SU1165851A1 - System for centralized heat and cold supply of non-interacting air conditioning plants - Google Patents

Abstract

1. A system for centralized heat and cold supply of non-autonomous air-conditioning installations, comprising a circulation loop with subsupply and two-way pipelines, a storage tank, a pumping station, two heat exchangers and irrigation chambers with a sump, a pipe collector nozzles and a circulation pump, at the same time, the storage tank is connected through a pumping station, two heat exchangers parallel to each other installed in a circulation circuit I and through a supply pipeline with parallel On the other, irrigation chambers, characterized in that, in order to increase efficiency, the system is equipped with a drain tank, which is connected via an installed overflow line with an accumulator tank and communicated through an additionally located pump with a connecting pipe and heat exchangers inlet The inlet and outlet of the heat exchangers are fitted with regulating locking elements, heat output. the exchangers are communicated via the additionally located return pipe: the pipeline with the storage tank, and the irrigation X1 measures are connected through the return pipe to the drain tank. 2. The system of claim 1, wherein the irrigation chambers are equipped with a second-row pipe nozzle collector along the air path, a partition is installed in the pan, the supply pipe is connected to the second-row pipe nozzle collector, the circulation pump is connected to the second nozzle tray It is also equipped with a pipe collector, nozzles of the first row, and the return pipe is connected with a nozzle tray of the first row. : l eo s71

Description

The invention relates to an air-conditioning technique and can be used, in particular, in systems for heat and cold supply of air-conditioning installations with mixing heat and mass transfer devices.

The purpose of the invention is to increase the efficiency of the system.

The drawing shows a schematic diagram of a system for centralized heat and cold supply of non-autonomous air conditioning installations,.

The system contains a circulation circuit with supply and return pipelines 1 and 2, a tank-battery 3, a pumping station 4 ,. two parallel1O arranged heat exchanger - water cooler 5 and n heater 6, and connected in parallel irrigation j chambers 7, having a pallet 8, a pipe collector nozzles 9 and 10, respectively, first and row, a partition 11 in the pallet and circ. lion pump 12,

The system is equipped with a drain tank 13, which is connected through an overflow. line 14 to the storage tank .3 and communicated via pump 1b with the supply pipe 1 and to the inlet of the water coolers 5 and heaters b ,,

At the inlet and outlet of the water coolers 5 and heaters 6, regulating locking elements 16-19 are installed in the form of; for example, three-way shut-off control valves.

The output of the water coolers 5 and heaters b communicates via an additional return pipe 20 to the storage tank 3, the irrigation chambers 7 are connected via a return pipe 2 to the drain tank 13, while the supply pipe 1 is connected to the second-row pipe nozzle collector 21 The circulation pump 12 is connected to the pallet 8 of the nozzles 10 of the second row and to the pipe collector of the injector 9 of the first row, and the return pipe 2 is connected to the pallet of 8 nozzles 9 of the first row of chambers 7.

Flow sensors 1, pressure sensors 23, and temperatures 24 are installed on flow line 1, and temperature sensors 25 are connected to additional flow lines 20 and are associated with flow control, pressure, and temperature regulators 2628, respectively. element 21 on the supply line 1 ,. The output of the pumping station 4 is connected to the supply pipe 1 through the locking element 29.

The system for centralized heat and cold supply of non-autonomous air-conditioning installations works as follows.

In the warmer months, with the minimum flow rate of chilled water, according to the signal of the flow controller 26 and the multichannel temperature controller 28, the storage tank 3 begins to be charged with cold. At the same time, the pump station 4 is put into operation (it is possible to connect the pumps in groups), which supplies water from the storage tank 3 through, for example, a shut-off element 17

0 to one of the water coolers 5 of the refrigeration unit (not shown) and from the water cooler 5 through the locking element 16 and through the additional return pipe 20 to the storage tank Z. The temperature of the cooled water is monitored. the temperature sensor 25 and when the predetermined value of the water temperature is reached, the charging of the storage tank 3 is terminated with

using temperature controller 28 with

 disconnecting the pumping station 4 and the water cooler 5. In the process of charging the storage tank 3. and after it has been carried out, the chambers 7 are supplied with cooled water by means of pump units 15, which take water from the drain tank 3 and feed it into another located water-. chiller 5 through the locking element 17. From the water cooler 5, cooled water through the locking element 16 and suction pipe 1 enters the chambers 7. Maintaining a given water pressure in the flow pipe 1 is provided by a pressure regulator 27, which acts. works on the locking element 21 ..

