WO2010038572A1 - Heat exchanger and hot-water system - Google Patents

Abstract

A defrost heat exchanger (14) is provided with low-pressure cooling medium piping (20) wherein a low-pressure medium flows, high-pressure cooling medium piping (21) which is brought into contact with the low-pressure cooling medium piping (20) and has the high-pressure cooling medium flowing therein, and water piping (56) which is brought into contact with the low-pressure cooling medium piping (20) and has water flowing therein.  The flow channel cross-section area of the low-pressure cooling medium piping (20) is larger than that of the water flow channel (56) and is also larger than that of the high-pressure cooling medium flow channel (21).

Description

Heat exchanger and hot water system

The present invention relates to a heat exchanger and a hot water system such as a hot water supply device or a heating hot water supply device.

Conventionally, as a hot water supply apparatus, there is one provided with a heat pump unit disposed outdoors and a hot water storage tank for storing hot water heated by the heat pump unit.

The heat pump unit has an evaporator that takes in heat from the outside air, but frost may adhere to the evaporator. In the state where frost adheres to the evaporator, the heat exchange performance of the evaporator is lowered, and as a result, sufficient heating cannot be performed. For this reason, the defrost driving | operation for defrosting the said evaporator becomes essential.

However, the conventional heating and hot water supply apparatus described above cannot boil water in the hot water storage tank with the heat pump unit during the defrost operation.

A heating and hot water supply apparatus that solves such a problem is described in Japanese Patent Application Laid-Open No. 2004-108597 (Patent Document 1). This heating and hot water supply apparatus includes a heat pump unit, a hot water storage tank, and a heating terminal.

The heat pump unit includes a fan, a first evaporator, a second evaporator, a compressor, a condenser, and an expansion valve.

The first evaporator receives outside air from the fan and takes in heat from the outside air. The first evaporator is located on the upstream side of the compressor and on the downstream side of the second evaporator. That is, the refrigerant exiting the second evaporator flows into the compressor after passing through the first evaporator.

According to the heating / hot water supply apparatus configured as described above, while the water in the hot water storage tank is being boiled by the heat pump unit, the hot water in the hot water storage tank is sent to the second evaporator by the pump. Thereby, since the refrigerant | coolant just before entering the said 1st evaporator is heated with the warm water, the frost adhering to the 1st evaporator can be thawed.

However, in the heating and hot water supply apparatus of Patent Document 1, since the refrigerant heated by the second evaporator enters the first condenser, the evaporation temperature of the first evaporator rises.

As a result, the amount of heat taken from the outside air in the first evaporator is reduced, resulting in a problem that the COP (coefficient of performance) of the heat pump unit is lowered.

Further, the heating and hot water supply apparatus of Patent Document 1 has a problem that the refrigerant entering the first evaporator cannot be supercooled because the heat pump unit does not include the supercooling heat exchanger.

If a supercooling heat exchanger is provided in the refrigerant circuit of the heat pump unit, the number of heat exchangers provided in the refrigerant circuit increases, so the pressure loss of the refrigerant circuit increases and the efficiency of the heat pump unit decreases. Will happen.

JP 2004-108597 A (FIG. 4)

Accordingly, an object of the present invention is to provide a heat exchanger that can improve the COP of a heat pump unit, for example, can supercool a high-pressure refrigerant, and can further increase the efficiency of the heat pump unit, for example. It is in.

Another object of the present invention is to provide a hot water system provided with the heat exchanger.

In order to solve the above problems, the heat exchanger of the present invention is
A low-pressure refrigerant flow path through which the low-pressure refrigerant flows;
A high-pressure refrigerant flow path in contact with the low-pressure refrigerant flow path and through which the high-pressure refrigerant flows;
A water channel in contact with the low-pressure refrigerant channel and through which water flows,
The cross-sectional area of the low-pressure refrigerant channel is larger than the cross-sectional area of the water channel and larger than the cross-sectional area of the high-pressure refrigerant channel.

According to the heat exchanger configured as described above, since the high-pressure refrigerant channel and the water channel are in contact with the low-pressure refrigerant channel, the low-pressure refrigerant absorbs the heat of the high-pressure refrigerant and water, and the temperature of the low-pressure refrigerant rises. Therefore, by providing the heat exchanger, for example, in the refrigerant circuit of the heat pump unit, the temperature of the low-pressure refrigerant entering the evaporator of the heat pump unit can be raised and the frost of the evaporator can be melted.

Further, even during the operation of melting the frost of the evaporator, that is, the defrost operation, the water can be heated by supplying water to, for example, the condenser of the heat pump unit.

In addition, the water flowing through the water channel is absorbed by the low-pressure refrigerant flowing through the low-pressure refrigerant channel, and the temperature drops. Therefore, the COP of the heat pump unit can be improved by supplying the water whose temperature has decreased by flowing through the water flow path to, for example, the condenser of the heat pump unit.

Further, since the high-pressure refrigerant flow is in contact with the low-pressure refrigerant flow path, the heat of the high-pressure refrigerant is absorbed by the low-pressure refrigerant, so that the high-pressure refrigerant can be supercooled.

Further, when the heat exchanger is used in, for example, a heat pump unit, the heat exchanger can supercool the high-pressure refrigerant, so that it is not necessary to install a supercooling heat exchanger separately from the heat exchanger. Therefore, since the number of heat exchangers of the heat pump unit can be reduced and the pressure loss of the refrigerant circuit can be reduced, the efficiency of the heat pump unit can be increased.

In addition, since the cross-sectional area of the low-pressure refrigerant channel is larger than the cross-sectional area of the water channel and larger than the cross-sectional area of the high-pressure refrigerant channel, the pressure loss of the low-pressure refrigerant is kept low. Can do. Therefore, when the heat exchanger is used in, for example, a heat pump unit, the efficiency of the heat pump unit can be further increased.

