JPH0875281A - Heat transferring device - Google Patents

Abstract

PURPOSE: To enable heat to be transferred even if there is a height difference between an installing position of a heat source side heat exchanger and an installing position of a utilization side heat exchanger. CONSTITUTION: Refrigerant of which gaseous phase and liquid phase are varied is enclosed in a closed circuit in which a heat source side heat exchanger 2, a utilization side heat exchanger 4, a container 5 having a radiator and a liquid pump 1 are connected to each other. Then, the liquid refrigerant is transferred from the utilization side heat exchanger 4 to the container 5 having a radiator in reference to a pressure difference based on a temperature difference between the utilization side heat exchanger 4 and the container 5 having a radiator.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat transfer device for transferring heat from a hot / cold heat source using a refrigerant having a gas-liquid phase change.

[0002]

2. Description of the Related Art As a heat transfer device using this kind of gas-liquid phase change refrigerant, Japanese Patent Laid-Open Nos. 4-236063 and 4-23
There is one disclosed in Japanese Patent No. 6064.

[0003]

In the above-mentioned conventional heat transfer device, the liquid pump for circulating the liquid refrigerant is located near the low temperature side heat exchanger regardless of whether it is the heat source side or the utilization side heat exchanger. It is necessary to install the heat exchanger, and especially when there is a difference in height between the heat source side heat exchanger and the use side heat exchanger, heat may not be transferred.

[0004]

The present invention has been invented in order to solve the above-mentioned problems, and the gist thereof is to include a heat source side heat exchanger, a use side heat exchanger, and a radiator-equipped container. The heat transfer device is characterized in that a liquid pump is connected in this order and a refrigerant that changes in a gas-liquid phase is enclosed in a closed circuit.

The liquid pump may be a reversible pump.

The liquid pump may be a variable discharge type pump.

The liquid pump may be installed near the heat source side heat exchanger.

The utilization side heat exchanger can be constituted by a plurality of heat exchangers connected in parallel with each other.

The heat source side heat exchanger can be composed of a plurality of heat exchangers.

The plurality of heat exchangers may be connected in series with each other.

The plurality of heat exchangers may be connected in close proximity to the liquid pump for the heat sources of the low and medium temperatures.

At least one of the heat sources of the heat source side heat exchanger can be combustion heat.

At least one of the heat sources of the heat source side heat exchanger may be heat supplied by a heat pump device.

At least one of the heat sources of the heat source side heat exchanger may be heat stored in the heat storage tank.

Heat can be supplied to the heat storage tank by a heat pump device.

The capacity of the heat pump device can be made smaller than the amount of heat transferred by the heat transfer device.

The opening position of the pipe connected to the liquid pump side of the radiator container can be set lower than the opening position of the pipe connected to the utilization side heat exchanger.

The container with the radiator and the heat exchanger for heat radiation can be connected in parallel.

The amount of heat released from the radiator-equipped container can be adjusted by the liquid level of the liquid refrigerant in the radiator-equipped container.

[0020]

In the heat transfer device of the present invention, the refrigerant evaporated and vaporized by absorbing heat from the high temperature heat source in the heat source side heat exchanger moves to the use side heat exchanger and radiates heat there to be condensed and liquefied. This liquid refrigerant enters the container with a radiator and further radiates heat through the radiator, so that the pressure becomes lower than the pressure of the refrigerant in the utilization side heat exchanger. Therefore, the refrigerant liquefied in the heat exchanger on the use side is equipped with a radiator only by the pressure difference between the heat exchanger on the use side and the container with radiator, that is, the temperature difference between the heat exchanger on the use side and container with radiator. Move into container. The refrigerant stored in the radiator-equipped container is extracted by the liquid pump and supplied to the heat source side heat exchanger.

[0021]

DESCRIPTION OF THE PREFERRED EMBODIMENT One embodiment of the present invention is shown in FIG. As shown in FIG. 1, a heat source side heat exchanger 2, a use side heat exchanger 4, a radiator-equipped container 5, and a liquid pump 1 are connected in this order via pipes 3, 6, and 7 to form a closed circuit. A refrigerant that changes in gas-liquid phase is enclosed in the closed circuit.

Then, the liquid refrigerant discharged from the liquid pump 1 enters the heat source side heat exchanger 2, where it absorbs heat from the high temperature heat source to be evaporated and vaporized into a gas refrigerant. The gas refrigerant enters the heat exchanger 4 on the use side through the pipe 3 and radiates heat to the low temperature heat source to be condensed and liquefied into a liquid refrigerant. The pressure of the liquid refrigerant in the use side heat exchanger 4 is determined by the temperature of the use side heat exchanger 4.

