PL246609B1 - Compressor device for cooling and/or heating a room - Google Patents

Abstract

The subject of the application is a compressor device for cooling and/or heating a room with an energy accumulation function. It is characterized in that it has two pressure tanks (81 and 82), solenoid valves (51, 52, 53, 54, 55 and 56) and an additional four-way valve (62), wherein the first solenoid valve (51) is placed between the node (91) connected to the output S of the first four-way valve (61) and to the compressor input (1) and the fifth solenoid valve (55), and the node (92) connected to the output D of the first four-way valve (61) and to the compressor output (1), the second solenoid valve (52) is placed between the node (93) connected to the fourth solenoid valve (54) and to the output E of the first four-way valve (61), and the node (94) connected to the third solenoid valve (53) and to the first pressure tank (81), the third solenoid valve (53) is placed is between a node (94) connected to the second solenoid valve (52) and to the first pressure tank (81) and the outlet S of the additional four-way valve (62), a fourth solenoid valve (54) is located between a node (93) connected to the second solenoid valve (52) and to the outlet E of the first four-way valve (61) and the first heat exchanger (71), a fifth solenoid valve (55) is located between a node (95) connected to the inlet of the compressor (1) and the first solenoid valve (51) and to the outlet S of the first four-way valve (61), and a node (96) connected to the inlet E of the additional four-way valve (62) and to the second pressure tank (82), and a sixth solenoid valve (56) is located between a node (97) connected to the second expansion valve (42), to the fourth non-return valve (34) and to outlet C of the additional four-way valve (62) and the node (98) connected to the filter (21) and the refrigerant tank (2), while in the additional four-way valve (62) the outlet D is connected to the second heat exchanger (72), the outlet E to the node (96) connected to the fifth solenoid valve (55) and to the second pressure tank (82), the outlet S to the third solenoid valve (53), and the outlet C to the fourth non-return valve (34) and to the node (97) connected to the second expansion valve (42) and the sixth solenoid valve (56). It is advantageous if the pressure tank (81) is equipped with a heater (811).

Description

Description of the invention

The subject of the invention is a compressor device for cooling and/or heating a room with an energy accumulation function.

A compressor device for cooling and/or heating a room is known, equipped with a compressor, evaporator and condenser. The compressor system, causing a pressure difference, allows the condensation of the agent, which, flowing through the heat exchanger - condenser, gives off heat, and then through the expansion valve and heat exchanger - evaporator, evaporates and lowers its temperature. The solution is commonly used in air conditioning devices and heat pumps.

There is also a known method of storing energy by changing the volume of gas in a pressure tank.

The purpose of the invention is to build a compressor device for cooling and/or heating a room, equipped with an energy accumulation function and its periodic operation without the use of a compressor and without drawing electrical energy from an external source.

The essence of the compressor device according to the invention, intended for cooling and/or heating a room, equipped with a compressor, two heat exchangers with fans, performing the functions of an evaporator and a condenser, a refrigerant filter, a sight glass, non-return valves, expansion valves, a four-way valve, and all these elements are connected by hydraulic lines forming a closed circuit in which the refrigerant circulates, is that it has two pressure tanks, six solenoid valves and an additional four-way valve, wherein the solenoid valves and the additional four-way valve are placed on the hydraulic lines, wherein the first solenoid valve is placed between the node connected to the output S of the first four-way valve and to the compressor inlet and the fifth solenoid valve, and the node connected to the output D of the first four-way valve and to the compressor outlet, the second solenoid valve is placed between the node connected to the fourth solenoid valve and to the output E of the first four-way valve, and a node connected to the third solenoid valve and to the first pressure tank, the third solenoid valve is located between the node connected to the second solenoid valve and to the first pressure tank and output S of the additional four-way valve, the fourth solenoid valve is located between the node connected to the second solenoid valve and output E of the first four-way valve and the first heat exchanger, the fifth solenoid valve is located between the node connected to the compressor inlet and the first solenoid valve and the output S of the first four-way valve and the node connected to the inlet E of the additional four-way valve and to the second pressure tank, and the sixth solenoid valve is located between the node connected to the second expansion valve, to the fourth non-return valve, and to output C of the additional four-way valve and the node connected to the filter and the refrigerant tank, while in the additional four-way valve output D is connected to the second heat exchanger, output E with the node connected to the fifth solenoid valve and to the second pressure tank, output S with the third solenoid valve, and output C with the fourth non-return valve and with the node connected to the second expansion valve and the sixth solenoid valve.

It is advantageous if the first pressure tank is equipped with a heater.

