KR101692243B1 - Heat pump with cascade refrigerating cycle - Google Patents

Abstract

The present invention relates to a heat pump using a cascade cycle, capable of reducing power consumption by operating only an upper end refrigerating cycle under the condition that a heating load is not large wherein the outdoor temperature is greater than or equal to a predetermined temperature. The heat pump using the cascade cycle includes: a low end refrigerating cycle in which a first refrigerant circulates along a first circuit including a first compressor, a first heat exchanger, a first expansion valve, and a first evaporator; the upper end refrigerating cycle in which a second refrigerant circulates along a second circuit including a second compressor, a second heat exchanger, a second expansion valve, and the first heat exchanger; a divergent flow path diverging between the second expansion valve and the first heat exchanger and connected between the first heat exchanger and the second compressor; a valve permitting the second refrigerant to pass through the divergent flow path or blocking the second refrigerant; and a second evaporator arranged on the divergent flow path.

Description

[0001] Heat pump with cascade cycle [0002]

The present invention relates to a heat pump using a cascade cycle capable of reducing unnecessary power consumption and reducing noise by operating only a high-stage side refrigeration cycle under a condition where the outside air temperature is a certain temperature or more and the heating load is not large.

Generally, a cascade refrigerating cycle implements each refrigeration cycle using refrigerants with different boiling points. The refrigeration cycle is divided into a low-stage side using low-temperature refrigerant boiling at low temperature and a high-stage side using high-temperature refrigerant boiling at a relatively high temperature. The evaporation of the high-temperature refrigerant and the condensation of the low-temperature refrigerant occur in one heat exchanger do.

The heat pump using such a cascade cycle can efficiently maintain the temperature of the refrigerant discharge gas on the high temperature side at a required high temperature even when the outdoor temperature is low in the winter, and is thus effective for producing hot water (heating water).

As an example of a conventional heat pump using a cascade cycle, Korean Patent Laid-Open No. 10-2012-0125857 entitled " a heat storage device having a dual refrigeration cycle and its operation method "

The heat storage device disclosed in the above patent is provided with a low pressure side compressor 12, a cascade heat exchanger 14, a low pressure side expansion device 16, and an outdoor heat exchanger 18, (Low-stage side) refrigeration cycle 2 in which the refrigerant circulates and the high-pressure side compressor 52, the regenerative heat exchanger 54, the high-pressure-side expansion mechanism 56 and the cascade heat exchanger 14 (High-stage side) refrigeration cycle 4 for heating the heat medium in the heat accumulation heat exchanger 54 while circulating the refrigerant while circulating the refrigerant in the refrigerant cycle, and a heat accumulation tank 6 connected to the heat accumulation heat exchanger 54 and the heat medium flow path.

The heat pump using the conventional cascade cycle including the above-described heat storage device uses a first refrigerant compressed and discharged at a high temperature and a high pressure in a low-stage side refrigeration cycle as a necessary heat source and a unique heat source in order to evaporate the second refrigerant So that the second refrigerant is evaporated through heat exchange in the cascade heat exchanger.

In order to realize a high-stage refrigeration cycle for hot water production, the low-stage refrigeration cycle must be operated. This means that not only the compressor on the high stage side refrigeration cycle but also the compressor on the low stage side refrigeration cycle must be operated for hot water production.

On the other hand, when the outside air temperature is higher than the predetermined temperature, the hot water of the required temperature can be sufficiently produced even if only the compressor of the high-stage side refrigeration cycle operates even when the heating load is not large.

However, as described above, the conventional heat pump using the cascade cycle has a structure in which not only the high-stage side compressor but also the low-stage side compressor must be operated regardless of the change of the heating load condition. There is a disadvantage in that it is accompanied by a noise problem due to the operation of both compressors.

The present invention has been conceived to solve the problem of the heat pump using the conventional cascade cycle as described above. When the heating load is not large according to the outside air temperature, the operation of the low-stage side compressor is stopped, And to provide a heat pump using a cascade cycle capable of significantly reducing power consumption and noise.

