program.
Multi-connected automatic control system (AR)		An AP system with several controlled variables interconnected through a regulated object, regulator or load. Example: Object - steam boiler: input values ​​- water supply, fuel. steam consumption; output values ​​- pressure, temperature, water level.
Systems for measuring and (or) automatic control of the chemical composition and physical properties of a substance		Measured medium and measured value for determining the chemical composition of substances: examples of measured values for gaseous environments are: concentration of oxygen, carbon dioxide, ammonia, CO + CO2 + H2 (off-gases from blast furnaces), etc., for liquid environments: electrical conductivity of solutions, salts, alkalis, concentration of aqueous suspensions, water salinity, pH, cyanide content, etc. The measured value and the investigated medium for determining the physical properties of a substance: Example measured value for water and solids: humidity, for liquid and pulp- density, for water- turbidity, for lubricating oils- viscosity, etc.
Special software automated system		Part of the AS software, which is a set of programs developed during / for the creation / (I) of this AS.
Telemechanical system		Telemechanics combines the means of automatic transmission over a distance of control commands and information about the state of objects using special transformations for the effective use of communication channels. Telemechanics provide information exchange between the objects of control and the operator (dispatcher), or between objects and KPTS. The set of devices of the control point (CP), devices of the controlled point (CP) and devices intended for the exchange of information through the communication channel between the CP and the CP forms a complex of telemechanics devices. A telemechanical system is a combination of a complex of telemechanics devices, sensors, information processing tools, dispatching equipment and communication channels that perform the complete task of centralized control and management of geographically dispersed objects. For the formation of control commands and communication with the operator, the telemechanical system also includes information processing tools based on the KPTS.
Terminal		1. A device for user or operator interaction with a computer system. The terminal consists of two relatively independent devices: input (keyboard) and output (screen or printer). 2. In a local area network, a device that is a source or recipient of data.
Technological control object		The control object, including technological equipment and the technological process implemented in it
Remote property		Separately standing building, in which the modules of the hardware-software complex are installed, physically located remotely from the location of other modules of the hardware-software complex
control function automated control system		ACS function, including obtaining information about the state of the TOU, evaluating information, choosing control actions and their implementation
Information display devices	IOI	Technical means used to transmit information to a person - an operator. IoIs are divided into two large groups: local or centralized representation of information, which can coexist in the system in parallel (simultaneously) or only centralized representation of information is used. IS are classified according to the forms of presentation of information into: signaling (light, mnemonic, sound); showing (analogue and digital); registering for direct perception (alphanumeric and diagrammatic) and with coded information (on magnetic or paper media); screen (display): alphanumeric, graphic, combined. Depending on the nature of the formation of local and target screen fragments, the tools of the specified type are divided into universal (fragments of an arbitrary fragment structure) and specialized (fragments of an unchanged form with an intermediate carrier of the fragment structure). In relation to automated process control systems, fragments can carry information about the current state of the technological process, about the presence of disorder in the process of functioning of an automated technological complex, etc.
Functional setting of the software		The process of bringing the software to a working configuration
Function		Function - a software function used to achieve the requirements for the AU and aimed at performing a specific task of the AU, described in the design decisions. The calculations take into account only the functions achieved by purposeful manual action in the process of setting up the AS software described in the design solutions. Functions that are implemented automatically when setting up the AU (during the software installation or present by default) and do not require the participation of a service technician are not included in the calculations
Human Operator		Personnel directly managing the facility

MINISTRY OF REGIONAL DEVELOPMENT OF THE RUSSIAN FEDERATION

ORDER

On amendments to the order of the Ministry of Regional Development
Russian Federation dated August 4, 2009№ 321 "About approval
state estimated standards for the installation of equipment,
overhaul of equipment and commissioning"

In order to update state estimated standards in the field of estimated rationing and pricing in the field of urban planning in accordance with the Regulations on the Ministry of Regional Development of the Russian Federation, approved by Decree of the Government of the Russian Federation dated January 26, 2005 No.№ 40 (Collected Legislation of the Russian Federation, 2005, No. 5, Art. 390; No. 13, Art. 1169; 2006, No. 6, Art. 712; No. 18, Art. 2002; 2007, No. 45, Art. 5488; 2008, No. 22, Article 2582; No. 42, Article 4825; No. 46, Article 5337; 2009, No. 3, Article 378; No. 6, Article 738; No. 14, Article 1669; No. 38, Article 4497; 2010, No. 9, item 960; No. 22, item 2776; No. 25, item 3190; No. 26, item 3350; No. 28, item 3702; No. 31, item 4251), by order of the Ministry of Regional Development of the Russian Federation of April 11, 2008№ 44 "On approval of the Procedure for the development and approval of standards in the field of estimated regulation and pricing in the field of urban planning" (registered by the Ministry of Justice of the Russian Federation on May 12, 2008, registration No. 11661, Bulletin of regulatory acts federal bodies executive branch, 2008, No. 22) and by order of the Ministry of Regional Development of the Russian Federation dated August 20, 2009 No.№ 353 “On approval of the classification of estimated standards to be applied when determining the estimated cost of capital construction projects, the construction of which is financed with the involvement of federal budget funds” (registered by the Ministry of Justice of the Russian Federation on October 2, 2009, registration No. 14940, Bulletin of regulatory acts of federal executive bodies, 2009 , No. 42), I order:

1. By order of the Ministry of Regional Development of the Russian Federation dated August 4, 2009 No.№ 321 "On the approval of state estimated standards for the installation of equipment, overhaul of equipment and commissioning" (Bulletin of Pricing and Estimated Rationing, 2009, No. 9) to make the following changes:

a) in Appendix No. 1 in accordance with Appendix No. 1 to this Order;

b) in Appendix No. 2 in accordance with Appendix No. 2 to this Order;

c) in Appendix No. 3 in accordance with Appendix No. 3 to this Order;

d) in Appendix No. 4 in accordance with Appendix No. 4 to this Order.

2. Recommend to the executive authorities of the constituent entities of the Russian Federation, within two months from the date of issuance of this order, to bring the territorial unit prices in line with this order.

