JPH01142356A - Air-conditioner - Google Patents

Abstract

PURPOSE:To prevent the reduction of a room temperature by a method wherein the hot gas of refrigerant from a compressor is passed directly through an outdoor heat exchanger to effect defrosting operation, in an air-conditioner in which a heat pump unit is combined with a brine circuit employing a heat accumulator. CONSTITUTION:A heat pump unit 1 is constituted principally of a compressor 3, provided in a refrigerant circuit 2, a four-way valve 4, the refrigerant side heat exchanger 6 of a brine/refrigerant heat exchanger 5, an expansion valve 7 and an outdoor heat exchanger 8, and is provided with a solenoid valve 9. A brine circuit 11 is constituted principally of the brine side heat exchanger 12 of the brine/refrigerant heat exchanger 5, a heat accumulator 13, a pump 14 and an indoor heat exchanger 15. Heat is accumulated in the heat accumulator 13 of the brine circuit 11 by the heating operation of the heat pump unit 1; thereafter, the heat is radiated from the indoor heat exchanger 15 upon the rise-up of heating under a condition that a predetermined amount of heat remains in the heat accumulator 13 while brine in the heat accumulator 13 is circulated through the indoor heat exchanger 15 upon defrosting operation, whereby the reduction of a room temperature upon the defrosting operation may be prevented.

Description

[Detailed description of the invention]

[Object of the Invention] (Industrial Application Field) The present invention relates to an air conditioner that combines a heat pump unit and a brine circuit using a heat storage device. (Conventional technology) Heat pumps generally include a compressor, a four-way valve, an expansion valve,
The basic components are indoor and outdoor heat exchangers, and during cooling, the refrigerant is circulated through the compressor indoor heat exchanger ~ r# valve ~ outdoor heat exchanger ~ compressor by switching the four-way valve, and during heating, the refrigerant is circulated through the compressor outdoor heat exchanger. It is circulated through a path from the container to the expansion valve to the indoor heat exchanger to the compressor. On the other hand, a regenerative heat pump has been considered that uses such a heat pump to store heat in brine in a heat storage device, and when the stored energy is used, drives a pump to circulate the brine to an indoor heat exchanger to perform heating and cooling. There is. With this heat storage type beat pump, only the pump needs to be driven during heating and cooling using heat storage, that is, during heat dissipation operation, so compared to a general heat pump that drives a compressor and performs heat storage operation, the power consumption is 1
It is as small as 75 to 1/10. Therefore, by performing the heat storage operation during the daytime peak power load and performing the heat storage operation using late-night power, there is an advantage that it helps to level out the power usage during the day. FIG. 7 shows the configuration of an air conditioner using a conventional regenerative heat pump. The heat pump unit 1 includes a compressor 3 provided at the refrigerant port N2, a four-way valve 4, and a brine/refrigerant heat exchanger 5. Refrigerant side heat exchanger 6, expansion valve 7
and an outdoor heat exchanger 8, and is further provided with a solenoid valve 9 used during defrosting operation. Brine/refrigerant heat exchange B5 has water or brine heat ii
. is fulfilled. The brine circuit 11 mainly includes a brine-side heat exchanger 12 of the brine/refrigerant heat exchanger 5, a heat storage device 13, a pump 14, and an outdoor heat exchanger 15, and further includes a solenoid valve 16.
~20 are provided. In the air conditioner with such a configuration, the heat pump unit 1 is operated IIJjj, and the refrigerant side heat exchanger 6 is used as a condenser, and the brine side heat exchanger 1 is transferred via heat *10.
Heat is stored in the heat storage fi 13 by heating the fi 2 and driving the pump 14 to circulate brine in the brine circuit 11. When the heating starts, the heat pump unit 1 is turned off, and the pump 14 is driven to transfer the high temperature brine flowing out from the heat storage device 13 to the indoor heat exchanger 1.
On the other hand, during heating operation, the heat pump unit 1 is operated in the same manner as during heat storage operation, and the pump 12 is operated with the solenoid valve 18 open and the heat storage device 13 bypassed. By driving the brine to circulate brine in the brine circuit 11, the heat of the refrigerant circuit 2 is transmitted to the indoor heat exchanger 15 via the brine/refrigerant heat exchanger 6 and the brine circuit 11. By the way, in the heat pump unit 1. During the heating operation, it is necessary to remove the frost adhering to the outdoor heat exchanger J[8].During this defrosting operation, the solenoid valve 9 is opened and the hot gas of the refrigerant from the compressor 3 is transferred to the outdoor heat exchanger J[8]. Since the heat is not transferred to the indoor heat exchanger 15 from the refrigerant port M2, the room temperature drops. (Problem to be solved by the invention) In this way, the conventional regenerative heat pump The air conditioner used had a problem in that the heat from the heat pump unit could no longer be used for heating during defrosting operation in the middle of room operation, resulting in a drop in room temperature.The present invention solves these problems and An object of the present invention is to provide an air conditioner capable of keeping indoor air temperature almost constant during frost operation.