The subject of the invention in an embodiment in the form of a diagram of a compressor device is shown in the drawing, in which:

Fig. 1 shows a diagram of a device with a heating function and an energy accumulation function;

Fig. 2 shows a diagram of a device without an energy accumulation function, known from the prior art;

Fig. 3 shows a diagram of the device - cooling when powered from the mains;

Fig. 4 shows a diagram of the device - heating when powered from the mains;

Figure 5 shows a diagram of the device - energy accumulation;

Figure 6 shows a diagram of the device - cooling when supplied from pressure tanks.

The compressor device according to the invention consists of a compressor 1, a refrigerant tank 2, a filter 21, a sight glass 22, four non-return valves 31, 32, 33 and 34, two expansion valves 41 and 42, six solenoid valves 51, 52, 53, 54, 55 and 56, two four-corner valves 61 and 62, two heat exchangers 71 and 72 and two pressure tanks 81 and 82 in the form of cylinders. These elements are connected to each other by hydraulic lines forming a circuit in which the refrigerant circulates in a closed circuit. Three lines converging at one point form a hydraulic circuit node.

The first solenoid valve 51 is located between nodes 91 and 92. Node 91 is connected to the output S of the first four-way valve 61 and to the input of compressor 1 and the fifth solenoid valve 55. Node 92 is connected to the output D of the first four-way valve 61 and to the output of compressor 1.

The second solenoid valve 52 is located between nodes 93 and 94. Node 93 is connected to the fourth solenoid valve 54 and output E of the first four-way valve 61. Node 94 is connected to the third solenoid valve 53 and to the first pressure tank 81.

The third solenoid valve 53 is located between the node 94, which is connected to the second solenoid valve 52 and to the first pressure tank 81, and the output S of the additional four-way valve 62.

The fourth solenoid valve 54 is located between the node 93, which is connected to the second solenoid valve 52 and the output E of the first four-way valve 61, and the first heat exchanger 71.

The fifth solenoid valve 55 is located between nodes 94 and 96. Node 95 is connected to the inlet of compressor 1 and to the first solenoid valve 51 and to the output S of the first four-way valve 61. Node 96 is connected to the inlet E of the additional four-way valve 62 and to the second pressure tank 82.

The sixth solenoid valve 56 is located between nodes 97 and 98. Node 97 is connected to the second expansion valve 42, to the fourth non-return valve 34 and to the outlet C of the additional four-way valve 62. Node 98 is connected to the filter 21 and the refrigerant tank 2.

In the additional four-way valve 62, outlet D is connected to the second heat exchanger 72, outlet E to the fifth solenoid valve 55 and to the second pressure tank 82, outlet S to the third solenoid valve 53, and outlet C to the fourth non-return valve 34 and to the node 97 connected to the second expansion valve 42 and the sixth solenoid valve 56.

The first heat exchanger 71 is located inside the room to be cooled or heated and is equipped with a fan 711. The second heat exchanger 72 is located outside the room and is equipped with a fan 721. The first pressure tank 81 is equipped with an electric heater 811.

For illustrative purposes, a compressor device known from the prior art, which does not have an energy accumulation function, is shown in Figure 2. It consists of a compressor 1, a refrigerant tank 2, a filter 21, a sight glass 22, four non-return valves 31, 32, 33 and 34, two expansion valves 41 and 42, one four-way valve 61 and two heat exchangers 71 and 72, which are equipped with fans 711 and 721.

In both the prior art devices and the device according to the invention, the heat exchangers 71 and 72 can interchangeably function as evaporators or condensers, depending on the assumed "heating" or "cooling" operating mode.

The refrigerant circuit in the “cooling” operating mode when the compressor 1 is supplied from an external electrical network is shown in Fig. 3. In this operating mode, the solenoid valves 51, 52, 53, 55 and 56 are closed, the fourth solenoid valve 54 is open, and the four-way valves 61 and 62 are set to the D-C and E-S connections. The direction of refrigerant flow is shown in Fig. 3 by the arrows marked on the hydraulic lines and the four-way valves 61 and 62. In this case, the first heat exchanger 71 acts as an evaporator, while the second heat exchanger 72 acts as a condenser.

The refrigerant circuit in the “heating” operating mode when the compressor 1 is powered from the electrical network is shown in Fig. 4. In this operating mode, the solenoid valves 51, 52, 53, 55 and 56 are closed, the fourth solenoid valve 54 is open, while the first four-way valve 61 is set to the D-E C-S connection, and the additional four-way valve 62 is set to the D-C E-S connection. The direction of refrigerant flow is shown in Fig. 4 by the arrows marked on the hydraulic lines and four-way valves 61 and 62. In this case, the first heat exchanger 71 acts as a condenser, while the second heat exchanger 72 acts as an evaporator.