3. To impose control over the execution of this order on the Deputy Minister of Regional Development of the Russian Federation K.Yu. Royal.

And about. Minister V.A. Tokarev

SYSTEM OF REGULATORY DOCUMENTS IN CONSTRUCTION

BUILDING REGULATIONS
RUSSIAN FEDERATION

GESNp 81-04-02-2001

Approved and put into effect on June 15, 2001
Decree of the Gosstroy of Russia dated June 23, 2001 No. 4

STATE ELEMENTARY
ESTIMATE RATES
FOR COMMISSIONING

GESNp-2001
Collection #2

AUTOMATED CONTROL SYSTEMS

State Committee of the Russian Federation
for construction and housing and communal complex
(Gosstroy of Russia)

Moscow 2001

These State Elemental Estimated Standards (GESNp) are intended to determine the need for resources (labor costs of commissioning personnel) when performing commissioning work on the commissioning of automated control systems and are used to draw up cost estimates (estimates) using the resource method. GESNp are the initial standards for the development of unit prices for commissioning of the federal (FER), territorial (TER), industry (OER) levels, individual and consolidated estimated norms (prices) and others normative documents used to determine direct costs in the estimated cost of commissioning. DEVELOPED AOOT "Association Montazhavtomatika" (B.Z. Barlasov, M.I. Logoiko), Federal State Unitary Enterprise Central Research Institute of Economics and Management in Construction (TsNIIEUS) of the Gosstroy of Russia (Ph.D. Zh.G. Chernysheva, L. V. Razmadze) with the participation of the Interregional Center for Pricing in Construction and the Industry of Building Materials (ICCC) of the State Construction Committee of Russia (I.I. Dmitrenko). CONSIDERED Department of Pricing and Estimated Rationing in Construction and Housing and Communal Complex of the Gosstroy of Russia (Editorial Committee: V.A. Stepanov - Head, V.N. Maklakov, T.L. Grishchenkova). INTRODUCED Department of Pricing and Estimated Rationing in Construction and Housing and Communal Complex of Gosstroy of Russia. APPROVED AND INTRODUCED from July 15, 2001 by the Decree of the Gosstroy of Russia dated July 23, 2001 No. 84.