This liquid refrigerant enters the container with radiator 5 through the pipe 6, and further radiates heat from the radiator 5z, whereby the temperature becomes lower than that of the heat exchanger 4 on the use side, and the pressure corresponding to this low temperature. Becomes Since there is no need to extremely reduce the pressure in the radiator-equipped container 5 and it is not necessary to condense and liquefy the refrigerant here, the height difference between the radiator-equipped container 5 and the use side heat exchanger 4 Liquid refrigerant head difference and piping 6
It suffices if there is a pressure difference that allows the liquid refrigerant to move from the use-side heat exchanger 4 into the radiator-equipped container 5 against the pressure loss accompanying the flow of the liquid refrigerant passing through the inside.

The liquid refrigerant condensed and liquefied in the heat exchanger 4 on the use side by keeping the pressure in the container 5 with the heat radiator lower than the pressure in the heat exchanger 4 on the use side passes through the pipe 6 to the container with a heat radiator. Enter within 5. The liquid refrigerant stored in the radiator-equipped container 5 enters the liquid pump 1 through the pipe 7 connected below the container 5 and forms a circulation cycle. Here, the liquid pump 1 is preferably placed near the radiator-equipped container 5, but may be separated as long as the liquid refrigerant does not foam in the pipe 7.

As shown in FIG. 2, in the radiator-equipped container 5, the opening 7z of the pipe 7 connected to the liquid pump 1 should be arranged at a lower position than the opening 6z of the pipe 6 connected to the utilization side heat exchanger 4. This makes it possible to prevent the vapor-phase refrigerant in the radiator-equipped container 5 from being sucked into the liquid pump 1. Of course, it is possible to prevent the gas-phase refrigerant from flowing into the pipe 7 by providing a partition wall inside the radiator-equipped container 5 or by separating the two openings 6z and 7z sufficiently.

The container 5 with a radiator does not need to be integrated with the radiator. Therefore, as shown in FIG. 3, the radiator is constituted by a heat exchanger 5d, and the container 5a and the heat exchanger 5d are formed. Alternatively, the pipes 5y and 5x may be separated and connected to each other. That is,
The container 5a and the heat exchanger 5d are connected in parallel, the upper part of the container 5a and the upper part of the heat exchanger 5d are connected by the pipe 5y, and the lower part of the container 5a and the lower part of the heat exchanger 5d are also connected by the pipe 5x. . By radiating heat in the heat exchanger 5d, the pressure in the heat exchanger 5d is kept lower than that in the utilization side heat exchanger 4, and the container 5a communicating with this is maintained.
Since the pressure inside is the same as the pressure inside the heat exchanger 5d,
The liquid refrigerant condensed and liquefied in the use side heat exchanger 4 flows into the container 5a through the pipe 6.

The pipe 6 is a container as shown in FIG.
It may be connected to a pipe 5y that connects the upper part of 5a and the upper part of the heat exchanger 5d at a position where it is possible to prevent a gas-phase refrigerant that may possibly flow with the liquid refrigerant from the pipe 6 from flowing into the pipe 7. If necessary, the pipe 6 may be connected to another position.

Further, the heat exchanger 5d is not necessarily required if there is another heat radiating means, and heat can be radiated by the container 5a itself. For example, as shown in FIG. 5, cooling air can be sent to the container 5a by a blower 5e to cool the container 5a.
The cooling air may be sent by natural convection. Further, as shown in FIG. 6, the cooling water pipe 5f may be wound around the container 5a to cool the container 5a with cooling water. Further, the container 5a may be cooled by using a refrigerating device.

FIG. 7 shows an example of a radiator-equipped container for maintaining an appropriate liquid level in the liquid refrigerant in the radiator-equipped container 5 without excessive heat dissipation. A liquid level detector 5h is provided in the container 5a, and when the liquid level is low, the signal is transmitted to the control device 5g, and the control device 5g drives the blower 5e. Then, the heat radiation amount of the container 5a increases, the temperature of the container 5a decreases, and the pressure inside the container 5a decreases.
As a result, the amount of liquid refrigerant flowing in from the pipe 6 increases, and the container
The liquid level in 5a rises.

When the liquid level becomes high, the liquid level detector 5h transmits the signal to the control device 5g, and the control device 5g stops the blower 5e. Then, the heat radiation amount of the container 5a decreases and the container
The temperature of 5a rises and the pressure inside it rises. As a result, the amount of the refrigerant flowing in from the pipe 6 is reduced and the liquid level in the container 5a is lowered.

Thus, by operating / stopping the blower 5e according to the rise or fall of the liquid level, the liquid level can be maintained within a certain range. The blower 5e may adjust the amount of blown air according to the liquid level detected by the liquid level detector 5h, and does not necessarily have to be controlled by starting and stopping.

FIG. 8 shows another example of the radiator-equipped container 5 for maintaining an appropriate liquid level. When the liquid level in the container 5a is low, the signal from the liquid level detector 5h is transmitted to the control device 5v, and the control device 5v opens the valve 5i. Then, the cooling water is passed through the valve 5i to the cooling water pipe 5f, whereby the container 5a is cooled and the pressure inside the container 5a is lowered, so that the liquid level rises.