In each irrigation chamber, 7 required quantity of chilled water

0 enters the pipe collector 10 of the second row of nozzles 10 (along the air), sprays and collects in the chamber 7 in the second compartment (along the air) of the pallet 8, from where the pump 12

J is supplied to the pipe collector of the nozzles 9 of the first row, where it is also sprayed and collected in the tank 7 in the first compartment of the pan 8. From the pan 8, water flows through the hydraulic lock and return pipe 2 into the drain tank 13.

The storage tank 3 is discharged by a signal from flow controllers 26 and pressure 27, when, as a result of an increase in consumption

chambers 7 cooled in water coolers 5 water is not enough. In this case, the pump station 4 is commissioned (if necessary, by groups of pumps) and supplies cooled water from the storage tank 3 through the currently open stop element 29 to the supply pipe 1.

The excess amount of wastewater flowing from the return pipe 2 to the drain, tank 13, overflow pipe 14 is discharged into the storage tank 3. In the cold season, with a minimum flow of heated water, the flow regulators 26 and the temperature 28 are charged. heat storage tank. At that, the pump station 4 is turned on (it is possible to connect the pumps in groups), which supplies water from the storage tank through, for example, the stop element 19 to one of the heaters 6 to the short circuit of the heater 6 through the stop element 18 and the additional return pipe 20 - into the tank 3. The temperature of the heated water is monitored by the sensor 25 and when the set water temperature is reached, the charging of the tank 3 is stopped using a regulator, 28 temperatures with the pump station turned off and the water heater body 6. In the process of charging the storage tank 3 and after it has been supplied, the chambers 7 are heated with water by means of pumps 15, which take water from the drain tank 13 and feed it, for example, to another, parallelly located heater b shut-off element 19. Water is heated from the heater 6 through the shut-off element 18 and the supply pipe 1 enters the chambers 7. Maintaining a predetermined water pressure in the supply line 1 is provided by a pressure regulator 27, which acts on the shut-off element 21. the redistribution of water in chambers 7 in the cold period of the year is carried out similarly to the above described operation of chambers 7 in the warm period of the year. The storage tank 3 is discharged by the signal of the flow controllers 25 and pressure 28 when, as a result of the increase in consumption in the chamber 7, the water heated in the heaters b is not enough. In this case, if necessary, the pumping station 4 is put into operation by groups of pumps) and supplies heated water from the storage tank 3 through the currently open shut-off element 29 to the supply pipe 1. Excessive amount of waste water coming from the return pipe 2 the drain tank 13, through the overflow pipe 14, is discharged into the storage tank 3.

Claims (2)

1. A system for centralized heat and cold supply of non-autonomous air conditioning units, containing a circulation circuit with supply and return pipelines, a storage tank, a pump station, two heat exchangers and irrigation chambers having a tray, a pipe manifold of nozzles and a circulation pump, while the tank the battery is connected through a pump station installed in the circulation I circuit two heat exchangers in parallel, and through the supply pipe with irrigation chambers located parallel to each other, characterized in that, in order to increase work efficiency, the system is equipped with a drain tank, which is connected through an installed overflow line with a storage tank and communicated through an additionally located pump with a supply pipe and with the inlet of the heat exchangers, at the inlet and outlet of the heat exchangers control shut-off elements are installed, the heat output. exchangers communicated through an additionally located return pipe with a storage tank, and irrigation chambers are connected through a return pipe to a drain tank 2. The system by π. 1, characterized in that the irrigation chambers are equipped with a pipe collector of nozzles of the second row along the air flow, a partition is installed in the pan, a supply pipe is connected to the pipe collector of nozzles of the second row, the circulation pump is connected to the pallet of nozzles of the second row and to the pipe collector, nozzles of the first row , and the return pipe is shared with the sump of nozzles of the first row