TECHNICAL PART

1. General Provisions

1.1. These State Elemental Estimated Standards (GESNp) are intended to determine the need for resources (labor costs of commissioning personnel) when performing commissioning work on commissioning automated control systems and are used to draw up estimates (estimates) for commissioning using the resource method. GESNp are the initial standards for the development of unit prices for commissioning of the federal (FER), territorial (TER) and industry (OER) levels, individual and aggregated estimated norms (prices) and other regulatory documents used to determine direct costs in the estimated cost of commissioning . 1.2. GESNp reflect the industry average level of technology and organization of commissioning. GESNp are mandatory for use by all enterprises and organizations, regardless of their affiliation and form of ownership, carrying out capital construction at the expense of the state budget of all levels and target off-budget funds. For construction projects financed at the expense of own funds of enterprises, organizations and individuals, the estimated norms of this collection are advisory in nature. 1.3. When applying this Collection, in addition to the provisions contained in this technical part, it is necessary to take into account the general requirements given in the Guidelines for the Application of State Elemental Estimated Standards for Commissioning Works (MDS 81-27.2001), approved and put into effect by the Decree of the Gosstroy of Russia dated 23.07. 2001 No. 83. 1.4. This Collection applies to: - automated process control systems (APCS); - centralized operational dispatching control systems: - automatic fire and fire alarm systems; - systems of control and automatic control of fire extinguishing and smoke protection; - telemechanical systems. The collection is not intended to determine labor costs in the estimated cost of work: - for precision in-line analyzers of the physical and chemical properties of media and products circulating in the technological process: refractometers, chromatographs, octanometers and other similar single-use analyzers; - for software and hardware complexes of computer centers for economic or other information not related to technological processes; - for video surveillance (security) systems using television installations, loud-speaking communications (alerts), etc., the labor intensity of which is determined according to the Collection for the installation of equipment No. 10 "Communication equipment". (Changed edition. Rev. No. 2) 1.5. The estimated norms of the Collection are developed on the basis of the following conditions: - complexes of software and hardware (KTS) or complexes of hardware (KTS) transferred for adjustment - serial, complete, with loaded system and application software, provided with technical documentation (passports, certificates and etc.), the period of their storage in the warehouse does not exceed the standard; - commissioning works are carried out by organizations licensed to carry out these types of work, when performing work at facilities supervised by state supervision bodies, additionally there are licenses and / or permits from these departments. Employees performing work have qualifications corresponding to the technical complexity of automated systems, have undergone the necessary training, attestation or certification, are provided with necessary equipment, measuring devices, control and test benches, instrumental software, programmers, calibrators, tools, personal protective equipment, etc.; - commissioning works are carried out on the basis of the working documentation approved by the customer, if necessary - taking into account the project for the production of works (PPR), program and schedule; - by the start of the commissioning organization, the customer transferred the working design documentation, including parts of the APCS project: software (MS), information support (IS), software (SW), organizational support (OO); - start-up and commissioning works are started if the customer has documents on the completion of the installation work provided for by SNiP (acts, protocols, etc.). In the event of forced breaks between installation and commissioning work for reasons beyond the control of the contractor, commissioning work is started after checking the safety of previously installed technical equipment and installation of previously dismantled ones (in this case, the act of completion of installation work is drawn up again on the start date of commissioning work); - switching of operating modes of technological equipment is carried out by the customer in accordance with the project, regulations and during the periods provided for by the agreed programs and work schedules; - detected defects in the installation of software and hardware (PTS) or hardware (TS) are eliminated by the installation organization. (Changed edition. Rev. No. 2) 1.6. Estimated norms are developed in accordance with the requirements of state standards, in particular, GOST 34.603-92 “Information technology. Types of testing of automated systems”, standards of the “State system of industrial instruments and automation equipment”, “State system for ensuring the uniformity of measurements”, part 3 of SNiP “Organization, production and acceptance of work”. Rules for the installation of electrical installations (PUE). Intersectoral rules for labor protection (safety rules) for the operation of electrical installations (POTRM-016-2001) RD 153-34.0-03.150-00, Safety rules for gas distribution and gas consumption systems (PB-12-529-03), General rules explosion safety for explosion and fire hazardous chemical, petrochemical and oil refining industries (PB 09-540-03) and other rules and norms of state supervision bodies, technical documentation of manufacturers of PTS or TS, duly approved instructions, technical and technological regulations, guiding technical materials and other technical documentation for the installation, commissioning and operation of PTS and TS. (Changed edition. Rev. No. 2) 1.7. The estimated norms take into account the labor costs for the production of a full range of works of one technological cycle of commissioning for the commissioning of the process control system in accordance with the requirements of regulatory and technical documentation, including the following stages (stages); 1.7.1. Preparatory work, verification of KTS (KTS) of automated systems: and study of working and technical documentation, incl. materials of the pre-project stage (technical requirements for the system, etc.), the implementation of other measures of engineering and technical preparation of work, inspection of the technological control object, external inspection of the equipment and installation work performed on the APCS, determination of the readiness of systems adjacent to the APCS (power supply, etc.). etc.), etc. verification of compliance of the main technical characteristics of the equipment with the requirements established in the passports and instructions of manufacturers (the results of verification and adjustment are recorded in the act or passport of the equipment, faulty PTS or TS are transferred to the customer for repair and replacement). (Changed edition. Rev. No. 2) 1.7.2. Autonomous adjustment of automated systems after completion of their installation: - checking the installation of the PTS (TS) for compliance with the requirements of the instructions of manufacturers and working documentation; - replacement of individual defective elements with serviceable ones issued by the customer; - verification of the correctness of marking, connection and phasing of electrical wiring: - phasing and control of the characteristics of actuators (IM); - setting up the logical and temporal relationships of signaling, protection, blocking and control systems, checking the correctness of the passage of signals; - checking the functioning of application and system software; - preliminary determination of the characteristics of the object, calculation and adjustment of the parameters of the equipment of automated systems, configuration of measuring transducers and software logic devices; - preparation for inclusion and inclusion in the operation of measurement, control and management systems to ensure individual testing of process equipment and adjustment of the settings for the equipment of control systems in the course of their operation; - registration of production and technical documentation. (Changed edition. Rev. No. 2) 1.7.3. Comprehensive adjustment of automated systems: - bringing the settings of the PTS (TS), communication channels and application software to values ​​(states) at which automated systems can be used in operation; alarm systems, protection and control algorithms of working documentation with the identification of the causes of failure or their "false" operation, setting the required values ​​for the operation of positional devices; - determination of the compliance of the flow capacity of the shut-off and control valves with the requirements of the technological process, the correct development of limit and limit switches, position and status sensors; - determination of the flow characteristics of regulatory bodies (RO) and bringing them to the required rate using the adjustment elements available in the design; - clarification of the static and dynamic characteristics of the object, adjustment of the values ​​of the system settings, taking into account their mutual influence in the process of work; - preparation for the inclusion in the operation of systems to ensure the comprehensive testing of technological equipment; - testing and determining the suitability of automated systems to ensure the operation of process equipment with a capacity that meets the standards for the development of design capacities in the initial period; - analysis of the work of automated systems; - registration of production documentation, act of acceptance into operation of systems in accordance with the requirements of SNiP; - making changes in one copy of the circuit diagrams from the set of working documentation based on the results of commissioning, agreed with the customer. 1.8. The norms of this Collection do not take into account the costs of: - commissioning, labor costs for which are given in the relevant sections of GESNp-2001-01 "Electrical devices": for electric machines (motors) of electric drives, switching devices, static converters, power devices, measurements and testing in electrical installations; - testing of automated systems in excess of 24 hours of their operation during the period of complex testing of technological equipment; - drawing up a technical report and estimate documentation (at the request of the customer); - delivery of measuring instruments for state verification; - configuring components and screen forms, adjusting and finalizing the design mathematical, information and software, determined on the basis of standards for design work; - revision of the PTS (TS), elimination of their defects (repair) and installation defects, including bringing the insulation of electrical equipment, cable communication lines and the parameters of the installed fiber-optic communication lines (FOCL) to the standards; - checking the compliance of wiring diagrams with circuit diagrams and making changes to wiring diagrams; - preparation of principal, assembly, detailed diagrams and drawings; - partial or complete reassembly of cabinets, panels, consoles; - coordination of work performed with supervisory authorities; - carrying out physico-technical and chemical analyses, supply of exemplary mixtures, etc., - drawing up a program for complex testing of technological equipment; - training of operating personnel; - development of operational documentation; - technical (service) maintenance and periodic checks of the KPTS (KTS) during the operation period. (Revised edition, Rev. No. 1). 1.9. The estimated norms of this Collection are developed for automated systems (hereinafter referred to as systems), depending on the category of their technical complexity, characterized by the structure and composition of the KTS (KTS), taking into account the complexity factor. Categories of technical complexity of systems, their characteristics and complexity factors are presented in Table. one.

Table 1

	Characteristics of the system (structure and composition of the KTS or KTS)	System complexity factor
I	Single-level information, control, information and control systems, characterized in that as components of the CTS to perform the functions of collecting, processing, displaying and storing information and generating control commands, they use measuring and control devices, electromagnetic semiconductor and other components, signal fittings etc. instrumental or hardware types of execution
II	Single-level information, control, information - control systems, characterized in that as components of the KPTS to perform the functions of collecting processing, displaying and storing information and generating control commands, they use programmable logic controllers (PLC), intrasystem communication devices, microprocessor operator interfaces ( display panel)
	Single-level systems with automatic mode of indirect or direct (direct) digital (digital-analog) control using object-oriented controllers with programming of settings parameters and for the operation of which the development of project MO and software is not required
	Information, control, information and control systems in which the composition and structure of the CTS meet the requirements established for classifying systems as category I of complexity and in which fiber-optic information transmission systems (FOTS) are used as communication channels
	Systems for measuring and (or) automatic control of the chemical composition and physical properties of a substance
	Measuring systems (measuring channels) for which metrological certification (calibration) is required according to the project
	Multi-level distributed information, control, information and control systems in which the composition and structure of the local level CPTS meet the requirements established for classifying the system to the second category of complexity and in which process (PCS) or operator (OS) are used to organize subsequent levels of control stations implemented on the basis of problem-oriented software, interconnected and with the local control level via local area networks
	Information, control, information and control systems in which the composition and structure of the CPTS (CTS) meets the requirements established for classifying systems as category II of complexity and in which fiber-optic information transmission systems (FOTSI) are used as communication channels