When the liquid level becomes high, the liquid level detector 5h transmits the signal to the control device 5v, and the control device 5v closes the valve 5i to stop the flow of cooling water. As a result, the heat radiation amount of the container 5a decreases, the temperature of the container 5a rises, and the internal pressure rises, so that the liquid level decreases.

That is, the liquid level can be maintained within a certain range by passing or stopping the cooling water according to the rise or fall of the liquid level. The opening degree of the valve 5i may be adjusted according to the liquid level detected by the liquid level detector 5h. Further, cooling means other than cooling water, such as a refrigerating device, can be used to cool the container 5a. In this case, the liquid level can be adjusted by adjusting the cooling capacity of the refrigerating device.

FIG. 9 shows a second embodiment. In this second embodiment, a reversible pump is used as the liquid pump.
11, a radiator-equipped container 5b is connected to the right side, and a radiator-equipped container 5c is connected to the left side. When the heat source of the heat source side heat exchanger 2 is hot, the liquid refrigerant discharged from the reversible pump 11 enters the radiator-equipped container 5c through the pipe 17a. This container 5c
In the above, heat radiation may or may not be performed, but if heat radiation is performed, the liquid surface level of the liquid refrigerant in the container 5c becomes relatively high and the container 5c may be filled with the liquid refrigerant.

When there is no heat radiation, the pipe 16a is placed in the container 5c.
If the liquid refrigerant accumulates at a height higher than the opening height of, it will flow out from the pipe 16a. If you keep the temperature of the container 5c with a radiator high,
Is not filled with the liquid refrigerant, and a proper gas phase region can be formed in the container 5c, so that an excessive refrigerant is not required.

The liquid refrigerant that has entered the pipe 16a enters the heat source side heat exchanger 2, where it absorbs heat from the heat source and evaporates. The vaporized refrigerant enters the use-side heat exchanger 4 through the pipe 3 and radiates heat there to be condensed and liquefied. This liquid refrigerant is sucked by the reversible pump 11 through the pipe 16b, the radiator-equipped container 5b, and the pipe 17b. As a result, the heat source side heat exchanger 2
The warm heat absorbed by is conveyed to the utilization side heat exchanger 4.

On the contrary, when the heat source of the heat source side heat exchanger 2 is cold heat, the liquid refrigerant enters the radiator-equipped container 5b from the reversible pump 11 through the pipe 17b. The container 5b may or may not radiate heat. The liquid refrigerant flowing out from the pipe 16b absorbs heat in the heat exchanger 4 on the use side, and evaporates and vaporizes. The vaporized refrigerant enters the heat source side heat exchanger 2 through the pipe 3 and radiates heat to the cold heat source to be condensed and liquefied. Then, it is sucked by the reversible pump 11 through the pipe 16a, the radiator-equipped container 5c, and the pipe 17a to form a circulation cycle.

That is, when the heat source is hot, the reversible pump 11 discharges to the pipe 17a side, and when the heat source is cold, the reversible pump 11 discharges to the pipe 17b side, so that either hot or cold heat is generated. However, it can be transported.

FIG. 10 shows a third embodiment of this third embodiment.
In this embodiment, the reversible pump 11 is arranged below the heat source side heat exchanger 2 in the vicinity thereof. When the heat source is warm, the refrigerant circulates as in the case of the first embodiment shown in FIG.

However, when the heat source is cold heat, the liquid refrigerant discharged from the reversible pump 11 enters the use side heat exchanger 4 via the pipe 17b, the radiator container 5 and the pipe 6, where it absorbs heat and evaporates. After being vaporized, it enters the heat source side heat exchanger 2 through the pipe 3 and radiates heat there to be condensed and liquefied.

Since the reversible pump 11 is installed in the vicinity of the heat source side heat exchanger 2 and below the heat source side heat exchanger 2, the liquefied refrigerant does not cause a pressure loss and does not become a reverse head. As it is, it is sucked into the reversible pump 11 to complete the circulation cycle. That is, this third embodiment can carry both hot and cold heat without the radiator-equipped container 5c shown in FIG.

FIG. 11 shows a fourth embodiment.
In the fourth embodiment, a variable speed reversible pump 21 is provided as a liquid pump, and the pump 21 is installed near and below the heat source side heat exchanger 2. A plurality of utilization side heat exchangers are connected in parallel with each other (in the figure, 3
Individual heat exchangers 24a, 24b, 24c, and valves 20a, 20b, 20c are installed on the radiator-equipped container 5 side of these heat exchangers 24a, 24b, 24c, respectively. These heat exchangers
24a-24b correspond to each indoor unit of the multi-room air conditioner.