A heat pump using a cascade cycle according to an embodiment of the present invention is characterized in that a first refrigerant is circulated along a first circuit including a first compressor, a first heat exchanger, a first expansion valve and a first evaporator, Side refrigerant cycle in which the second refrigerant circulates along a second circuit including a second compressor, a second heat exchanger, a second expansion valve, and the first heat exchanger, and a high- A branch flow path branched from a first point on the second circuit located between the first heat exchanger and connected to a second point on the second circuit located between the first heat exchanger and the second compressor, The second refrigerant passing through the second expansion valve is blocked from flowing to the first heat exchanger while allowing the second refrigerant to pass through the branch passage, 1 is disposed on the valve, and the branch flow passage that allows circulation into the heat exchanger, and a second evaporator such that the second refrigerant is evaporated passing through the branch flow path.

A heat pump using a cascade cycle according to an embodiment of the present invention is provided with a first valve disposed on a branch passage for allowing or blocking passage of the second refrigerant through a branch passage, A second valve disposed on the refrigerant flow path at least one of the first point and the first heat exchanger or between the first heat exchanger and the second point so as to allow or block the circulation to the first heat exchanger, . ≪ / RTI >

The heat pump using the cascade cycle according to the embodiment of the present invention further includes a control unit for controlling the operation of the first compressor, the second compressor, and the valve, and when the second compressor is operated , The controller may control the valve to operate so that the second refrigerant passes through the branch passage while the first compressor is not operated when the outside air temperature is equal to or higher than the predetermined temperature Ta.

In the heat pump using the cascade cycle according to the embodiment of the present invention, the water circulating in the second heat exchanger is heated by the heat exchange with the second refrigerant in the second heat exchanger, .

The heat pump using the cascade cycle according to the embodiment of the present invention may further include a heat storage tank connected to the hot water passage.

In the heat pump using the cascade cycle according to the embodiment of the present invention, either or both of the first evaporator and the second evaporator may be a fin-tube type heat exchanger.

In the heat pump using the cascade cycle according to the embodiment of the present invention, the first evaporator and the second evaporator are arranged side by side in the outdoor unit, and the outside air flows into the first evaporator and the second evaporator And a blowing fan for blowing air.

In the heat pump using the cascade cycle according to the embodiment of the present invention, either or both of the first heat exchanger and the second heat exchanger may be a plate-type heat exchanger.

According to the present invention, when the outside air temperature is equal to or higher than a certain temperature, under the condition that the heating load is not large, only the high stage side refrigeration cycle is operated without the low stage side refrigeration cycle being operated, and unnecessary power consumption can be reduced.

In addition, the advantage that noise is reduced by not operating the first compressor in the low-stage side refrigeration cycle is also provided.

1 is a schematic view of a conventional heat pump using a cascade cycle,
FIG. 2 is a view showing the construction of a heat pump using a cascade cycle according to an embodiment of the present invention, in which refrigerant circulation when the outside air temperature is lower than Ta is shown,
FIG. 3 is a view showing a structure of a heat pump using a cascade cycle according to an embodiment of the present invention, showing a circulation of refrigerant when the outside temperature is Ta or higher.

Hereinafter, a heat pump using a cascade cycle according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a schematic view of a heat pump using a cascade cycle according to an embodiment of the present invention. FIG. 3 is a view showing a circulation of refrigerant when the outside air temperature is lower than Ta. FIG. 3 is a cross- Is a diagram showing the refrigerant circulation when the outside air temperature is Ta or more.

As shown in the figure, the heat pump 1 using the cascade cycle according to the embodiment of the present invention is configured such that the first refrigerant flows through the first compressor 110, the first heat exchanger 120, the first expansion valve 130 Side refrigerating cycle in which the first refrigerant is circulated along the first circuit 100 including the first evaporator 140 and the first evaporator 140 and the second refrigerant is circulated through the second compressor 210, the second heat exchanger 220, (230), and a second circuit (200) including a first heat exchanger (120).

The first refrigerant and the second refrigerant may be made of a refrigerant having a different condensing temperature and a different evaporating temperature. For example, the first refrigerant may be R-410A having a low condensation temperature and the evaporation temperature, and the second refrigerant may be R-134a having a higher condensation temperature and a higher evaporation temperature than the first refrigerant.

In the low-stage refrigeration cycle, the first refrigerant flows along the first circuit 100 including the first compressor 110, the first heat exchanger 120, the first expansion valve 130, and the first evaporator 140 And circulates through a refrigerant passage connecting them.

Specifically, in the heating operation mode, the first refrigerant flows through the first compressor 110, the first heat exchanger 120, the first expansion valve 130, and the first evaporator 140 in the direction indicated by the solid line in FIG. . ≪ / RTI >

In the defrosting operation mode, the first refrigerant is introduced into the first compressor 110, the first evaporator 140, the first expansion mechanism, and the first heat exchanger (120).

