KR20120077106A - A load active heat pump combined two parallel single stage compressor - Google Patents

Abstract

PURPOSE: A load active heat pump with two parallel compressors is provided to enable the efficient and stable load operation of first and second compressors by operating the first and second compressors in series or parallel. CONSTITUTION: A load active heat pump with two parallel compressors comprises first and second compressors(100,200), a condenser(300), an evaporator(500), and an expansion valve(400). The first and second compressors compress refrigerant gas. The condenser condenses the high-temperature and high-pressure refrigerant gas. The condensed refrigerant flows into the evaporator, and the evaporator evaporates the refrigerant. The expansion valve is installed on a first return line(351) which connects the condenser and the evaporator to each other and decompresses and expands the refrigerant flowing from the condenser.

Description

LOAD ACTIVE HEAT PUMP COMBINED TWO PARALLEL SINGLE STAGE COMPRESSOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a load active heat pump combining a single stage parallel compressor. More particularly, the present invention relates to a load active heat system combining a single stage parallel compressor capable of efficiently operating two single stage compressors in response to a change in load. It is about a pump.

Heat pumps are used to produce cold and hot water for industrial water in industrial facilities such as cold and hot water supply of buildings or nuclear power plants through cycles of compressing and evaporating refrigerant.

Heat pumps can be classified into single compressor type, single stage parallel compressor type, and multi-stage series compressor type according to the number of compressors used and the connection method. A single compressor is a type that uses one compressor, and a single stage parallel compressor is a type in which two or more compressors are configured in parallel so that each compressor compresses refrigerant, and a multi-stage series compressor connects two or more compressors in series. It is a form that is sequentially compressed in the high stage compressor compressed in the low stage compressor.

The heat pump comprised of the 1st stage parallel compressor is shown in FIG.

In the heat pump shown in FIG. 1, the high temperature and high pressure refrigerant gas compressed in the first and second compressors 10 and 20, respectively, enters the condenser 30 and condenses. The refrigerant liquid from the condenser 30 enters the evaporator 50 through the sub cooler 35 and the expansion valve 40.

The heating water (hot water) heat exchanger is disposed inside the condenser 30, and the heating water absorbs the heat of the condensation while heating the heating water heat exchanger inside the condenser 110, becomes hot, and is then supplied to the load side (use point).

In addition, a cooling water heat exchanger is disposed inside the evaporator 50. The cooling water (cold water) flows through the heat exchanger inside the evaporator 50, absorbs the heat of evaporation, cools, and is then supplied to the load side (used for use).

In such a one-stage parallel compressor type heat pump, since the first compressor 10 and the second compressor 20 are connected to the condenser 30 and the evaporator 50 in parallel, respectively, the first compressor 10 according to the load variation. ) Or only the first compressor 10 and the second compressor (2) at the same time to compress the refrigerant.

For example, the first compressor 10 and the second compressor are only driven when the high compressor is not required such as a cooling operation or when the load is low, and the high compressor is required or the load is high, such as a heating operation. Drive 20 simultaneously.

In such a first stage parallel compressor type heat pump, the first compressor 10 and the second compressor 20 have different freezing capacities during a refrigeration operation. Typically, the first compressor 10 is a second stage compressor ( Have a larger capacity than 20). Accordingly, in case of partial load, only the first compressor 10 can satisfy the required refrigeration capacity. However, when the load fluctuation frequently occurs in an area exceeding the capacity of the first compressor 10, the first compressor 10 is used to avoid surge. In addition, the two compressors (10, 20) are distributed in the same head, there is a disadvantage to prepare for load fluctuations. As described above, in the conventional parallel driving method, the operation must be performed at the same head to avoid the surge of each compressor, and the partial load operation in the efficient area is difficult and the operation control becomes complicated.

The present invention was developed to solve the problems of the conventional one-stage parallel compression type heat pump described above, and an object of the present invention is to enable two compressors to sequentially control loads according to load fluctuations, thereby making them more efficient and stable. It is to provide a load active heat pump that combines a single stage parallel compressor to enable partial load operation and simple operation control.

