KR20110066780A - Water circulation system associated with refrigerant system - Google Patents

Abstract

PURPOSE: A water circulating system cooperating with a refrigerant system is intended to provide higher temperature of water since water is heat-exchanged with second refrigerant which has been heat-exchanged with the first refrigerant of a first refrigerant system. CONSTITUTION: A water circulating system cooperating with a refrigerant system comprises a first refrigerant system(1), a second refrigerant system(2), a middle heat exchanger(25), a heat accumulating unit(16), and a water circulating unit. The first refrigerant system forms a refrigerant cycle, in which first refrigerant flows. The first refrigerant system comprises a first compressor(11) and a first heat exchanger(13) for heat-exchanging air with the first refrigerant. The second refrigerant system forms another refrigerant cycle, in which second refrigerant flows. The second refrigerant system comprises a second compressor(21). The middle heat exchanger heat-exchanges the first refrigerant with the second refrigerant in a process the first and second refrigerant flow.

Description

Water circulation system associated with refrigerant system

The present embodiment relates to a system for performing hot water supply and cooling and heating functions in conjunction with a refrigerant system.

The hot water supply and cooling / heating device interlocked with the refrigerant system is a device in which a refrigerant cycle and a water circulation cycle are combined. The hot water supply and cooling / heating unit is a device that allows the refrigerant flowing through the refrigerant pipe and the water flowing through the water pipe to exchange heat. .

In the conventional system, when the outdoor temperature is extremely low, the operation rate is low, and there is a problem that it is difficult to take hot water.

In addition, when the defrost of the heat exchanger is required while the refrigerant system is operating in the heating mode, the refrigerant system is operated in the cooling mode for defrosting, so that the heating of the room is not performed while the refrigerant system is cooling operation and hot water is not obtained. There is no problem.

An object of the present embodiment is to provide a refrigerant system interlocking water circulation system capable of improving operating performance and taking in hot water.

Another object of the present embodiment is to provide a refrigerant system interlocking water circulation system capable of heating the room even while the refrigerant system is operating in the defrost mode and capable of taking in hot water.

A refrigerant system interlocking water circulation system according to an aspect includes a first refrigerant system including a refrigerant cycle through which a first refrigerant flows, a first compressor, and a first heat exchanger configured to exchange heat between the air and the first refrigerant; A second refrigerant system forming a refrigerant cycle through which the second refrigerant flows, the second refrigerant system including a second compressor; An intermediate heat exchanger having a first refrigerant passage and a second refrigerant passage so as to exchange heat during the flow of the first refrigerant and the second refrigerant; A heat storage device including a heat storage agent that exchanges heat with the first or second refrigerant; And a water circulation unit configured to form a water circulation cycle to perform indoor water supply or indoor air conditioning, and to heat-exchange with the second refrigerant in the course of circulating water, and wherein the first and second refrigerant systems are operated in a heating mode. The heat storage agent absorbs heat from the first refrigerant or the second refrigerant, and when the defrosting operation condition for defrosting the first heat exchanger is satisfied, the first refrigerant system is operated in a cooling mode, and the first refrigerant is operated. The refrigerant or the second refrigerant is characterized by absorbing heat from the heat storage agent.

According to the proposed embodiment, the water of the higher temperature can be taken as the water is heat-exchanged with the second refrigerant heat-exchanged with the first refrigerant of the first refrigerant system.

In addition, even when the outdoor temperature is extremely low, the refrigerant system can be operated stably, there is an advantage that can take hot water.

In addition, even while the first refrigerant system is operated in the defrost mode, the second refrigerant system can be operated in the heating mode, so that hot water can be taken in and the indoor heating is possible.

In addition, when the first refrigerant system is operated in the defrost mode, since the first refrigerant or the second refrigerant absorbs heat from the high temperature refrigerant discharged from the heat storage agent or the compressor, the temperature of each of the refrigerants is increased so that each refrigerant system is increased. The lowering of the evaporation pressure can be minimized.

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

1 is a view schematically showing a refrigerant cycle interlocking water circulation system according to a first embodiment.

Referring to FIG. 1, the refrigerant system interlocking water circulation system S according to the present embodiment includes a first refrigerant system 1 forming a first refrigerant cycle through which a first refrigerant is circulated, and a second refrigerant therein. And a second refrigerant system 2 for exchanging the first refrigerant and heat exchange of water with the second refrigerant, and a hot water supply connected to the second refrigerant system 2 to supply hot water. part 4) and a cooling and heating unit 5 connected to the second refrigerant system 2 to perform indoor cooling and heating.

The second refrigerant system 2 then forms a second refrigerant cycle through which the second refrigerant is circulated.

In detail, the first refrigerant system 1 includes a first compressor 11 for compressing the first refrigerant and a first four-way valve for controlling a flow direction of the first refrigerant discharged from the first compressor 11. -way valve: 12, an intermediate heat exchanger (25) for exchanging the first refrigerant and the second refrigerant, a first expansion (14) for expanding the first refrigerant, and the first refrigerant A first heat exchanger 13 is included to allow outdoor air to exchange heat.

The first compressor 11, the first four-way valve 12, the intermediate heat exchanger 25, the first expansion part 14, and the first heat exchanger 13 may include a first refrigerant pipe 15. Connected by

The second refrigerant system 2 includes a second four-way valve 21 for compressing the second refrigerant and a second four-way valve for controlling the flow direction of the second refrigerant discharged from the second compressor 21. way valve 22, a second heat exchanger 23 for exchanging the second refrigerant and water, a second expander 24 for expanding the second refrigerant, the first refrigerant and the second The intermediate heat exchanger 25 to allow the refrigerant to heat exchange is included.

