JPWO2012121326A1 - Two-way refrigeration cycle equipment - Google Patents

Abstract

The dual refrigeration cycle apparatus includes a heat source side heat exchanger that absorbs heat from an external heat source and a low temperature side refrigeration cycle that includes a low temperature side compressor, a use side heat exchanger that supplies heat to the user side, and a high temperature side compressor. A high temperature side refrigeration cycle, an intermediate heat exchanger for exchanging heat between the refrigerant of the low temperature side refrigeration cycle and the high temperature side refrigeration cycle, a housing on which at least the use side heat exchanger is mounted, and the housing A use side pipe that is mounted and connected to the use side heat exchanger, exchanges heat between the circulating use side fluid and the refrigerant of the high temperature side refrigeration cycle and supplies the heat to the use side, and the use side heat exchange with the use side pipe A bypass passage that is connected in parallel with the heat exchanger and sends the utilization side fluid on the utilization side heat exchanger outlet side of the utilization side piping to the utilization side heat exchanger inlet side, and the flow of the utilization side fluid that circulates in the bypass passage Fluid control means for controlling The has.

Description

  Embodiments of the present invention relate to a binary refrigeration cycle apparatus.

  In refrigeration cycle apparatuses such as air conditioners and heat pump water heaters, a binary refrigeration cycle apparatus having a low temperature side refrigeration cycle and a high temperature side refrigeration cycle may be used to supply high temperature heat to heat utilization equipment. .

  The low temperature side refrigeration cycle and the high temperature side refrigeration cycle of the binary refrigeration cycle apparatus each have a compressor and an expansion device, and are connected so as to be able to exchange heat by an intermediate heat exchanger. And the heat pumped up by the heat source side heat exchanger, which is the low temperature side evaporator provided in the low temperature side refrigeration cycle, through the utilization side heat exchanger, which is the high temperature side condenser provided in the high temperature side refrigeration cycle, Supply high-temperature heat to heat utilization equipment.

JP 08-189714 A

  However, when the temperature of the fluid flowing from the heat utilization device to the utilization side heat exchanger (utilization side) is low, the compression ratio in the high temperature side refrigeration cycle decreases, and the reliability of the compressor decreases. It is known that the reliability of the refrigeration cycle apparatus itself decreases.

  The present invention has been made in view of the above-described problems, and according to the embodiment, a binary refrigeration cycle apparatus that solves the problem of deterioration in reliability of the compressor and, in turn, reliability of the refrigeration cycle apparatus is provided. To do.

  A binary refrigeration cycle apparatus according to an embodiment of the present invention includes a low temperature side refrigeration cycle that absorbs heat from an external heat source, a high temperature side refrigeration cycle that supplies heat to a user side, a low temperature side refrigeration cycle, and the high temperature side refrigeration cycle. An intermediate heat exchanger for exchanging heat of the refrigerant is provided.

  The utilization side heat exchanger is provided with utilization side piping that exchanges heat between the utilization side fluid and the refrigerant of the high temperature side refrigeration cycle and supplies the heat to the utilization side. Moreover, the housing | casing which mounts the utilization side heat exchanger at least is provided. This housing has a bypass passage connected to the use side pipe in parallel with the use side heat exchanger, and allowing the use side fluid on the use side heat exchanger outlet side of the use side pipe to flow to the use side heat exchanger inlet side. It is installed. Furthermore, fluid control means for controlling the flow of the use side fluid flowing in the bypass passage is provided.

1 is a schematic diagram of a binary refrigeration cycle apparatus according to an embodiment of the present invention. The block diagram of the controller which concerns on embodiment of this invention, and its peripheral device. The flowchart figure of the control which concerns on embodiment of this invention.

  Embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
A first embodiment will be described with reference to FIG.

  As shown in FIG. 1, the binary refrigeration cycle apparatus 100 according to the present embodiment is configured such that a heat exchange between a low temperature side refrigeration cycle 6 a and a high temperature side refrigeration cycle 6 b can be performed by an intermediate heat exchanger 5.

  The binary refrigeration cycle apparatus 100 includes a first housing 8a and a second housing 8b.

  In the first housing 8a, a low-temperature side compressor 1a, a low-temperature side four-way valve 2a connected to the low-temperature side compressor 1a via a refrigerant pipe, and heat source side heat exchange for exchanging heat with outside air (external heat source). The vessel 3 and the low temperature side expansion device 4a are sequentially connected by a refrigerant pipe. Moreover, the low-temperature side four-way valve 2a and the low-temperature side expansion device 4a are connected to the transition pipes 9a and 9b, respectively. The transition pipes 9a and 9b are connected to the intermediate heat exchanger 5 provided in the second casing 8b. It is connected to the.

  The heat source side heat exchanger 3 is provided with a blower 11 to promote heat exchange with the outside air. In addition, the heat source side heat exchanger 3 is provided with an outside air temperature sensor 16 which is an external heat source temperature detecting means, and detects the temperature of the outside air supplied to the heat source side heat exchanger 3 by the blower 11. It has become.

