JP2021173459A - External air conditioner - Google Patents

Abstract

To provide an external air conditioner that meets different demands for adjusting outside air in winter and summer and contributes to reduction of power consumption.SOLUTION: A cooler 14 that cools outside air taken into a flow passage and a heater 16 that heats the outside air having passed through the cooler 14 are composed of a refrigerant reheat circuit 34. A sensible heat recovery circuit 32 has a first heat exchanger 18 arranged on the upstream side of the cooler 14, a second heat exchanger 20 arranged on the downstream side of the cooler 14, and a third heat exchanger 26 arranged on the downstream side of the heater 16. Provided is a control unit 40 that operates a three-way valve 30 provided in the sensible heat recovery circuit, to switch a summer mode in which brine is circulated between the first heat exchanger 18 and the second heat exchanger 20 and a winter mode in which the brine is circulated between the first heat exchanger 18 and the third heat exchanger 26.SELECTED DRAWING: Figure 1

Description

The present invention relates to an external air conditioner that adjusts the temperature and humidity of the outdoor air when the outdoor air is taken indoors.

The external air conditioner is an air conditioner for adjusting the temperature and humidity of the outdoor air when the outdoor air is taken indoors.
For example, Patent Document 1 discloses an external air conditioner in a case where a temperature gradient is large, such as when an outside air having a high temperature (eg 35 ° C.) is introduced into an indoor space having a low temperature (eg 5 ° C.).
The external air conditioner of Patent Document 1 includes a refrigeration cycle circuit that circulates a refrigerant with the outside of the cold air chamber in a closed cold air chamber. The outside air is taken into the cold air chamber, cooled and supplied to the room.

Further, Patent Document 2 discloses an external air conditioner that adjusts the temperature of the outside air and the indoor air and returns the temperature to the indoor state.
The external conditioner of Patent Document 2 includes a refrigeration cycle circuit in which a refrigerant circulates in the order of a compressor, a condenser, a reheater, an expansion valve, and an evaporator, and indoor air and outside air are an evaporator and a reheater. By passing through, the temperature and humidity are adjusted to a predetermined level.

JP-A-2019-66171 International Publication No. 2015/166541

In the case of an external air conditioner that mainly cools the outside air as in Patent Document 1, it is not possible to supply the cold outside air in winter to an appropriate temperature indoors.
For example, in summer, there are cases where it is desired to only dehumidify without significantly changing the temperature. In such a case, if the evaporator and reheater of the refrigeration cycle circuit are used as in Patent Document 2, the work of the sensible heat cooling is also the refrigeration cycle circuit, although the work actually required is only dehumidification. Therefore, there is a problem that wasteful power for operating the refrigeration cycle circuit is large.
In winter, the cooler side that cools the outside air becomes cold and frosts, so defrosting must be performed to melt the frost. However, since the operation as an external controller is stopped during defrosting, there is a problem that it is not necessary to execute defrosting.

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to provide an external air conditioner that meets different demands for adjusting the outside air in winter and summer and contributes to reduction of power consumption.

According to the external conditioner according to the present invention, a flow passage through which the outside air introduced from the intake port for taking in the outside air flows, a cooler for cooling the outside air taken into the flow passage, and an outside air flow of the cooler. A heater arranged on the downstream side in the direction to heat the outside air passing through the cooler, a first heat exchanger arranged on the upstream side in the outside air flow direction of the cooler, and a downstream side in the outside air flow direction of the cooler. The arranged second heat exchanger, the third heat exchanger arranged on the downstream side in the outside air flow direction of the heater, the first heat exchanger, the second heat exchanger, and the third heat exchanger. In the middle of the distribution pipe, a distribution pipe through which brine that circulates and exchanges heat with the outside air flows, a three-way valve that switches the flow of brine between the second heat exchanger and the third heat exchanger. The cooler and the heater are provided with a sensible heat recovery circuit having a pump for circulating brine in the flow pipe, and a control unit for controlling the drive of the pump and switching of the three-way valve. The refrigerant compressed and sent out by the compressor is distributed, and one of the distributed refrigerants is circulated in the order of a condenser, an expansion valve, a cooler, and a compressor that releases heat to an external heat medium which is an external heat source. A part of the configuration of a refrigerant reheat circuit having a cooling circuit and a heating circuit provided so that the other distributed refrigerant joins the cooling circuit at the expansion valve after passing through the heater. The control unit operates the three-way valve to circulate brine between the first heat exchanger and the second heat exchanger, and the first heat exchanger and the third heat exchanger. It is characterized in that it can be controlled to switch between the winter mode in which brine is circulated with the heat exchanger.
By adopting this configuration, in the summer mode, the sensible heat recovery circuit recovers the sensible heat on the outside air inlet side of the cooler, so that the cooling capacity of the cooler can be saved. Contributes to the reduction of power consumption. In the winter mode, the brine is heated in the third heat exchanger on the downstream side of the heater and circulated to the first heat exchanger on the cooler side. Therefore, it is possible to prevent frost from forming on the cooler, and the operation can be performed without defrosting even in winter. Further, when the defrost is executed by the electric heater, it contributes to the reduction of power consumption.