The second compressor 21, the second four-way valve 22, the second heat exchanger 23, the second expansion part 24, and the intermediate heat exchanger 25 may include a second refrigerant pipe ( 26).

In the present embodiment, since the second heat exchanger 23 allows the second refrigerant and water to heat exchange, the second heat exchanger 23 may be referred to as a water refrigerant heat exchanger.

The intermediate heat exchanger 25 includes a first flow path 251 through which the first refrigerant flows and a second flow path 252 through which the second refrigerant flows. The first flow path 251 and the second flow path 252 may be formed by the first refrigerant pipe 15 and the second refrigerant pipe 26, respectively.

Unlike this, the first flow path 251 and the second flow path 252 are separately formed in the intermediate heat exchanger 25, and the first refrigerant pipe 15 is connected to the first flow path 251. The second refrigerant pipe 26 may be connected to the second flow path 252.

The second heat exchanger 23 is provided with a refrigerant flow passage 231 through which the second refrigerant flows and a water flow passage 232 through which the water flows. The refrigerant flow path 231 and the water flow path 232 may be formed by the second refrigerant pipe 26 and the first water pipe 30, respectively.

Unlike this, the refrigerant flow path 231 and the water flow path 232 are separately formed in the second heat exchanger 23, and the second refrigerant pipe 26 is connected to the refrigerant flow path 231. The first water pipe 30 may be connected to the second flow path 232.

For example, a plate-type heat exchanger may be used as the intermediate heat exchanger 25 and the second heat exchanger 23, but is not limited thereto.

The intermediate heat exchanger 25 may be located inside a first case containing the first refrigerant system 1 or inside a second case including the second refrigerant system 2. In the present embodiment, for example, the intermediate heat exchanger 25 is positioned inside the second case.

In the present embodiment, for example, R410a may be used as the first refrigerant, and R134a may be used as the second refrigerant.

That is, different types may be used for the first refrigerant of the first refrigerant system 1 and the second refrigerant of the second refrigerant system 2.

When the first refrigerant system 1 is operated in the heating mode, the first refrigerant compressed by the first compressor 11 is controlled by the flow path of the first four-way valve 12 to the intermediate heat exchanger 25. Flows into. The first refrigerant flowing into the intermediate heat exchanger 25 is moved to the first expansion part 14 after heat exchange with the second refrigerant. The first refrigerant is then expanded by the first expansion portion 14 and then evaporated while flowing through the first heat exchanger 13. Then, the evaporated first refrigerant is sucked into the first compressor (11). That is, when the first refrigerant system 1 is operated in the heating mode, the intermediate heat exchanger acts as a condenser.

When the second refrigerant system 2 is operated in the heating mode, the second refrigerant compressed by the second compressor 12 is controlled by the flow path of the second four-way valve 22 to the second heat exchanger. Flows to (23). The second refrigerant flowing into the second heat exchanger 23 is moved to the second expansion part 24 after heat exchange with water. Then, the second refrigerant is expanded by the second expansion part 24, and then heat exchanges with the first refrigerant while the intermediate heat exchanger 25 flows to evaporate. The second refrigerant evaporated is sucked into the second compressor 21. That is, when the second refrigerant system 2 is operated in the heating mode, the intermediate heat exchanger 25 serves as an evaporator.

In FIG. 1, the solid line shows the flow of the refrigerant when the respective refrigerant system is operated in the heating mode, and the dotted line shows the flow of the refrigerant when the respective refrigerant system is operated in the cooling mode.

In summary, the intermediate heat exchanger 25 serves as a condenser for the first refrigerant system 1 when each of the refrigerant systems 1 and 2 is operated in a heating mode, and the second refrigerant system 2 ) Acts as an evaporator.

Therefore, if the first refrigerant system 1 is cooled and the second refrigerant system 2 is heated, the intermediate heat exchanger 25 serves as an evaporator for each of the refrigerant systems 1 and 2. Will be

When the first refrigerant system 1 is operated in the heating mode, a part of the first pipe 151 on the inlet side of the intermediate heat exchanger 25 and the second refrigerant system 2 are in the heating mode. When operated, a part of the third pipe 261 on the inlet side of the intermediate heat exchanger 25 passes through the heat storage 16.

At this time, if each of the refrigerant system is operated in the cooling mode, it will be readily understood that each pipe serves as an outlet pipe of the intermediate heat exchanger.

In detail, the first pipe 151 communicates with the first refrigerant passage 251, and the third pipe 261 communicates with the second refrigerant passage 252.

The heat storage agent 161, which is a medium for storing heat, is accommodated in the heat storage 16. As the heat storage agent 161, water, an aqueous sodium acetate solution, an oil, an aqueous sodium chloride solution, and the like may be used. In the present embodiment, the type of the heat storage agent 161 is not limited.

When each of the refrigerant systems 1 and 2 is operated in a heating mode, a high temperature first refrigerant flows through the first pipe 151 and a second low temperature refrigerant that is expanded to the third pipe 261. Will flow. When the first refrigerant having a high temperature flows through the first pipe 151, the heat storage agent 161 stores the heat of the first refrigerant.