In the heat exchanger of one embodiment,
The low-pressure refrigerant channel, the high-pressure refrigerant channel, and the water channel are combined in a braid shape.

According to the heat exchanger of the above embodiment, since the low-pressure refrigerant channel, the high-pressure refrigerant channel, and the water channel are combined in a braid shape, the low-pressure refrigerant channel, the high-pressure refrigerant channel, and the water channel are combined. It can be firmly integrated.

The hot water system of the present invention is
A heat pump unit having the heat exchanger of the present invention;
A hot water storage tank for storing hot water heated by the heat pump unit,
The hot water in the hot water storage tank heats the low-pressure refrigerant through the water flow path.

According to the hot water system having the above configuration, since the hot water in the hot water storage tank heats the low-pressure refrigerant through the water flow path, the temperature of the low-pressure refrigerant entering, for example, the evaporator of the heat pump unit rises, and the evaporator frost is removed. Can be melted. That is, the defrosting operation can be performed by the warm water flowing through the water flow path.

Also, even when the heat pump unit is boiling hot water in the hot water storage tank, the hot water in the hot water storage tank can be supplied to the water flow path, so defrost operation is performed while boiling the hot water in the hot water storage tank. Can do.

Also, the hot water in the hot water storage tank is cooled through the water flow path and the temperature is lowered. Therefore, the COP of the heat pump unit can be improved by sending warm water whose temperature has decreased through the water flow path to, for example, a condenser of the heat pump unit.

Further, in the above heat exchanger, since the high-pressure refrigerant channel is in contact with the low-pressure refrigerant channel, the heat of the high-pressure refrigerant is absorbed by the low-pressure refrigerant, so that the high-pressure refrigerant can be supercooled.

Also, since the heat exchanger can supercool the high-pressure refrigerant, the number of heat exchangers in the heat pump unit can be reduced, and the pressure loss in the refrigerant circuit can be reduced. As a result, the efficiency of the heat pump unit can be increased.

In addition, since the cross-sectional area of the low-pressure refrigerant channel is larger than the cross-sectional area of the water channel and larger than the cross-sectional area of the high-pressure refrigerant channel, the pressure loss of the low-pressure refrigerant is kept low. Can do. Therefore, the efficiency of the heat pump unit can be further increased.

In one embodiment of the hot water system,
The heat pump unit includes a refrigerant circuit including the high-pressure refrigerant channel and the low-pressure refrigerant channel, and an evaporator, a compressor, a condenser, and an expansion mechanism provided in the refrigerant circuit,
The low-pressure refrigerant flow path is a pipe that guides the low-pressure refrigerant that has exited the expansion mechanism to the compressor,
The high-pressure refrigerant flow path is a pipe that guides the refrigerant exiting the compressor to the expansion mechanism.

According to the hot water system of the above embodiment, the low-pressure refrigerant flow path is a pipe that guides the low-pressure refrigerant that has exited the expansion mechanism to the compressor, so that the temperature of the refrigerant entering the compressor can be increased.

Further, since the high-pressure refrigerant flow path is a pipe that guides the high-pressure refrigerant exiting the compressor to the expansion mechanism, the temperature of the refrigerant entering the expansion mechanism can be lowered.

In one embodiment of the hot water system,
The heat pump unit uses a CO ₂ refrigerant.

According to the hot water system of the above embodiment, the heat pump unit uses a CO ₂ refrigerant, so that the heat pump unit can perform hot hot water discharge.

When the heat exchanger of the present invention is provided, for example, in a refrigerant circuit of a heat pump unit, the low-pressure refrigerant absorbs the heat of the high-pressure refrigerant and water by contacting the high-pressure refrigerant channel and the water channel with the low-pressure refrigerant channel. Therefore, the defrosting operation can be performed by raising the temperature of the low-pressure refrigerant entering, for example, the evaporator of the heat pump unit.

Further, even during the defrost operation, the water can be heated by supplying water to, for example, a condenser of the heat pump unit.

Further, since the water flowing through the water flow path is absorbed by the low-pressure refrigerant and the temperature is lowered, the COP of the heat pump unit can be improved by supplying the water having the lowered temperature to, for example, the condenser of the heat pump unit. it can.

Further, since the high-pressure refrigerant flow is in contact with the low-pressure refrigerant flow path, the heat of the high-pressure refrigerant is absorbed by the low-pressure refrigerant, so that the high-pressure refrigerant can be supercooled.

In addition, when the heat exchanger is used in, for example, a heat pump unit, the heat exchanger can supercool the high-pressure refrigerant, thereby reducing the number of heat exchangers in the heat pump unit and reducing the pressure loss in the refrigerant circuit. The efficiency of the heat pump unit can be increased.

Further, when the heat exchanger is used, for example, in a heat pump unit, the flow path cross-sectional area of the low-pressure refrigerant flow path is larger than the flow path cross-sectional area of the water flow path, and is larger than the flow path cross-sectional area of the high-pressure refrigerant flow path. By being large, the pressure loss of the low-pressure refrigerant can be kept low, so that the efficiency of the heat pump unit can be further increased.

According to the hot water system of the present invention, the hot water in the hot water storage tank heats the low-pressure refrigerant through the water flow path, whereby the temperature of the low-pressure refrigerant entering, for example, the evaporator of the heat pump unit is increased, and the defrost operation can be performed. it can.

Also, even when the heat pump unit is boiling hot water in the hot water storage tank, the hot water in the hot water storage tank can be supplied to the water flow path, so defrost operation is performed while boiling the hot water in the hot water storage tank. Can do.

Further, since the hot water in the hot water storage tank is cooled through the water flow path and the temperature is lowered, the COP of the heat pump unit can be improved by sending the hot water having the lowered temperature to, for example, a condenser of the heat pump unit. .

