Requirements for the heating unit of an apartment building. Typical requirements for premises for the placement of heat metering units for consumers. ITP for heating

Appendix 2

Typical requirements for premisesfor placement of heat metering units for consumers

Premises for placing consumer heat metering units must comply with the requirements established by the following regulatory documents:

1. JV “Design of heating points” (Introduction date
01.07.1996);

2. Rules for metering thermal energy and coolant (approved by order
Ministry of Energy of Russia dated January 1, 2001 No. VK-4936);

3. Rules for the technical operation of thermal power plants
(approved by the order of the Ministry of Energy of Russia);

4. Rules for electrical installations;

5. SNiP 2.04.07-86* Heating networks (with Amendments No. 1,2) (approved
Decree of the USSR State Construction Committee dated January 1, 2001 No. 75).

A heat metering unit is installed at a heating point owned by the consumer.

Individual heating units (hereinafter referred to as IHP) must be built into the buildings they serve and located in separate rooms on the ground floor near the outer walls of the building. It is allowed to place ITP in technical undergrounds or in the basements of buildings and structures.

Buildings of detached and attached ITPs should be one-story; it is allowed to construct basements in them for placing equipment, collecting, cooling and pumping condensate and constructing a sewage system.

Free-standing ITPs may be provided underground, provided:

Lack of groundwater in the area where the inlets are placed and sealed
utilities into the building of a heating point, excluding
the possibility of flooding the heating point with sewerage,
flood and other waters;

Ensuring gravity drainage of water from thermal pipelines
point;

Ensuring automated operation of thermal equipment
point without permanent staff with emergency
alarm and partial remote control with
control center.

In terms of explosion and fire hazards, the premises of heating points should be classified as category D.

Heating units may be placed in industrial premises of categories G and D, as well as in technical basements and underground areas of residential and public buildings. In this case, the premises of heating points must be separated from these premises by fences (partitions) that prevent unauthorized persons from accessing the heating point.

In the premises of heating points, fencing must be finished with durable, moisture-resistant materials that allow easy cleaning, and the following work must be performed:

Plastering the ground part of brick walls;

Joint joints of panel walls;

Whitewashing of ceilings;

Concrete or tile flooring.

The walls of heating points must be covered with tiles or painted to a height of 1.5 m from the floor with oil or other waterproof paint, and above 1.5 m from the floor - with adhesive or other similar paint.

The following exits must be provided from heating points built into buildings:

a) when the length of the heating point room is 12 m or less and
its location at a distance of less than 12 m from the exit from the building to the outside
- one exit to the outside through a corridor or staircase;

b) when the length of the heating point room is 12 m or less and
its location at a distance of more than 12 m from the exit of the building - one
independent exit outside;

c) if the length of the heating point room is more than 12 m - two
exit, one of which should be directly outside, the second -
through a corridor or stairwell.

In underground, free-standing or attached heating units, it is allowed to place a second exit through an attached shaft with a hatch or through a hatch in the ceiling, and in heating units located in technical undergrounds or basements of buildings - through a hatch in the wall

Doors and gates from the heating point must open from the premises or building of the heating point away from you.

The size of the doorway of the ITP must provide free passage for personnel.

All passages, entrances, and exits must be illuminated, free, and safe for movement.

The passage between equipment and pipelines must provide free passage for personnel and be at least 0.6 m. Transition platforms must be installed through pipelines located at or above the floor level.

The height of the premises from the finished floor mark to the bottom of the protruding ceiling structures (in the clear) is recommended to be at least 2.2 m.

When placing ITP in basements and basements, as well as in technical underground areas of buildings, the height of the premises and free passages to them is allowed to be at least 1.8 m.

To drain water, floors should be designed with a slope of 0.01 towards the drain or drainage pit. The minimum dimensions of the drainage pit must be in plan - at least 0.5 x 0.5 m, with a depth of at least 0.8 m. The pit must be covered with a removable grid.

Open pipe laying must be provided at heating points. It is allowed to lay pipes in channels, the top of which overlaps with the level of the finished floor, if through these channels no explosive or flammable gases and liquids enter the heating unit.