Further, the first heat exchanger, the cooler, the second heat exchanger, the heater, and the third heat exchanger are arranged in a straight line in the flow passage along the flow direction of the outside air. It may be characterized by that.
According to this configuration, the outside air can be efficiently adjusted with a simple configuration.

Further, the control unit may be characterized in switching from the summer mode to the winter mode when it detects that the suction temperature of the refrigerant into the compressor becomes equal to or lower than the evaporation temperature of the refrigerant.
When the suction temperature of the refrigerant into the compressor becomes lower than the evaporation temperature of the refrigerant, liquid back to the compressor occurs. Therefore, by switching at this point, the refrigerant reheat circuit can be operated without causing liquid back. can do.

Further, the control unit drives the pump so that the brine flows from the upper part to the lower part of the first heat exchanger in the summer mode, and in the winter mode, the control unit drives the pump so that the brine flows from the upper part to the lower part. 1. The pump may be driven so that brine flows from the lower part to the upper part of the heat exchanger.
According to this configuration, especially in the winter mode, the high temperature brine is raised from below to exchange heat with the outside air, so that the heat exchange efficiency is good and reliable heat exchange can be performed.

According to the external conditioner according to the present invention, a flow passage through which the outside air introduced from the intake port for taking in the outside air flows, a cooler for cooling the outside air taken into the flow passage, and an outside air flow of the cooler. A heater arranged on the downstream side in the direction to heat the outside air passing through the cooler, a first heat exchanger arranged on the upstream side in the outside air flow direction of the cooler, and a downstream side in the outside air flow direction of the cooler. An arranged second heat exchanger, a flow pipe through which brine or hot water that flows between the first heat exchanger and the second heat exchanger and exchanges heat with the outside air flows, and the flow pipe. A sensible heat recovery circuit provided in the middle and having a pump for circulating brine or hot water between the first heat exchanger and the second heat exchanger is provided, and the cooler and the heater are provided. The refrigerant compressed and sent out by the compressor is distributed, and one of the distributed refrigerants is circulated in the order of a condenser, an expansion valve, a cooler, and a compressor that releases heat to an external heat medium that is an external heat source. A part of the configuration of a refrigerant reheat circuit having a cooling circuit and a heating circuit provided so that the other distributed refrigerant joins the cooling circuit at the expansion valve after passing through the heater. The exposed heat recovery circuit is provided with a discharge valve for discharging brine or hot water in the flow passage, and a supply valve for supplying brine or hot water in the flow passage. The discharge valve and the supply valve are controlled so as to be switchable between a summer mode in which brine is circulated in the sensible heat recovery circuit and a winter mode in which hot water supplied from the outside is circulated in the sensible heat recovery circuit. It is characterized by doing.
By adopting this configuration, in the summer mode, the sensible heat recovery circuit recovers the sensible heat on the outside air inlet side of the cooler, so that the cooling capacity of the cooler can be saved. Contributes to the reduction of power consumption. Further, in the winter mode, since hot water is circulated in the sensible heat recovery circuit, frost formation on the cooler can be prevented, and the operation can be performed without defrosting even in the winter period. Further, when the defrost is executed by the electric heater, it contributes to the reduction of power consumption.

Further, the first heat exchanger, the cooler, the second heat exchanger, and the heater may be characterized in that they are arranged in a straight line in the flow passage along the flow direction of the outside air.
According to this configuration, the outside air can be efficiently adjusted with a simple configuration.