In the present embodiment, when the refrigerant system is operated in the heating mode, the flow direction of the first refrigerant and the second refrigerant in the intermediate heat exchanger 25 are parallel to each other. The flow direction of the refrigerant and the second refrigerant may be reversed.

Meanwhile, the second refrigerant system 2 further includes a water flow system for flowing water.

The water flow system includes a first water pipe 30 through which water flows, a flow switch 32 mounted on the first water pipe 30 to sense the flow of water, and the flow switch 32. Expansion tank 33, which is branched at a point spaced in the direction of water flow from the water), and a portion of the water pipe is inserted, the collection tank 34, the auxiliary heater 35 is provided therein, and the collection Included is a water pump 36 provided at any point on the outlet side second water line 61 of the tank 34.

The first water pipe 30 includes an inlet pipe 301 provided on the inlet side of the second heat exchanger 23 and an outlet pipe 302 provided on the outlet side of the second heat exchanger 23. Included. In addition, the outlet pipe 302 is connected to the collection tank 34.

In this embodiment, the water pump 36 may be used an inverter pump (Adverter pump) that can adjust the amount of water pumped.

When the second refrigerant system 2 is operated in the heating mode, heat QH is transferred from the second refrigerant discharged from the second compressor 21 to the water flowing along the water flow path 232. The water supplied to the water passage 232 is lukewarm through a hot water supply process or an indoor heating process, and the temperature of the water in the water passage 232 is increased by heat transfer of the second refrigerant.

On the other hand, the expansion tank 33 performs a buffer function that absorbs the volume of the heated water while passing through the second heat exchanger 23 when the volume of the heated water is expanded to an appropriate level or more. The expansion tank 33 is provided with a diaphragm (not shown) to move in response to a volume change of water in the outlet pipe 302. The expansion tank 33 is filled with nitrogen gas.

The collection tank 34 is a container in which water supplied from the outlet pipe 302 is stored. The collection tank 34 is provided with an auxiliary heater 35 which is operated when the temperature of the water does not reach the required temperature.

The collecting tank 34 is provided with an air vent 343 for discharging the superheated air present in the collecting tank 34. In addition, the collection tank 34 is provided with a pressure gauge 341 and a relief valve 342, so that the pressure inside the collection tank 35 is appropriately adjusted. For example, when the water pressure of the collection tank 34 sensed by the pressure gauge 341 is excessively high, the relief valve 342 may be opened to adjust the pressure in the collection tank 34. .

The water pump 36 pumps the water in the collecting tank 34 so as to flow into the second water pipe 61. The water pumped into the second water pipe 61 may be supplied to the hot water supply unit 4 or the cooling / heating unit 5.

On the other hand, the hot water supply unit 4, the user warms and supplies the water required for work such as washing or washing dishes.

In detail, the second water pipe 61 is provided with a three-way valve 71 for adjusting the flow direction of water. The three-way valve 71 is a directional valve for allowing the water pumped by the water pump 36 to flow into the hot water supply part 4 and / or the air-conditioning part 5.

Accordingly, the hot water supply pipe 62 extending to the hot water supply unit 4 and the air conditioning heating pipe 63 extending to the air conditioning unit 5 are connected to the outlet side of the three-way valve 71. The water pumped by the water pump 36 flows into the hot water supply pipe 62 and / or the air conditioning pipe 63 under the control of the three-way valve 71.

The hot water supply unit 4 includes a hot water tank 41 for storing water supplied from the outside and heating the stored water, and an auxiliary heater 42 provided inside the hot water tank 41. In addition, an auxiliary heat source for supplying heat to the hot water tank 41 may be further added according to the installation form. As the auxiliary heat source that can be presented, the heat storage 43 using solar heat is possible. In addition, one side of the hot water supply unit 4 is provided with a water inlet 411 for introducing water, and a water outlet 412 for discharging the heated water.

In detail, a part of the hot water supply pipe 62 extending from the three-way valve 71 is introduced into the hot water tank 41 to heat the water stored in the hot water tank 41. That is, heat is transferred from the hot water flowing along the inside of the hot water supply pipe 62 to the water stored in the hot water tank 41. And, in certain cases, the auxiliary heater 42 and the auxiliary heat source may operate to supply additional heat.

For example, the auxiliary heater 42 or the auxiliary heat source may operate when the water needs to be heated in a short time, such as when the user needs a lot of hot water to take a bath. And, one side of the hot water tank 41 may be equipped with a temperature sensor 414 for detecting the temperature of the water.

According to an embodiment, the hot water discharge device such as the shower 45 or the home appliance such as the humidifier 46 may be connected to the water outlet 412. In addition, when the heat accumulator 43 using solar heat is used as the auxiliary heat source, the heat storage pipe 47 extending from the heat accumulator 43 may be inserted into the hot water tank 41. In addition, an auxiliary pump 44 for controlling the flow rate inside the heat storage pipe closed circuit is mounted on the heat storage pipe 47, and a direction switching valve VA for controlling the flow direction of water in the heat storage pipe 47 is mounted. Can be. In addition, a temperature sensor 471 for measuring the temperature of the water may be mounted on any one side of the heat storage pipe 47.

The auxiliary heat source structure such as the heat storage unit using the solar heat as described above is not limited to the above-described embodiment, and it can be found that it can be mounted at different positions in various forms.