[Structure of the invention]

(Means for Solving the Problems) In order to achieve the above object, the present invention provides an air conditioner that combines a heat pump unit and a brine circuit, in which the heat pump unit is operated for heating to store heat in the brine in the heat storage device. After doing it. At the start of heating, the heat of the brine in the heat storage device is radiated from the indoor heat exchanger while leaving a predetermined amount of heat, and during the defrosting operation during DI cell operation, the brine in the heat storage device is circulated to the indoor heat exchanger. It is characterized by having a means. (Function) Defrosting operation is performed by passing the hot refrigerant gas from the compressor directly to the outdoor heat exchanger, so there is no heat transfer from the heat pump unit to the indoor heat exchanger, but instead the heat is transferred to the heat storage device. The high temperature brine left inside is circulated to the indoor heat exchanger, thereby preventing the room temperature from dropping. (Example) Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 shows the configuration of an air conditioner according to an embodiment of the present invention. In FIG. 1, a heat pump unit 1 includes a compressor 3 provided in a refrigerant circuit 2, a four-way valve 4, and a refrigerant side heat exchanger 6 of a brine/refrigerant heat exchanger 5, similar to the conventional device shown in FIG. , an expansion valve 7 and an outdoor heat exchanger 8, and is further provided with a solenoid valve 9 used during defrosting operation. The brine/refrigerant heat exchanger 5 is filled with a heat medium 10 such as water or brine. The brine circuit 11 mainly includes a brine side heat exchanger 12 of the brine/refrigerant heat exchanger 5, a heat storage device 13, a pump 14, and an outdoor heat exchanger 15. Connected to the heat storage device 13 are electromagnetic valves 21 to 24 for switching the direction of brine passing therethrough depending on the operating mode. Further, a flow rate regulating valve 25 is installed in a brine bypass circuit provided in parallel with the indoor heat exchanger 15. A plurality (n) of temperature sensors 27 are installed in the heat storage device 13 to detect the remaining 5lffl of brine. In addition, brine side heat exchanger 1 of brine/refrigerant heat exchange B5
Temperature sensors 28, 29, 30, and 31 are also installed at the inlet and outlet of the heat exchanger 2 and the inlet and outlet of the indoor heat exchanger 15, respectively. The outputs of the temperature sensors 27 to 31 are led to a control circuit 35. This control circuit 35 controls the pressure regulator 3, the four-way valve 4, the electromagnetic valves 9.21 to 24.26, the pump 14, and the flow rate adjustment valve 25. Next, the operation of the air conditioner of this embodiment will be explained for each operation mode with reference to FIGS. 2 to 6. Figure 2 shows the compressor 3, four-way valve 4, and solenoid valve 9.21 to 21 for each operation mode.
24.26 shows the control pattern of the pump 14 and the current amount adjustment valve 25. Moreover, FIG. 3 is a flowchart showing the flow of operations from the start of operation. 1N In heat storage operation, the heat pump unit 1 is in heating operation, that is, the four-way valve 4 is in the state shown in the figure (this state is positive).
Combret refrigerant 3 ~ four-way valve 4 ~ outdoor heat exchanger 8 ~ #
, through the path from the eye valve 7 to the refrigerant side heat exchanger 6 of the brine/refrigerant heat exchanger 5 to the compressor 3, and by operating the refrigerant side heat exchanger 6 as a condenser, the brine side is passed through the heat medium 10. Heat exchanger 12 is heated. Then, in the brine circuit 11, the solenoid valves 21 and 24 are opened, and the solenoid valves 22 and 22 are opened.
3 is used as a lever, and the pump 14 is driven to circulate the brine, thereby storing heat in the heat storage device 13. Heat storage device 1
Brine flows into No. 3 from above, and heat is stored from above. At this time, the solenoid valve 26 is opened to prevent the indoor heat exchanger 15 from being heated by the brine. Here, this heat storage operation is carried out in step S1 of FIG. 3 when the temperatures C1 to TCn measured by the temperature sensor 27 in the heat storage device 13 are less than the maximum heat storage utilization temperature Th (step 82). Then, the heat storage operation is continued until the temperature TC1 to TC7cn in the heat storage device 13 becomes equal to or higher than the maximum heat storage utilization temperature Th (step 83). Note that the temperature sensor 27 in the heat storage device 13 is installed nfA in the vertical direction as shown in FIG. Now, assuming that the heat accumulator 13 is filled with high temperature brine 32 and low temperature brine 33, the high temperature brine moves to the top, so the interface between the high temperature brine and the low temperature brine 3
4 is formed. The temperature sensors 27 are installed at minimum intervals that allow them to detect the temperature gradient in the vicinity of this boundary surface 34. Next, in step S3 of FIG. 3, Tcl~Tcn≧
When Th is reached, the process shifts to heat dissipation operation in step S4. 11 In mutual heat dissipation operation, compressor 3 of heat pump unit 1
At the same time, the pump 14 is turned on in the brine circuit 11, the solenoid valves 22 and 23°26 are opened, and the solenoid valves 21
．． 24 is used as a lever, the high temperature brine flowing out from above the heat storage device 13 is flowed into the indoor heat exchanger 15, and 11 cells are heated. Here, in the present invention, the remaining hot water Q in the heat storage device 13