Further, the control unit may be characterized in switching from the summer mode to the winter mode when it detects that the suction temperature of the refrigerant into the compressor becomes equal to or lower than the evaporation temperature of the refrigerant.
When the suction temperature of the refrigerant into the compressor becomes lower than the evaporation temperature of the refrigerant, liquid back to the compressor occurs. Therefore, by switching at this point, the refrigerant reheat circuit can be operated without causing liquid back. can do.

Further, the control unit may be characterized in that after the hot water is introduced into the flow pipe, the pump is driven so that the hot water flows from the lower part to the upper part of the first heat exchanger.
According to this configuration, especially in the winter mode, the brine heated by the pump heat or the like is raised from under the first heat exchanger to exchange heat with the outside air, so that the heat exchange efficiency is good and reliable heat is obtained. Can be exchanged.

According to the present invention, it is possible to meet different demands for adjusting the outside air in winter and summer, and to contribute to reduction of power consumption.

It is a piping system diagram which shows the 1st Embodiment of an external air conditioner. It is a piping system diagram which shows the 2nd Embodiment of an external air conditioner.

(First Embodiment)
Hereinafter, preferred embodiments of the external air conditioner according to the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a piping system diagram showing a schematic configuration of an external air conditioner according to the present embodiment.
The external regulator 10 is a temperature regulator for adjusting the outdoor air to a predetermined temperature and humidity and taking it into the room.

The external air conditioner 10 has a flow passage 12 through which the outside air introduced from the intake port 11 for taking in the outside air flows.
In the flow passage 12, a cooler 14 for cooling the outside air and a heater 16 for heating the outside air passing through the cooler 14 on the downstream side in the distribution direction of the outside air from the cooler 14 are provided.
Further, the outside air that has passed through the cooler 14 becomes low temperature and low humidity, and then is heated by the heater 16 to reduce the relative humidity, so that the heater 16 functions as a reheater.
On the outlet side (indoor side) of the flow passage 12, a fan 27 for generating an air flow toward the room is provided on the downstream side in the outside air flow direction of the third heat exchanger 26 described later.

Further, in the flow passage 12, the first heat exchanger 18 is arranged on the upstream side of the cooler 14 in the outside air flow direction, and the second heat exchanger 20 is arranged on the downstream side of the cooler 14 in the outside air flow direction. There is. The first heat exchanger 18 and the second heat exchanger 20 are connected by a distribution pipe 22 so that brine can circulate.
The brine may be a liquid having a low freezing temperature and high thermal conductivity, and an alcohol solution or the like can be used, for example.
A pump 24 for circulating brine is provided in the middle of the distribution pipe 22. The drive of the pump 24 is controlled by the control unit 40.

Further, a third heat exchanger 26 is arranged on the downstream side of the heater 16 in the outside air flow direction.
A branch pipe 28 branched from the distribution pipe 22 is connected to the third heat exchanger 26, and brine circulates in the third heat exchanger 26 through the branch pipe 28. The branching point in the distribution pipe 22 is a place where the second heat exchanger 20 and the third heat exchanger 26 are branched, and a three-way valve 30 is provided at this branching point.
Therefore, under the control of the three-way valve 30, the brine circulates between the first heat exchanger 18 and the second heat exchanger 20, and the brine is between the first heat exchanger 18 and the third heat exchanger 26. It can be switched between the case of circulating between.

The sensible heat recovery circuit 32 is composed of the first heat exchanger 18, the second heat exchanger 20, the third heat exchanger 26, the flow pipe 22, the branch pipe 28, and the pump 24.

Next, the refrigerant reheat circuit will be described.
The cooler 14 and the heater 16 are provided as part of the configuration of the refrigerant reheat circuit 34.
The refrigerant reheat circuit 34 includes a compressor 36, a heater 16, a condenser 38, an expansion valve 42, and a cooler 14. Further, the heater 16 and the cooler 14 are arranged in the flow passage 12. The compressor 36, the condenser 38, and the expansion valve 42 are arranged outside the flow passage 12.