In order to achieve the above object, a load active heat pump combining a first stage parallel compressor according to the present invention includes a first stage parallel compressor (100) and a second compressor (200) for compressing a refrigerant gas; A condenser 300 condensing the high temperature and high pressure refrigerant gas from the first and second compressors 100 and 200 into a liquid phase and passing a heating load side heat exchanger therein; An evaporator 500 through which the liquid refrigerant from the condenser 300 flows in and evaporates and passes through a cooling load-side heat exchanger; It is installed in the middle of the first recovery line 351 connecting the condenser 300 and the evaporator 500 includes an expansion valve 400 for decompressing and expanding the refrigerant from the condenser 300, the first compressor (100) ) Is connected to the evaporator (500) and the first compressor inlet line (111); The outlet side of the first compressor 100 is connected to the inlet side of the condenser 300 and the first discharge line 112, the opening and closing valve 121 is installed in the first discharge line 112, the first A second discharge line 113 is further provided at the outlet side of the compressor 100 to be connected to the inlet side of the second compressor 200 for series connection with the second compressor 200; A second compressor inlet line 211 extending from the evaporator 500 is connected in the middle of the second discharge line 113, and a second connection line between the second discharge line 113 and the second compressor inlet line 211 is provided. A three-way valve 150 is installed to selectively connect the first compressor 100 and the second compressor 200 in series or to selectively connect the evaporator 500 and the second compressor 200; An outlet side of the second compressor 200 and an inlet side of the condenser 300 are connected to a discharge line 212, and a check valve 213 is provided in the middle of the discharge line 212; Bypass line 250 is branched from the discharge line 212 is connected to the inlet side of the evaporator 500, the bypass line 250 is characterized in that the on-off valve 251 is installed.

A second recovery line 352 is branched from the first recovery line 351 connecting the condenser 300 and the evaporator 500; A first control line 351 and a second recovery line 352 are provided with control valves for selectively opening and closing the first recovery line 351 and the second recovery line 352; The second recovery line 352 is provided with an economizer 600 for separating the gas refrigerant and the liquid refrigerant; The liquid refrigerant return line 611 which sends the liquid refrigerant separated from the economizer 600 to the evaporator 500 and the flash gas recycle which sends the gas refrigerant separated by the economizer 600 back to the inlet side of the second compressor 200. Line 612 is installed; Expansion valves 370 and 620 are respectively installed in the second recovery line 352 and the liquid refrigerant return line 611.

The control valve for the selection of the first recovery line 351 and the second recovery line 352 is a solenoid on-off valve 355, respectively installed in the first recovery line 351 and the second recovery line 352 ( 360).

The on-off valve 121 and on-off valve 251 is composed of a solenoid valve.

According to the load active heat pump combining the first stage parallel compressor according to the present invention, only the first compressor can be driven, or the first and second compressors can be driven in parallel or in series, and the bypass valve and the bypass line are controlled to control the load variation. Therefore, sequential load control is possible and fine control is possible, so that more efficient and stable partial load operation is possible and operation control is simple.

1 is a conventional single stage parallel compressor heat pump circuit diagram.
2 is a circuit diagram of a load active heat pump according to the present invention.
3 is a diagram showing an example of heating operation using a heat pump according to the present invention.
4 is a view showing an example of a cooling operation using a heat pump according to the present invention.
5 is a view showing another example of the cooling operation using a heat pump according to the present invention.
6 is a view showing still another example of the cooling operation using a heat pump according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram of a load active heat pump according to the present invention.

As shown in FIG. 2, the heat pump of the present invention includes a first stage compressor 100 and a second compressor 200 which compress refrigerant gas, and the first and second compressors 100 and 200. The condenser 300 is condensed into a liquid phase and is installed in the condenser 300 through which a heat load side heat exchanger passes, and a first recovery line 351 connecting the condenser 300 and the evaporator 500. Expansion valve 400 for decompressing and expanding the refrigerant from the expansion, and the evaporator 500 through which the liquid refrigerant from the expansion valve 400 flows in and evaporates and passes through the cooling load side heat exchanger.