When a plurality of utilization side heat exchangers 24a, 24b, 24c are provided, the variable speed pump 21 that can obtain the refrigerant flow rate according to the number of operating units, that is, the load, becomes more effective. Of course, it goes without saying that the variable speed pump is also effective in adjusting the heat transfer amount in the first to third embodiments.

In the fourth embodiment, when the heating operation is performed by each of the use side heat exchangers 24a, 24b, 24c, the valve 20
All of a, 20b, 20c are open, and variable speed reversible pump
21 is driven at high speed. The liquid refrigerant discharged from the variable speed reversible pump 21 enters the heat source side heat exchanger 2 through the pipe 17a, where the liquid refrigerant absorbs heat and evaporates, and then passes through the pipe 23 to the use side heat exchanger 24a. It flows into 24b and 24c.

After being condensed and liquefied by radiating heat in the use side heat exchangers 24a, 24b, 24c, this liquid refrigeration is valved.
The variable speed reversible pump 21 is sucked through the pipe 26b through the pipes 20b, 20b, 20c, and the radiator-equipped container 5 and the pipe 17b.

When heating is performed by the use side heat exchangers 24a and 24b and the use side heat exchanger 24c is not operated, the valves 20a and 20b are opened, the valve 20c is closed, and the variable speed reversible pump 21 is operated at a medium speed. Driven. The liquid refrigerant discharged from the variable speed reversible pump 21 flows through the pipe 17a, the heat source side heat exchanger 2 and the pipe 23 into the use side heat exchangers 24a, 24b, 24c. Since the valve 20c is closed, when the liquid refrigerant accumulates in the use side heat exchanger 24c due to its natural heat dissipation, the gas refrigerant does not flow thereafter. The refrigerant condensed and liquefied by radiating heat in the heat exchangers 24a and 24b on the utilization side merges with the pipe 26b through the valves 20a and 20b, and is sucked into the variable speed reversible pump 21 through the container 5 with radiator and the pipe 17b. It

When the heating operation is performed only by the use side heat exchanger 24a, only the valve 20a is opened and the valves 20b and 20c are closed.
The variable speed reversible pump 21 is driven at a low speed.

The heat source is cold and the heat exchangers 24a and 24b on the respective use sides
, 24c, the valves 20a, 20b, 20c are all opened. The variable speed reversible pump 21 is driven at high speed, and the liquid refrigerant is discharged to the pipe 17b. This liquid refrigerant flows into the heat exchangers 24a, 24b, 24c on the use side through the radiator-equipped container 5, the pipe 26b, the valves 20a, 20b, 20c, respectively, and absorbs heat at these heat exchangers 24a, 24b, 24c. By doing so, it vaporizes and enters the pipe 23. Next, the gas refrigerant flows into the heat source side heat exchanger 2 and radiates heat there to be condensed and liquefied, and then sucked into the variable speed reversible pump 21 through the pipe 17a.

When the user side heat exchanger 24c is stopped, the valve 20
Only c is closed. When the cooling operation is performed only by the use side heat exchanger 24a, the valve 20a is opened and the valves 20b and 20c are closed.

The rotation speed of the variable speed reversible pump 21, that is, the discharge amount of the liquid refrigerant is determined by the use side heat exchangers 24a, 24b, 24c.
However, the rotation speed of the variable speed reversible pump 21 is changed depending on the number of operating side heat exchangers 24a, 24b.
, 24c may be changed according to the load to supply the refrigerant in an amount commensurate with the load. Further, when only one of the hot heat and the cold heat is conveyed, the reversible pump does not have to be used.

FIG. 12 shows a fifth embodiment. This fifth embodiment comprises a one-way discharge pump 1 and a four-way switching valve 18. When the heat source of the heat source side heat exchanger 2 is cold, the four-way switching valve 18 is switched as shown by the solid line in the figure. The liquid refrigerant discharged from the pump 1 passes through the four-way switching valve 18 and the use side heat exchanger 4, the pipe 3, the heat source side heat exchanger 2, the four way switching valve.
Returning to the pump 1 via 18, the pipe 6a, the radiator container 5, and the pipe 7.

When the heat source of the heat source side heat exchanger 2 is hot, the four-way switching valve 18 is switched as shown by the broken line in the figure, and the liquid refrigerant discharged from the pump 1 is transferred to the four-way switching valve 18 and the heat source side heat exchange. It is sucked into the pump 1 through the device 2, the pipe 3, the use side heat exchanger 4, the four-way switching valve 18, the pipe 6a, the radiator-equipped container 5, and the pipe 7 in this order. Also in this example, the amount of heat transferred can be adjusted by making the discharge amount of the pump 1 variable.

