RU62218U1 - HEAT SUPPLY SYSTEM - Google Patents

Abstract

The utility model relates to a power system and allows to increase the efficiency and resource of heat supply systems. The system includes a heat generator 1 connected by a return pipe 2 to the output of the circulation pump unit 3, the input of which is connected to the first output of the filter 4. The output of the heat generator 1 is connected to the input of another filter 5, the first output of which is connected by a supply pipe 6 to the input of the consumer 7, the output of which is connected with the input of the filter 4. The first input of the sampling unit 8 and the first input of the cooling and filtration unit 9 are connected to pipeline 6. The first input of the surface-active emulsion preparation unit is connected to pipeline 2 another 10, the second input of which is connected to the source of surfactants 11, and the output with the input of the accumulation unit of the emulsion of surfactants 12. The first output of block 12 is connected to the input of the registration and analysis of samples 13, the second output is connected to the input of the dosing unit and accounting for the emulsion of surfactants 14, the output of which is connected to the input of the pumps 3 and the output of the first filter 4 and the pipe 6 to the input of the consumer 7. The pipe 2 is connected to the second input of the block 8 and to the third input of the block 9. The input of the heat recharge unit heating system carrier 15, the third input of block 8 and the second input of block 9 are connected to a water source. The first output of the coolant recharge unit 15 is connected to the input of the filter 4, and its second output to the first input of the preparation and supply of the air-air mixture 16. The output of the compressed air supply 17 is connected to the second input of the block 16, and its input to the air source. The first output of block 16 is connected by a pipe 6 to the input of consumer 7, and its second output by a pipe 2 to the output of consumer 7. The first output of block 8 is connected to the second block 18, and the first output of block 9 is connected to the third block of registration and analysis of samples 19. Second outputs filters 4, 5, block 8 and block 9 are connected to the recycling unit 20. 1 ill., 1 pfp

Description

The utility model relates to a power system and is intended for use in centralized and autonomous heat supply systems of residential buildings and industrial premises. In addition, it ensures the removal of old deposits, slows down the rate of corrosion and accumulation of deposits on the surfaces of pipelines, fittings and associated heat exchangers, in particular heating appliances and other functional surfaces, while providing the possibility of using unprepared water as a coolant, as from surface sources (from rivers, lakes, ponds), and underground (artesian wells).

A known heat supply system (see the rules for the technical operation of power plants, registered in the Ministry of Justice of the Russian Federation on 04.04.2003 No. 4358 p.117) containing a heating circuit that includes a heat generator, the outlet of which is connected to a supply pipe connected to the consumer, and the input of the heat generator is connected to the output of the circulation pump unit, at the input of which the first output of the filter is connected, the input of which is connected by a return pipe to the consumer's output, a water source connected to the input of the control, metering and supply unit chi water, the outlet of which is connected to the inlet of the filter. Equipment cavities and pipelines are filled with a coolant in the form of softened deaerated water specially prepared to reduce the corrosion rate of metal surfaces and form deposits on them before the start of the heating period, the heating medium is moved, heated and cooled by pumps and heat exchange equipment, and coolant leaks from softened deaerated water to the heating medium are replenished period, as well as emptying the cavities, hydropneumatic washing, filter cleaning and dirt collectors and protection of equipment surfaces from corrosion during the period of inactivity after the end of the heating period or during repair.

However, such a system does not provide highly effective protection against corrosion, requires large financial and operating costs, and leads to the discharge of a significant amount of wastewater, with large concentrations of salts. In addition, during downtime, additional special measures are required to protect internal surfaces from corrosion.

The closest in technical essence to a utility model is a heat supply system (see codes of rules for design and construction, design of heating units, agreed by the main department of standardization, technical regulation and certification of the Ministry of Construction of Russia SP 41-101-95, introduction date 1996-07-01 p. 87), containing a heating circuit that includes a heat generator, to the output of which a supply pipe is connected that is connected to the consumer, and the input of the heat generator is connected to the output of the circulation pump unit, the inlet of which includes the first output of the filter, the input of which is connected by a return pipe to the consumer's output, a water source connected to the input of the control unit, metering and water supply, the output of which is connected to the input of the filter. The cavities of the equipment and pipelines are filled with a coolant in the form of softened deaerated water specially prepared to reduce the corrosion rate of metal surfaces and form deposits on them before the start of the heating period, the movement, heating and cooling of the coolant with pumps and heat exchange equipment are provided, and the coolant leaks with softened deaerated water to the heating period.

However, such a system is ineffective, requires high capital and operating costs for water treatment, but does not remove the problem of corrosion and the formation of deposits, it has low efficiency of heat exchange equipment, high operating costs, and low operating life of the systems.

The technical task of the utility model is to increase the efficiency and resource of heat supply systems, reduce capital and

operating costs, improving the environment, improving the protection of heat exchange equipment and pipelines from corrosion and from the formation of deposits.