The first and second compressors 100 and 200 may be operated in series with a load or a parallel operation, and the refrigerant from the second compressor 200 may be configured to enter the condenser 300 or bypass the evaporator 500. In series operation, like a multi-stage compression type refrigerator, an operation method of compressing a refrigerant in two stages to improve efficiency is suitable for use in heating high load operation, which requires a high head mainly.

Furthermore, the inlet side of the first compressor 100 is connected to the evaporator 500 and the first compressor inlet line 111.

In addition, the outlet side of the first compressor 100 is connected to the inlet side of the condenser 300 and the first discharge line 112, the first discharge line 112 is provided with an on-off valve 121, A second discharge line 113 is further installed at the outlet side of the first compressor 100 to be connected to the inlet side of the second compressor 200 for series connection with the second compressor 200. The on-off valve 121 is preferably configured as a solenoid valve.

A second compressor inlet line 211 extending from the evaporator 500 is connected in the middle of the second discharge line 113, and a second connection line between the second discharge line 113 and the second compressor inlet line 211 is provided. A three-way valve 150 is installed to selectively connect the first compressor 100 and the second compressor 200 in series or to selectively connect the evaporator 500 and the second compressor 200.

An outlet side of the second compressor 200 and an inlet side of the condenser 300 are connected to a discharge line 212, and a check valve 213 is installed in the middle of the discharge line 212.

On the other hand, the bypass line 250 is branched from the discharge line 212 is connected to the inlet side of the evaporator 500, the bypass line 250 is provided with an on-off valve 251. The on-off valve 251 is preferably configured as a solenoid valve to enable instantaneous operation.

In addition, the second recovery line 352 is branched from the first recovery line 351 connecting the condenser 300 and the evaporator 500, the first recovery line 351 and the second recovery line 352 The control valve for selectively opening and closing the first recovery line 351 and the second recovery line 352 is provided. The control valve may be composed of solenoid on-off valves 360 and 355 respectively installed in the second recovery line 352 and the first recovery line 351.

In addition, the second recovery line 352 is provided with an economizer 600 for separating the gas refrigerant and the liquid refrigerant, the liquid refrigerant return line 611 for sending the liquid refrigerant separated from the economizer 600 to the evaporator 500. ) And a flash gas recirculation line 612 for sending the gas refrigerant separated from the economizer 600 back to the inlet side of the second compressor 200. When the first compressor 100 and the second compressor 200 are connected in series, the economizer 600 passes flash gas (gas refrigerant) out of the refrigerant passing from the condenser 300 and passing through the expansion valve 370 of the two-stage compressor. The second compressor 200 acts as a suctioner to reduce the load of the first compressor 100 serving as the first stage compressor and decreases the amount of refrigerant circulating in the evaporator 500, thereby increasing the efficiency. By lowering the inlet temperature of), it reduces the specific volume of the refrigerant to improve the compression efficiency.

In addition, an expansion valve 370 is respectively provided in the second recovery line 352 connected to the economizer 600 from the condenser 300 and the liquid refrigerant return line 611 connecting the economizer 600 and the evaporator 500. 620 is installed.

Meanwhile, a sub cooler 350 is installed before reaching the first and second recovery lines 351 from the condenser 300.

The driving mode of the present invention thus constructed will be described with reference to FIGS. 3 to 5.

3 is a diagram showing an example of heating operation using a heat pump according to the present invention.

As shown in FIG. 3, in the heating operation, the opening / closing valve 121 is closed to close the first discharge line 112 of the first compressor 100, and the three-way valve 150 is switched to the first compressor ( The second discharge line 113 of 100 is opened and the second compressor inlet line 211 is closed, thereby connecting the first compressor 100 and the second compressor 200 in series. In a heating operation requiring high lift, the first compressor 100 and the second compressor 200 are connected in series to compress the refrigerant in two stages so as to sufficiently cope with the heating load.