On the other hand, in the air-conditioning unit 5, a part of the floor air-conditioning unit 51 formed by embedding a part of the air-conditioning pipe 63 is embedded in the indoor floor, and branched from any point of the air-conditioning pipe 63 and the floor air-conditioning unit Air cooling and heating unit 52 connected in parallel with the 51 is included.

In detail, the floor heating and cooling unit 51 may be buried in the form of a meander line (meander line) on the indoor floor as shown. In addition, the air-conditioning unit 52 may be a fan coil unit or a radiator. In addition, a part of the air-conditioning pipe 54 branched from the air-conditioning pipe 63 is provided to the air-conditioning unit 52 as a heat exchange means. At the point where the air cooling and heating pipe 54 is branched, flow path switching valves 55 and 56 such as three-way valves are installed, and water flowing along the cooling and heating pipe 63 flows into the floor heating and cooling unit 51 and the air. Can be divided into the air-conditioning unit 52 or only flow to either side.

The hot water supply pipe 62 passing through the hot water tank and the air conditioning pipe 63 passing through the air conditioning unit 5 are connected to the inlet pipe 301.

Here, each of the hot water supply pipe 62 and the air-conditioning pipe 63 may be provided with a check valve (V) to prevent the water of one pipe from flowing back to the other pipe.

In this embodiment, since the water flow system provided in the second refrigerant system 2, the hot water supply unit 4 and the air-conditioning unit 5 forms a water circulation cycle in which water is circulated, the water circulation system Let's call it a unit.

Hereinafter, the flow of water occurring in the refrigerant system interlocking water circulation system will be described by dividing each operation mode.

In the present embodiment, the operation mode of each refrigerant system includes a cooling mode, a heating mode, and a defrost mode, the hot water supply unit includes a hot water supply mode, and the air conditioning unit includes a cooling mode and a heating mode.

In the present embodiment, the hot water supply mode of the hot water supply unit and the heating mode of the heating and cooling unit is mainly concerned, the following description will be described with respect to the operation of the above two modes.

In the hot water supply mode or the heating mode of the heating and cooling unit, the respective refrigerant systems are heated and operated.

When each of the refrigerant systems 1 and 2 is heated and operated, the intermediate heat exchanger 25 acts as a condenser with respect to the first refrigerant system 1 as described above, Act as an evaporator.

Then, the second refrigerant flowing through the intermediate heat exchanger 25 receives heat from the first refrigerant to increase the temperature. As such, when the temperature of the second refrigerant rises, the temperature of the second refrigerant sucked into the second compressor 21 increases. When the temperature of the second refrigerant sucked into the second compressor 21 increases, the temperature of the second refrigerant discharged from the second compressor 21 rises and eventually flows to the second heat exchanger 23. The temperature of the refrigerant is increased.

Therefore, a higher amount of heat is transferred from the second refrigerant flowing through the second heat exchanger 23 to the water flowing through the second heat exchanger 23, thereby increasing the temperature rise of the water.

At this time, the condensation temperature (or second compressor outlet temperature) of the second refrigerant is higher than the condensation temperature (or first compressor outlet temperature) of the first refrigerant due to the characteristics of the respective refrigerants.

In the case of the existing system, since the water is configured to heat exchange with the refrigerant of the single refrigerant system, it can be easily confirmed that the temperature rise of the water according to the present system is larger than the temperature rise of the water of the existing system.

Increasing the temperature of the water heat-exchanged in the second heat exchanger 23 means that the temperature of the water stored in the collecting tank 34 is increased than the temperature of the water of the existing system, which is to take water of higher temperature or This means that room heating can be carried out with higher temperature water.

Therefore, according to the present embodiment, it is possible to take water of a higher temperature, and even when the outdoor temperature is extremely low, the refrigerant system can be stably operated, and there is an advantage of taking water of high temperature.

Meanwhile, when the hot water supply mode is selected, the three-way valve 71 controls the flow of water to flow into the hot water supply pipe 62. Therefore, the water circulates along the closed circuit connecting the second heat exchanger 23, the collecting tank 34, the water pump 36, the three-way valve 71, and the hot water supply pipe 62. In this circulation process, water flowing into the water inlet 411 of the hot water tank 41 is heated and then discharged to the outside through the water outlet 412 to be supplied to the user.

In addition, when the heating mode of the cooling and heating unit is selected, the three-way valve 71 is controlled to flow the water to the cooling and heating pipe (63). Therefore, the water circulates along the closed circuit connecting the second heat exchanger 23, the collecting tank 34, the water pump 36, the three-way valve 71, and the cooling / heating pipe 63. In addition, the water flowing along the cooling and heating pipe 63 flows to the air cooling and heating unit 52 or the floor cooling and heating unit 51.

Of course, the hot water mode and the heating mode of the heating and cooling unit may be selected at the same time. In this case, the water flows into the hot water supply pipe and the air conditioning pipe 63 by the three-way valve 71.

As described above, when each refrigerant system is operated in the heating mode, the first heat exchanger 13 of the first refrigerant system 1 acts as an evaporator. Therefore, when the first refrigerant system 1 is continuously operated in the heating mode, the first heat exchanger 13 generates an frost, and defrost is required.

Hereinafter, the defrosting method of the first heat exchanger 13 will be described.

The refrigerant system interlocking water circulation system according to the present embodiment operates in a mode set by a user's selection. In this embodiment, since there is a major interest in defrosting operation, a description will be given of a case in which each of the refrigerant systems 1 and 2 is defrosted while being operated in a heating mode.