FIG. 13 shows a sixth embodiment. In the sixth embodiment, combustion heat is supplied to the heat source side heat exchanger 2. The heat generated in the combustor 30 is supplied to the refrigerant by the heat source side heat exchanger 2 and is radiated by the use side heat exchanger 4. In this way, the combustion heat can be used in the use side heat exchanger 4 installed in the room without generating exhaust gas accompanying the combustion in the room.

FIG. 14 shows a seventh embodiment. In the seventh embodiment, a heat storage tank 31 and a heat pump device 40 for storing hot or cold heat are provided. When storing heat in the heat storage tank 31, the four-way valve 42 is switched as shown by the solid line. Then, the high-temperature and high-pressure gas refrigerant discharged from the compressor 41 enters the heat storage heat exchanger 45 through the four-way valve 42 and radiates heat there, thereby raising the temperature of the water stored in the heat storage tank 31 and Is condensed and liquefied.

The liquefied refrigerant is decompressed by the throttle 44 and then enters the heat source heat exchanger 43 where it is evaporated and vaporized by removing heat from the heat source such as air, river water, hot water for district cooling and heating. The vaporized refrigerant returns to the compressor 41 via the four-way valve 42. As a result, the temperature of the water in the heat storage tank 31 rises, and when the temperature of this water rises to a predetermined temperature, the compressor 41 stops.

When cold heat is stored in the heat storage tank 31, a four-way valve
42 is switched as shown by the dashed line. Then the compressor
The gas refrigerant discharged from 41 is a four-way valve 42, heat source heat exchanger 4
3, the throttle 44, the heat storage heat exchanger 45, and the four-way valve 42 are passed in this order and returned to the compressor 41. During this time, the water in the heat storage tank 31 is cooled,
When it becomes 0 ° C. or less, it freezes, and when the proportion of this ice increases to a predetermined amount, the compressor 41 stops.

When hot heat is stored in the heat storage tank 31, the liquid refrigerant discharged from the reversible pump 11 enters the heat source side heat exchanger 12, where it absorbs the heat stored in the heat storage tank 31 and Is transferred to the use side heat exchanger 4 and radiated therefrom. When the reversible pump 11 is operating, or the heat storage tank 31
When the internal water temperature drops to a predetermined level, the compressor 41 is driven to perform heat storage operation.

When cold heat is stored in the heat storage tank 31, the reversible pump 11 discharges the liquid refrigerant to the pipe 17b side, and the cold heat stored in the heat storage tank 31 is transferred to the heat exchanger 4 on the use side. It absorbs heat. When the reversible pump 11 is operating, or when the proportion of ice in the heat storage tank 31 has decreased to a predetermined value, the compressor 41 is driven to perform the cold storage operation. Since the amount of heat stored by ice is large, it is possible not to perform the cold storage operation within a predetermined time after the operation of the reversible pump 11.

Further, instead of the heat pump device 40, it is possible to store heat by using a heater such as midnight power, and the heater may be used together with the heat pump device. In addition, if the reversible pump 11 has a variable speed, heat can be transferred according to the load.

FIG. 15 shows an eighth embodiment. The eighth embodiment uses the heat supplied by the heat pump device 40 as a heat source. When the four-way valve 42 is in the position indicated by the solid line, the gas refrigerant discharged from the compressor 41 enters the heat source side heat exchanger 12 via the four-way valve 42, and the liquid refrigerant supplied from the reversible pump 11 via the pipe 17a. By applying heat to the liquid, it condenses itself into liquid. The liquefied refrigerant is decompressed by the throttle 44, and then enters the heat source heat exchanger 43 where the heat is taken from the heat source to be evaporated and vaporized. The vaporized refrigerant is a four-way valve
It returns to the compressor 41 via 42 and completes a refrigeration cycle.

On the other hand, the liquid refrigerant discharged from the reversible pump 11 enters the heat source side heat exchanger 12 via the pipe 17a, and absorbs heat from the heat pump device 40 to be evaporated and vaporized.
The vaporized refrigerant is pipe 3, use side heat exchanger 4, pipe 16b,
Return to the reversible pump 11 via the radiator-equipped container 5 and the pipe 17b.

When the four-way valve 42 is in the broken line position, the compressor
The gas refrigerant discharged from 41 is a four-way valve 42, heat source heat exchanger 4
3. After passing through the throttle 44, the heat source side heat exchanger 12 enters the heat source side heat exchanger 12, where heat is taken from the gas refrigerant flowing in from the pipe 3 of the heat transfer device, so that the heat vaporizer itself evaporates. The vaporized refrigerant is a four-way valve 42
And returns to the compressor 41 to complete the refrigeration cycle.

On the other hand, the liquid refrigerant discharged from the reversible pump 11 passes through the pipe 17b, the radiator-equipped container 5, the pipe 16b, the use side heat exchanger 4, the pipe 3, the heat source side heat exchanger 12, and the pipe 17a. Return to 11. In this way, the heat supplied by the heat pump device 40 can be transferred to the utilization side heat exchanger 4.