Notes 1 Systems of the II and III categories of technical complexity may have one or more features given as a characteristic of the system. 2. In the event that a complex system contains systems (subsystems) that, according to the structure and composition of the CPTS or CTS, are attributed to different categories of technical complexity, the complexity factor of such a system is calculated in accordance with clause 2.2 1.10. Estimated norms are developed for systems of I, II and III categories of technical complexity, depending on the number of communication channels for the formation of input and output signals. Under the communication channel for the formation of input and output signals (hereinafter - the channel) should be understood as a set of technical means and communication lines that provide the transformation, processing and transmission of information for use in the system. The Collection takes into account the number of: - information channels (including measurement, control, notification, address, status, etc. channels); - control channels. The composition of information and control channels, in turn, takes into account the number of channels: - discrete - contact and non-contact on AC and DC, pulse from discrete (signaling) measuring transducers, for monitoring the status of various on-off devices, as well as for transmitting signals such as "turn on-off", etc.; - analog, which include (for the purposes of this Collection) all the rest - current, voltage, frequencies of mutual inductance, natural or unified signals of measuring transducers (sensors) that change continuously, coded (pulse or digital) signals for the exchange of information between various digital information processing devices, etc. In the following presentation, the symbols for the number of channels given in Table 1 are used. 2.

table 2

Symbol	Name
	Number of information analogue channels
	Number of information discrete channels
	Number of analog control channels
	Number of discrete control channels
	The total number of information analog and discrete channels
	Total number of analog and discrete control channels
	Total number of information and control channels analog and discrete

2. The procedure for applying estimated norms 2.1. The table of estimated norms of the Collection shows the basic norms () of labor costs for commissioning for systems of I, II and III categories of technical complexity ( , , ), depending on the total number of information and control channels, analog and discrete () in this system. Basic norms for the system of II and III category of technological complexity (table. GESNp 02-01-002 and 02-01-003) are calculated on the basis of the basic norms for the system of category I of technical complexity (table. GESNp 02-01-001) using him the coefficients of complexity given in table. one:

2.2. The basic norm for a complex system that includes subsystems with different category technical complexity, is determined by applying to the corresponding basic norm for the system of the I category of technical complexity the coefficient of complexity (C), calculated by the formula:

Where: , , - the total number of analog and discrete channels of information and control related to subsystems, respectively, I, II, III category of technical complexity;

; (1.1)

In this case, the base rate for a complex system is calculated by the formula:

at 1< С < 1,313 Нsl b=H I b×С (2.1.)

at 1.313< С < 1,566 Нsl b= H II b×C: 1.313 (2.2.)

(Changed version. Rev. No. 2) 2.3. When drawing up cost estimates (estimates) for commissioning to take into account the characteristics of a particular system, the following coefficients should be applied to the basic rate of labor intensity (): 2.3.1. Coefficient (), taking into account two factors: "metrological complexity" and "development of information functions" of the system The coefficient is calculated by the formula:

Where - the coefficient of "metrological complexity", determined by the table. 3; - coefficient of "development of information functions", determined by Table 4. (Changed edition, Rev. No. 1)

Table 3

	Characteristics of the factors of "metrological complexity" ( M) systems		The coefficient of "metrological complexity" of the system
	Measuring transducers (sensors) and measuring instruments, etc., operating in normal environmental and technological environment, accuracy class:
	less than or equal to 1.0
	below 0.2 and above 1.0
	greater than or equal to 0.2

Note: If the system has measuring transducers (sensors) and measuring devices related to different accuracy classes, the coefficient is calculated by the formula:

Table 4

	Characteristics of the factors of "development of information functions" ( AND) systems	Designation of the number of channels	Coefficient of "development of information functions" of the system
	Parallel or centralized control and measurement of the parameters of the state of the technological control object (TOU)
	The same as according to clause 1, including archiving, documenting data, compiling emergency and production (shift, daily, etc.) reports, presenting parameter trends, indirect measurement (calculation) of individual complex indicators of the functioning of the TOU
	Analysis and generalized assessment of the state of the process as a whole according to its model (recognition of the situation, diagnostics of emergency conditions, search for a bottleneck, forecast of the process)

(Changed edition. Change No. 2 ) Note: If the system has different characteristics of the "development of information functions", the coefficient AND is calculated by the formula:

2.3.2. Coefficient taking into account the "development of control functions", calculated by the formula:

, (6)

Where: Y - the coefficient of "development of control functions", is determined according to Table 5

Table 5

	Characterization of the factors of "development of control functions" ( At) systems	Designation of the number of channels	Coefficient of "development of control functions" of the system ( At)
	Single-circuit automatic control (AR) or automatic single-cycle logic control (switching, blocking, etc.).
	Cascade and (or) software AP or automatic program logic control (APLC) on a "hard" cycle, multi-connected AP or APLC on a loop with branches.
	Control of fast processes in emergency conditions or control with adaptation (self-learning and changing algorithms and system parameters) or optimal control (OC) of steady state (in statics), OC of transients or the process as a whole (optimization in dynamics).