Channels must have removable ceilings with a unit weight of no more than 30 kg.

The bottom of the canals must have a longitudinal slope of at least 0.02 towards the drainage pit.

To service equipment and fittings located at a height of 1.5 to 2.5 m from the floor, mobile or portable structures (platforms) must be provided. In cases where it is impossible to create passages for mobile platforms, as well as for servicing equipment and fittings located at a height of 2.5 m or more, it is necessary to provide stationary platforms 0.6 m wide with fences and permanent stairs. The distance from the level of the stationary platform to the ceiling must be at least 1.8 m.

The minimum distance from the edge of the movable supports to the edge of the supporting structures (traverses, brackets, support pads) of pipelines should ensure the maximum possible lateral displacement of the support with a margin of at least 50 mm. In addition, the minimum distance from the edge of the traverse or bracket to the pipe axis must be at least 1.0 Dy (where Dy is the nominal diameter of the pipe).

The clear distance from the surface of the heat-insulating structure of the pipeline to the building structures of the building or to the surface of the heat-insulating structure of another pipeline must be at least 30 mm, taking into account the movement of the pipeline.

The laying of the water supply system must be carried out in one row or under the pipelines of heating networks, and the water supply system must be thermally insulated to prevent the formation of condensation on the surface of the water supply pipes.

At heating points, the supply pipeline must be located to the right of the return pipeline (along the coolant flow in the supply pipeline) when laying pipelines in one row.

For heating points, supply and exhaust ventilation should be provided, designed for air exchange, determined by heat release from pipelines and equipment. The design air temperature in the work area in the cold season should be taken no higher than 28°C, in the warm season - 5°C higher than the outside air temperature.

In the premises of heating points it is necessary to carry out measures to destroy insects and rodents (disinsection, deratization).