FIG. 16 shows a ninth embodiment. In the ninth embodiment, a plurality (two in the figure) of heat source side heat exchangers 12a, 12b are connected in series. The heat source side heat exchanger 12b is capable of exchanging heat with the hot water passed through the valve 50, and the heat source side heat exchanger 12a is a heat pump device.
Also serves as an evaporator for 40a. Multiple heat source side heat exchangers 12a
, 12b may be connected in parallel with each other and the valves may be switched to operate one or more of them.

First, when heat is absorbed in the utilization side heat exchanger 4, the reversible pump 11 discharges to the pipe 17b side, the valve 50 is closed, and the heat pump device 40a is operated. The liquid refrigerant discharged from the reversible pump 11 passes through the pipe 17b, the radiator-equipped container 5, the pipe 16b, the use-side heat exchanger 4, and the pipe 3 without passing through the heat-source-side heat exchanger 12b and the heat-source-side. After entering the heat exchanger 12a and condensing and liquefying by absorbing heat from the refrigerant on the heat pump device 40a side, it returns to the reversible pump 11 via the pipe 17a.

On the other hand, in the heat pump device 40a,
The refrigerant discharged from the compressor 41 is a heat source heat exchanger 43 and a throttle 44.
Through the heat source side heat exchanger 12a, where heat is exchanged with the refrigerant on the side of the heat transfer device to evaporate and vaporize the compressor 41.
Return to

Next, when heat is dissipated in the use side heat exchanger 4, the heat pump device 40a is stopped and the valve 50 is opened. The reversible pump 11 discharges the liquid refrigerant to the pipe 17a side.
This liquid refrigerant enters the heat source side heat exchanger 12a, but since the heat pump device 40a is stopped, it passes through this without heat exchange and enters the heat source side heat exchanger 12b, where it absorbs heat from hot water. Evaporate and vaporize. The vaporized refrigerant is used side heat exchanger 4, piping 16b, radiator container 5, piping 17b.
Return to reversible pump 11 via.

FIG. 17 shows a tenth embodiment. In the tenth embodiment, the heat supplied by the heat pump device 40 and the heat provided by the combustor 30 are selectively used as heat sources. When cooling is performed by the use side heat exchanger 4, the combustor 30 is stopped and the four-way valve 42 of the heat pump device 40 is used.
Is switched as indicated by a broken line to operate the compressor 41. Then, the refrigerant discharged from the compressor 41 enters the heat source side heat exchanger 12a through the four-way valve 42, the heat source heat exchanger 43, and the throttle 44, where it itself removes heat from the refrigerant on the heat transfer device side. After evaporating, it returns to the compressor 41 via the four-way valve 42.

On the other hand, in the heat transfer device, a reversible pump
The liquid refrigerant discharged from 11 is the pipe 17b, the radiator container 5,
It enters the heat exchanger 4 on the utilization side through the pipe 16b, evaporates and vaporizes by taking heat from the indoor air, and then enters the heat exchanger 12b on the heat source side through the pipe 3, but the combustor 30 is operating. Since there is no gas refrigerant, it flows out as it is, and the heat source side heat exchanger
12a and liquefy by radiating heat to the heat pump device 40 side here, and then via the pipe 17a to the reversible pump 11a.
Return to

When the heating operation is performed by the heat exchanger 4 on the use side, there are two cases where the outside air temperature is relatively high and low. First, when the outside air temperature is relatively high, the combustor 30 is not operated, the four-way valve 42 of the heat pump device 40 is switched as shown by the solid line in the figure, and the compressor 41 is operated. Then, the refrigerant discharged from the compressor 41 enters the heat source side heat exchanger 12a through the four-way valve 42, where heat is radiated to the heat transfer device side refrigerant to be condensed and liquefied, and then the throttle 44, the heat source heat exchanger.
It returns to the compressor 41 through 43, the four-way valve 42.

On the other hand, in the heat transfer device, a reversible pump
The liquid refrigerant discharged from 11 enters the heat source side heat exchanger 12a via the pipe 17a, evaporates and vaporizes by absorbing heat from the heat pump device 40 side, and then passes through the heat source side heat exchanger 12b without heat exchange. Then, it enters the heat exchanger 4 on the use side through the pipe 3. Here, the heat is radiated to the room air to be condensed and liquefied, and then returns to the reversible pump 11 through the pipe 16b, the radiator container 5, and the pipe 17b. In this way, the heat absorbed by the heat pump device 40 from the outside air is transferred to the utilization side heat exchanger 4 and the heating operation is performed.