Then, the closing valve 251 is closed so that the bypass line 250 is closed so that all refrigerant from the second compressor 200 enters the condenser 300.

In addition, the open / close valve 355 is closed and the open / close valve 360 is opened to allow the refrigerant from the condenser 300 to enter the economizer 600 through the second recovery line 352.

Therefore, the refrigerant evaporated in the evaporator 500 enters the first compressor 100 through the first compressor inlet line 111 and is compressed, and enters the second compressor 200 through the second discharge line 113. After being compressed, it enters the condenser 300.

As such, the refrigerant is compressed in two stages, so that the temperature and pressure of the refrigerant entering the condenser 300 can be greatly increased to cope with a high heating load.

The refrigerant exchanging heat from the condenser 300 enters the second recovery line 352 via the subcooler 350 and enters the economizer 600 through the expansion valve 370.

In the economizer 600, after the liquid (liquid) refrigerant and the gas (gas) refrigerant are separated, the liquid refrigerant enters the evaporator 500 through the liquid refrigerant return line 611 and the expansion valve 620, and the gas refrigerant is The flash gas recirculation line 612 is recycled to the second compressor 200 which is a high stage compressor.

When heating, the first and second compressors 100 and 200 are connected in series to be used as a two-stage compressor, and the economizer 600 is used to recycle the flash gas to a high stage compressor, that is, the second compressor 200 to heat the heat. The high lift required by the pump can be easily obtained.

4 is a view showing an example of a cooling operation using a heat pump according to the present invention.

4 corresponds to a cooling low load operation, in which case it corresponds to a refrigeration cycle using only the first compressor 100.

That is, the second compressor 200 stops driving and drives only the first compressor 100, and the on / off valve 251 and the on / off valve 300 are closed.

Therefore, the refrigerant evaporated in the evaporator 500 enters and compresses the first compressor 100 through the first compressor inlet line 111 and enters the condenser 300 through the first discharge line 112.

The refrigerant from the condenser 300 enters the first recovery line 351 via the subcooler 350 and enters the evaporator 600 through the expansion valve 400.

In this way, in the cooling low load operation, only the first compressor 100 is driven to reduce power consumption.

On the other hand, if the load fluctuation occurs within the capacity of the first compressor 100, the first compressor 100 itself, for example, the partial load operation by the capacity control of the compressor itself to control the inlet guide vane (IGV), etc. Corresponds.

5 illustrates another example of a cooling operation using a heat pump according to the present invention, and drives the first compressor 100 and the second compressor 200 in parallel.

When the load demand exceeds the capacity of the first compressor 100, the second compressor 200 is driven in addition to the first compressor 100.

In this case, the on / off valve 251 is closed to close the bypass line 250, the on / off valve 360 is closed and the on / off valve 355 is opened. In general, the cooling load does not require high lift as the heating load, so it is not necessary to use the economizer 600.

Then, the opening and closing valve 121 is opened, and the three-way valve 150 is switched to close the second discharge line 113 connecting the first compressor 100 and the second compressor 200 to the evaporator 500. The refrigerant is introduced into the first compressor 100 and the second compressor 200 separately (parallel).

Therefore, the refrigerant compressed by the first compressor 100 and the refrigerant compressed by the second compressor 200 enter the condenser 300 through the first discharge line 112 and the discharge line 212, respectively. As such, a large amount of refrigerant compressed by the first compressor 100 and the second compressor 200 flows into the condenser 300 to condense, and then passes through the first recovery line 351 and the expansion valve 400 to evaporate. Entering 500, the evaporator 500 is a large amount of refrigerant to participate in the cooling to cope with the cooling high load operation.

6 is a view showing still another example of the cooling operation using a heat pump according to the present invention. This embodiment is an operation method suitable for partial load operation that exceeds the required pressure of the condenser 300 according to the load demand amount changed during the cooling high load operation described in FIG.