In the heat exchanger of the heat pump unit, the high-pressure refrigerant is absorbed by the low-pressure refrigerant because the high-pressure refrigerant flow channel is in contact with the low-pressure refrigerant flow channel, so that the high-pressure refrigerant is supercooled. Can do.

Also, since the heat exchanger can supercool the high-pressure refrigerant, the number of heat exchangers in the heat pump unit can be reduced and the pressure loss in the refrigerant circuit can be reduced, so that the efficiency of the heat pump unit can be increased.

Further, the pressure cross-sectional area of the low-pressure refrigerant channel is larger than the channel cross-sectional area of the water channel and larger than the channel cross-sectional area of the high-pressure refrigerant channel, so that the pressure loss of the low-pressure refrigerant is kept low. Therefore, the efficiency of the heat pump unit can be further increased.

FIG. 1 is a schematic diagram of a heating and hot water supply apparatus according to a first embodiment of the present invention. FIG. 2 is a schematic diagram of the defrost heat exchanger according to the first embodiment of the present invention. FIG. 3 is a schematic view of a defrost heat exchanger according to a second embodiment of the present invention. FIG. 4 is a schematic view of a modification of the defrost heat exchanger according to the second embodiment of the present invention. FIG. 5 is a schematic view of a defrost heat exchanger according to a third embodiment of the present invention. FIG. 6 is a schematic diagram of a defrost heat exchanger according to a fourth embodiment of the present invention.

Hereinafter, the heat exchanger and the hot water system of the present invention will be described in detail with reference to the illustrated embodiments.

[First Embodiment]
Drawing 1 is a mimetic diagram showing composition of a heating hot-water supply device of a 1st embodiment of the present invention.

The heating / hot water supply apparatus includes a heat pump unit 1, a hot water storage tank 2, a hot water supply heat exchanger 3, a heating circulation circuit 4, a boiling circulation circuit 5, and a defrost circulation circuit 50.

First, the heat pump unit 1 will be described. The heat pump unit 1 includes a refrigerant circuit 16 and an electric blower 17 and boiles water in the hot water storage tank 2 to make warm water. The heat pump unit 1 is connected to a hot water storage tank 2 via a boiling circulation circuit 5.

The refrigerant circuit 16 includes an evaporator 11, a compressor 12, a condenser 13, a defrost heat exchanger 14, an expansion valve 15, a low-pressure refrigerant pipe 20, and a high-pressure refrigerant pipe 21. In the refrigerant circuit 16, CO ₂ refrigerant circulates. The expansion valve 15 is an example of an expansion mechanism, the defrost heat exchanger 14 is an example of a heat exchanger, the low pressure refrigerant pipe 20 is an example of a low pressure refrigerant flow path, and the high pressure refrigerant pipe 21 is an example of a high pressure refrigerant flow path. It is.

The low-pressure refrigerant pipe 20 is a pipe that guides the low-pressure CO ₂ refrigerant that has exited the expansion valve 15 to the compressor 12. This low-pressure CO ₂ refrigerant passes through the evaporator 11 and the defrost heat exchanger 14 in this order from the expansion valve 15 to the compressor 12.

The high-pressure refrigerant pipe 21 is a pipe that guides the high-pressure CO ₂ refrigerant that has exited the compressor 12 to the expansion valve 15. This high-pressure CO ₂ refrigerant passes through the condenser 13 and the defrost heat exchanger 14 in this order from the compressor 12 to the expansion valve 15.

The defrost heat exchanger 14 is connected to the hot water storage tank 2 via a defrost circulation circuit 50. Thereby, the hot water in the hot water storage tank 2 can be supplied to the defrost heat exchanger 14 through the water pipe 56 of the defrost circulation circuit 50. The water pipe 56 is an example of a water channel.

FIG. 2 is a diagram schematically showing the structure of the defrost heat exchanger 14. In FIG. 2, the water pipe 56 is hatched to facilitate identification of the water pipe 56 with respect to the high-pressure refrigerant pipe 21.

In the defrost heat exchanger 14, the high-pressure refrigerant pipe 21 and the water pipe 56 are alternately wound around a substantially linear portion of the low-pressure refrigerant pipe 20, and are in thermal contact with the portion. The flow path cross-sectional area of the low-pressure refrigerant pipe 20 is larger than the flow path cross-sectional area of the water pipe 56 and larger than the flow path cross-sectional area of the high-pressure refrigerant pipe 21.

Next, changes in pressure and temperature of the CO ₂ refrigerant flowing through the low-pressure refrigerant pipe 20 and the high-pressure refrigerant pipe 21 will be described. The low-pressure CO ₂ refrigerant entering the evaporator 11 absorbs heat in the air sent from the electric blower 17 and rises in temperature. The low-pressure CO ₂ refrigerant flows through the low-pressure refrigerant pipe 20 and reaches the defrost heat exchanger 14. In the defrost heat exchanger 14, the low-pressure CO ₂ refrigerant absorbs the heat of the high-pressure CO ₂ refrigerant in the high-pressure refrigerant pipe 21 and the temperature further increases. The low-pressure CO ₂ refrigerant is compressed by the compressor 12 to become a high-pressure CO ₂ refrigerant, and the temperature further increases. This high-pressure CO ₂ refrigerant releases heat at the condenser 13 and becomes low temperature, and then reaches the defrost heat exchanger 14 through the guidance of the high-pressure refrigerant pipe 21. In this defrost heat exchanger 14, CO ₂ refrigerant pressure is absorbed heat to the CO ₂ refrigerant low pressure in the low-pressure refrigerant pipe 20, the temperature further lowers. The high-pressure CO ₂ refrigerant whose temperature has further decreased is reduced in pressure by the expansion valve 15 and then returned to the evaporator 11.