When the first refrigerant system 1 operates in the heating mode, as described above, the first refrigerant having a high temperature flows through the first pipe 151, and the heat storage agent 161 stores heat.

It is determined whether a defrosting operation condition is satisfied while the water circulation system is operating in the set mode. For example, whether the defrosting operation condition is satisfied may be determined by comparing a pipe outlet temperature of the first heat exchanger 13 with an outdoor temperature. However, in the present embodiment, the determination of whether the defrosting operation condition is satisfied may be performed by various methods.

If the defrosting operation condition is satisfied, the first refrigerant system 1 operates in the defrost mode, and the second refrigerant system 2 maintains the original operation mode (heating mode).

In this embodiment, the defrosting operation of the first refrigerant system 1 means that the first refrigerant system 1 operates in a cooling mode.

When the first refrigerant system 1 is operated in the defrost mode, the intermediate heat exchanger 25 serves as an evaporator for each of the refrigerant systems 1 and 2, and the first heat exchanger 25 is It will act as a condenser. Therefore, while the first refrigerant system 1 is operated in the defrost mode, defrosting of the first heat exchanger 13 is performed by a high temperature refrigerant flowing through the first heat exchanger 13.

At this time, since the intermediate heat exchanger 25 serves as an evaporator for each of the refrigerant systems 1 and 2, the evaporation pressure of each of the refrigerant systems is reduced so that the cycle performance of each refrigerant system is deteriorated. Each compressor may be damaged.

However, in the present embodiment, when the first refrigerant system 1 is operated in the heating mode, the heat storage agent 161 stores the heat obtained from the first refrigerant, so that the first refrigerant system in the defrost mode When operated, the first refrigerant and the second refrigerant absorb heat from the heat storage agent 161.

Therefore, since each of the refrigerant absorbs heat from the heat storage agent 16, the lowering of the evaporation pressure of each of the refrigerant system can be minimized.

Then, it is determined whether defrost is terminated while the first refrigerant system 1 is operating in the defrost mode. When it is determined that the defrost is finished, the first refrigerant system 1 is operated in the previous mode. In the present embodiment, the first refrigerant system will operate in the heating mode.

According to the present embodiment as described above, even when the first refrigerant system 1 is operated in the defrost mode, the second refrigerant system 2 is operated in the heating mode, and thus hot water extraction and / or indoor heating are possible. There is this.

In addition, since the hot water exchanges heat with the first refrigerant flowing into the intermediate heat exchanger 25, the evaporation pressure is minimized to reduce the performance of each refrigerant system.

In addition, since the heat storage agent absorbs heat when the first refrigerant system 1 is operated in the heating mode, when the first refrigerant system 1 is operated in the defrost mode, heat is transferred from the heat storage agent to each refrigerant. The temperature of each of the refrigerants may be increased to be transmitted, and a decrease in the evaporation pressure of the refrigerant system may be minimized.

2 is a flowchart illustrating a defrosting operation method of a refrigerant system interlocking water circulation system according to a second embodiment.

The present embodiment is different from the first embodiment, and when the first refrigerant system is operated in the defrost mode, the second refrigerant system also operates in the defrost mode. Therefore, hereinafter, only characteristic parts of the embodiment will be described.

2, the refrigerant system interlocking water circulation system according to the present embodiment is operated in a mode set by the user's selection (S21). In the present embodiment, since the main interest is in defrosting operation, the case where each of the refrigerant systems 1 and 2 are operated in the heating mode will be described.

It is determined whether a defrosting operation condition is satisfied while the water circulation system is operated in the set mode (S22).

As a result of the determination in step S22, when the defrosting operation condition is satisfied, the first refrigerant system 1 and the second refrigerant system 2 operate in the defrost mode.

In this embodiment, the operation of the first refrigerant system 1 in the defrost mode means that the first refrigerant system 1 is operated in the cooling mode.

Operation of the second refrigerant system 2 in the defrost mode means two cases as follows. The first means that the operation of the second refrigerant system 2 is stopped, and the second means that the second refrigerant system 2 is basically operated in a heating mode while the second compressor 21 is in a previous mode. This means that the driving frequency is lower than the operating frequency of the second compressor (eg, the minimum frequency).

According to the first case, the low temperature second refrigerant does not pass through the intermediate heat exchanger 25, and in the second case, the amount of the low temperature second refrigerant flows is reduced, and as a result, the respective intermediate heat exchangers The reduction in the evaporation pressure of the group 25 can be minimized.

In addition, since the refrigerant absorbs heat during the flow of the heat accumulator 16, the decrease in the evaporation pressure of the intermediate heat exchanger 25 will be further reduced.

Then, it is determined whether defrost is terminated while each of the refrigerant systems 1 and 2 is operated in the defrost mode (S25).

If it is determined that the defrost is completed, the refrigerant systems 1 and 2 operate in the previous mode (S25). In this embodiment, each of the refrigerant systems will operate in a heating mode.

3 is a flowchart illustrating a defrosting operation method of a refrigerant system interlocking water circulation system according to a third embodiment.

This embodiment is the same as the first embodiment in other parts, except that the amount of water flowing through the second water pipe is reduced when the first refrigerant system is operated in the defrost mode. Therefore, hereinafter, only characteristic parts of the embodiment will be described.

