SU1270503A1 - Thermocompressor - Google Patents

Abstract

The invention can be used for heat supply of buildings. The purpose of the invention is to increase efficiency by using low potential heat. The evaporator (I) 7 is made in the form of a solar collector with a receiving chamber 8 and, on the solar radiation side, has a transparent wall 9 and a solar energy concentrator 10 along its perimeter. And 7 is filled with a porous liner (PV) 11 of heat-conducting material. Inside PI 11, perforated tubes 12 are placed, connected at the inlet to chamber 8, and at the outlet to the contour. The heat energy of the concentrated solar radiation and the heat of the surrounding air are transferred to the MF 11. The working fluid circulating in the circuit, in I 7, absorbs heat from MW II and evaporates, enters the tubes 12. 1 Cp f-ly, 2 ill. and 111 i 11 I (Lu y Q cl o CO

Description

Isorethiation is related to cold technology, namely heat pumps, and can be used for building supply systems.

The purpose of the invention is to improve the economy through the use of low-potential heat.

FIG. An image of a heat pump with a single evaporator; Figure 2 is the same with two evaporators.

The heat pump contains a KoiiTyp vapor-liquid circulating and electrochemical compressor 1 installed in it with cavities of high 2 and low 3 pressures, condenser 4, heat exchanger-regenerator 5, throttle 6 and evaporator 7. The evaporator is made in the form of a solar receiver with a receiving chamber 8 having on the side of solar radiation, the transparent wall 9 and the solar energy concentrator 10 but the perimeter of the latter, and is filled with a porous insert 11 of heat-conducting material, the perforated tube is placed and 12, connected at the entrance to the receiving chamber 8, and at the output at the contour. The second isharitor 13 with the throttle valve 14 is connected in parallel to the first evaporator 7 through additional three-position switches 15.

Compressor I contains an ion-exchange membrane 16, porous electrodes of low G / and high pressure 18 of the working fluid, heat-conducting metal grids 19 and 20, ceramic frame 21, submersible heat-conducting walls 22 and 23, and metal ribs 24 and 25.

Capacitor 4 contains an internally developed surface 26 and external fins 27.

The perforated tubes 12 of the evaporator 7 are connected to the receiving chamber 8 by a pipe 28. The pipe 29 between the compressor 1 and the condenser 4 is provided with fins 30. The rheostat 31 serves to smoothly control the parameters of the heat pump. The evaporator contains fins 32.

 The heat pump works as follows.

The heat energy of the concentrated solar radiation passing through the wall - & and the warmth of the surrounding air through the fringes 32 are transferred to the porous

 P. Through the throttle 6 in the receiving chamber 8 enters the working body. From the receiving chamber 8 through pipe 28 one component of the working fluid enters the non-perforated tubes 12, and the other, under the influence of gravity and capillary forces, equipotently fills the poroshog of the liner 11, absorbs heat and, evaporates, enters the perforated tubes 12 where it is mixed with the first component volume. From the evaporator 7, the working fluid enters the heat exchanger-regenerator 5, where it is heated, and then supplied to the low pressure cavity 3 of the compressor 1. In the compressor I, due to the external electric energy, the working fluid is compressed. From the high-pressure cavity 2, the working fluid passes through conduit 29, where supercooling occurs and enters the condenser 4.

From the condenser 4, the working fluid enters the heat exchanger-regenerator 5, where it is cooled, and through the throttle 6 is fed into the receiving chamber 8.

The heat pump cycle is closed.

Pzs-bretens formula

1. A heat pump containing a vapor-liquid circulating circuit and an electrochemically installed compressor in series with high-pressure and low-pressure cavities, a heat exchanger-regenerator, an inductor and an evaporator. Except for the fact that, in order to ecomomicity by using heat of a potential, the evaporator is designed as a solar receiver with a receiving chamber having a transparent wall with solar radiation and a solar concentrator around the perimeter of the right side, and is filled with a porous liner (i3 heat conductor). , inside which pa3Mcnieiibi perforated tube connected to

the entrance to the camera, and the output to the contour.

2. Pump P.O. p., Characterized in that. JTO pump additionally contains a second evaporator with a throttle, parallel to njjik; Directly to the first evaporator via additional three-position switches.

Claims (2)

Claim 1. A heat pump containing a vapor-liquid circulation circuit and an electrochemical compressor with high and low pressure cavities, a heat exchanger-rsgever- ³⁰ torr, a choke and an evaporator, characterized in that, in order to increase efficiency by using low potential heat, the evaporator is installed in series designed as a solar collector with a receiving chamber having a side with a solar radiation-transparent wall ³⁵ hydrochloric .i concentrator of solar energy in the last perimeter, and filled with a porous insert m of a heat conductive material, inside which are placed perforated tube connected to the inlet 40 to the inlet chamber and the outlet to the contour. 2. Pump π.ό π. 1, characterized in that the pump further comprises a second evaporator with a choke, parallel to the night connected to the first evaporator through additional three-position switches. I 270503 Figure 2. Compiled by E. Vinogradov