Next, when the outside air temperature is low, the heat pump device 40 is stopped, the combustor 30 is operated, and the reversible pump 11 discharges to the pipe 17a side. The liquid refrigerant discharged from the reversible pump 11 passes through the pipe 17a and the heat source side heat exchanger 12a without heat exchange and enters the heat source side heat exchanger 12b, where the combustor is set.
It absorbs the heat of combustion of 30 and evaporates. The vaporized refrigerant is condensed and liquefied by warming the indoor air in the utilization side heat exchanger 4 via the pipe 3 and returns to the reversible pump 11 via the pipe 16b, the radiator container 5 and the pipe 17b.

In this example, the combustor 30 and the heat pump device 40
Either one of them is operated, but both may be operated simultaneously. Further, the amount of refrigerant discharged from the reversible pump 11 may be changed according to the air conditioning load, and it is desirable to adjust the capacity of the heat pump device 40 and the heat generation amount of the combustor 30 according to the change in the amount of refrigerant.

The various embodiments have been described above.
For example, it is possible to use a heater, exhaust heat of a heat engine, hot spring water, heated steam, etc. as a heat source, and cold water including brine, air, river water, seawater, etc. can also be used as a heat source. It is possible.

[0076]

As described above, by using the heat transfer device according to the present invention, the liquid pump can be installed even if one of the use side heat exchanger and the heat source side heat exchanger is installed higher than the other. It is possible to transfer heat without changing the position each time.

If a reversible pump is used, heat can be dissipated or absorbed in the utilization side heat exchanger simply by reversing the circulation direction of the refrigerant.

If the discharge amount variable pump is used, it is possible to transfer heat according to the load by changing the discharge amount. If the heat exchanger on the use side is an indoor unit of an air conditioner, more comfortable air conditioning with less temperature change becomes possible.

If the liquid pump is installed near the heat source side heat exchanger, one container with a radiator can be used when a reversible pump is used. In addition, when the heat exchanger on the use side is an indoor unit of an air conditioner, if the liquid pump during cooling operation is in the vicinity of the heat exchanger on the heat source side, it is not necessary to install a container with a radiator between them, and heat radiation during heating operation Since the container with a device can be installed in the place where the outside temperature is low, the heat can be easily dissipated. If the liquid pump is integrated with the heat source side heat exchanger or the radiator-equipped container, the installation work on site will be easy.

If the utilization side heat exchanger is composed of a plurality of heat exchangers connected in parallel with each other, the plurality of heat exchangers can be selectively used as necessary to, for example, perform air conditioning of a large number of chambers. In this case, the heat exchanger on the heat source side, the liquid pump, the container with the radiator, and the piping can be shared, so that the cost is low and the waste of providing many pipings can be omitted.

If the heat source side heat exchanger is composed of a plurality of heat exchangers, various heat sources can be used according to their advantages. Therefore, the heating heat source and the cooling heat source can be different from each other. In addition, by connecting these multiple heat exchangers in series, a switching valve becomes unnecessary,
It becomes possible to make a simple circuit.

Further, if the heat exchanger for the low temperature side heat source is connected close to the liquid pump, the liquid refrigerant can be easily sucked by the liquid pump, and the radiator-equipped container can be omitted. Becomes

When the heat of combustion is used as the heat source, the heat of combustion can be used without generating the exhaust gas accompanying the combustion in the place where the heat exchanger on the use side is installed, for example, indoors. Further, if the combustor is installed indoors, its shape, installation location, usability, etc. are restricted. However, use of the heat transport device of the present invention can remove those restrictions.

If the heat source is the heat stored in the heat storage tank, the heat quantity supplied to this heat storage tank does not necessarily need to match the heat quantity per unit time required by the utilization side heat exchanger. It is possible to shift the heat from the time when it requires heat. Therefore, it becomes possible to use an inexpensive heat source such as midnight power. Further, this heat source is not limited to the heat pump device, but may be a heater or combustion heat generated by midnight power, and a wide range of heat sources can be used.

If cold heat is stored in the heat storage tank, cold heat for cooling can be conveyed. Further, if heat is supplied to the heat storage tank by a heat pump, it can be used for both cooling and heating. In other words, in the case of offices, which are the main uses of air conditioners, the cooling load is large, the heating load is relatively small, and the air-conditioning load is relatively small due to the improvement of the heat insulation performance of buildings, the spread of office automation and the improvement of lighting equipment. Is needed mainly during the daytime.

Therefore, if a heat storage tank capable of dealing with the peak load is installed, the heat pump device as the heat source does not have to deal with the peak capacity, and a flat load can be provided. Since the heat is transported by the liquid pump, the maximum driving force itself can be greatly reduced.

In the air conditioner for the office, the cooling load is large and the heating load is mainly limited at the time of its rise. Therefore, the heat storage device using water can use the latent heat of ice during cooling, and thus stores a large amount of cold heat. In addition, the heat storage can be effectively used when the heating is started.

As a heat source for cooling, the water temperature in the heat storage tank is 0.
Although it is desirable to have a temperature of about ℃, generally used chilled water including water for district heating and cooling is about 7 ℃, and it is possible to obtain heat at a lower temperature by using a heat pump device. Also,
Since it is possible to utilize other heat sources such as outside air for heating, more efficient heating is possible.