And the low-stage side refrigeration cycle may include a mode switching valve that can be switched between the heating operation mode and the defrost operation mode. The four-way valve 115 may be connected to the first compressor 110, the first heat exchanger 120, and the first evaporator 140 through a refrigerant passage.

Hereinafter, the refrigerant circulation direction in the heating operation mode will be described as a reference. The term "upstream" or "downstream ", as used below, is an expression separated from the reference of this circulation direction.

An accumulator 150 for separating the liquid refrigerant in the first refrigerant may be disposed on the refrigerant path upstream of the first compressor 110 in order to prevent liquid compression in the first compressor 110.

The first refrigerant compressed in the first compressor (110) and discharged in a gaseous state at a high temperature and a high pressure flows into the first heat exchanger (120). The first refrigerant flowing into the first heat exchanger (120) is heat-exchanged with the second refrigerant flowing into the first heat exchanger (120).

The first refrigerant passes through the first heat exchanger 120 to dissipate heat and is condensed. The second refrigerant passes through the first heat exchanger 120 and absorbs heat of the first refrigerant to evaporate. Accordingly, the first heat exchanger 120 functions as a condenser in relation to the first refrigerant, and functions as an evaporator in relation to the second refrigerant.

The first heat exchanger 120 may be, for example, a plate-type heat exchanger. However, the present invention is not limited thereto, and may be various other known heat exchangers such as a dual-pipe heat exchanger.

The refrigerant condensed in the first heat exchanger 120 flows into the first expansion valve 130 and is decompressed to a pressure capable of causing evaporation by the throttling action. The first expansion valve 130 may be an electronic expansion valve (EEV) capable of adjusting the opening degree.

A strainer 131 may be disposed on the refrigerant flow paths upstream and downstream of the first expansion valve 130 to filter foreign substances in the refrigerant.

The refrigerant having passed through the first expansion valve (130) flows into the first evaporator (140). The heat pump 1 according to the present embodiment may be an air heat source heat pump that takes the heat of the outdoor air while the first refrigerant passes through the first evaporator 140. The first evaporator 140 may be a fin-tube type heat exchanger, for example, an air-cooled heat exchanger for exchanging heat between the outdoor air and the first refrigerant.

The refrigerant expanded in the first expansion valve 130 flows through the refrigerant distributor 132 to the refrigerant circulating structure between the first expansion valve 130 and the first evaporator 140, The first evaporator 140, which is a type of heat exchanger, is distributed and supplied.

In this structure, the heat pump 1 according to the present embodiment may include a blowing fan 340 for flowing outdoor air to the first evaporator 140, which is a fin tube type heat exchanger.

Meanwhile, an economizer heat exchanger 125 may be further disposed on the refrigerant flow path between the first heat exchanger 120 and the first expansion valve 130.

A refrigerant flow path branched from the refrigerant flow path between the first heat exchanger 120 and the first expansion valve 130 and connected to the first compressor 110 after passing through the economizer heat exchanger 125 is formed, The expansion valve 126 can be disposed.

By including such an additional heat exchange structure, the discharge temperature of the first compressor 110 can be more efficiently managed.

The first refrigerant evaporated while passing through the first evaporator 140 flows into the first compressor 110 again through the four-way valve 115 and the liquid separator 150.

In the high stage side refrigeration cycle, the second refrigerant flows along the second circuit 200 including the second compressor 210, the second heat exchanger 220, the second expansion valve 230 and the first heat exchanger 120 And circulates through a refrigerant passage connecting them.

The liquid separator 250 may be disposed on the refrigerant passage upstream of the second compressor 210.

The refrigerant discharged from the second compressor 210 is heat-exchanged with water circulating in the hot water passage 310 connected to the second heat exchanger 220 through the second heat exchanger 220 to heat the water, In other words, it is condensed as heat is released.

Thus, the second heat exchanger 220 functions as a condenser with respect to the second refrigerant. The second heat exchanger 220 may be a plate heat exchanger like the first heat exchanger 120, or various other heat exchangers known in the art such as a dual-pipe heat exchanger.

The second refrigerant passing through the second heat exchanger 220 passes through the second expansion valve 230 and the second expansion valve 230 is connected to the first expansion valve 130 via the EEV have. A strainer 229 for removing foreign substances from the refrigerant may be disposed on the refrigerant flow path upstream of the second expansion valve 230.