This opens the bypass valve 251 when the outlet pressure of the second compressor 200 exceeds the required pressure of the condenser 300. Then, the refrigerant from the second compressor 200 is blocked by the check valve 213 is not entered into the condenser 300 side and bypass the evaporator 500 through the bypass line 250.

By opening and closing the bypass valve 251, when the load fluctuation occurs frequently during partial load, it can respond quickly.

The foregoing is a description of certain preferred embodiments of the present invention. However, the present invention is not limited to the above-described embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims.

100: first compressor 111: first compressor inlet line
112: first discharge line 113: second discharge line
121: on-off valve 150: three-way valve
200: second compressor 211: second compressor inlet line
212 discharge line 213 check valve
250: bypass line 251: on-off valve
300: condenser 350: sub cooler
351: first recovery line 352: second recovery line
355: valve opening 360: valve opening
370: expansion valve 400: expansion valve
600: economizer 611: liquid refrigerant return line
612 flash gas circulation line 620 expansion valve

Claims (4)

A first stage parallel first compressor 100 and a second compressor 200 compressing the refrigerant gas;
A condenser 300 condensing the high temperature and high pressure refrigerant gas from the first and second compressors 100 and 200 into a liquid phase and passing a heating load side heat exchanger therein;
An evaporator 500 through which the liquid refrigerant from the condenser 300 flows in and evaporates and passes through a cooling load-side heat exchanger; And
The expansion valve 400 is installed in the middle of the first recovery line 351 connecting the condenser 300 and the evaporator 500 to depressurize and expand the refrigerant from the condenser 300.
The inlet side of the first compressor 100 is connected to the evaporator 500 and the first compressor inlet line 111,
The outlet side of the first compressor 100 is connected to the inlet side of the condenser 300 and the first discharge line 112, the opening and closing valve 121 is installed in the first discharge line 112, the first A second discharge line 113 is further installed at the outlet side of the compressor 100 to be connected to the inlet side of the second compressor 200 for series connection with the second compressor 200.
A second compressor inlet line 211 extending from the evaporator 500 is connected in the middle of the second discharge line 113, and a second connection line between the second discharge line 113 and the second compressor inlet line 211 is provided. A three-way valve 150 is installed to selectively connect the first compressor 100 and the second compressor 200 in series or selectively connect the evaporator 500 and the second compressor 200.
An outlet side of the second compressor 200 and an inlet side of the condenser 300 are connected to a discharge line 212, and a check valve 213 is installed in the middle of the discharge line 212.
Bypass line 250 is branched from the discharge line 212 is connected to the inlet side of the evaporator 500, the bypass line 250 is a one-stage parallel compressor characterized in that the on-off valve 251 is installed Combined load active heat pump. The method of claim 1,
A second recovery line 352 is branched from the first recovery line 351 connecting the condenser 300 and the evaporator 500,
In the first recovery line 351 and the second recovery line 352, a control valve for selectively opening and closing the first recovery line 351 and the second recovery line 352 is provided,
The second recovery line 352 is provided with an economizer 600 for separating the gas refrigerant and the liquid refrigerant,
The liquid refrigerant return line 611 which sends the liquid refrigerant separated from the economizer 600 to the evaporator 500 and the flash gas recirculation which sends the gas refrigerant separated from the economizer 600 back to the inlet side of the second compressor 200. Line 612 is installed,
The second recovery line (352) and the liquid refrigerant return line (611), respectively, expansion valves (370, 620) is a load active heat pump combined with a first stage parallel compressor, characterized in that is installed. The method of claim 2,
The control valve for selecting the first recovery line 351 and the second recovery line 352 is a solenoid on-off valve 355 installed in the first recovery line 351 and the second recovery line 352, respectively ( A load active heat pump incorporating a one-stage parallel compressor, comprising: 360). The method of claim 1,
The on-off valve 121 and the on-off valve 251 is a load active heat pump in combination with a first stage parallel compressor, characterized in that consisting of a solenoid valve.

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