SU217405A1 - CENTRALIZED COOLING SYSTEM - Google Patents

Description

A centralized heat supply system is known, which includes a steam ejector unit with an evaporator connected to the cold supply network and a condenser-deaerator connected to the heating network, and a water heater of the hot water system.

In the proposed system for providing water de-aeration, the condenser is made with a distribution device installed therein and a coil connected to the water supply network.

The system, in order to prevent it from being fed with non-deaerated water, is provided with a steam generator connected to a return pipeline. The steam generator coil is connected in series with a water heater, which ensures self-regulation of heat supply in the heat supply system.

The drawing shows a diagram of the proposed system.

The steam-sector refrigeration installation of the system consists of an ejector 1, an evaporator 2 and a condenser 3, connected by a steam line 4, a steam generator 5, auxiliary ejectors, a gas separator tank 8. In addition, the heating system 9 includes a heating system pump 10 and a supply pipe 11 Consumers 12 of heat from the hot water supply and heating system with a reverse circulation pipe 13 are connected to this pipeline. The system also includes the input of a water supply system 14, a cooling supply network pump 15, sweat cold side 16, cold pipeline 17, supply pipe 18 of the urban heating system, return pipeline 19 of the urban heating system. In the condenser 3 installed switchgear 20 and the coil 21, connected to the water supply network.

The cold is obtained as follows. In the steam generator 5, from the return circulation pipe 13, a portion of the circulation water is supplied from the intra-district heating system, which is heated in it by the water supplied through the pipeline 18 to the coil from the city heating system. Under pressure 0, ata

circulating water evaporates.

The working steam rushes into the nozzle of the ejector 1 and, when it leaves it at high speed, creates a deep vacuum in the evaporator 2, in which the water heated by the consumer from the refrigeration system boils and evaporates at a low temperature.

the vapor of the evaporator is sent to the condenser 3, where it is condensed under vacuum much less than in the evaporator. In order to cool down the seeded steam, tap water is supplied to the condenser 3 through the pipeline for use in the hot water supply system.

Having heated up in the condenser coil 3, this water enters the auxiliary ejector 6, with a HELP. And of which a gas-air mixture is sucked out of the condenser through a pipeline.

Thus, for the operation of the ejector, the water pressure in the return pipe 13 is used. To create a deeper vacuum, a second auxiliary ejector 7 is used, connected in series with the ejector 6 and operating under pressure in the urban water supply network.

A mixture of heated tap water, water from the return pipe 13 and the gas-air mixture sucked from condenser 3 enters the gas separator tank 8. From this tank, the gas-air mixture is removed to the atmosphere, and the mixture of water and circulating water enters back to the condenser for deaeration. Cold tap water is heated in the condenser coil a few degrees below the condensation temperature so that the temperature of the mixed water coming in to the tank is slightly higher than the temperature of the vapors entering them to the condenser from the ejector 1, i.e. The superheated water would have boiled due to overheating, deaerating it.

The vapors from the ejector 1, together with the steam. M, formed from the mixture of tap and circulating water, are condensed and deaerated.

The condensate freed from oxygen and gases is pumped into the water heater 9 by the pump 10. The water, heated to the required temperature, is supplied to the consumer 12 with hot water through the pipeline 11.

The sequential connection scheme of the steam generator 5 with the water heater 9 ensures the self-regulation of heat transfer when too much water is supplied from the pipe 13 to the steam generator 5.

Thus, condenser 3 is used in the proposed system at the same time as a deaerator and a P-stage of heating water supplied to the heat-transfer system. The pressure of the circulating line and the city water network serves to create a vacuum in the condenser. By combining the preparation of cold and heat, as well as the vacuum deaeration of water, the condenser does not consume electricity. This creates a vacuum, eliminates the device for vacuum deaeration, eliminates the water loss that has occurred in the previously proposed schemes, and reduces the total heat consumption for getting cold.

Subject invention

Claims (3)

1. District heating system, including a steam ejector refrigeration unit with an evaporator connected to the cold supply network, and with a condenser-deaerator connected to the heat network, the water heater of the hot water supply system, so as to ensure water de-aeration, the condenser is with a distribution device installed in it and a coil connected to the water mains. 2. A system according to claim 1, characterized in that, in order to prevent the system from being fed with non-deaerated water, the system is provided with a steam generator connected to a return pipeline. 3. The system of claim 1, characterized in that, for the purpose of self-regulating heat supply in the heat supply system, the steam coil is connected in series with a water heater. G8