Further, during the defrost operation for defrosting the evaporator 11, the hot water in the hot water storage tank 2 is supplied to the defrost heat exchanger 14 through the water pipe 56 of the defrost circulation circuit 50. Accordingly, during the defrost operation, in the defrost heat exchanger 14, the low-pressure CO ₂ refrigerant in the low-pressure refrigerant pipe 20 is the heat of the hot water in the water pipe 56 and the high-pressure CO ₂ refrigerant in the high-pressure refrigerant pipe 21. Absorbs heat and rises in temperature.

On the other hand, since the defrost heat exchanger 14 is not supplied with hot water from the hot water storage tank 2 during non-defrost operation, the defrost heat exchanger 14 does not perform heat exchange between the hot water and the low-pressure CO ₂ refrigerant.

Next, the defrost circuit 50 will be described. The defrost circuit 50 has a branch valve 55 and a water pipe 56. The branch valve 55 has an inlet through which hot water from the hot water storage tank 2 flows and two outlets through which hot water flows out. Of these two outlets, one outlet is connected to the condenser 13, and the other outlet is connected to the defrost heat exchanger 14 via a water pipe 56. The amount of warm water entering the condenser 13 can be adjusted by adjusting the opening degree of the one outlet. Further, the amount of hot water entering the defrost heat exchanger 14 can be adjusted by adjusting the opening degree of the other outlet. The opening degree of each outlet of the branch valve 55 is adjusted by the control unit 7.

Next, the boiling circulation circuit 5 will be described. The boiling circulation circuit 5 is provided with a boiling circulation pump 51 and a boiling three-way valve 52. The boiling circulation circuit 5 is connected to the second heating forward connection port 42, the heating supply port 53, and the antifreezing water return connection port 54.

Hot water flows from the condenser 13 or warm water flows from the defrost heat exchanger 14 to the anti-freezing water return connection port 54.

Further, a part of the upstream side of the condenser 13 in the boiling circulation circuit 5 is also used as a part of the upstream side of the defrost heat exchanger 14 in the defrosting circulation circuit 50. That is, the portion where the hot water flows between the hot water storage tank 2 and the branch valve 55 is a part of the boiling circuit 5 and a part of the defrost circuit 50. A branch valve 55 is provided at a branch portion between the boiling circuit 5 and the defrost circuit 50.

The supply port 53 is provided in the lower part of the hot water storage tank 2. Thereby, the hot water in the lower region in the hot water storage tank 2 can be supplied to the boiling circulation pump 51 through the supply port 53.

The boiling circulation pump 51 sucks the hot water in the lower part of the hot water storage tank 2 and discharges it toward the branch valve 55. As the boiling circulation pump 51, a variable flow rate pump or a fixed flow rate circulation pump can be employed.

In the condenser 13, the heat of the CO ₂ refrigerant is transferred to the hot water, and the hot water becomes a high temperature (for example, 60 ° C. to 85 ° C.). The hot hot water exiting the condenser 13 goes to the boiling three-way valve 52.

The boiling three-way valve 52 allows hot hot water from the condenser 13 to flow to the upper region in the hot water storage tank 2 through the second heating forward connection port 42 during hot water supply operation and heating operation. Further, when the heat pump unit 1 is started up, the hot water coming out of the condenser 13 of the heat pump unit 1 is not sufficiently high, so the boiling three-way valve 52 prevents the hot water from the condenser 13 from freezing. It flows through the water return connection port 54 to the lower region in the hot water storage tank 2. Thereby, it is possible to prevent the hot water that has not been sufficiently heated by the condenser 13 from returning to the upper region in the hot water storage tank 2 and disturbing the temperature distribution in the hot water storage tank 2.

Next, the hot water storage tank 2 will be described. The hot water storage tank 2 stores hot water heated by the heat pump unit 1. In addition, a heater 6 is disposed at a substantially central portion in the vertical direction in the hot water storage tank 2, and the heater 6 directly heats the hot water in the hot water storage tank 2. In addition, a plurality of temperature sensors 40A, 40B,..., 40E are provided in the hot water storage tank 2 in order to detect the temperature of the hot water in each part in the hot water storage tank 2. The plurality of temperature sensors 40 </ b> A, 40 </ b> B,..., 40 </ b> E detect the temperature of hot water in each part in the hot water storage tank 2 and send a signal indicating the temperature to the control unit 7.

Next, the hot water supply heat exchanger 3 will be described. This hot water supply heat exchanger 3 is formed of a coiled pipe and is arranged from the lower region to the upper region in the hot water storage tank 2. The hot water is heated by flowing through the hot water heat exchanger 3. More specifically, the hot water enters the hot water storage tank 2 from the lower part of the hot water storage tank 2 and flows upward through the hot water supply heat exchanger 3 arranged in the lower region of the hot water storage tank 2. The hot water flows through the hot water heat exchanger 3 disposed in the upper region of the hot water tank 2 upward, and then flows out of the hot water tank 2 from the upper part of the hot water tank 2.

If the temperature of the hot water supplied from the hot water storage tank 2 is too high, the hot water mixing valve 31 is opened, and the hot water supplied from the hot water storage tank 2 and the hot water before flowing into the hot water storage tank 2 are separated. Mix together. Thereby, the temperature of the hot water supplied from the hot water storage tank 2 can be lowered.

Next, the heating circulation circuit 4 will be described. The heating circulation circuit 4 passes the hot water stored in the hot water storage tank 2 through the plurality of heating terminals 8A, 8B,... Outside the hot water storage tank 2, and then returns to the hot water storage tank 2 for circulation. belongs to. The heating circulation circuit 4 is connected to the first and second heating forward connection ports 41 and 42 and the heating return connection port 43.