(Revised edition, Rev. No. 1). Note: If the system has different characteristics of "development of control functions", the Y coefficient is calculated by the formula:

; (7.1)

2.4. Estimated labor cost rate ( H) for a specific system is calculated by applying to the base rate established in accordance with clause 2.2., the coefficients , , which are multiplied with each other:

2.5. When performing commissioning work in more difficult production conditions, in comparison with those provided for in the collection, as a result of which labor productivity decreases, the coefficients of Table 1 should be applied to the estimated labor costs. 1 Guidelines for the application of state elemental standards for commissioning (MDS 81-27.2001). (Revised edition, Rev. No. 1). 2.6. When performing repeated commissioning works (before putting the facility into operation), a coefficient of 0.537 must be applied to the estimated labor costs. Re-commissioning should be understood as work caused by the need to change the technological process, the mode of operation of technological equipment, in connection with a partial change in the design or forced replacement of equipment. The need to re-perform work must be confirmed by a reasonable task (letter) from the customer. 2.7. In the event that the automated process control system is created as part of an automated technological complex (ATC) included in the pilot or experimental construction plan, or in the list of unique or especially important (most important) objects (constructions), or the automated process control system includes experimental or experimental software and hardware (technical) means, a coefficient of 1.2 is applied to the estimated labor costs. 2.8. In the event that commissioning is carried out with the technical guidance of the personnel of the manufacturer or supplier of equipment, a coefficient of 0.8 should be applied to the estimated labor costs. 2.9. Specified in paragraphs. 2.5 - 2.8 coefficients are applied to the estimated cost rates of those stages of work (the corresponding number of information and control channels), which are subject to the above conditions. If multiple coefficients are used, they must be multiplied. 2.10. Reducing factor for the same type of automated technological complexes (ATK) in accordance with clause 2.5. MDS 81-40.2006 is taken into account by the norms of this Collection, subject to a special calculation procedure, in which the estimated cost rate is initially determined as a whole for several similar ATCs in accordance with the project and, if necessary, an estimated labor cost is allocated for one single-type ATC. It is not allowed, when determining the estimated labor costs, artificial, contrary to the project, division of the automated system into separate measurement systems, control (regulation) loops, subsystems. For example. For a centralized system of operational dispatch control of ventilation and air conditioning, which includes several subsystems of supply and exhaust ventilation, the estimated labor cost is determined as a whole for the centralized control system; if necessary, labor costs for individual subsystems are determined within the framework of the general norm of labor costs for the whole system, taking into account the number of channels assigned to subsystems. Change No. 2 ). 2.11. When drawing up estimates, the amount of funds for the remuneration of labor for commissioning personnel is calculated on the basis of estimated labor costs, taking into account the qualification composition of the link (team) of commissioning performers (as a percentage of participation in total labor costs), given in Table. 6.

Table 6

	Norm table cipher	Lead Engineer
	GESNp 02-01-001
	GESNp 02-01-002
	GESNp 02-01-003

Note: For a complex system consisting of subsystems of different categories of technical complexity, the basic amount of funds for wages (WP) is calculated as follows: at 1< С < 1313 RFP SL B= RFP IB × С × (0.14 × С + 0.86), ………………………………………………………..(9) formula (1); RFP IB- base salary for the system of the I category of technical complexity (C=1) according to Table. 6. at 1.313< С < 1,566 RFP SL B= RFP IIB × C: 1.313 (0.34 × C + 0.56), ……………………………………………….(10) where: RFP IIB- base salary for the system of the II category of technical complexity (С=1.313) according to the table. 6. (Changed edition. Change No. 2 ) 2.12. If it is necessary to make intermediate payments for the performed commissioning works, it is recommended to use the approximate structure of the labor intensity of commissioning works by their main stages (unless the contract provides for other conditions for mutual settlements of the parties), given in Table. 7.

Table 7

(Changed edition. Change No. 2 ) Notes: 1. The content of the work execution stages corresponds to clause 1.7. of this technical part. 2. In the event that the customer engages one organization to carry out commissioning work on software and hardware (for example, a project developer or equipment manufacturer that has the appropriate licenses to perform commissioning work), and on technical means - another commissioning organization, the distribution of the volumes of work performed by them works (within the framework of the general norm of labor costs for the system), including the stages of Table. 7 is produced, in agreement with the customer, taking into account the total number of channels related to the MTS and TS. 3. The procedure for preparing the initial data for budgeting. 3.1. Preparation of initial data for budgeting is carried out on the basis of design and technical documentation for a specific system. When preparing the initial data, it is recommended to use the "Scheme of the Automated Technological Complex (ATC)" given in Appendix 1. Preparation of the initial data is carried out in the following sequence: 3.1.1. As part of the ATK, according to the scheme, the following groups of channels are distinguished according to Table. 8

Table 8

Channel group symbol
KPTS ® TOU (KTS)	Control channels analog and discrete ( and ) transmission of control actions from KPTS (KTS) to TOU. The number of control channels is determined in count actuators: membrane, piston, electric single- and multi-turn, non-engine (cut-off), etc.
TOU ® KPTS (KTS)	Channels analog and discrete information ( and ) conversion of information (parameters) coming from the technological control object (TOU) to the KPTS (KTS). The number of channels is determined quantity measuring transducers, contact and non-contact signaling devices, equipment position and condition sensors, limit and limit switches, etc. wherein combined fire alarm sensor ( pic) is taken into account as one discrete channel
Op ® KTS (KTS)	Analogue and discrete information channels ( , and ) from the operator (Op) for influencing the KTS (KTS). The number of channels is determined the number of organs of influence, used by the operator ( buttons, keys, controls etc.) to implement the functioning of the system in the modes of automated (automatic) and manual remote control of actuators without taking into account as additional channels of organs impact KPTS (KTS) for setting and other auxiliary functions (except management) keyboard of terminal devices of information and control panels, buttons, switches, etc., panels of multifunctional or multi-channel devices of POS control panels, etc., as well as voltage switches, fuses and other auxiliary bodies of influence of the above and other technical means, the adjustment of which taken into account by the norms of this Collection
KPTS ® Op (KTS)	Analog and discrete channels ( and ) for displaying information coming from KTS (KTS) to Op when determining the number of system channels not taken into account, except for cases when the project provides for the display of the same technological parameters (equipment status) on more than one terminal device (monitor, printer, interface panel, information board). Adjustment of information displays on the first terminal device is taken into account by the norms of this Collection. In this case, when displaying information on each terminal device in addition to the first, the displayed parameters ( And ) taken into account with the coefficient 0,025 , with coefficient 0,01 . Doesn't count as channels indicators (lamps, LEDs, etc.) of status and position built into measuring transducers (sensors), contact or non-contact signaling devices, buttons, control keys, switches, as well as indicators of the presence of voltage of devices, recorders, terminal devices of shields , consoles, etc. the adjustment of which is taken into account by the norms of this Collection
No. 1, No. 2, ..., No. i	Communication channels (interactions) analog and discrete information (K a and K d and) with related systems, made on separate projects. “The number of physical channels through which communication signals (interactions) with adjacent systems are transmitted is taken into account: discrete - contact and non-contact direct and alternating current (with the exception of coded ones) and analog signals, the values ​​​​of which are determined on a continuous scale, and also, for the purposes of this Collection , coded (pulse and digital)". Various types of electrical system voltage used as power sources for APCS equipment (boards, consoles, actuators, information converters, terminal devices, etc.) as communication channels (interactions) with adjacent systems are not taken into account.