The second refrigerant expanded while passing through the second expansion valve 230 passes through the first heat exchanger 120 and is heat-exchanged with the first refrigerant in the first heat exchanger 120 to be evaporated.

The second refrigerant having passed through the first heat exchanger 120 flows into the second compressor 210 through the liquid separator 250.

The low-stage side refrigeration cycle and the high-stage side refrigeration cycle described above may be all disposed, for example, in the outdoor unit (O). Alternatively, the low-stage side refrigeration cycle may be disposed in the outdoor unit (O), and the high-stage side refrigeration cycle may be disposed in the indoor unit (I).

The configuration excluding the second heat exchanger 220 in the high stage side refrigeration cycle as well as the low stage side refrigeration cycle is arranged in the outdoor unit O and the second heat exchanger 220 is disposed in the indoor unit I It is possible. In this structure, since the second compressor 210 is not disposed in the indoor unit I, noise generated in the indoor unit I can be greatly reduced, and the second heat exchanger 220 can be easily replaced can do.

The hot water channel 310 is connected to the second heat exchanger 220. The water circulating in the hot water passage 310 may be heated by heat exchange with the second refrigerant and used as hot water. For concrete use, the water used as heating water for heating the room 330 may be used as heating water.

A heat storaging tank 320 may be disposed on the hot water channel 310 to store the hot water heated by the second heat exchanger 220 as a heating medium.

On the other hand, under the condition that the outside air temperature is lower than Ta, which is a constant temperature, and the heating load is large, the low stage side refrigeration cycle and the high stage side refrigeration cycle can be operated simultaneously as shown in FIG.

However, when the outside air temperature is equal to or higher than the constant temperature Ta, only the high-stage side refrigerating cycle is operated under the condition that the heating load is not high, and the low-stage side refrigerating cycle including the first compressor 110 is not operated, It is necessary to reduce power and noise.

However, when the low-stage refrigeration cycle is not operated, a separate means for performing the role of the first heat exchanger 120 performing the function as the evaporator with respect to the second refrigerant is needed. In order to provide such a means, the heat pump 1 according to the present embodiment includes a branch passage 260, a valve, and a second evaporator 263.

Specifically, the branch flow passage 260 branches from the first point 231 of the second circuit 200 positioned between the second expansion valve 230 and the first heat exchanger 120, and flows into the first heat exchanger 120 to the second point 234 of the second circuit 200 located between the second compressor 210.

The valve prevents the second refrigerant that has passed through the second expansion valve 230 from passing through the branch passage 260 and prevents the second refrigerant from circulating toward the first heat exchanger 120, To the first heat exchanger (120) while blocking the second heat exchanger (120) from passing therethrough. The valve may be, for example, a solenoid valve.

The valve may include a first valve 261, 264 disposed on the branch flow passage 260 to specifically allow or block the second refrigerant from passing through the branch flow passage 260.

The first valves 261 and 264 may be disposed on the branch passage 260 on the upstream side of the second evaporator 263 or on the branch passage 260 on the downstream side of the second evaporator 263. Or may be disposed on the branch flow path 260 on the upstream side and the downstream side of the second evaporator 263, respectively, as shown in FIG.

Further, the valve may block the second refrigerant from circulating toward the first heat exchanger 120 when the second refrigerant is allowed to pass through the branch passage 260 according to the operation of the first valves 261 and 264, And a second valve (232, 233) that allows the refrigerant to circulate to the first heat exchanger (120) when the second refrigerant is blocked from passing through the branch flow path (260).

The second valves 232 and 233 may be disposed on the upstream side or the downstream side of the first heat exchanger 120, or both of them. Here, the upstream side of the first heat exchanger 120 may be on the refrigerant flow path between the first point 231 and the first heat exchanger 120. The downstream side of the first heat exchanger 120 may be on the refrigerant flow path between the first heat exchanger 120 and the second point 234.

The second evaporator 263 is disposed on the branch passage 260 so that the second refrigerant passing through the branch passage 260 is evaporated. The second evaporator 263 may be a fin-tube type heat exchanger like the first evaporator 140 and the refrigerant distributor 262 may be provided at the inlet end of the second evaporator 263.

The first evaporator 140 and the second evaporator 263 can be disposed in parallel with the first evaporator 140 and the outdoor unit O. The second evaporator 263 can be installed not only in the first evaporator 140 but also in the outside So that the air can flow.