The solution to this technical problem is achieved by the fact that the known heat supply system containing a heating circuit including a heat generator, to the output of which a supply pipe is connected, connected to the consumer, and the input of the heat generator is connected to the output of the circulation pump unit, at the input of which the first filter output is connected, the input of which is connected by a return pipe to the consumer's output, a water source connected to the input of the control unit, metering and water supply, the output of which is connected to the filter input a, is equipped with a surfactant source, a surfactant emulsion preparation unit, the first inlet of which is connected to a return pipe, a second inlet is connected to a surfactant source, a surfactant emulsion storage unit, a first sample analysis and registration unit, connected to the first output of the surfactant emulsion storage unit, the dosing and metering unit of the surfactant emulsion, the input of which is connected to the second output of the surfactant accumulation of an emulsion of surfactants, and the output to the inlet of the circulation pump unit and the supply pipe to the consumer input, another filter included in the heating circuit and connected by the supply pipe to the heat generator output and the consumer input, cooling and filtering unit, the first input of which is connected by the supply pipe with the consumer input, the second input is connected to the third output of the control unit, metering and water supply, and the third input is connected to the consumer output, sampling unit, the second a sample analysis and recording unit connected to the first output of the sampling unit, the first input of which is connected by a supply pipe to the first output of another filter, the second input is connected by a return pipe to the consumer output, and the third input is connected to the fourth output of the control, metering and

water supply, the third unit of analysis and registration of samples connected to the first output of the cooling and filtration unit, the disposal unit whose input is connected to the second outputs of the filters, cooling and filtration and sampling units, the compressed air preparation and supply unit, the inlet of which is connected to the air source, a unit for preparing and supplying the air-water mixture, the first input of which is connected to the second output of the unit for regulating, metering and supplying water, and its second input is connected to the output of the unit for preparing and supplying compressed air, and you ode connected supply and return piping to the input and output of the consumer.

The essence of the utility model is illustrated by the drawing, which shows a block diagram of a heat supply system.

The heat supply system comprises a heating circuit including a heat generator 1 having, for example, a boiler or heat exchanger connected by a return pipe 2 to the output of the circulation pump unit 3, the input of which is connected to the first output of the filter 4. The output of the heat generator 1 is connected to the input of another filter 5, the first output of which is connected by the supply pipe 6 to the input of the consumer 7, the output of which is connected to the input of the filter 4. The first input of the sampling unit 8, the first input of the cooling unit are connected to the supply pipe 6 filtration 9. The first input of the preparation unit for the emulsion of surfactants 10 is connected to the return pipe 2, the second input of which is connected to the source of surfactants 11, and the output to the input of the storage unit of the emulsion of surfactants 12. The first output of the emulsion storage unit is surface -active substances 12 is connected to the input of the unit for registration and analysis of samples 13, the second output is connected to the input of the dosing and metering unit of the emulsion of surface-active substances 14, the output of which is connected to the input of ka circulation pumps 3 and the output of the first filter 4 and the supply pipe 6 to the input of the consumer 7.

The return pipe 2 is connected to the second input of the sampling unit 8 and to the third input of the cooling and filtration unit 9. Water source

connected to the input of the control unit, metering and water supply 15, the first output of which is connected to the input of the filter 4, its second output is connected to the first input of the preparation and supply of the air-air mixture 16, the third output is connected to the second input of the cooling and filtration unit 9, and the fourth the output is connected to the third input of the sampling unit 8. The output of the compressed air supply 17 is connected to the second input of the preparation and supply of the air-air mixture 16, and its input is an air source. The first output of the preparation and supply of the air-water mixture 16 is connected by a supply pipe 6 to the input of the consumer 7, and its second output by a return pipe 2 to the output of the consumer 7.

The first output of the sampling unit 8 is connected to the second analysis and registration unit of the samples 18, and the first output of the cooling and filtration unit 9 is connected to the third unit of the registration and analysis of samples 19. The second outputs of the filters 4, 5, sampling unit 8 and the cooling and filtration unit 9 are connected to the disposal unit 20.

Film-forming amines, for example, octadecylamine, are used as surfactants.

The system operates as follows.

Before the start of the heating period, water, which is the coolant of the system, is supplied to the control unit, metering and water supply 15 from the first output of which water flows through the return pipe 2 to the consumer 7, as well as to the filter 4, the circulation pump unit 3, the heat generator 1, filter 5 supplying the pipeline 6. For water supply to the heat supply system, tap water, natural water, both surface (from rivers, lakes, ponds) and underground (from artesian wells) can be used.

After starting the heating system, the circulation pump unit 3 provides the movement of the coolant, the heat generator 1 heats up, and the consumer 7 provides cooling of the coolant, while the coolant is cleaned in filters 4, 5.

