SU753224A1 - Staged thermocompressor unit - Google Patents

Abstract

Ü CASCADE HEAT PUMP INSTALLATION, containing a compressor with a condenser in the top and a compressor with an evaporator in the lower stages, a condenser-evaporator between the stages and connected to the evaporator, a heat source of low potency, which is designed to increase efficiency by using the heat of the surrounding air at its negative temperatures, the heat source of low potential is filled in the form of a cooling tower, and the installation additionally contains a compressor with a liquid separator, a circulating brine unit a tour in which a cooling tower and a device for the regeneration of brine from moisture falling out of air in the cooling tower are included, moreover, this device is implemented as a solar hot box with a coil in the brine cavity connected in series with an additional compressor and liquid separator in the communication line of the upper compressor cascade with condenser and the last with condenser-evaporator. 2. Installation according to claim 1, ex (the case is that the cooling tower is equipped with an agitator, the drive of which is made in the form of Segner wheels placed inside the cooling tower and included in the circulation brine circuit. N | SL oo tc 09 4

Description

The invention relates to the field of refrigeration, and more specifically to cascade heat pump installations using low potential, full. tplo ambient air. Known cascade teylon installation, containing a compressor with a condenser in the top and a compressor with an evaporator in the lower stages, a condenser-evaporator between the stages and connected to the evaporator low-potential heat source lj. A disadvantage of the known installations is the impossibility of using as a heat source a low potential of the heat of the ambient air at its negative temperatures. The aim of the invention is to increase efficiency by using the heat of the ambient air at its negative temperatures. This goal is achieved by the fact that the low potential heat source is designed as a cooling tower, and the installation additionally contains a compressor with a liquid separator, a circulating brine circuit, in which included a cooling tower and a device for the regeneration of brine from moisture falling out of the air in the cooling tower, and this device is made in the form of a solar burner with a coil in It is connected in series with an additional compressor and liquid separator in the communication line of the compressor upper stage with a condenser and the latter with a condenser-evaporator, the gradient is equipped with an agitator driven in the form of Segner wheels located inside the cooling tower and included in the circulating brine circuit. In the drawing a schematic representation of the described installation. It contains a compressor 1 with a condenser 2 in the top and a compressor 3 with an evaporator 4 in the lower stages, a condenser-evaporator 5 between the stages, a cooling tower 6, an additional compressor 7, a liquid separator 8, a brine pump 9, a device 10 for regenerating brine from moisture coil 11, line 12 of compressor 1 to condenser 2, line 13 of condenser 2 to condenser-evaporator 5, stirrer 14, Segner wheels 15 and 16, throttles 17, 18 and 19, valves 20 - 37 and 38, collection 39 brine and pump AO. The operation of the installation is carried out as follows. In the winter mode, valves 20, 23, 26, 29 are opened, valves 21, 22, 27 and 28 are closed respectively. Compressor 3 sucks the vapor of the lower stage of the refrigerant 4 from the evaporator 4 and pumps it into the condenser vaporizer 5, in which it condenses due to evaporation under low liquid pressure refrigerant of the upper cascade. The resulting fluid lowers its pressure in throttle 19 and flows back to the evaporator 4, in which it boils at low pressure, removing heat from the circulating brine, which is heated in the cooling tower 6 with the heat of the blown outside air. The refrigerant vapors of the upper stage are sucked out from the condenser-evaporator 5 by the compressor 1 and injected into the condenser 2, in which the water supplied to the consumer of hot water is liquefied. The resulting liquid. from condenser 2 flows through choke 18 back into condenser-evaporator 5. Brine is circulated by pumping 9 through evaporator 4, Segner wheels 15 and 16, which serve as stirrer 14, and cooling tower 6. Over time, brine is irrigated due to moisture loss from the nose to cooling towers This excess moisture is regenerated in the device 10, both by solar radiation and by condensation of a portion of the refrigerant vapor in the upper stage. To this end, refrigerant vapor is sucked out of line 12 by compressor 7 and injected into coil 11, in which they condense. The liquid refrigerant is directed through the choke 17 to the liquid separator 8, which serves as an intermediate vessel, from which enters through the choke 18 to the condenser-evaporator 5. Water vapor from the device 10 through the valve 37 is discharged to the atmosphere, and the brine recovered from moisture enters through the valve. 31 in the cooling tower sump 6. In summer mode, the installation is used as a refrigeration unit, for this purpose the valves 20, 23, 26 and 29 are closed, and the valves 21, 22, 27 and 28 are opened. Accordingly, condenser 2 acts as an evaporator, and evaporator A as a condenser. The rasso from the cooling tower 6 and from the device 10 is discharged into the collector 39. At the same time, the cooling tower 6 and the device 10 are filled with all the pipelines of the circulation circuit. Now, during the operation of the plant, cold water or brine from the second cavity of the condenser 2 is directed to the cold consumer. The evaporator is cooled with water, circulating pump 9 through the Segner wheels 15 and 16 and cooling tower 6. A part of the heated in the A / 4 evaporator is fed into the device 10, which is heated by solar radiation and part of the refrigerant condensing in the coil 11 to a hot condition. It is also supplied by the pump AO to the consumer of hot water supply, the Circuit / 1 qi of the refrigerant in each stage of the installation, as well as through the additional compressor 7, the liquid separator 8 and the coil 11 remain the same as. described in the winter mode of the installation. The economic efficiency of the proposal is reflected in a reduction in the cost of producing cold and heat during year-round operation of the installation.

Claims (2)

1. CASCADE HEAT PUMP INSTALLATION, containing a compressor with a condenser in the upper and a compressor with an evaporator in the lower stages, a condenser-evaporator between the cascades and connected to the evaporator'Low potential heat source, characterized in that, in order to increase efficiency by using the heat of the ambient air at its negative temperatures, the heat source of low potential is made in the form of a cooling tower, and the installation additionally contains a compressor with a liquid separator, a circulation brine circuit, which includes a cooling tower and a device for regenerating brine from moisture falling from the air in the cooling tower, said device being made in the form of a solar hot box with a coil in a brine cavity, connected in series with an additional compressor and a liquid separator in the communication line of the compressor of the upper cascade with a condenser and the latter with a condenser-evaporator. 2. Installation according to π. 1, characterized in that the tower is equipped with a stirrer, the drive of which is made in the form of segner wheels located inside the tower and included in the circulating brine circuit.