When the outside air temperature is lower than Ta, the low-stage side refrigerating cycle and the high-stage side refrigerating cycle are both operated, and the first valve is shut off and the second valve is opened. In the heat pump 1 according to this embodiment, The refrigerant circulates in the refrigerant circulation direction indicated by the solid line arrow in FIG.

However, when the outdoor temperature is above Ta, the operation of the lower stage refrigeration cycle is not started, or the operation is stopped when it is in operation. That is, the first compressor 110 is not operated. The first valves 261 and 264 are opened while the second valves 232 and 233 are blocked and the second refrigerant is discharged to the second expansion valve 230 to the second compressor (210) via the second evaporator (263).

The ambient temperature can be measured by various known methods and can be detected by temperature sensors 141 and 264 provided on the first evaporator 140 or a second evaporator 263 to be described later.

The heat pump 1 according to the present embodiment may include at least a controller 400 that controls the operation of at least the first compressor 110, the second compressor 210 and the valves 232, 233, 261, have.

The control unit 400 receives a signal related to the sensed outdoor temperature, or determines whether the sensed temperature is equal to or greater than a predetermined temperature Ta, and if the sensed temperature is equal to or greater than Ta, the first compressor 110 operates The first valve 261 and the second valve 264 are opened while the second valve 232 and 233 are closed so that the second refrigerant passes through the branch passage 260. [

Here, Ta is an already set temperature value, but the temperature value can be changed according to the operating conditions by the user by inputting a new value as required or by the control logic configured in the controller 400.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is evident that modifications or improvements can be made by those skilled in the art.

1: Heat pump 100: First circuit
110: first compressor 115: four-way valve
120: first heat exchanger 125: economizer heat exchanger
126: expansion valve 130: first expansion valve
131: Strainer 132: Refrigerant distributor
140: first evaporator 141: temperature sensor
150: liquid separator 200: second circuit
210: second compressor 220: second heat exchanger
229: Strainer 230: Second expansion valve
231: First point 232, 233: Second valve
234: second point 250: liquid separator
260: branching flow path 261,264: first valve
262: Refrigerant distributor 263: Second evaporator
264: Temperature sensor 310: Hot water passage
320: heat storage tank 330: indoor
340: blower fan 400: control unit

Claims (8)

A lower stage refrigeration cycle in which a first refrigerant is circulated along a first circuit including a first compressor, a first heat exchanger, a first expansion valve and a first evaporator;
A high-stage side refrigeration cycle in which the second refrigerant is circulated along the second circuit including the second compressor, the second heat exchanger, the second expansion valve, and the first heat exchanger;
To a second point on the second circuit that is located between the first heat exchanger and the second compressor and which branches from a first point on the second circuit located between the second expansion valve and the first heat exchanger A branching flow channel;
The second refrigerant passing through the second expansion valve is allowed to pass through the branch passage and is prevented from circulating to the first heat exchanger or circulated to the first heat exchanger while blocking the branch refrigerant from passing through the branch passage Allowable valve;
A second evaporator disposed on the branch passage to evaporate the second refrigerant passing through the branch passage; And
A control unit for controlling operations of the first compressor, the second compressor, and the valve;
/ RTI >
When the second compressor is operated, when the outdoor temperature is equal to or higher than the predetermined temperature Ta, the control unit operates the valve while the first compressor is not operated to control the second refrigerant to pass through the branch passage A heat pump using a cascade cycle. The valve according to claim 1,
A first valve disposed on the branch flow passage for allowing or blocking the second refrigerant from passing through the branch flow passage,
A refrigerant flow path is formed between the first point and the first heat exchanger or between the first point and the second point so as to allow or block the circulation of the second refrigerant toward the first heat exchanger, And a second valve disposed in the second heat exchanger. delete The method according to claim 1,
Further comprising a hot water channel connected to the second heat exchanger and heated by heat exchange with water circulating in the second heat exchanger with the second coolant in the second heat exchanger. The method of claim 4,
And a heat storage tank connected to the hot water flow path. The method according to claim 1,
Wherein one or both of the first evaporator and the second evaporator is a fin-tube type heat exchanger. The method of claim 6,
Wherein the first evaporator and the second evaporator are arranged side by side in the outdoor unit,
Further comprising a blowing fan for allowing the outside air to flow to the first evaporator and the second evaporator. The method according to claim 1,
Wherein one or both of the first heat exchanger and the second heat exchanger is a plate-type heat exchanger.

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