(Changed edition, Rev. No. 1, Change No. 2 ). Notes: 1. Voltage switches, fuses built into appliances, etc. are not counted as channels. 2. Status or position indicators (lamp, LED) built into primary measuring transducers (sensors), contact or non-contact signaling devices, buttons, control keys, switches, etc. channels are not counted. 3. Indicators (lamp, LED) of the presence of voltage built into the devices are not taken into account as channels. 4. If the parameter is displayed by one form of information presentation at the local and centralized levels, then such information display is taken into account as two channels. 3.1.2. For each group of channels in Table. 8 counts the number of information channels (analog and discrete) and control channels (analog and discrete), as well as the total number of information and control channels (). 3.1.3. Based on the table. 1, the category of technical complexity of the system is established and, depending on the corresponding table of GESNp, the basic rate of labor costs () is determined, if necessary, the basic rate for a complex system () is calculated using formulas (1) and (2). 3.1.4. To link the base rate to a specific system, correction factors are calculated and in accordance with paragraphs. 2.3.1 and 2.3.2, then the estimated rate is calculated using formula (8).

DEPARTMENT 01. AUTOMATED CONTROL SYSTEMS

Table GESNp 02-01-001 Automated control systems of the 1st category of technical complexity

Gauge: system (norms 1, 3, 5, 7, 9, 11, 13, 15, 17, 19); channel (norms 2, 4, 6, 8, 10, 12, 14, 16, 18, 20) System with the number of channels (): 02-01-001-01 2 02-01-001-02 for each channel St. 2 to 9 add to the norm 1 02-01-001-03 10 02-01-001-04 for each St. 10 to 19 add to the norm 3 02-01-001-05 20 02-01-001-06 for each channel of St. 20 to 39 add to the norm 5 02-01-001-07 40 02-01-001-08 for each St. 40 to 79 add to the norm 7 02-01-001-09 80 02-01-001-10 for each channel of St. 80 to 159 add to the norm 9 02-01-001-11 160 02-01-001-12 for each St. 160 to 319 add to the norm 11 02-01-001-13 320 02-01-001-14 for each St. 320 to 639 add to the norm 13 02-01-001-15 640 02-01-001-16 for each St. 640 to 1279 add to the norm 15 02-01-001-17 1280 02-01-001-18 for each St. 1280 to 2559 add to the norm 17 02-01-001-19 2560 02-01-001-20 for each St. 2560 add to norm 19

Table GESNp 02-01-002 Automated control systems of the II category of technical complexity

System with the number of channels (): 02-01-002-01 2 02-01-002-02 for each channel of St. 2 to 9 add to the norm 1 02-01-002-03 10 02-01-002-04 for each St. 10 to 19 add to the norm 3 02-01-002-05 20 02-01-002-06 for each channel of St. 20 to 39 add to the norm 5 02-01-002-07 40 02-01-002-08 for each St. 40 to 79 add to the norm 7 02-01-002-09 80 02-01-002-10 for each channel of St. 80 to 159 add to the norm 9 02-01-002-11 160 02-01-002-12 for each St. 160 to 319 add to the norm 11 02-01-002-13 320 02-01-002-14 for each St. 320 to 639 add to the norm 13 02-01-002-15 640 02-01-002-16 for each St. 640 to 1279 add to the norm 15 02-01-002-17 1280 02-01-002-18 for each St. 1280 to 2559 add to the norm 17 02-01-002-19 2560 02-01-002-20 for each St. 2560 add to norm 19

Table GESNp 02-01-003 Automated control systems of the III category of technical complexity

Gauge: system (norms 1, 3, 5, 7, 9, 11, 13, 15, 17, 19); channel (norms 2, 4, 6, 8, 10, 12, 14, 16, 18, 20) System with the number of channels (): 02-01-003-01 2 02-01-003-02 for each channel of St. 2 to 9 add to the norm 1 02-01-003-03 10 02-01-003-04 for each St. 10 to 19 add to the norm 3 02-01-003-05 20 02-01-003-06 for each channel of St. 20 to 39 add to the norm 5 02-01-003-07 40 02-01-003-08 for each St. 40 to 79 add to the norm 7 02-01-003-09 80 02-01-003-10 for each channel of St. 80 to 159 add to the norm 9 02-01-003-11 160 02-01-003-12 for each St. 160 to 319 add to the norm 11 02-01-003-13 320 02-01-003-14 for each St. 320 to 639 add to the norm 13 02-01-003-15 640 02-01-003-16 for each St. 640 to 1279 add to the norm 15 02-01-003-17 1280 02-01-003-18 for each St. 1280 to 2559 add to the norm 17 02-01-003-19 2560 02-01-003-20 for each St. 2560 add to norm 19

Attachment 1

Scheme of an automated technological complex (ATC)

Annex 2

Terms and their definitions used in the Collection

Symbol

Definition

Automated system

A system consisting of personnel and a set of means for automating its activities, implementing information technology for performing established functions

Automated process control system

An automated system that ensures the operation of an object due to the appropriate choice of control actions based on the use of processed information about the state of the object

Automated technological complex

The set of jointly functioning technological control object (TOU) and the process control system that controls it

Automatic mode of indirect control when performing the APCS function

The mode of execution of the APCS function, in which the APCS automation tool complex automatically changes the settings and (or) settings of the local automation systems of the technological control object.