The compressor device according to the invention can operate in the "cooling" mode without power supply to the compressor from an external electrical network. Such operation may be necessary in the event of a power failure or in the event of a desire to limit the consumption of electrical energy at times when its cost is high. In order for the device to be ready to operate without power supply to the compressor 1 from an external electrical network, the energy of the refrigerant should be accumulated by storing it in the first pressure tank 81 under pressure and creating a vacuum in the second pressure tank 82.

The refrigerant circulation in the "energy accumulation" operating mode when the compressor 1 is supplied from the electrical network is shown in Fig. 5. In this operating mode, solenoid valves 51, 53 and 54 are closed, solenoid valves 52, 55 and 56 are open, while four-way valves 61 and 62 are set to the D-E and C-S connections. The direction of refrigerant flow is shown in Fig. 5 by the arrows marked on the hydraulic lines and four-way valves 61 and 62. The refrigerant is collected under pressure in the first pressure tank 81, and at the same time it is sucked out of the second pressure tank 82, creating a vacuum there. The refrigerant collected in the first pressure tank 81 can be heated by means of a heater 811 supplied from the electrical network, which will cause an additional increase in its pressure and thus contribute to an additional increase in the accumulated energy.

The refrigerant circulation in the “cooling” installation mode with the compressor 1 power supply from the electrical network switched off is shown in Fig. 6. In this operating mode, solenoid valves 52, 55 and 56 are closed, solenoid valves 51, 53 and 54 are open, while the first four-way valve 61 is set to the D-C E-S connection, and the additional four-way valve 62 is set to the D-E C-S connection. The direction of refrigerant flow is shown in Fig. 6 by the arrows marked on the hydraulic lines and four-way valves 61 and 62. The refrigerant flows from the first pressure tank 81, where the pressure is high, to the second pressure tank 82, where the pressure is low. In this case, the first heat exchanger 71 acts as an evaporator, while the second heat exchanger 72 acts as a condenser.

List of designations:

compressor refrigerant tank filter sight glass first check valve second check valve third check valve fourth check valve first expansion valve second expansion valve first solenoid valve second solenoid valve third solenoid valve fourth solenoid valve fifth solenoid valve sixth solenoid valve first four-way valve additional four-way valve first heat exchanger second heat exchanger

711, 721 fan first pressure tank second pressure tank

811 heater

91, 92, 93, 94, 95, 96, 97, 98 hydraulic circuit node

Claims (2)

1. A compressor device for cooling and/or heating a room, equipped with a compressor, two heat exchangers with fans, performing the functions of an evaporator and a condenser, a refrigerant tank, a refrigerant filter, a sight glass, non-return valves, expansion valves, a four-way valve, and all these elements connected by hydraulic lines forming a closed circuit in which the refrigerant circulates, characterized in that it has two pressure tanks (81) and (82), solenoid valves (51), (52), (53), (54), (55) and (56) and an additional four-way valve (62), wherein the first solenoid valve (51) is placed between the node (91) connected to the outlet S of the first four-way valve (61) and to the compressor inlet (1) and the fifth solenoid valve (55), and the node (92) connected to the outlet D of the first four-way valve (61) and to the outlet (1) a second solenoid valve (52) is arranged between a node (93) connected to the fourth solenoid valve (54) and the outlet E of the first four-way valve (61) and a node (94) connected to the third solenoid valve (53) and the first pressure tank (81), a third solenoid valve (53) is arranged between a node (94) connected to the second solenoid valve (52) and the first pressure tank (81) and the outlet S of the additional four-way valve (62), a fourth solenoid valve (54) is arranged between a node (93) connected to the second solenoid valve (52) and the outlet E of the first four-way valve (61) and the first heat exchanger (71), a fifth solenoid valve (55) is arranged between a node (95) connected to the inlet of the compressor (1) and the first solenoid valve (51) and the outlet S of the first four-way valve (81), (61) and the node (96) connected to the inlet E of the additional four-way valve (62) and to the second pressure tank (82), and the sixth solenoid valve (56) is placed between the node (97) connected to the second expansion valve (42), to the fourth non-return valve (34), and to the outlet C of the additional four-way valve (62), and the node (98) connected to the filter (21) and the refrigerant tank (2), while in the additional four-way valve (62), the outlet D is connected to the second heat exchanger (72), the outlet E to the node (96) connected to the fifth solenoid valve (55) and to the second pressure tank (82), the outlet S to the third solenoid valve (53), and the outlet C to the fourth non-return valve (34) and to the node (97) connected to the second expansion valve (42) and the sixth solenoid valve (56). 2. A compressor device according to claim 1, characterized in that the pressure tank (81) is equipped with a heater (811).