Referring to FIG. 3, the refrigerant system interlocking water circulation system according to the present embodiment is operated in a mode set by a user's selection (S31). In the present embodiment, since the main interest is in defrosting operation, the case where each of the refrigerant systems 1 and 2 are operated in the heating mode will be described.

It is determined whether a defrosting operation condition is satisfied while the water circulation system is operated in the set mode (S32).

As a result of the determination in step S32, if the defrosting operation condition is satisfied, the first refrigerant system 1 operates in the defrost mode, and the second refrigerant system 2 maintains the original operation mode (heating mode). do.

When the first refrigerant system 1 is operated in the defrost mode, the intermediate heat exchanger 25 serves as an evaporator for each of the refrigerant systems 1 and 2.

At this time, since the intermediate heat exchanger acts as an evaporator for each of the refrigerant systems, the evaporation pressure of each of the refrigerant systems is reduced, resulting in a lower condensation temperature of the second heat exchanger. When the condensation temperature of the second heat exchanger is lowered, the temperature of the water stored in the collection tank 34 is lowered.

When the temperature of the water stored in the collecting tank 34 is lowered, the temperature of the water flowing in the air-conditioning pipe 63 of the air-conditioning unit 5 may be lowered to lower the temperature of the room.

Therefore, in the present embodiment, when the first refrigerant system 1 is operated in the defrost mode, the water pump 36 so that the amount of water pumped is reduced than when the first refrigerant system 1 is operated in the heating mode. The operation of is changed (S34). In this case, since the amount of water flowing in the air-conditioning pipe 63 of the air-conditioning unit 5 is reduced, the temperature of the room can be minimized.

Next, it is determined whether defrost is terminated while the first refrigerant system 1 is operated in the defrost mode (S35).

And, when it is determined that the defrost is finished, the water pump 36 is operated in the previous state, the flow rate of the air-conditioning pipe 63 is returned to the previous state (S36). In operation S37, the first refrigerant system operates in the previous mode.

4 is a view schematically illustrating a refrigerant system interlocking water circulation system according to a fourth embodiment.

This embodiment is the same as the other embodiments, except that the type of the first refrigerant pipe drawn into the heat storage is different. Therefore, hereinafter, the characteristic parts of the embodiment will be described.

Referring to FIG. 4, a portion of the second pipe 152 serving as an outlet pipe of the intermediate heat exchanger 25 based on when the first refrigerant system 1 is operated in a heating mode, and the second Part of the third pipe 261 serving as the inlet pipe of the intermediate heat exchanger 25 on the basis of when the refrigerant system 1 is operated in the heating mode, the heat accumulator 16 having the heat storage agent 161 is provided. Pass through.

In detail, the second pipe 152 communicates with the first refrigerant path 251, and the third pipe 261 communicates with the second refrigerant path 252.

When each of the refrigerant systems 1 and 2 is operated in a heating mode, the first refrigerant having a high temperature passing through the intermediate heat exchanger 25 flows into the second pipe 152, and the third pipe 261 is operated. ), The expanded low temperature second refrigerant flows. When the first refrigerant having a high temperature flows through the second pipe 152, the heat storage agent 161 stores the heat of the first refrigerant.

Also in this embodiment, as in the first embodiment, when the first refrigerant system is operated in the defrost mode, each refrigerant absorbs heat from the heat storage agent 161, so that the evaporation pressure of each refrigerant system is lowered. Can be minimized.

In the present exemplary embodiment, the second pipe 152 is introduced into the heat storage 16, but the fourth pipe 262 may also be drawn into the heat storage 16.

Accordingly, when the first embodiment is combined with the present embodiment, a part of two pipes selected from the pipes 151, 161, 161, and 162 may be introduced into the heat storage 16.

5 is a cross-sectional view illustrating a structure of an intermediate heat exchanger according to a fifth embodiment.

The present embodiment is the same as the first embodiment in other parts, except that the heat storage is removed and the heat storage is provided in the intermediate heat exchanger. Therefore, hereinafter, only characteristic parts of the exemplary embodiment will be described.

Referring to FIG. 5, the intermediate heat exchanger 27 is located inside the first wall 271 and the first wall 271 and the second wall 272 spaced apart from the first wall 271. ) And a third wall 273 positioned inside the second wall 272 and spaced apart from the second wall 272. The second wall 272 surrounds the third wall 273 and the first wall 271 surrounds the second wall 272.

A first refrigerant passage 274 is formed between the second wall 272 and the third wall 273 to flow the first refrigerant, and the first wall 271 and the second wall 272 are formed. The second refrigerant passage 275 through which the second refrigerant flows is formed therebetween. The heat storage agent 276 is provided in the third wall 273.

Thus, the first refrigerant exchanges heat with the second refrigerant and the heat storage agent 276. That is, the third wall 273 and the heat storage agent 276 serve as a heat storage device.

The first refrigerant pipe 15 is connected to the first refrigerant path 274, and the second refrigerant pipe 26 is connected to the second refrigerant path 275.

According to the present embodiment, when each of the refrigerant systems is heated and operated, a high temperature first refrigerant flows through the first refrigerant passage, and a low temperature refrigerant flows through the second refrigerant passage. Then, the heat storage agent 276 absorbs heat from the high temperature first refrigerant to store heat.