Automatic mode of direct (immediate) digital (or analog-to-digital) control when performing the control function of the process control system

The mode of execution of the APCS function, in which the APCS automation tool complex generates and implements control actions directly on the actuators of the technological control object.

Interface (or input-output interface)

A set of unified constructive, logical, physical conditions that technical means must satisfy in order to be able to connect them and exchange information between them. In accordance with the purpose, the interface includes: - a list of interaction signals and rules (protocols) for the exchange of these signals; - modules for receiving and transmitting signals and communication cables; - connectors, interface cards, blocks; The interfaces unify information, control, notification, address and status signals.

Information function of the automated control system

ACS function, including receiving information, processing and transmitting information to the ACS personnel or outside the system about the state of the TOU or the external environment

Information support of the automated system

A set of forms of documents, classifiers, regulatory framework and implemented decisions on the volume, placement and forms of existence of information used in the AS during its operation

Actuating devices (ID) are designed to influence the technological process in accordance with the command information KPTS (KTS). The output parameter of the IU in the automated process control system is the consumption of matter or energy entering the TOU, and the input is the signal of the KTS (KTS). In the general case, MDs contain an actuator (IM): electric, pneumatic, hydraulic and control body (RO): throttling, dosing, manipulating. There are complete DUTs and systems: with an electric drive, with a pneumatic drive, with a hydraulic drive and auxiliary devices of the DUT (power amplifiers, magnetic starters, positioners, position indicators and control devices). To control some electrical devices (electric baths, large electric motors, etc.), the controlled parameter is the flow of electrical energy, and in this case, the role of the DUT is performed by the amplification unit.

Executive device

Actuating mechanism

Regulatory body

Measuring transducer (sensor), measuring device

Measuring devices designed to obtain information about the state of the process, designed to generate a signal that carries measurement information both in a form accessible to the direct perception of the operator (measuring devices), and in a form suitable for use in process control systems for the purpose of transmission and (or ) transformation, processing and storage, but not amenable to direct perception by the operator. To convert natural signals into unified ones, various normalizing converters are provided. Measuring transducers are divided into main groups: mechanical, electromechanical, thermal, electrochemical, optical, electronic and ionization. Measuring transducers are divided into transducers with natural, unified and discrete (relay) output signal (signaling devices), and measuring instruments - into devices with natural and unified input signal.

Configuration (computer system)

The set of functional parts of a computer system and the connections between them, due to the main characteristics of these functional parts, as well as the characteristics of the data processing tasks being solved.

Configuration

Configuration setting.

Indirect measurement (calculation) of individual complex indicators of the functioning of TOU

Indirect automatic measurement (calculation) is performed by converting a set of partial measured values ​​into a resulting (complex) measured value using functional transformations and subsequent direct measurement of the resulting measured value, or by direct measurement of partial measured values, followed by automatic calculation of the values ​​of the resulting (complex) measured value by results of direct measurements.

Mathematical support of the automated system

A set of mathematical methods, models and algorithms used in AS

Metrological certification (calibration) of measuring channels (MC) APCS

-

MC must have metrological characteristics that meet the requirements of accuracy standards, the maximum permissible errors. IC APCS are subject to state or departmental certification. The type of metrological certification must correspond to that established in the terms of reference for the process control system. IC APCS are subject to state metrological certification, the measurement information of which is intended for: - use in commodity and commercial operations; - accounting of material assets; - protecting the health of workers, ensuring safe and harmless working conditions. All other MCs are subject to departmental metrological certification.

Multilevel process control system

-

APCS, which includes APCS of different levels of hierarchy as components.

Single-level process control system

-

A process control system that does not include other, smaller process control systems.

Optimal Control

OU

Control that provides the most advantageous value of a certain optimality criterion (OC), which characterizes the effectiveness of control under given constraints. Various technical or economic indicators can be chosen as KOs: - time of transition (performance) of the system from one state to another; - some indicator of product quality, the cost of raw materials or energy resources, etc. DT example : In furnaces for heating blanks for rolling, by optimally changing the temperature in the heating zones, it is possible to ensure the minimum value of the root-mean-square deviation of the heating temperature of the processed blanks with a change in the rate of their advancement, size and thermal conductivity.

Parameter

-

An analog or discrete value that takes on various values ​​and characterizes either the state of the ATC, or the process of functioning of the ATC, or its results. Example : temperature in the working space of the furnace, pressure under the top, coolant flow rate, shaft rotation speed, terminal voltage, calcium oxide content in raw meal, signal for assessing the condition of the mechanism (unit), etc.

Automated system software

ON

A set of programs on data carriers and program documents designed for debugging, operation and testing of the AU

Software regulation

-

Regulation of one or more quantities that determine the state of the object, according to predetermined laws in the form of functions of time or some system parameter. Example . A hardening furnace in which the temperature, as a function of time, changes during the hardening process according to a predetermined program.

Multi-connected automatic control system (AR)

-

An AP system with several controlled variables interconnected through a regulated object, regulator or load. Example: Object - steam boiler; input quantities - water supply, fuel, steam consumption; output values ​​- pressure, temperature, water level.

Systems for measuring and (or) automatic control of the chemical composition and physical properties of a substance

Medium and measured variable for determining the chemical composition of substances: examples of measured variables for gaseous environments are: the concentration of oxygen, carbon dioxide, ammonia, (off-gases of blast furnaces), etc. for liquid media: electrical conductivity of solutions, salts, alkalis, concentration of aqueous suspensions, salinity of water. pH. cyanide content, etc. Measured quantity and test medium for determining the physical properties of a substance: Example of a measured quantity for water and solids: humidity, for liquid and pulp- density, for water- turbidity, for lubricating oils- viscosity, etc.

Technological control object

The control object, including technological equipment and the technological process implemented in it

Telemechanical system

Telemechanics combines the means of automatic transmission over a distance of control commands and information about the state of objects using special transformations for the effective use of communication channels. Telemechanics provide information exchange between the objects of control and the operator (dispatcher), or between objects and KPTS. The set of devices of the control point (CP), devices of the controlled point (CP) and devices intended for the exchange of information through the communication channel between the CP and the CP forms a complex of telemechanics devices. A telemechanical system is a combination of a complex of telemechanics devices, sensors, information processing tools, dispatching equipment and communication channels that perform the complete task of centralized control and management of geographically dispersed objects. For the formation of control commands and communication with the operator, the telemechanical system also includes information processing tools based on the KPTS.