SNiP 41-02-2003

14.1 Heating points are divided into:
individual heating points (ITP)— for connecting heating, ventilation, hot water supply and technological heat-using installations of one building or part of it;
central heating points (CHS)- the same, two buildings or more.
14.2 Thermal points provide for the placement of equipment, fittings, monitoring, control and automation devices, through which the following is carried out:
transformation of the type of coolant or its parameters; control of coolant parameters;
accounting for heat loads, coolant and condensate flow rates;
regulation of coolant flow and distribution across heat consumption systems (through distribution networks in central heating stations or directly to heating and heating systems);
protection of local systems from emergency increases in coolant parameters;
filling and replenishing heat consumption systems;
collection, cooling, return of condensate and quality control;
heat accumulation;
water treatment for hot water supply systems.
At a heating point, depending on its purpose and local conditions, all of the listed activities or only part of them can be carried out. Devices for monitoring coolant parameters and metering heat consumption should be provided at all heating points.
14.3 The installation of an ITP input is mandatory for each building, regardless of the presence of a central heating point, while the ITP provides only for those measures that are necessary for connecting a given building and are not provided for in the central heating point.
14.4 In closed and open heat supply systems, the need to install central heating stations for residential and public buildings must be justified by technical and economic calculations.
14.5 In the premises of heating points it is allowed to place equipment for sanitary systems of buildings and structures, including booster pumping units that supply water for domestic drinking and fire-fighting needs.
14.6 Basic requirements for the placement of pipelines, equipment and fittings in heating points should be taken according to Appendix B.
14.7 The connection of heat consumers to heating networks at heating points should be provided according to schemes that ensure minimum water consumption in heating networks, as well as heat savings through the use of heat flow regulators and limiters of the maximum flow of network water, correction pumps or elevators with automatic control that reduce the temperature water entering heating, ventilation and air conditioning systems.
14.8 The design temperature of water in the supply pipelines after the central heating point should be accepted:
when connecting heating systems of buildings according to a dependent scheme - equal, as a rule, to the calculated water temperature in the supply pipeline of the heating networks to the central heating point;
with an independent scheme - no more than 30 °C below the design temperature of water in the supply pipeline of the heating networks to the central heating point, but not higher than 150 °C and not lower than the design temperature accepted in the consumer’s system.
Independent pipelines from central heating stations for connecting ventilation systems with an independent connection scheme for heating systems are provided at a maximum thermal load for ventilation of more than 50% of the maximum thermal load for heating.
14.9 When calculating the heating surface of water-water heaters for hot water supply and heating systems, the water temperature in the supply pipeline of the heating network should be taken equal to the temperature at the break point of the water temperature graph or the minimum water temperature if there is no break in the temperature graph, and for heating systems - also the temperature water corresponding to the calculated outside air temperature for heating design. The larger of the obtained values ​​of the heating surface should be taken as the calculated value.
14.10 When calculating the heating surface of hot water supply water heaters, the temperature of the heated water at the outlet from the water heater into the hot water supply system should be taken to be at least 60 °C.
14.11 For high-speed sectional water-to-water water heaters, a countercurrent flow pattern of coolant should be adopted, while heating water from the heating network should flow:
in water heaters of heating systems - in tubes;
the same for hot water supply - into the interpipe space.
In steam-water water heaters, steam must enter the inter-tube space.
For hot water supply systems with steam heating networks, it is allowed to use capacious water heaters, using them as hot water storage tanks, provided that their capacity corresponds to that required in the calculation for storage tanks.
In addition to high-speed water heaters, it is possible to use other types of water heaters that have high thermal and operational characteristics and small dimensions.
14.12 The minimum number of water-to-water heaters should be:
two, connected in parallel, each of which must be calculated for 100% of the heat load - for heating systems of buildings that do not allow interruptions in the heat supply;
two, each designed for 75% of the heat load, for heating systems of buildings constructed in areas with a design outdoor temperature below minus 40 °C;
one for other heating systems;
two, connected in parallel in each heating stage, designed for 50% of the heat load each - for hot water supply systems.
With a maximum heat load for hot water supply of up to 2 MW, it is allowed to provide one hot water supply water heater in each heating stage, except for buildings that do not allow interruptions in the supply of heat to hot water supply.
When installing steam-water water heaters in heating, ventilation or hot water supply systems, their number must be at least two, connected in parallel; backup water heaters need not be provided.
For technological installations that do not allow interruptions in the heat supply, backup water heaters must be provided, designed for the heat load in accordance with the operating mode of the enterprise's technological installations.
14.13 Pipelines should be equipped with fittings with shut-off valves with a nominal bore of 15 mm for releasing air at the highest points of all pipelines and with a nominal bore of at least 25 mm for draining water at the lowest points of water and condensate pipelines.
It is permissible to install devices for draining water not in the central heating station pit, but outside the central heating station in special chambers.
14.14 Mud traps should be installed:
at the heating point on the supply pipelines at the inlet;
on the return pipeline in front of control devices and water and heat flow metering devices - no more than one;
in ITP - regardless of their availability in the central heating center;
in thermal units of consumers of the 3rd category - on the supply pipeline at the inlet.