The high temperature and high pressure refrigerant produced by the compressor 36 is branched and supplied to the heater 16 and the condenser 38. The refrigerant supplied to the heater 16 is supplied to the expansion valve 42 provided on the upstream side of the cooler 14.
The refrigerant supplied to the condenser 38 exchanges heat with the outside air that is not subject to temperature adjustment, and is supplied to the expansion valve 42 provided on the upstream side of the cooler 14.
The refrigerant that has passed through the heater 16 and the refrigerant that has passed through the condenser 38 merge, adiabatically expand by the expansion valve 42, and are introduced into the cooler 14.
The refrigerant supplied to the cooler 14 exchanges heat with the outside air emitted from the first heat exchanger 18, and is supplied to the compressor 36.

The control unit 40 controls the drive of the pump 24 of the sensible heat recovery circuit 32 and executes the switching control of the three-way valve 30.
Further, the control unit 40 also executes drive control of the compressor 36 of the refrigerant reheat circuit 34.

Next, the operation of the external controller 10 in the present embodiment will be described.
First, the case of the summer mode will be described. The summer mode is a mode when the liquid back does not occur in the refrigerant reheat circuit 34. The liquid back refers to a phenomenon in which the refrigerant in a liquid state flows into the compressor 36. Liquid backing can occur when the temperature of the refrigerant supplied to the compressor 36 is equal to or lower than the evaporation temperature of the refrigerant. Since the liquid back causes a decrease in the function of the refrigeration cycle and a failure of the compressor, it is important to prevent the liquid back in order to maintain the function of the external air conditioner 10.
Therefore, the control unit 40 detects the temperature of the refrigerant supplied to the compressor 36 by the temperature sensor 44 provided on the upstream side of the compressor 36, and the temperature of the refrigerant supplied to the compressor 36> the evaporation temperature of the refrigerant. In the case of, each configuration is controlled as a summer mode.

In the summer mode, the control unit 40 switches the three-way valve 30 of the sensible heat recovery circuit 32 so that the brine circulates between the first heat exchanger 18 and the second heat exchanger 20.
By circulating the brine between the first heat exchanger 18 and the second heat exchanger 20, the cold air from the cooler 14 cools and cools the brine passing through the second heat exchanger 20. Since the brine circulates in the first heat exchanger 18, the outside air introduced into the cooler 14 can be cooled in advance. That is, in the summer mode, the first heat exchanger 18 functions as a precooler.

Further, the control unit 40 may control the rotation direction of the pump 24 so that the brine flows from the upper part to the lower part of the first heat exchanger 18 in the summer mode.
That is, in the case of FIG. 1, the brine circulates clockwise between the first heat exchanger 18 and the second heat exchanger 20.
Since outside air having a higher temperature than the lower part passes through the upper part of the first heat exchanger 18 in FIG. 1, the brine cooled by the second heat exchanger 20 is shown by the arrow in FIG. 1 in the first heat exchanger 18. By flowing from the upper part to the lower part in this way, the heat exchange efficiency between the outside air and the brine in the first heat exchanger 18 is increased.

Further, in the case of the summer mode, the control unit 40 controls the rotation of the pump 24 of the sensible heat recovery circuit 32.
For example, as shown in FIG. 1, the target temperature of the air supplied into the room is Tc, and the temperature of the air that has passed through the second heat exchanger 20 is Tm. A temperature sensor 45 is provided on the downstream side of the second heat exchanger 20, and the control unit 40 detects Tm by the temperature sensor 45.
For example, when Tc is set to 25 ° C., the control unit 40 determines whether Tm is higher than 25 ° C. or 25 ° C. or lower, and switches the rotation control of the pump 24.

In the summer mode, when the control unit 40 determines that Tm> Tc, the control unit 40 lowers the rotation speed of the pump 24 to reduce the amount of sensible heat recovered.
On the other hand, when the control unit 40 determines that Tm ≦ Tc, the rotation speed of the pump 24 is maximized to increase the sensible heat recovery amount. Therefore, the load on the cooler 14 can be reduced.

The control of the pump 24 by the control unit 40 may be not the rotation speed control of the pump 24 but the flow rate control by adjusting the operating time of the pump 24.
That is, in the summer mode, when the control unit 40 determines that Tm> Tc, the pump 24 flow rate is reduced to reduce the sensible heat recovery amount.
Further, when the control unit 40 determines that Tm ≦ Tc, the control unit 40 increases the flow rate of the pump 24 to increase the amount of sensible heat recovered.