During operation of the heating system without changing operating modes and forced stops at the input of the circulation pump unit 3, a constant or periodic dosing of surfactants is carried out. Surfactants from block 11 enter the second input of the emulsion preparation block 10, and the coolant enters the first input through the return pipe 2 from the consumer 7. As a result, an aqueous emulsion of surfactants comes from the outlet and is fed to the input of the surfactant emulsion accumulation unit 12, which ensures uninterrupted supply and preservation of the necessary properties of the emulsion, while the analysis and recording unit 13 systematically determines the quality of the emulsion from periodically taken samples . The finished emulsion enters the dosing and metering unit of the emulsion of surfactants 14, which provides the optimal amount of surfactants in the circuit of the heating system and registers the emulsion consumption. To maintain the calculated concentration of the emulsion of surface-active substances in the coolant during the operation of the heating system from the supply 6 and return 2 pipelines, sampling is performed. To do this, in the process of work, water is supplied to the third input of block 8, cooling the coolant entering the first and second inputs from direct 6 and return 2 pipelines. After cooling the coolant, water enters the recovery unit 20, and the coolant in the form of a sample is analyzed in block 18.

The dosing process is stopped when the optimum concentration of surfactants in the circuit is reached, depending on the characteristics of a particular heating system (surface material of heating appliances, distribution pipes, heat transfer quality, etc.).

In the process, insoluble compounds are deposited in filters 4, 5. To ensure good filtration of the coolant, periodically wash the filters 4, 5 with coolant, for this periodically

they are washed with coolant, which then enters the block 20 for disposal.

At the end of the heating period, the heating circuit is emptied. For this, the coolant enters block 9, in which it is cooled, filtered and supplied to block 19 for subsequent analysis. The coolant then goes to the disposal unit 20.

In the inter-heating period, deposits are removed from the functional surfaces of equipment and pipelines of consumer 7, supply and return pipelines 2 and 6, filters 4 and 5 using hydraulic and hydropneumatic flushing.

The washing is carried out with water supplied from the source to the input of the control unit, metering and water supply 15 and compressed air entering the input of the compressed air preparation and supply unit 17. Water with the required parameters is supplied to the first input, and compressed air to the second input of the preparation and supply unit of air-water mixture 16, in which the working fluid is formed for flushing the system. From block 16, the working fluid with the necessary parameters is fed through a supply pipe 6 or return 2, the first or second exits, to the consumer 7, filters 4, 5, heat generator 1. The spent working fluid, water flow or air-water mixture, is fed to the first or third inputs block 9, in which it is filtered, enters through the first output to the block analysis and registration of samples 19 and is disposed of through the second output in block 20.

In case of violation of the continuity of the film of surfactant on the functional surfaces of the heating system during the washing process, measures are taken to form a new protective film. For this, during the washing process or at the end of it, the surfactant molecules are dosed into the working medium through the first or second outputs of block 14. Thus, reliable corrosion protection is provided for the period of inactivity, right up to the start of the heating period.

Washing is completed after removal of deposits from the internal surfaces of the equipment and the formation of an anti-corrosion film of surfactants on them.

Using the utility model provides an increase in the efficiency and resource of heat supply systems, a decrease in capital and operating costs, an improvement in the environment, and an increase in the protection of heat exchange equipment and pipelines against corrosion and from the formation of deposits.

Claims (1)

A heat supply system comprising a heating circuit including a heat generator, the output of which is connected to a supply pipe connected to a consumer, and the input of a heat generator is connected to the output of a circulation pump unit, at the input of which a first filter output is connected, the input of which is connected by a return pipe to the consumer output, a water source connected to the input of the control unit, metering and water supply, the output of which is connected to the input of the filter, characterized in that it is equipped with a surface source active substances, a surfactant emulsion preparation unit, the first input of which is connected to the return pipe, the second input is connected to a surfactant source, a surfactant emulsion storage unit, a first sample analysis and registration unit, connected to the first output of the accumulation unit emulsions of surfactants, by the metering and metering unit of the emulsion of surfactants, the input of which is connected to the second output of the emulsion accumulation unit of the surfactant - active substances, and the output is to the input of the circulation pump unit and the supply pipe to the consumer input, another filter included in the heating circuit and connected by a supply pipe to the output of the heat generator and the consumer input, a cooling and filtering unit, the first input of which is connected by a supply pipe to the consumer input , the second input is connected to the third output of the control unit, metering and water supply, and the third input is connected to the consumer output, the sampling unit, the second analysis and registration unit of samples, p connected to the first output of the sampling unit, the first input of which is connected by a supply pipe to the first output of another filter, the second input is connected by a return pipe to the consumer's output, and the third input is connected to the fourth output of the control unit, metering and water supply, the third sample analysis and registration unit connected to the first output of the cooling and filtering unit, a disposal unit, the input of which is connected to the second outputs of the filters, cooling and filtering and sampling units, the preparation and supply unit is compressed air, the inlet of which is connected to the air source, the unit for the preparation and supply of water-air mixture, the first inlet of which is connected to the second output of the control unit, metering and water supply, and its second input is connected to the output of the unit for preparation and supply of compressed air, and the outputs are connected to the supply and a return pipe to the input and output of the consumer.