Filters should be installed in front of mechanical water meters (vane, turbine), plate heat exchangers and other equipment along the water flow (as required by the manufacturer).
14.15 At heating points, it is not allowed to install starting jumpers between the supply and return pipelines of heating networks, as well as bypass pipelines in addition to pumps (except for booster pumps), elevators, control valves, mud traps and devices for metering water and heat consumption.
Overflow regulators and steam traps must have bypass piping.
14.16 To protect pipelines and equipment of centralized hot water supply systems connected to heating networks through water heaters from internal corrosion and scale formation, water treatment should be provided, usually carried out in a central heating station. In ITP, only magnetic and silicate water treatment is allowed.
14.17 Treatment of drinking water should not worsen its sanitary and hygienic indicators. Reagents and materials used for water treatment that have direct contact with water entering the hot water supply system must be approved by the Russian State Sanitary and Epidemiological Supervision authorities for use in domestic drinking water supply practice.
14.18 When installing storage tanks for hot water supply systems in heating points with vacuum deaeration, it is necessary to protect the inner surface of the tanks from corrosion and the water in them from aeration by using sealing liquids. In the absence of vacuum deaeration, the internal surface of the tanks must be protected from corrosion through the use of protective coatings or cathodic protection. The design of the tank should include a device that prevents sealing liquid from entering the hot water supply system.
14.19 For heating points, supply and exhaust ventilation should be provided, designed for air exchange determined by heat release from pipelines and equipment. The calculated air temperature in the work area in the cold period of the year should be taken no higher than 28 °C, in the warm period of the year - 5 °C higher than the outside air temperature according to parameters A. When placing heating points in residential and public buildings, a verification calculation of heat inputs from heating point into adjacent rooms. If the permissible air temperature in these rooms exceeds the permissible air temperature, measures should be taken for additional thermal insulation of the enclosing structures of adjacent rooms.
14.20 A drain should be installed in the floor of the heating unit, and if gravity drainage of water is not possible, a drainage pit should be installed measuring at least 0.5 ‘0.5 x 0.8 m. The pit is covered with a removable grate.
To pump water from the catchment pit into the sewerage system, drainage system or associated drainage, one drainage pump should be provided. A pump designed for pumping water from a catchment pit is not allowed to be used for flushing heat consumption systems.
14.21 At heating points, measures should be taken to prevent noise levels from exceeding those allowed for premises in residential and public buildings. Heating units equipped with pumps are not allowed to be placed adjacent to or above the premises of residential apartments, dormitories and playrooms of preschool institutions, sleeping quarters of boarding schools, hotels, hostels, sanatoriums, rest homes, boarding houses, wards and operating rooms of hospitals, premises with long stays patients, doctors' offices, auditoriums of entertainment enterprises.
14.22 The minimum clear distances from free-standing ground central heating centers to the external walls of the listed premises must be at least 25 m.
In particularly cramped conditions, it is permissible to reduce the distance to 15 m, provided that additional measures are taken to reduce noise to a level acceptable according to sanitary standards.
14.23 Based on their placement on the general plan, heating points are divided into free-standing, attached to buildings and structures, and built into buildings and structures.
14.24 Heating units built into buildings should be located in separate rooms near the outer walls of buildings.
14.25 The following exits must be provided from the heating point:
if the length of the heating point room is 12 m or less - one exit to the adjacent room, corridor or staircase;
if the length of the heating point room is more than 12 m, there are two exits, one of which should be directly outside, the second to the adjacent room, staircase or corridor.
The premises of heating points for consumers of steam with a pressure of more than 0.07 MPa must have at least two exits, regardless of the dimensions of the room.
14.26 There is no need to provide openings for natural lighting of heating points. Doors and gates must open from the premises or building of the heating point away from you.
14.27 In terms of explosion and fire hazards, the premises of heating points must comply with category D according to NPB 105.
14.28 Heating units located in industrial and warehouse buildings, as well as administrative buildings of industrial enterprises, residential and public buildings, must be separated from other premises by partitions or fences that prevent unauthorized persons from accessing the heating unit.
14.29 For installation of equipment whose dimensions exceed the dimensions of the doors, installation openings or gates in the walls should be provided in ground-based heating units.
In this case, the dimensions of the installation opening and gate should be 0.2 m larger than the overall dimensions of the largest equipment or pipeline block.
14.30 To move equipment and fittings or integral parts of equipment units, inventory lifting and transport devices should be provided.
If it is impossible to use inventory devices, it is allowed to provide stationary lifting and transport devices:
with a mass of transported cargo from 0.1 to 1.0 tons - monorails with manual hoists and crampons or single-girder manual overhead cranes;
the same, more than 1.0 to 2.0 t - single-girder manual overhead cranes;
the same, more than 2.0 t - single-girder electric overhead cranes.
It is allowed to provide for the possibility of using mobile lifting and transport equipment.
14.31 To service equipment and fittings located at a height of 1.5 to 2.5 m from the floor, mobile platforms or portable devices (stepladders) must be provided. If it is impossible to create passages for mobile platforms, as well as to maintain equipment and fittings located at a height of 2.5 m or more, it is necessary to provide stationary platforms with fencing and permanent stairs. The dimensions of platforms, stairs and fences should be taken in accordance with the requirements of GOST 23120.
The distance from the level of the stationary platform to the upper ceiling must be at least 2 m.
14.32 In central heating stations with permanent staff, a bathroom with a washbasin should be provided.