Terminal

1. A device for user interaction or an opera mountain with a computer system. The terminal consists of two relatively independent devices: input (keyboard) and output (screen or printer). 2. In a local area network, a device that is a source or recipient of data.

Control function of the automated control system

ACS function, including obtaining information about the state of the TOU, evaluating information, choosing control actions and their implementation

Information display devices

Technical means used to transmit information to a person - an operator. IoIs are divided into two large groups: local or centralized representation of information, which can coexist in the system in parallel (simultaneously) or only centralized representation of information is used. URIs are classified according to the forms of information presentation into: - signaling (light, mnemonic, sound), - showing (analog and digital); - registering for direct perception (alphabetic and diagrammatic) and with encoded information (on magnetic or paper media); - screen (display): alphanumeric, graphic, combined. Depending on the nature of the formation of local and target screen fragments, the tools of the specified type are divided into universal (fragments of an arbitrary fragment structure) and specialized (fragments of an unchanged form with an intermediate carrier of the fragment structure). In relation to automated process control systems, fragments can carry information about the current state of the technological process, about the presence of disorder in the process of functioning of an automated technological complex, etc.

Human Operator

Personnel directly managing the facility

Table 1

	System characteristic (structure and composition of the CPTC or CCC)	System complexity factor
	Single-level information, control, information and control systems, characterized in that as components of the CTS to perform the functions of collecting, processing, storing information and generating control commands, they use measuring and control devices, electromagnetic, semiconductor and other components, signal fittings and etc. instrumental or hardware types of execution.
	Single-level information, control, information and control systems, characterized in that they use programmable logic controllers (PLC), intrasystem communication devices, microprocessor interfaces as components of the KPTS to perform the functions of collecting, processing, displaying, storing information and generating control commands operator (display panel)
	Single-level systems with automatic mode of indirect or direct (direct) digital (digital-analog) control using object-oriented controllers with programming of settings parameters and for the operation of which the development of project MO and software is not required.
	Information, control, information and control systems in which the composition and structure of the CTS meet the requirements established for classifying systems as category I of complexity and in which fiber-optic information transmission systems (FOTSI) are used as communication channels
	Systems for measuring and (or) automatic control of the chemical composition and physical properties of a substance
	Measuring systems (measuring channels) for which metrological certification (calibration) is required according to the project
	Multilevel distributed information, control, information and control systems, in which the composition and structure of the local level CPTS meet the requirements established for classifying the system to the second category of complexity and in which process (PCS) or operator (OS) are used to organize subsequent levels of control stations implemented on the basis of problem-oriented software, connected to each other and to the local control level via local area networks.
	Information, control, information and control systems in which the composition and structure of the CPTS (CTS) meet the requirements established for classifying systems as category II of complexity and in which fiber-optic information transmission systems (FOTSI) are used as communication channels

Notes: 1. Systems of II and III categories of technical complexity may have one or more features given as a characteristic of the system.

2. In the event that a complex system contains in its composition systems (subsystems) that, according to the structure and composition of the CPTS or CTS, are attributed to different categories of technical complexity, the complexity factor of such a system is calculated in accordance with clause 2.2.

1.10. Estimated norms are developed for systems of I, II and III categories of technical complexity, depending on the number of communication channels for the formation of input and output signals.

Under the communication channel for the formation of input and output signals (hereinafter - the channel) should be understood as a set of technical means and communication lines that provide the transformation, processing and transmission of information for use in the system.

The Collection takes into account the quantity:

Information channels (including measurement, control, notification, address, status, etc. channels);

Control channels.

The composition of information channels and control channels, in turn, takes into account the number of channels:

Discrete - contact and non-contact on alternating and direct current, pulsed from discrete (signaling) measuring transducers, for monitoring the status of various on-off devices, as well as for transmitting command signals of the “on-off” type, etc .;

Analog, which include (for the purposes of this Collection) all the rest - current, voltage, frequency, mutual inductance, natural or unified signals of measuring transducers (sensors) that change continuously, encoded (pulse or digital) signals for the exchange of information between various digital information processing devices, etc.

How to properly apply the collection GESNp-2001-02 "Automated control systems" to determine the number of information channels in the production of commissioning fire alarms. Our organization, guided by Table. No. 8 of the Technical part to the Collection GESNp-2001-02 "Automated control systems", "A manual for the preparation of estimates (estimates) for commissioning work on automated process control systems (APCS), namely chapter II" Comments on certain provisions of the collections GESNp-2001-02, FERp-2", chapter III "Examples of determining the total number of information and control channels and labor costs", Example No. 11 "Determination of labor costs in the production of commissioning work on a fire alarm system based on a receiving control panel", calculates the number of information channels fire alarm systems by the number of smoke, heat and manual call points.

Is this true?

Answer: Magazine No. 1 (53), 2009 "Consultations and clarifications on pricing and estimated rationing in construction"

LLC "KTsTS", whose specialists are the developers of the Collections for commissioning GESNp (FERp) -2001-02 "Automated control systems" and "Guidelines for the application of federal unit prices for commissioning" (MDS 81-40.2006), "Manuals for the preparation of estimates calculations (estimates) for commissioning works on automated control systems (APCS)”, on the merits of the question asked, reports: In the absence of actuating mechanisms in the fire alarm system, the number of channels is determined by the 2nd group of information channels according to the number of sensors-detectors, according to the principle of one sensor - one information discrete channel. The number of signal lines (loops) is not taken into account in the calculation of discrete information channels. During commissioning (testing) and acceptance tests of the system, it is necessary to check the operation of each sensor in the signal lines (loops), along with other tests:

measurement of line insulation resistance;

measurement of ohmic resistance;

measurement of electrical parameters of operating modes (“duty”, “break”, “fire”, “alarm”);

measurement of electrical tests, including interaction with adjacent systems, ensuring stable and stable operation of the substation (“without false alarms”) in accordance with the requirements of the project.

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