(Remaining amount of high-temperature brine) is detected by the temperature sensor 27, and the heat dissipation operation is stopped while leaving high-temperature brine equivalent to the amount of heat required for several defrosting operations (step 85). Subsequently, in step S6, the heat pump unit 1
@ Cell capacity and indoor heat exchange! ! The heating load of the heater 15 is compared with the heating load, and if the heating load is larger, the process moves to step S7 and direct air operation is performed. In addition, @room capacity is calculated by pump flow fM) X (brine specific heat)
Calculated by a1-Ta21. 1 q 1 direct m operation means direct@m operation, in which the heat pump unit 1 is operated for heating without using the heat in the heat storage device 13, and the heat is transferred to the indoor heat exchanger 15 via the brine circuit 11. . In this case, the pump 14 is turned on, the solenoid valves 21, 23, and 26 are closed, and the solenoid valves 22, 24 are closed, allowing the brine to bypass the heat storage device 13, and the brine circuit 11
circulate within. When it is determined in step S6 that the heating load of the indoor heat exchanger 15 is smaller than the WFM capacity of the heat pump unit 1, or as a result of the direct air operation described in t, the @m load becomes smaller than the heating capacity of the heat pump unit 1 in step S8. If it is determined that this is the case, the process moves to direct heat storage operation in step S9. 1 Disaster 1j The direct heat storage operation is a heating operation in which the excess heat of the heat pump unit 1 is stored in the heat storage device 13 because the [Wm load of the indoor heat exchanger 15 is smaller than the heating capacity of the heat pump unit 1. At this time, brine cycle 2a1
1, the pump 14 is turned on, the solenoid valve 21.23.2
4.26 is open and the solenoid valve 22 is closed. In this direct heat storage operation, in a state where it is determined in step 810 that the heating capacity is larger than the 11 store load, when the temperature IC1 to Tcn in the heat storage device 13 becomes equal to or higher than the maximum heat storage utilization temperature Th in step 811, step S4 is performed. Return to heat dissipation operation. In step 810, the heating capacity is I!
! When the load becomes smaller than the cell load, the process shifts to direct m operation in step S7. On the other hand, if it is determined in step S812 that frost has formed on the outdoor heat exchanger 8 while the heating capacity is lower than the heating load in step S8, defrosting operation in step 813 is performed. ! 111 The defrosting operation is an operation to remove the frost that has adhered to the outdoor heat exchanger 38 during the heating operation of the heat pump unit 1, and @magnetic valve 9
The hot refrigerant gas from the compressor 3 is passed directly to the outdoor heat exchanger 8. At this time, heat is not transferred from the refrigerant side heat exchanger 6 to the 7 line side heat exchanger 12, so in the present invention, in the brine circuit 11, the solenoid valves 22, 23, 26 are connected between the solenoid valves 22, 23, and By setting the valves 21 and 24 as leaps and turning on the pump 14, the residual hot water left in the heat storage device 13 during the previous heat radiation operation is radiated by the indoor heat exchanger 15 during one defrosting period. It is equivalent to the amount of heatG
) The indoor heat exchanger 15 is caused to flow out from above the heat storage WA 13.
flow to. This prevents a decrease in vfA during defrosting operation. Here, as shown in FIG. 5, if the outlet temperature Ta2 of the indoor heat exchanger 15 is higher than the normal heating air rjA degree 78O in step 821, the flow control valve 25 moves to step 822 and is controlled in the opening direction. When Ta2 is lower than TaO, it is controlled in the closed direction. This keeps the indoor temperature almost constant. Note that the flow rate regulating valve 25 is also controlled in other operating modes as shown in FIG. 5 to keep the room temperature constant. However, it is desirable to fully open the am adjustment valve 25 during heat storage operation. FIG. 6 is a diagram for explaining the present invention in detail, where the horizontal axis shows the elapsed time from the start of heat storage operation, and the vertical axis shows the room temperature,
The heat storage ff1Q and the amount Q' of heat storage are taken. In the figure, since the storage Faffl is equal to the total amount of heat radiation, the following relationship exists. (heat storage) = (heat dissipation amount at startup) + (defrosting M5
1) Furthermore, the room temperature T rises rapidly at the start of AM operation, remains constant thereafter, and remains constant during defrosting. The broken line in FIG. 6 shows the change in room temperature in the conventional example, and the change in room temperature is observed at the start-up of heating and at the time of defrosting. ■5F + Song 1 of the invention According to the present invention, after the heat pump unit is operated for heating and heat is stored in the heat storage device of the brine circuit, a predetermined amount of heat is left in the heat storage device at the start of heating and the heat is radiated from the indoor heat exchanger. By circulating the brine in the heat storage device to the indoor heat exchanger during the defrosting operation, it is possible to prevent the room temperature from decreasing during the defrosting operation.