The first heating outgoing connection port 41 is for taking out hot water in the hot water storage tank 2. The first heating / outgoing connection port 41 is provided at a substantially central portion in the vertical direction of the hot water storage tank 2, and is positioned near and above the heater 6. Thereby, the warm water immediately after heated with the said heater 6 can be taken out from the 1st heating outgoing connection port 41, and can be sent to several heating terminal 8A, 8B, ....

The second heating forward connection port 42 is also for taking out hot water in the hot water storage tank 2 in the same manner as the first heating forward connection port 41. The second heating / outgoing connection port 42 is provided in the upper part of the hot water storage tank 2. Thereby, the warm water of the upper area | region in the said hot water storage tank 2 can be taken out from the 2nd heating outgoing connection port 42, and can be sent to several heating terminal 8A, 8B, .... The second heating / outgoing connection port 42 is also used as a heating return connection port.

Each of the heating terminals 8A, 8B,... Directly takes out the heat of hot water flowing from the hot water storage tank 2 and releases it into the room. And the said warm water becomes low temperature, leaves heating terminal 8A, 8B, ..., and flows toward the heating return connection port 43. FIG.

The heating return connection port 43 is provided in the lower part of the hot water storage tank 2. Thereby, the hot water which came out of the said heating return connection port 43 can be mixed with the hot water of the lower area | region in the hot water storage tank 2. FIG.

The heating circulation circuit 4 is provided with a bypass pipe 44, a heating mixing valve 45, temperature sensors 40F and 40G, a heating circulation pump 48, and a heating three-way valve 49.

The bypass pipe 44 guides a part of the hot water flowing from the heating terminals 8A, 8B,... To the heating return connection port 43 to the heating mixing valve 45.

The heating mixing valve 45 has an inlet through which hot water from the hot water storage tank 2 flows and an inlet through which hot water from the bypass pipe 44 flows. Although described in detail later, the opening degree of each inlet of the heating mixing valve 45 is adjusted by the control unit 7.

The control unit 7 receives the output signal of the outside temperature sensor 18 and the output signals of the temperature sensors 40A, 40B, ..., 40G. The control unit 7 also receives a signal indicating the room temperature from a room temperature sensor (not shown). Here, the output signal of the outside air temperature sensor 18 is a signal indicating the outside air temperature, the output signals of the temperature sensors 40A and 40B are signals indicating the temperature of hot water in the upper region in the hot water storage tank 2, and the output signal of the temperature sensor 40C is hot water storage. A signal indicating the temperature of the hot water in the middle region in the vertical direction in the tank 2 and the output signals of the temperature sensors 40D and 40E are signals indicating the temperature of the hot water in the lower region in the hot water storage tank 2. The output signal of the temperature sensor 40F is a signal indicating the temperature of the hot water from the hot water storage tank 2 toward the heating terminals 8A, 8B,. And the said temperature sensor 40G is a signal which shows the temperature of the warm water which goes to the hot water storage tank 2 from heating terminal 8A, 8B, ....

The heating circulation pump 48 sucks the hot water in the hot water storage tank 2 through the second heating outgoing connection port 42 or the first heating outgoing connection port 41 and discharges it toward the plurality of heating terminals 8A, 8B,.

The heating three-way valve 49 extracts hot water from the first heating forward connection port 41 when a high temperature region of the hot water in the hot water storage tank 2 is present in the vicinity of the first heating forward connection port 41. Further, the heating three-way valve 49 extracts hot water from the second heating forward connection port 42 when the high temperature region of the hot water in the hot water storage tank 2 does not exist in the vicinity of the first heating forward connection port 41. The control unit 7 switches the heating three-way valve 49. That is, the control unit 7 switches the heating three-way valve 49 based on signals from a plurality of temperature sensors for detecting the temperature of hot water in each part in the hot water storage tank 2.

According to the heating and hot water supply apparatus having the above configuration, when the heating operation is started, the control unit 7 turns on the heating circulation pump 48. Thereby, the hot water stored in the hot water storage tank 2 is sent to the plurality of heating terminals 8A, 8B,... And returned to the hot water storage tank 2 again. Thereby, the heat of the hot water is released into the room through the heating terminals 8A, 8B,... To heat the room.

During the heating operation, the control unit 7 determines that the compressor 12, the expansion valve 15, the boiling circulation pump 51, and the outside air temperature sensor 18, the temperature sensors 40A, 40B,. The branch valve 55 is controlled.

For example, when the control unit 7 determines from the output signals of the temperature sensors 40A, 40B,..., 40E that the hot water in the upper region of the hot water tank 2 is low, the heat pump unit 1 causes the hot water tank 2 to be reduced. Boil the warm water inside. More specifically, the compressor 12 and the boiling circulation pump 51 are turned on, and the expansion valve 15 is opened. At this time, the control unit 7 fully opens the outlet of the branch valve 55 on the condenser 13 side, and fully closes the outlet of the branch valve 55 on the defrost heat exchanger 14 side. Thereby, the hot water in the lower region in the hot water storage tank 2 flows to the condenser 13, and the hot water heated to the high temperature by the condenser 13 enters the hot water storage tank 2 through the second heating forward connection port 42. Return.

While the hot water in the hot water storage tank 2 is being boiled by the heat pump unit 1, the control unit 7 needs to perform a defrost operation for removing the frost of the evaporator 11 from the output of the outside air temperature sensor 18, for example. If it is determined that, defrost operation is started.

When the defrost operation starts, the control unit 7 increases the opening degree of the expansion valve 15 and opens the outlet of the branch valve 55 on the defrost heat exchanger 14 side. Accordingly, warm water having a medium temperature (for example, 30 ° C. to 50 ° C.) in the lower region in the hot water storage tank 2 flows to both the condenser 13 and the defrost heat exchanger 14. The medium-temperature hot water that has entered the defrost heat exchanger 14 gives heat to the CO ₂ refrigerant that goes to the compressor 12 and becomes low-temperature hot water. This low temperature hot water returns to the hot water storage tank 2 through the freeze prevention water return connection port 54.