The switching from the summer mode to the winter mode will be described.
The control unit 40 detects the temperature of the refrigerant supplied to the compressor 36 by the temperature sensor 44, and when the temperature of the refrigerant supplied to the compressor 36 ≤ the evaporation temperature of the refrigerant, the mode is changed from the summer mode to the winter mode. Execute switching control.
When the control unit 40 determines that the temperature of the refrigerant supplied to the compressor 36 ≤ the evaporation temperature of the refrigerant, the control unit 40 exchanges the three-way valve 30 of the sensible heat recovery circuit 32 with the first heat exchanger 18 and the third heat exchanger. Switch so that the brine circulates with the vessel 26.
By circulating the brine between the first heat exchanger 18 and the third heat exchanger 26, the heated air from the heater 16 heats the brine passing through the third heat exchanger 26 and heats it. The prepared brine is distributed to the first heat exchanger 18.

Therefore, the cold outside air in the first heat exchanger 18 is heated, and the heated air is introduced into the cooler 14, so that liquid backing in the refrigerant reheat circuit 34 is prevented and frost formation in the cooler 14 occurs. Be prevented. Therefore, it is not necessary to temporarily stop the operation of the refrigerant reheat circuit 34 to perform defrosting, and stable operation is possible.

Further, the pump 24 of the sensible heat recovery circuit 32 may be arranged in the vicinity of the cooler 20. As a result, in the winter mode, the control unit 40 drives the pump 24 at full throttle to heat the vicinity of the cooler 14 using the pump 24 as a heat source, prevent liquid backing, and cause frost formation in the cooler 14. Be prevented.

Further, the control unit 40 may control the rotation direction of the pump 24 so that the brine flows from the lower part to the upper part of the first heat exchanger 18 in the winter mode.
That is, in the case of FIG. 1, the brine circulates counterclockwise between the first heat exchanger 18 and the third heat exchanger 26.
Since outside air at a lower temperature than the upper part passes through the lower part of the first heat exchanger 18 in FIG. 1, the brine heated to some extent by the third heat exchanger 26 is shown by the arrow in FIG. 1 in the first heat exchanger 18. As shown in the above, the heat exchange efficiency between the outside air and the brine in the first heat exchanger 18 is increased by flowing from the lower part to the upper part.

The control unit 40 detects the temperature of the refrigerant supplied to the compressor 36 by the temperature sensor 44, and when the temperature of the refrigerant supplied to the compressor 36> the evaporation temperature of the refrigerant, the winter mode is started. Executes switching control to summer mode.

(Second Embodiment)
Next, a second embodiment of the external air conditioner according to the present invention will be described.
FIG. 2 is a piping system diagram showing a schematic configuration of the external air conditioner according to the present embodiment. The same components as those of the above-described first embodiment are designated by the same reference numerals, and the description thereof may be omitted.

In the present embodiment, unlike the first embodiment, in the sensible heat recovery circuit 32, the third heat exchanger 26 is not arranged on the downstream side of the heater 16 in the outside air flow direction, and the first heat exchanger Only 18 and the second heat exchanger 20 are provided.
In the present embodiment, in the summer mode, the brine circulates between the first heat exchanger 18 and the second heat exchanger 20, and in the winter mode, hot water is used instead of the brine in the first heat exchanger. It is characterized by circulating between 18 and the second heat exchanger 20.

That is, the manifest heat recovery circuit 32 of the present embodiment has a first heat exchanger 18 provided on the upstream side of the cooler 14 in the outside air flow direction and a second heat provided on the downstream side of the cooler 14 in the outside air flow direction. A switch 20 is provided, and the first heat exchanger 18 and the second heat exchanger 20 are connected by a flow pipe 22 so that brine or hot water can flow. A pump 24 for circulating brine or hot water is provided in the middle of the distribution pipe 22. The drive of the pump 24 is controlled by the control unit 40.

The distribution pipe 22 is provided with a discharge valve 50 for discharging the brine or hot water circulating in the distribution pipe 22, and a supply valve 52 for supplying the brine or hot water into the circulation pipe 22.
The discharge valve 50 is connected to a discharge pipe 53 to the outside of the external air conditioner 10. Further, the supply valve 52 is connected to a supply pipe 54 from the outside of the external air conditioner 10.
When discharging brine, it is necessary to connect a storage container for brine (not shown) to the tip of the discharge pipe 53, but when discharging hot water, it may be treated as wastewater or hot water. It may be returned to the generator (not shown).
Further, when supplying brine, a storage container for storing brine is connected to the tip of the supply pipe 54, and when supplying hot water, a hot water generator that generates hot water is connected.