When the first refrigerant system is operated in the defrost mode, low temperature refrigerant flows through each of the refrigerant passages. At this time, since heat is transferred from the heat storage agent 276 to the first refrigerant, the temperature of the first refrigerant is increased, and thus the temperature of the second refrigerant that is heat-exchanged with the first refrigerant is increased. Therefore, the lowering of the evaporation pressure of each of the refrigerant systems can be prevented.

In the present embodiment, a second refrigerant flows between the first wall 271 and the second wall 272, and a first refrigerant flows between the second wall 272 and the third wall 273, but vice versa The first refrigerant may flow between the first wall 271 and the second wall 272, and the second refrigerant may flow between the second wall 272 and the third wall 273.

However, in order to increase the amount of heat storage of the heat storage agent 276, it is preferable that a first refrigerant flows between the second wall 272 and the third wall 273.

6 is a view schematically illustrating a refrigerant system interlocking water circulation system according to a sixth embodiment.

This embodiment is the same as the other embodiments in other parts, and there is a difference in that a bypass pipe is formed in each refrigerant pipe. Therefore, hereinafter, only characteristic parts of the embodiment will be described.

Referring to FIG. 6, the intermediate heat exchanger 25 is formed with a first refrigerant passage 251 through which a first refrigerant flows and a second refrigerant passage 252 through which the second refrigerant flows.

And, when the first refrigerant system 1 is operated in the cooling mode, the discharge side pipe 153 of the first compressor 11 and the first refrigerant passage 251 of the intermediate heat exchanger 25. The first bypass pipe 17 for bypassing the first refrigerant of high temperature discharged from the first compressor 11 is connected to the second pipe 152 of the inlet side of the ().

The first bypass pipe 17 is provided with a first bypass valve 18 capable of adjusting the flow rate of the first refrigerant.

In addition, the discharge side pipe 263 of the second compressor 21 and the second refrigerant flow path 252 of the intermediate heat exchanger 25 are used when the second refrigerant system 2 is heated. A second bypass pipe 28 for bypassing the high temperature second refrigerant discharged from the second compressor 21 is connected to the inlet side third pipe 261.

The second bypass pipe 28 is provided with a second bypass valve 29 capable of adjusting the flow rate of the second refrigerant.

Each of the bypass valves 18 and 29 may be opened during the defrost mode operation of the first refrigerant system.

In FIG. 6, the solid line shows the flow of the refrigerant when each refrigerant system is operated in the heating mode, the dotted line shows the flow of the refrigerant when the respective refrigerant system is operated in the cooling mode, and the dashed-dotted line is shown in FIG. 1 shows the flow of refrigerant when the refrigerant system is operating in defrost mode.

7 is a flowchart illustrating a defrosting operation method of a refrigerant system interlocking water circulation system according to a sixth embodiment.

Referring to FIG. 7, the refrigerant system interlocking water circulation system according to the present embodiment is operated in a mode set by a user's selection (S41). In the present embodiment, since the main interest is in defrosting operation, the case where each of the refrigerant systems 1 and 2 are operated in the heating mode will be described.

It is determined whether a defrosting operation condition is satisfied while the water circulation system is operating in the set mode (S42). As a result of the determination in step S42, when the defrosting operation condition is satisfied, the first refrigerant system 1 operates in the defrost mode, and the second refrigerant system 2 maintains the original operation mode (heating mode). (S43).

In the present embodiment, the defrosting operation of the first refrigerant system means that the first refrigerant system is operated in a cooling mode.

When the first refrigerant system 1 is operated in the defrost mode, the intermediate heat exchanger 25 serves as an evaporator for each refrigerant system, and the first heat exchanger 13 serves as a condenser. . Therefore, while the first refrigerant system is operated in the defrost mode, defrosting of the first heat exchanger 13 is performed by a high temperature refrigerant flowing through the first heat exchanger 13.

At this time, since the intermediate heat exchanger 25 serves as an evaporator for each refrigerant system, the evaporation pressure of each of the refrigerant systems 1 and 2 is reduced, so that the cycle performance of each refrigerant system is deteriorated. Each compressor may be damaged.

Therefore, in the present embodiment, in order to reduce the decrease in the evaporation pressure in the intermediate heat exchanger 25, each of the bypass valves 18 and 29 according to the outdoor temperature while the first refrigerant system is operating the defrost mode. Allow at least one of them to open.

First, it is determined whether the outdoor temperature detected by the outdoor temperature sensor (not shown) exceeds the first reference temperature (S44). For example, the first reference temperature may be 5 ° C.

If the outdoor temperature exceeds the first reference temperature, the first bypass valve 18 operates to allow the high temperature first refrigerant to flow into the first bypass pipe 17 (S45). .

On the other hand, if the detected outdoor temperature does not exceed the first reference temperature, it is determined whether the next detected outdoor temperature is a temperature between the second reference temperature lower than the first reference temperature and the first reference temperature (S46). ). The second reference temperature may be, for example, -5 ° C.

If the detected outdoor temperature is a temperature between the second reference temperature and the first reference temperature, the second bypass valve 29 may be operated so that a high temperature second refrigerant flows into the second bypass pipe 28. (S47).

On the other hand, when the sensed outdoor temperature is less than the second reference temperature, the first and second bypass valves 18 and 29 operate to allow the first high temperature refrigerant to flow into the first bypass pipe 17. In operation S48, a high temperature second refrigerant flows through the second bypass pipe 28.