When the opening position of the pipe connected to the liquid pump side of the radiator container is set lower than the opening position of the pipe connected to the utilization side heat exchanger, the gas-phase refrigerant is sucked into the liquid pump and the circulating refrigerant amount decreases. It can be avoided that stable heat transfer is possible.

If the container of the radiator-equipped container and the heat-dissipating heat exchanger are separately provided and connected in parallel with each other, the amount of heat radiation can be adjusted more easily without adjusting the size of the container.

By adjusting the heat radiation amount of the radiator-equipped container according to the liquid level of the liquid refrigerant capacity in the radiator-equipped container, it is possible to prevent more heat than necessary from being released from the radiator-equipped container. Since the opening of the pipe connected to the liquid pump side can be filled with the liquid refrigerant, stable operation becomes possible.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a heat transfer device according to a first embodiment of the present invention.

FIG. 2 is a schematic cross-sectional view showing a pipe connection state to a radiator-equipped container.

FIG. 3 is a configuration diagram showing another example of the radiator-equipped container.

FIG. 4 is a configuration diagram showing still another example of the radiator-equipped container.

FIG. 5 is a configuration diagram showing still another example of the radiator-equipped container.

FIG. 6 is a configuration diagram showing still another example of the radiator-equipped container.

FIG. 7 is a configuration diagram showing still another example of the radiator-equipped container.

FIG. 8 is a configuration diagram showing still another example of the radiator-equipped container.

FIG. 9 is a circuit diagram of a heat transfer device according to a second embodiment of the present invention.

FIG. 10 is a circuit diagram of a heat transfer device according to a third embodiment of the present invention.

FIG. 11 is a circuit diagram of a heat transfer device according to a fourth embodiment of the present invention.

FIG. 12 is a circuit diagram of a heat transfer device according to a fifth embodiment of the present invention.

FIG. 13 is a configuration diagram of a heat transfer device according to a sixth embodiment of the present invention.

FIG. 14 is a configuration diagram of a heat transfer device according to a seventh embodiment of the present invention.

FIG. 15 is a configuration diagram of a heat transfer device according to an eighth embodiment of the present invention.

FIG. 16 is a configuration diagram of a heat transfer device according to a ninth embodiment of the present invention.

FIG. 17 is a configuration diagram of a heat transfer device according to a tenth embodiment of the present invention.

[Explanation of symbols]

 1 Liquid Pump 2 Heat Source Side Heat Exchanger 4 Use Side Heat Exchanger 5 Radiator Container 3, 6, 7 Piping

Claims (16)

[Claims] 1. A heat transfer device comprising a heat source side heat exchanger, a use side heat exchanger, a radiator-equipped container, and a liquid pump, in which a refrigerant that changes in a gas-liquid phase is enclosed in a closed circuit. .. 2. The heat transfer device according to claim 1, wherein the liquid pump is a reversible pump. 3. The heat transfer device according to claim 1, wherein the liquid pump is a variable discharge amount type pump. 4. The heat transfer device according to claim 1, wherein the liquid pump is installed near the heat source side heat exchanger. 5. The heat transfer device according to claim 1, wherein the heat exchanger on the use side is constituted by a plurality of heat exchangers connected in parallel with each other. 6. The heat transfer device according to claim 1, wherein the heat source side heat exchanger comprises a plurality of heat exchangers. 7. The heat transfer device according to claim 6, wherein the plurality of heat exchangers are connected in series with each other. 8. The heat transfer device according to claim 7, wherein the heat exchangers for the heat sources on the low and medium temperature sides are connected in close proximity to the liquid pump. 9. The heat transfer device according to claim 1, wherein at least one of the heat sources of the heat source side heat exchanger is combustion heat. 10. The heat transfer device according to claim 1, wherein at least one of the heat sources of the heat source side heat exchanger is heat supplied by a heat pump device. 11. The heat transfer device according to claim 1, wherein at least one of the heat sources of the heat source side heat exchanger is heat stored in a heat storage tank. 12. The heat transfer device according to claim 11, wherein heat is supplied to the heat storage tank by a heat pump device. 13. The heat transfer device according to claim 12, wherein the capacity of the heat pump device is smaller than the amount of heat transferred by the heat transfer device. 14. The opening position of the pipe connected to the liquid pump side of the radiator-equipped container is lower than the opening position of the pipe connected to the utilization side heat exchanger.
The heat transfer device described. 15. The heat dissipation heat exchanger and the container of the heat dissipation container are connected in parallel.
The heat transfer device described. 16. The heat transfer device according to claim 1, wherein the heat radiation amount of the container with the radiator is adjusted according to the liquid level of the liquid refrigerant in the container with the radiator.