As described above, after the intermediate temperature warm water passes through the defrost heat exchanger 14 and returns to the hot water storage tank 2, the temperature of the CO ₂ refrigerant entering the evaporator 11 is appropriately increased. As a result, frost can be removed from the evaporator 11.

During the above defrost operation, heat is taken from the warm water in the lower area of the hot water tank 2 instead of taking heat from the outside air. This heat is the heat of the hot water boiled before the defrost operation by the heat pump unit 1. For this reason, the COP of the heat pump unit 1 becomes worse if it is limited only during the defrost operation. However, it is the same in the conventional defrost operation that does not use the warm water in the lower region in the hot water storage tank 2.

However, if it is a defrost operation using medium temperature warm water in the lower region in the hot water storage tank 2, the medium temperature warm water goes down through the defrost heat exchanger 14 and becomes low temperature warm water. Return to the lower area in the hot water storage tank 2. Thus, when the hot water in the hot water storage tank 2 is boiled after the defrost operation is completed, the low temperature hot water in the lower region in the hot water storage tank 2 is supplied to the heat pump unit 1. As a result, the COP of the heat pump unit 1 is improved, and the COP of the heat pump unit 1 can be expected to be improved in the total operation.

In the above defrosting heat exchanger 14, by the high-pressure refrigerant pipe 21 is wound around the low-pressure refrigerant pipe 20, the CO ₂ refrigerant in the high pressure refrigerant pipe 21 heat the CO ₂ refrigerant in the low-pressure refrigerant pipe 20 Since it is absorbed, the CO ₂ refrigerant in the high-pressure refrigerant pipe 21 can be supercooled.

Further, since the defrost heat exchanger 14 can supercool the CO ₂ refrigerant in the high-pressure refrigerant pipe 21, it is not necessary to install a supercooling heat exchanger separately from the defrost heat exchanger 14. Therefore, since the number of heat exchangers of the heat pump unit 1 can be reduced and the pressure loss of the refrigerant circuit 16 can be reduced, the efficiency of the heat pump unit 1 can be increased.

Moreover, since the defrost heat exchanger 14 is manufactured by winding the high pressure refrigerant pipe 21 and the water pipe 56 around the low pressure refrigerant pipe 20, the manufacture of the defrost heat exchanger 14 can be simplified.

In the defrost heat exchanger 14, the low-pressure refrigerant pipe 20 extends substantially linearly, so that the pressure loss of the CO ₂ refrigerant in the low-pressure refrigerant pipe 20 is reduced. Therefore, the efficiency of the heat pump unit 1 can be further increased.

In addition, since the high-pressure refrigerant pipe 21 and the water pipe 56 are alternately wound around the low-pressure refrigerant pipe 20, the temperature relationship between the CO ₂ refrigerant in the high-pressure refrigerant pipe 21 and the hot water in the water pipe 56 is not affected. In addition, the temperature of the CO ₂ refrigerant in the low-pressure refrigerant pipe 20 can be reliably increased.

Further, since the cross-sectional area of the low-pressure refrigerant pipe 20 is larger than the flow-path cross-sectional area of either the water pipe 56 or the high-pressure refrigerant pipe 21, the pressure loss of the CO ₂ refrigerant flowing through the low-pressure refrigerant pipe 20 can be reduced.

Further, since the low-pressure refrigerant pipe 20 is a pipe that guides the CO ₂ refrigerant that has exited the expansion valve 15 to the compressor 12, the temperature of the CO ₂ refrigerant that enters the compressor 12 can be increased.

Further, since the high-pressure refrigerant pipe 21 is a pipe that guides the CO ₂ refrigerant that has exited the compressor 12 to the expansion valve 15, the temperature of the CO ₂ refrigerant that enters the expansion valve 15 can be lowered.

Further, the heat pump unit 1 because it uses CO ₂ refrigerant, the heat pump unit 1 can hot tapping.

In addition, since a part of the upstream side of the condenser 13 in the boiling circulation circuit 5 is also used as a part of the upstream side of the defrost heat exchanger 14 in the defrosting circulation circuit 50, the boiling circulation circuit 5 If a part of the upstream side of the condenser 13 is implemented, a part of the upstream side of the defrost heat exchanger 14 in the defrost circuit 50 need not be implemented.

Therefore, the labor involved in the construction of the boiling circuit 5 and the defrost circuit 50 is small, and the workability of the boiling circuit 5 and the defrost circuit 50 is good.

Further, since the circulation of the hot water in the circulation circuit 5 for boiling and the circulation of the hot water in the circulation circuit 50 for the defrost are controlled by only one branch valve 55, the control of the circulation is prevented from being complicated. be able to.

Further, during the non-defrost operation in which the heating operation is not performed, the control unit 7 turns on the circulation pump 51 for boiling, opens the outlet of the branch valve 55 on the defrost heat exchanger 14 side, and circulates for the defrost. A small amount of warm water is allowed to flow through the circuit 50. Thereby, it is possible to prevent the hot water remaining in the defrost circulation circuit 50 from being cooled and frozen.

[Second Embodiment]
FIG. 3 is a diagram schematically showing the structure of the defrost heat exchanger 114 of the heating and hot water supply apparatus according to the second embodiment of the present invention. In FIG. 3, the water pipe 156 is hatched to facilitate identification of the water pipe 156 with respect to the high-pressure refrigerant pipe 121.

The heating / hot water supply apparatus differs from the first embodiment only in that a defrost heat exchanger 114 is provided instead of the defrost heat exchanger 14 of FIG.