Next, the operation of the external controller 10 in the present embodiment will be described.
First, the case of the summer mode will be described. Similar to the first embodiment, the summer mode is a mode in which liquid backing does not occur in the refrigerant reheat circuit 34.
Therefore, the control unit 40 detects the temperature of the refrigerant supplied to the compressor 36 by the temperature sensor 44, and when the temperature of the refrigerant supplied to the compressor 36> the evaporation temperature of the refrigerant, each configuration is set as the summer mode. To control.

In the summer mode, the control unit 40 drives the pump 24 so that the brine circulates between the first heat exchanger 18 and the second heat exchanger 20.
Further, the control unit 40 may control the rotation direction of the pump 24 so that the brine flows from the upper part to the lower part of the first heat exchanger 18 in the summer mode.
That is, in the case of FIG. 2, the brine circulates clockwise between the first heat exchanger 18 and the second heat exchanger 20.
Since outside air having a higher temperature than the lower part passes through the upper part of the first heat exchanger 18 in FIG. 2, the brine cooled by the second heat exchanger 20 is shown by the arrow in FIG. 2 in the first heat exchanger 18. By flowing from the upper part to the lower part in this way, the heat exchange efficiency between the outside air and the brine in the first heat exchanger 18 is increased.

Further, in the case of the summer mode, the control unit 40 controls the rotation of the pump 24 of the sensible heat recovery circuit 32.
For example, as shown in FIG. 2, the target temperature of the air supplied into the room is Tc, and the temperature of the air that has passed through the second heat exchanger 20 is Tm. For example, when Tc is set to 25 ° C., the control unit 40 determines whether the Tm detected by the temperature sensor 45 is higher than 25 ° C. or 25 ° C. or lower, and switches the rotation control of the pump 24.

In the summer mode, when the control unit 40 determines that Tm> Tc, the control unit 40 lowers the rotation speed of the pump 24 to reduce the amount of sensible heat recovered.
On the other hand, when the control unit 40 determines that Tm ≦ Tc, the rotation speed of the pump 24 is maximized to increase the sensible heat recovery amount. Therefore, the load on the cooler 14 can be reduced.

As in the first embodiment, the control of the pump 24 by the control unit 40 may be not the rotation speed control of the pump 24 but the flow rate control by adjusting the operation time of the pump 24.
That is, in the summer mode, when the control unit 40 determines that Tm> Tc, the pump 24 flow rate is reduced to reduce the sensible heat recovery amount.
Further, when the control unit 40 determines that Tm ≦ Tc, the control unit 40 increases the flow rate of the pump 24 to increase the amount of sensible heat recovered.

The switching from the summer mode to the winter mode will be described.
The control unit 40 detects the temperature of the refrigerant supplied to the compressor 36 by the temperature sensor 44, and when the temperature of the refrigerant supplied to the compressor 36 ≤ the evaporation temperature of the refrigerant, the mode is changed from the summer mode to the winter mode. Execute switching control.
When switching to the winter mode, the control unit 40 opens the discharge valve 50 and discharges the brine in the distribution pipe 22. Then, after closing the discharge valve 50, the supply valve 52 is opened to supply the hot water from the hot water generator into the flow pipe 22. The hot water supplied from the hot water generator is water whose temperature is higher than that of brine. A temperature sensor 46 is provided in the distribution pipe 22 so that the temperature of the hot water flowing in the distribution pipe 22 can be detected.

After the hot water is supplied to the flow pipe 22, the control unit 40 drives the pump 24 to circulate the hot water between the first heat exchanger 18 and the second heat exchanger 20. Therefore, the outside air introduced into the cooler 14 is heated by exchanging heat with hot water in the first heat exchanger 18 and introduced into the cooler 14. Therefore, liquid backing in the refrigerant reheat circuit 34 can be prevented, and frost formation in the cooler 14 can be prevented. It also eliminates the need for defrosting to eliminate frost.