Below are the requirements of regulatory documents relating to the premises of a heating point. The above list of requirements is not exhaustive and will expand over time. The technical requirements for the Heat Substation Premises were taken from the regulatory documentation governing the design, installation and operation of engineering systems of residential and public buildings and may differ from similar rules for objects for other purposes.

DBN V.2.5-39 Heat networks

Clause 16.5 - Chapter 16 Heating points

Equipment for sanitary systems of buildings and structures may be located in the premises of heating points.

In heating points built into residential buildings, pumps with an acceptable (low) noise level should be installed only.

Clause 16.20 - Chapter 16 Heating points

A drain should be installed in the floor of the heating unit, and if it is impossible to drain water by gravity, a drainage pit with dimensions of at least 0.5 x 0.5 x 0.8 m should be installed. The pit should be covered with a removable grate.

It is allowed to drain water not into a sump or drain of a heating point, but into special containers.

A single sump pump should be used to pump water from the catch basin to the sewer system, drainage system or associated drainage system.

A pump designed to pump water from a catchment pit is not allowed to be used for flushing a heat consumption system.

SNiP 2.04.01 Internal water supply and sewerage of buildings

Clause 12.3 - Chapter 12 Pumping units

Pumping units supplying water for domestic drinking, fire-fighting and circulation needs should, as a rule, be located in the premises of heating points, boiler rooms and boiler rooms.

Clause 12.4 - Chapter 12 Pumping units

It is not allowed to locate pumping units (except for fire departments) directly under residential apartments, children's or group rooms of kindergartens and nurseries, classrooms of secondary schools, hospital premises, workrooms of administrative buildings, auditoriums of educational institutions and other similar premises.

Pumping units with fire-fighting pumps and hydropneumatic tanks for internal fire extinguishing are allowed to be located in the first and basement floors of buildings of I and II degrees of fire resistance made of non-combustible materials. In this case, the premises of pumping units and hydropneumatic tanks must be heated, fenced off with fire walls (partitions) and ceilings and have a separate exit to the outside or to the staircase.

Notes:

• 1. In some cases, in agreement with local sanitary and epidemiological service authorities, it is allowed to locate pumping units next to the listed premises, while the total noise level in the premises should not exceed 30 dB.
• 2. Rooms with hydropneumatic tanks should be located directly (next to, above, below) with rooms where a large number of people can stay simultaneously - 50 people. and more (auditorium, stage, dressing room, etc.) are not allowed. Hydropneumatic tanks may be located on technical floors. When designing hydropneumatic tanks, the requirements of the “Rules for the Design and Safe Operation of Pressure Vessels” of the USSR State Mining and Technical Supervision Committee should be taken into account. In this case, the need to register hydropneumatic tanks is established by paragraphs 6-2-1 and 6-2-2 of these Rules.
• 3. It is not allowed to locate fire pumping installations in buildings in which the power supply is interrupted during the absence of maintenance personnel.

SNiP 2.04.05 Heating, ventilation and air conditioning

Clause 10.8 - Chapter 10 Space planning and design solutions

With centralized heat supply to buildings, they must provide premises for individual heating points, which must meet the requirements of the standards for the design of heating networks. To place electronic devices for commercial heat consumption metering, it is necessary to provide premises protected from unauthorized access that meet the requirements for the operation of these devices.

An individual heating point is designed to save heat and regulate supply parameters. This is a complex located in a separate room. Can be used in a private or apartment building. ITP (individual heating point), what it is, how it works and functions, let’s take a closer look.

ITP: tasks, functions, purpose

By definition, an IHP is a heating point that heats buildings completely or partially. The complex receives energy from the network (central heating station, central heating point or boiler house) and distributes it to consumers:

• DHW (hot water supply);
• heating;
• ventilation.

At the same time, it is possible to regulate, since the heating mode in the living room, basement, and warehouse is different. The ITP is assigned the following main tasks.