In the defrost heat exchanger 114, the water pipe 156 is spirally wound only on a predetermined part of the low-pressure refrigerant pipe 20 and only the adjacent part on one side in the axial direction of the above-mentioned part of the low-pressure refrigerant pipe 20. A high-pressure refrigerant pipe 121 is spirally wound around. Thereby, the high pressure refrigerant pipe 121 and the water pipe 156 are in thermal contact with the low pressure refrigerant pipe 20. The high-pressure refrigerant pipe 121 is an example of a high-pressure refrigerant flow path, and the water pipe 156 is an example of a water flow path.

The flow path cross-sectional area of the low-pressure refrigerant pipe 20 is larger than the flow path cross-sectional area of the high-pressure refrigerant pipe 121 and larger than the flow path cross-sectional area of the water pipe 156.

The high-pressure refrigerant pipe 121 is a pipe that guides the high-pressure CO ₂ refrigerant exiting the compressor 12 to the expansion valve 15 after passing through the condenser 13 and the defrost heat exchanger 114 (see FIG. 1).

The water pipe 156 is a pipe that guides the hot water taken out from the supply port 53 to the hot water storage tank 2 after passing through the defrost heat exchanger 114 (see FIG. 1).

Such a defrost heat exchanger 114 can be easily manufactured without complicating the winding work of the low-pressure refrigerant pipe 20 and the high-pressure refrigerant pipe 21.

Note that the high-pressure refrigerant pipe 121 and the water pipe 156 differ from the high-pressure refrigerant pipe 21 and the water pipe 56 of the first embodiment only in the way of winding around the low-pressure refrigerant pipe 20.

In the second embodiment, a defrost heat exchanger 214 shown in FIG. 4 may be used instead of the defrost heat exchanger 114.

In the defrost heat exchanger 214, the high-pressure refrigerant pipe 221 is spirally wound only around a predetermined portion of the low-pressure refrigerant pipe 20, and the water is placed so that the high-pressure refrigerant pipe 221 is sandwiched only between the predetermined portions of the low-pressure refrigerant pipe 20. The pipe 256 is spirally wound. Thus, the high-pressure refrigerant pipe 221 and the water pipe 256 are in thermal contact with the low-pressure refrigerant pipe 20. The high-pressure refrigerant pipe 221 is an example of a high-pressure refrigerant flow path, and the water pipe 256 is an example of a water flow path.

The flow passage cross-sectional area of the low-pressure refrigerant pipe 20 is larger than that of the high-pressure refrigerant pipe 221 and larger than that of the water pipe 256.

The high-pressure refrigerant pipe 221 is a pipe that guides the high-pressure CO ₂ refrigerant exiting the compressor 12 to the expansion valve 15 after passing through the condenser 13 and the defrost heat exchanger 214 (see FIG. 1).

The water pipe 256 is a pipe that guides the hot water taken out from the supply port 53 to the hot water storage tank 2 after passing through the defrost heat exchanger 214 (see FIG. 1).

Such a defrost heat exchanger 214 can be easily manufactured in the same manner as the defrost heat exchanger 114.

Note that the high-pressure refrigerant pipe 221 and the water pipe 256 are different from the high-pressure refrigerant pipe 21 and the water pipe 56 of the first embodiment only in the way of winding around the low-pressure refrigerant pipe 20.

Also in FIG. 4, the water pipe 256 is hatched to facilitate identification of the water pipe 256 with respect to the high-pressure refrigerant pipe 221.

[Third Embodiment]
FIG. 5 is a diagram schematically showing the structure of the defrost heat exchanger 314 of the heating and hot water supply apparatus according to the third embodiment of the present invention. In FIG. 5, the high-pressure refrigerant pipe 321 and the water pipe 356 are hatched to facilitate identification of the high-pressure refrigerant pipe 321 and the water pipe 356 with respect to the low-pressure refrigerant pipe 320.

The heating / hot water supply apparatus differs from the first embodiment only in that a defrost heat exchanger 314 is provided instead of the defrost heat exchanger 14 of FIG.

In the defrost heat exchanger 314, the low-pressure refrigerant pipe 320, the high-pressure refrigerant pipe 321 and the water pipe 356 are combined in a braid shape and are in thermal contact with each other. The low-pressure refrigerant pipe 20 is an example of a low-pressure refrigerant flow path, the high-pressure refrigerant pipe 321 is an example of a high-pressure refrigerant flow path, and the water pipe 356 is an example of a water flow path.

The low-pressure refrigerant pipe 320 is a pipe that guides the low-pressure CO ₂ refrigerant exiting the expansion valve 15 to the compressor 12 after passing through the evaporator 11 and the defrost heat exchanger 314. The flow passage cross-sectional area of the low-pressure refrigerant pipe 320 is larger than that of the high-pressure refrigerant pipe 221 and larger than that of the water pipe 256.

The high-pressure refrigerant pipe 321 is a pipe that guides the high-pressure CO ₂ refrigerant exiting the compressor 12 to the expansion valve 15 after passing through the condenser 13 and the defrost heat exchanger 314 (see FIG. 1).

The water pipe 356 is a pipe that guides the hot water taken out from the supply port 53 to the hot water storage tank 2 after passing through the defrost heat exchanger 314 (see FIG. 1).

In such a defrost heat exchanger 314, the low-pressure refrigerant pipe 320, the high-pressure refrigerant pipe 321 and the water pipe 356 are combined in a braid shape, so that the low-pressure refrigerant pipe 320, the high-pressure refrigerant pipe 321 and the water pipe are combined. 356 can be firmly integrated.

[Fourth Embodiment]
FIG. 6 is a diagram schematically showing the structure of the defrost heat exchanger 414 of the heating and hot water supply apparatus according to the fourth embodiment of the present invention.

The heating and hot water supply apparatus is different from the first embodiment only in that a defrost heat exchanger 414 is provided instead of the defrost heat exchanger 14 in FIG.