When the control unit 40 determines that the temperature of the hot water detected by the temperature sensor 46 is lower than the preset predetermined temperature during the execution of the winter mode (the temperature of the hot water decreases due to heat exchange with the outside air). In the case of), the discharge valve 50 is opened to discharge the cold hot water in the flow pipe 22. Then, after closing the discharge valve 50, the supply valve 52 is opened to supply new hot water from the hot water generator into the flow pipe 22.

When the temperature of the refrigerant supplied to the compressor 36> the evaporation temperature of the refrigerant, the control unit 40 executes switching control from the winter mode to the summer mode.
When switching to the summer mode, the control unit 40 opens the discharge valve 50 and discharges the hot water in the distribution pipe 22. Then, after closing the discharge valve 50, the supply valve 52 is opened to supply the brine into the flow pipe 22.

Further, the control unit 40 may control the rotation direction of the pump 24 so that hot water flows from the lower part to the upper part of the first heat exchanger 18 in the winter mode.
That is, in the case of FIG. 2, the hot water circulates counterclockwise between the first heat exchanger 18 and the second heat exchanger 20. Further, the hot water that has passed through the second heat exchanger 20 is heated by the pump heat based on the drive of the pump 24.
Since the outside air having a lower temperature than the upper part passes through the lower part of the first heat exchanger 18 in FIG. 2, hot water heated to some extent by the pump heat is shown by the arrow in FIG. 2 in the first heat exchanger 18. By flowing from the lower part to the upper part, the heat exchange efficiency between the outside air and the hot water in the first heat exchanger 18 is increased.

The control unit 40 detects the temperature of the refrigerant supplied to the compressor 36 by the temperature sensor 44, and when the temperature of the refrigerant supplied to the compressor 36> the evaporation temperature of the refrigerant, the winter mode is started. Executes switching control to summer mode.

(Other embodiments)
In the first embodiment described above, the first heat exchanger 18, the cooler 14, the second heat exchanger 20, the heater 16, and the third heat exchanger 26 are arranged linearly along the flow direction of the outside air. The configuration that has been done has been explained.
However, the first heat exchanger 18, the cooler 14, the second heat exchanger 20, the heater 16, and the third heat exchanger 26 may be arranged in a non-linear shape (for example, in a curved shape).
Similarly, in the second embodiment, the first heat exchanger 18, the cooler 14, the second heat exchanger 20, and the heater 16 may be arranged in a non-linear shape (for example, in a curved shape).

Further, in the first embodiment, switching between the second heat exchanger 20 and the third heat exchanger 26 is included in the concept of the three-way valve even when two two-way valves are used instead of the three-way valve. ..
When two two-way valves are used, the position of the flow pipe 22 from the branch point of the second heat exchanger 20 and the third heat exchanger 26 to the second heat exchanger 20 side, and from the branch point to the third heat exchanger 26 Two-way valves are provided at the side positions.
By opening the two-way valve on the second heat exchanger 20 side from the branch point of the flow pipe 22 and closing the two-way valve on the third heat exchanger 26 side from the branch point, the brine is closed to the first heat exchanger 18 and the second. It can be distributed to and from the heat exchanger 20.
Further, by closing the two-way valve on the second heat exchanger 20 side from the branch point of the flow pipe 22 and opening the two-way valve on the third heat exchanger 26 side from the branch point, the brine is connected to the first heat exchanger 18. It can be distributed to and from the third heat exchanger 26.

10 External conditioner 11 Intake port 12 Flow passage 14 Cooler 16 Heater 18 1st heat exchanger 20 2nd heat exchanger 22 Flow pipe 24 Pump 26 3rd heat exchanger 27 Fan 28 Branch pipe 30 Three-way valve 32 Specified heat Recovery circuit 34 Coolant reheat circuit 36 Compressor 38 Condenser 40 Control unit 42 Expansion valve 44 Temperature sensor 45 Temperature sensor 46 Temperature sensor 50 Discharge valve 52 Supply valve 53 Discharge pipe 54 Supply pipe

Claims (8)