• Heat consumption accounting.
• Protection against accidents, control of parameters for safety.
• Disabling the consumption system.
• Even heat distribution.
• Adjustment of characteristics, control of temperature and other parameters.
• Coolant conversion.

To install ITP, buildings are modernized, which is not cheap, but brings benefits. The point is located in a separate technical or basement room, an extension to the house or a separate building located nearby.

Benefits of having an ITP

Significant costs for the creation of an ITP are allowed in connection with the benefits that follow from the presence of a point in the building.

• Cost-effective (in terms of consumption - by 30%).
• Reduce operating costs by up to 60%.
• Heat consumption is controlled and taken into account.
• Optimization of modes reduces losses by up to 15%. The time of day, weekends, and weather are taken into account.
• Heat is distributed according to consumption conditions.
• Consumption can be adjusted.
• The type of coolant is subject to change if necessary.
• Low accident rate, high operational safety.
• Full automation of the process.
• Silence.
• Compactness, dependence of dimensions on load. The item can be placed in the basement.
• Maintenance of heating points does not require numerous personnel.
• Provides comfort.
• The equipment is completed to order.

Controlled heat consumption and the ability to influence performance are attractive in terms of savings and rational resource consumption. Therefore, it is believed that the costs are recouped within an acceptable period.

Types of TP

The difference between TPs is in the number and types of consumption systems. Features of the type of consumer predetermine the design and characteristics of the required equipment. The method of installation and placement of the complex in the room differs. The following types are distinguished.

• ITP for a single building or part thereof, located in the basement, technical room or nearby structure.
• Central heating center - the central heating center serves a group of buildings or objects. Located in one of the basements or a separate building.
• BTP - block heating point. Includes one or more units manufactured and supplied in a factory. It features compact installation and is used to save space. Can perform the function of ITP or TsTP.

Principle of operation

The design diagram depends on the energy source and specific consumption. The most popular is independent, for a closed hot water system. The operating principle of ITP is as follows.

1. The heat carrier arrives at the point through a pipeline, giving the temperature to the heating, hot water and ventilation heaters.
2. The coolant goes into the return pipeline to the heat generating enterprise. Reusable, but some may be used by the consumer.
3. Heat losses are replenished by make-up available in thermal power plants and boiler houses (water treatment).
4. Tap water enters the heating installation, passing through a cold water pump. Part of it goes to the consumer, the rest is heated by the 1st stage heater, sent to the DHW circuit.
5. The DHW pump moves water in a circle, passing through the consumer's TP, and returns with partial flow.
6. The 2nd stage heater operates regularly when the liquid loses heat.

The coolant (in this case, water) moves along the circuit, which is facilitated by 2 circulation pumps. Its leaks are possible, which are replenished by replenishment from the primary heating network.

Schematic diagram

This or that ITP scheme has features that depend on the consumer. A central heat supplier is important. The most common option is a closed hot water system with an independent heating connection. A heat carrier enters the TP through a pipeline, is sold when heating water for the systems, and is returned. For return, there is a return pipeline going to the main line to the central point - the heat generation enterprise.

Heating and hot water supply are arranged in the form of circuits through which the coolant moves with the help of pumps. The first is usually designed as a closed cycle with possible leaks replenished from the primary network. And the second circuit is circular, equipped with pumps for hot water supply, supplying water to the consumer for consumption. When heat is lost, heating is carried out by the second heating stage.

ITP for different consumption purposes

Being equipped for heating, the IHP has an independent circuit in which a plate heat exchanger with 100% load is installed. Pressure loss is prevented by installing a double pump. Make-up is carried out from the return pipeline in the heating networks. Additionally, the TP is equipped with metering devices, a DHW unit if other necessary components are available.


ITP intended for hot water supply is an independent circuit. In addition, it is parallel and single-stage, equipped with two plate heat exchangers loaded at 50%. There are pumps that compensate for the decrease in pressure, and metering devices. The presence of other nodes is assumed. Such heat points operate according to an independent scheme.

This is interesting! The principle of district heating for a heating system can be based on a plate heat exchanger with 100% load. And the DHW has a two-stage circuit with two similar devices, each loaded by 1/2. Pumps for various purposes compensate for the decreasing pressure and recharge the system from the pipeline.