[Brief explanation of the drawing]

Fig. 1 is a configuration diagram of an air conditioner according to an embodiment of the present invention, Fig. 2 is a diagram showing control patterns for each operation mode of the embodiment, and Fig. 3 is a diagram showing control patterns from the start of operation of the embodiment. FIG. 4 is a flowchart showing the details of the heat storage device and temperature sensor in the same embodiment. FIG. 5 is a flowchart showing the control of the flow rate regulating valve in the same embodiment. FIG. 7, which is a diagram for explaining the present invention in detail, is a configuration diagram of a conventional air conditioner. 1... Heat pump unit, 2... Refrigerant circuit, 3
... Compressor, 4... Four-way valve, 5... Brine/refrigerant heat exchanger, 6... Refrigerant side heat exchanger, 7...
i Magnetic valve, 8... Outdoor heat exchanger, 9... N magnetic piece, 10
...Heat medium, 11...Brine circuit, 12...Brine side heat exchanger, 13...Regenerator, 14...Pump, 15...Indoor heat exchanger, 21-24... ·solenoid valve,
25...Flow rate adjustment valve, 26...Solenoid valve, 27-31
Temperature sensor, 32... High temperature brine, 33... Low temperature brine, 34... Boundary surface, 35... Control circuit. Applicant's representative Patent attorney Takehiko Suzue Figure 3 Figure 4 Figure 5 Figure 7

Claims (2)

[Claims] (1) A heat pump unit whose basic components include a compressor, a four-way valve, a refrigerant side heat exchanger of the brine/refrigerant heat exchanger, an expansion valve, and an outdoor heat exchanger, and a brine side heat exchanger of the brine/refrigerant heat exchanger. a brine circuit whose basic components are a heat storage device, a heat storage device, a pump, and an indoor heat exchanger, radiating heat from the indoor heat exchanger while leaving a predetermined amount of heat, and circulating brine in the heat storage device to the indoor heat exchanger during a defrosting operation during a heating operation. air conditioner. (2) The control means detects the remaining amount of high-temperature brine in the heat storage device at the time of heating start-up, and leaves high-temperature brine equivalent to the amount of heat consumed by the indoor heat exchanger during defrosting operation. The air conditioner according to scope 1.