The flow path through which the outside air introduced from the intake that takes in the outside air flows, and
A cooler that cools the outside air taken into the flow path,
A heater arranged on the downstream side in the outside air flow direction of the cooler and heating the outside air that has passed through the cooler, and a heater.
The first heat exchanger arranged on the upstream side in the outside air flow direction of the cooler, the second heat exchanger arranged on the downstream side in the outside air flow direction of the cooler, and the second heat exchanger arranged on the downstream side in the outside air flow direction of the heater. A third heat exchanger, a distribution pipe through which brine that circulates between the first heat exchanger, the second heat exchanger, and the third heat exchanger and exchanges heat with the outside air, and the second. A sensible heat recovery circuit having a three-way valve for switching the flow of brine between the heat exchanger and the third heat exchanger, and a pump provided in the middle of the flow pipe to circulate the brine in the flow pipe.
A control unit for controlling the drive of the pump and switching of the three-way valve is provided.
The cooler and the heater
The refrigerant compressed and sent out by the compressor is distributed, and one of the distributed refrigerants is circulated in the order of a condenser, an expansion valve, a cooler, and a compressor that releases heat to an external heat medium that is an external heat source. It is a part of the configuration of a refrigerant reheat circuit having a circuit and a heating circuit provided so that the other distributed refrigerant passes through the heater and then joins the cooling circuit at the expansion valve.
The control unit
A summer mode in which the three-way valve is operated to circulate brine between the first heat exchanger and the second heat exchanger, and between the first heat exchanger and the third heat exchanger. An external air conditioner characterized in that it can be controlled to switch between the winter mode in which the brine is circulated. The first heat exchanger, the cooler, the second heat exchanger, the heater, and the third heat exchanger are arranged in a straight line in the flow passage along the flow direction of the outside air. The external conditioner according to claim 1, which is characterized. The control unit
The external regulator according to claim 1 or 2, wherein when it is detected that the suction temperature of the refrigerant into the compressor becomes equal to or lower than the evaporation temperature of the refrigerant, the mode is switched from the summer mode to the winter mode. The control unit
In the summer mode, the pump is driven so that the brine flows from the upper part to the lower part of the first heat exchanger.
Any one of claims 1 to 3, wherein in the winter mode, the pump is driven so that brine flows from the lower part to the upper part of the first heat exchanger. External conditioner described in the section. The flow path through which the outside air introduced from the intake that takes in the outside air flows, and
A cooler that cools the outside air taken into the flow path,
A heater arranged on the downstream side in the outside air flow direction of the cooler and heating the outside air that has passed through the cooler, and a heater.
A first heat exchanger arranged on the upstream side in the outside air flow direction of the cooler, a second heat exchanger arranged on the downstream side in the outside air flow direction of the cooler, the first heat exchanger and the second heat exchange. A flow pipe through which brine or hot water that flows between the vessel and exchanges heat with the outside air flows, and a brine or hot water provided in the middle of the flow pipe to exchange the brine or hot water with the first heat exchanger and the second. A sensible heat recovery circuit having a pump to be circulated to and from the heat exchanger is provided.
The cooler and the heater
The refrigerant compressed and sent out by the compressor is distributed, and one of the distributed refrigerants is circulated in the order of a condenser, an expansion valve, a cooler, and a compressor that releases heat to an external heat medium that is an external heat source. It is a part of the configuration of a refrigerant reheat circuit having a circuit and a heating circuit provided so that the other distributed refrigerant passes through the heater and then joins the cooling circuit at the expansion valve.
The sensible heat recovery circuit is provided with a discharge valve for discharging brine or hot water in the flow passage, and a supply valve for supplying brine or hot water in the flow passage.
The control unit
The discharge valve and the supply valve are switched so as to be switchable between a summer mode in which brine is circulated in the sensible heat recovery circuit and a winter mode in which hot water supplied from the outside is circulated in the sensible heat recovery circuit. An external air conditioner characterized by being controlled. 5. The fifth aspect of claim 5, wherein the first heat exchanger, the cooler, the second heat exchanger, and the heater are arranged in a straight line in the flow passage along the flow direction of the outside air. External conditioner. The control unit
The external conditioner according to claim 5 or 6, wherein when it is detected that the suction temperature of the refrigerant into the compressor becomes equal to or lower than the evaporation temperature of the refrigerant, the mode is switched from the summer mode to the winter mode. The control unit
Of claims 5 to 7, the pump is driven so that hot water flows from the lower part to the upper part of the first heat exchanger after the hot water is introduced into the flow pipe. The external conditioner described in any one of the items.

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