For ventilation, a plate heat exchanger with 100% load is used. DHW is provided to two such devices loaded at 50%. Through the operation of several pumps, the pressure level is compensated and replenishment is provided. Addition - accounting device.

Installation steps

During installation, the TP of a building or facility undergoes a step-by-step procedure. The mere desire of the residents in an apartment building is not enough.

• Obtaining consent from the owners of premises in a residential building.
• Application to heat supply companies for design in a specific house, development of technical specifications.
• Issuance of technical specifications.
• Inspection of a residential or other facility for the project, determining the presence and condition of equipment.
• The automatic TP will be designed, developed and approved.
• An agreement is concluded.
• The ITP project for a residential building or other facility is being implemented and tests are being carried out.

Attention! All stages can be completed in a couple of months. The responsibility is entrusted to the responsible specialized organization. To be successful, a company must be well established.

Operational safety

The automatic heating point is serviced by properly qualified workers. The staff is introduced to the rules. There are also prohibitions: the automation does not start if there is no water in the system, pumps are not turned on if the shut-off valves at the inlet are closed.
Requires control:

• pressure parameters;
• noises;
• vibration level;
• engine heating.

The control valve must not be subjected to excessive force. If the system is under pressure, the regulators are not disassembled. Before starting, the pipelines are flushed.

Permission to operate

The operation of AITP complexes (automated ITP) requires obtaining permission, for which documentation is provided to Energonadzor. These are technical connection conditions and a certificate of their implementation. Needed:

• agreed upon design documentation;
• act of responsibility for operation, balance of ownership from the parties;
• act of readiness;
• heating points must have a passport with heat supply parameters;
• readiness of the thermal energy metering device - document;
• certificate of existence of an agreement with the energy company for the provision of heat supply;
• work acceptance certificate from the installation company;
• An order appointing someone responsible for the maintenance, serviceability, repair and safety of the ATP (automated heating point);
• list of persons responsible for maintenance of AITP installations and their repair;
• a copy of the welder’s qualification document, certificates for electrodes and pipes;
• acts on other actions, as-built diagram of an automated heating point facility, including pipelines, fittings;
• certificate for pressure testing, flushing of heating, hot water supply, which includes an automated point;
• briefing

An admission certificate is drawn up, logs are kept: operational, on instructions, issuance of work orders, detection of defects.

ITP of an apartment building

An automated individual heating point in a multi-storey residential building transports heat from central heating stations, boiler houses or combined heat and power plants (CHP) to heating, hot water supply and ventilation. Such innovations (automatic heating point) save up to 40% or more of thermal energy.

Attention! The system uses a source - the heating networks to which it is connected. The need for coordination with these organizations.

A lot of data is required to calculate modes, loads and savings results for payments in housing and communal services. Without this information, the project will not be completed. Without approval, the ITP will not issue permission to operate. Residents receive the following benefits.

• Greater accuracy of temperature maintenance devices.
• Heating is carried out with a calculation that includes the state of the outside air.
• The amounts for services on housing and communal services bills are being reduced.
• Automation simplifies facility maintenance.
• Reduced repair costs and personnel numbers.
• Finances are saved on the consumption of thermal energy from a centralized supplier (boiler houses, combined heat and power plants, central heating stations).

Bottom line: how the savings happen

The heating point of the heating system is equipped with a metering unit upon commissioning, which is a guarantee of savings. Heat consumption readings are taken from the devices. Accounting itself does not reduce costs. The source of savings is the possibility of changing modes and the absence of overestimation of indicators on the part of energy supply companies, their precise determination. It will be impossible to attribute additional costs, leakages, and expenses to such a consumer. Payback occurs within 5 months, as an average, with savings of up to 30%.

The supply of coolant from a centralized supplier - the heating main - is automated. Installation of a modern heating and ventilation unit allows you to take into account seasonal and daily temperature changes during operation. Correction mode is automatic. Heat consumption is reduced by 30% with a payback period of 2 to 5 years.