When the high temperature refrigerant is bypassed to at least one of the bypass pipes 17 and 28, the temperature of the first refrigerant and / or the second refrigerant is increased to lower the evaporation pressure of the intermediate heat exchanger 27. Can be prevented.

Next, it is determined whether defrost is terminated while the first refrigerant system is operating in the defrost mode (S49).

When it is determined that defrost is completed, the bypass valve opened is closed (S50). In operation S51, the first refrigerant system 1 operates in the previous mode. In the present embodiment, the first refrigerant system 1 will operate in the heating mode.

During the defrost mode operation of the first refrigerant system described in the present embodiment, as mentioned in the second and third embodiments, the second refrigerant system is operated in the defrost mode or the water flowing in the air-conditioning pipe 63 flows. The amount can be reduced.

However, when the second refrigerant system is stopped, when the defrosting operation condition is satisfied, the first bypass valve 18 may be operated so that the first refrigerant may flow into the first bypass pipe 17. .

1 is a view schematically showing a refrigerant cycle interlocking water circulation system according to a first embodiment.

2 is a flowchart illustrating a defrosting operation method of a refrigerant system interlocking water circulation system according to a second embodiment.

3 is a flowchart illustrating a defrosting operation method of a refrigerant system interlocking water circulation system according to a third embodiment.

4 is a schematic view of a refrigerant system interlocking water circulation system according to a fourth embodiment;

5 is a cross-sectional view illustrating a structure of an intermediate heat exchanger according to a fifth embodiment.

6 is a schematic view of a refrigerant system interlocking water circulation system according to a sixth embodiment;

7 is a flowchart illustrating a defrosting operation method of a refrigerant system interlocking water circulation system according to a sixth embodiment.

Claims (12)

A first refrigerant system forming a refrigerant cycle through which the first refrigerant flows, the first refrigerant system including a first compressor and a first heat exchanger for exchanging air and the first refrigerant; A second refrigerant system forming a refrigerant cycle through which the second refrigerant flows, the second refrigerant system including a second compressor; An intermediate heat exchanger having a first refrigerant passage and a second refrigerant passage so as to exchange heat during the flow of the first refrigerant and the second refrigerant; A heat storage device including a heat storage agent that exchanges heat with the first or second refrigerant; And Forming a water circulation cycle to perform indoor water supply or room air conditioning, and includes a water circulation unit for heat exchange with the second refrigerant in the course of circulating water, When the first and second refrigerant systems are operated in a heating mode, the heat storage agent absorbs heat from the first or second refrigerant, When the defrosting operation condition for defrosting the first heat exchanger is satisfied, the first refrigerant system is operated in a cooling mode, and the first refrigerant or the second refrigerant absorbs heat from the heat storage agent. system. The method of claim 1, When each refrigerant system is operated in a heating mode, the intermediate heat exchanger acts as a condenser for the first refrigerant system and acts as an evaporator for the second refrigerant system, And the intermediate heat exchanger acts as an evaporator for each of the refrigerant systems when the first refrigerant system is operated in a defrost mode. The method of claim 1, The first refrigerant passage is connected to the first pipe and the second pipe for entering and exiting the first refrigerant, The second refrigerant passage is connected to the third pipe and the fourth pipe for entering and exiting the second refrigerant, A refrigerant system interlocking water circulation system, wherein any one of the first pipe and the second pipe and one of the third pipe and the fourth pipe pass through a heat storage agent inside the heat storage device. The method of claim 1, The regenerator is a refrigerant system interlocking water circulation system provided on the outside of the intermediate heat exchanger. The method of claim 1, The regenerator is a refrigerant system interlocking water circulation system provided inside the intermediate heat exchanger. The method of claim 1, And the second refrigerant system is stopped when the defrosting operation condition is satisfied. The method of claim 1, And the second refrigerant system operates in a defrost mode in which the second compressor is operated at a frequency lower than an operating frequency of the second compressor in the heating mode when the defrosting operation condition is satisfied. The method of claim 1, The water circulation unit has a water pipe through which water flows, Including an inverter pump capable of adjusting the flow rate of the water pumped to the water pipe, And the inverter pump is operated such that the flow rate of the water pipe is lower than the flow rate of the water pipe in the heating mode when the defrosting operation condition is satisfied. The method of claim 1, On the discharge side of the first compressor or the second compressor is provided with a bypass pipe to bypass the first refrigerant or the second refrigerant to the intermediate heat exchanger, The bypass pipe is provided with a bypass valve for controlling the flow rate of the refrigerant, When the defrosting operation condition is satisfied, A refrigerant system interlocking water circulation system in which the bypass valve is opened. The method of claim 9, A first bypass pipe for allowing the refrigerant discharged from the first compressor to bypass the inlet side of the first refrigerant passage; A second bypass pipe for allowing the refrigerant discharged from the second compressor to bypass the inlet side of the second refrigerant path; It includes a first bypass valve and a second bypass valve provided in each bypass pipe, The refrigerant system interlocking water circulation system in which the number of bypass valves opened according to the outdoor temperature is varied when the defrosting operation condition is satisfied. 11. The method of claim 10, When the outdoor temperature is equal to or greater than the first reference temperature, the first bypass valve is opened, The second bypass valve is opened when the second reference temperature at which the outdoor temperature is lower than the first reference temperature is a temperature between the first reference temperatures, And the first and second bypass valves open when the outdoor temperature is lower than the second reference temperature. The method of claim 1, The first refrigerant is R410a, And the second refrigerant is R134a.

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