The defrost heat exchanger 414 is mounted on the flat plate-like high-pressure refrigerant channel plate 421 and the high-pressure refrigerant channel plate 421 and is in flat contact with the high-pressure refrigerant channel plate 421. A refrigerant flow path plate 420 and a flat water flow path plate 456 mounted on the low pressure refrigerant flow path plate 420 and in thermal contact with the low pressure refrigerant flow path plate 420 are provided. A flat space is provided inside each of the high-pressure refrigerant channel plate 421, the low-pressure refrigerant channel plate 420, and the water channel plate 456. The low-pressure refrigerant channel plate 420 is an example of a low-pressure refrigerant channel, the high-pressure refrigerant channel plate 421 is an example of a high-pressure refrigerant channel, and the water channel plate 456 is an example of a water channel. .

The space within the low-pressure refrigerant flow path plate 420 flows is CO ₂ refrigerant low pressure from the expansion valve 15, CO ₂ refrigerant pressure through this space flows into the compressor 12 (see FIG. 1) . The flow passage cross-sectional area of the low-pressure refrigerant flow passage plate 420 is larger than the flow passage cross-sectional area of the high-pressure refrigerant flow passage plate 421 and larger than the flow passage cross-sectional area of the water flow passage plate 456. ing.

Above the space of the high-pressure refrigerant flow path plate 421 with CO ₂ refrigerant inflow of high pressure from the compressor 12, CO ₂ refrigerant pressure which has passed through this space flows toward the expansion valve 15 (see FIG. 1) .

Hot water from the supply port 54 flows into the space in the water flow channel plate 456, and the hot water flowing through this space flows toward the hot water storage tank 2 (see FIG. 1).

With such a defrost heat exchanger 414, the contact area between the high-pressure refrigerant channel plate 421 and the low-pressure refrigerant channel plate 420 is large, so the high-pressure refrigerant channel plate 421 and the low-pressure refrigerant channel plate 420. The heat exchange efficiency between the two can be increased.

Further, since the contact area between the water channel plate 456 and the low-pressure refrigerant channel plate 420 is large, the heat exchange efficiency between the water channel plate 456 and the low-pressure refrigerant channel plate 420 is increased. Can do.

In the defrost heat exchangers of the first and second embodiments, the high-pressure refrigerant pipe and the water pipe are wound around the low-pressure refrigerant pipe extending in a substantially straight line. For example, the high-pressure refrigerant is provided in the low-pressure refrigerant pipe having at least one bent portion. Piping and water piping may be wound.

In the first to fourth embodiments, the heat pump unit 1 uses the CO ₂ refrigerant, but may use an NH ₃ refrigerant, an R22 refrigerant, or the like.

Further, a combination of the contents of the first to fourth embodiments may be used as an embodiment of the present invention. For example, the high-pressure refrigerant pipe 21 and the water pipe 56 in FIG. 2 may be brought into thermal contact with the low-pressure refrigerant flow path plate 420 in FIG.

Further, from the first to fourth embodiments, the heating terminals 8A, 8B,... And the heating circulation circuit 4 related thereto may be eliminated to provide a hot water supply device. That is, the present invention is not limited to a heating hot water supply apparatus, and can also be applied to a hot water supply apparatus that performs only hot water supply.

DESCRIPTION OF SYMBOLS 1 Heat pump unit 2 Hot water storage tank 11 Evaporator 12 Compressor 13 Condenser 15 Expansion valve 16 Refrigerant circuit 14,114,214,314,414 Defrost heat exchanger 20,320 Low pressure refrigerant piping 21,121,221,321 High pressure refrigerant piping 56, 156, 256, 356 Water piping 420 Low-pressure refrigerant channel plate 421 High-pressure refrigerant channel plate 456 Water channel plate

Claims (5)

1. A low-pressure refrigerant flow path (20, 320, 420) through which the low-pressure refrigerant flows;
   High-pressure refrigerant flow paths (21, 121, 221, 321 and 421) through which high-pressure refrigerant flows in contact with the low-pressure refrigerant flow paths (20, 320, 420);
   A water flow path (56, 156, 256, 356, 456) through which water flows in contact with the low-pressure refrigerant flow path (20, 320, 420);
   The channel cross-sectional area of the low-pressure refrigerant channel (20, 320, 420) is larger than the channel cross-sectional area of the water channel (56, 156, 256, 356, 456), and the high-pressure refrigerant channel ( 21, 121, 221, 321, 421) which is larger than the flow path cross-sectional area.
2. The heat exchanger according to claim 1,
   The heat exchanger, wherein the low-pressure refrigerant channel (320), the high-pressure refrigerant channel (321), and the water channel (356) are combined in a braid shape.
3. A heat pump unit (1) comprising a heat exchanger (14, 114, 214, 314, 414) according to claim 1 or 2;
   A hot water storage tank (2) for storing hot water heated by the heat pump unit (1),
   A hot water system in which hot water in the hot water storage tank (2) heats the low-pressure refrigerant through the water flow path (56, 156, 256, 356, 456).
4. The hot water system according to claim 3,
   The heat pump unit (1) includes a refrigerant circuit (16) including the high-pressure refrigerant flow path (21, 121, 221, 321, 421) and the low-pressure refrigerant flow path (20, 320, 420), and the refrigerant circuit ( An evaporator (11), a compressor (12), a condenser (13) and an expansion mechanism (15) provided in 16),
   The low-pressure refrigerant flow path (20, 320, 420) is a pipe that guides the low-pressure refrigerant that has exited the expansion mechanism (15) to the compressor (12),
   The hot water system, wherein the high-pressure refrigerant flow path (21, 121, 221, 321, 421) is a pipe that guides the refrigerant exiting the compressor (12) to the expansion mechanism (15).
5. The hot water system according to claim 3,
   The hot water system is characterized in that the heat pump unit (1) uses a CO ₂ refrigerant.

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