  In the second housing 8b, a high temperature side compressor 1b, a high temperature side four-way valve 2b connected to the high temperature side compressor 1b, an intermediate heat exchanger 5, a high temperature side expansion device 4a, and a use side heat exchange are provided. The vessel 7 is sequentially connected by refrigerant piping, and the high temperature side refrigeration cycle 6b is configured.

  High temperature side refrigerant temperature sensors 17a and 17b, which are refrigerant temperature detecting means, are provided on the inlet side and the outlet side of the refrigerant pipe of the usage side heat exchanger 7, and the refrigerant temperature flowing into the usage side heat exchanger 7 is The refrigerant temperature flowing out is detected.

  Here, the intermediate heat exchanger 5 is connected to packed valves 21a and 21b that can be connected to the transition pipes 9a and 9b. By connecting the transition pipes 9a and 9b to the packed valves 21a and 21b, the low temperature is reduced. The side refrigeration cycle 6 a is configured, and the low temperature side refrigeration cycle 6 a and the high temperature side refrigeration cycle 6 b can exchange heat via the intermediate heat exchanger 5.

  Refrigerants having different characteristics are sealed in the low temperature side refrigeration cycle 6a and the high temperature side refrigeration cycle 6b, respectively.

  The type of refrigerant to be sealed varies depending on the use of the binary refrigeration cycle apparatus 100. For example, in the case of a high-temperature heat pump water heater for generating hot water close to 90 ° C. using the use-side heat exchanger 7 as a water heat exchanger, The low-temperature side refrigerant used in the low-temperature side refrigeration cycle 6a is preferably a working refrigerant having good performance even at a low outside air temperature (about −15 ° C.) such as R410A, and the high-temperature side refrigerant used in the high-temperature side refrigeration cycle 6b. A working refrigerant having good performance at a high temperature (about 95 ° C.) such as R134a is preferable.

  The utilization side heat exchanger 7 is connected to a utilization side fluid pipe 18 for supplying heat utilization equipment that uses heat pumped up by the two-way refrigeration cycle apparatus 100.

The use side pipe 18 includes connection ports 23a and 23b to be connected to a heat use device, and a feed pump 10 for sending the use side fluid in the use side fluid pipe 18. 23a, the inlet side branch part 12a, the flow pump 10, the use side heat exchanger 7, the outlet side branch part 12b, and the connection port body 23b are sequentially connected by the use side pipe 18.
Furthermore, the inlet side branching portion 12 a and the outlet side branching portion 12 b are directly connected by a bypass passage 13, and the bypass passage 13 is connected to the usage side pipe 18 in parallel with the usage side heat exchanger 7. A flow control valve 14 is provided in the middle of the bypass passage 13.

  The fluid control means in this embodiment controls the flow rate of the use-side fluid flowing through the bypass passage 13 by controlling the opening degree of the flow rate control valve 14.

  When the feed-side pump 10 provided between the inlet-side branch part 12a and the use-side heat exchanger 7 is operated during the flow of the use-side fluid, the inlet-side branch part 12a, the use-side heat is connected from the connection port 23a. The use side fluid is sent to the connection port body 23b through the exchanger 7 and the outlet side branching portion 12b sequentially. The flow direction of the use side fluid is indicated by a broken line arrow in FIG.

  Since the feed pump 10 is provided in the section between the inlet side branching portion 12a and the use side heat exchanger 7, the flow direction of the use side fluid in the bypass passage 13 when the flow control valve 14 is opened. Is the direction from the outlet branch 12b to the inlet branch 12a. In addition, the inlet side branch part 12a, the outlet side branch part 12b, the feed pump 10, and the bypass passage 13 are mounted in the second housing 8b.

  A water temperature sensor 15 as a use side fluid temperature detecting means is provided in a section between the feed pump 10 and the use side heat exchanger 7 of the use side fluid pipe 18, and the use flowing into the use side heat exchanger 7. The temperature of the side fluid is detected.

  Warm water, brine, or the like for supplying heat to the heat utilization device is enclosed in the utilization side fluid piping 18 and is distributed.

  The outside air temperature sensor 16, the high temperature side refrigerant temperature sensors 17a and 17b, and the water temperature sensor 15 are connected to the controller 23, and the outside air temperature, the refrigerant temperature of the high temperature side refrigeration cycle, the hot water flowing into the use side heat exchanger 7, The temperature of the use side fluid such as brine is detected.

  The second casing 8b is provided with an electrical component box 22 for controlling the operation of the two-way refrigeration cycle apparatus 100.

  The electrical component box 22 includes an inverter circuit (not shown) that drives the low temperature side compressor 1a and the high temperature side compressor 1b, the opening of the low temperature side expansion device 4 and the high temperature side expansion device 10, the low temperature side four-way valve, and the high temperature side. A controller 23 that controls switching of the four-way valve 9 is provided. By these inverter circuit and controller 23, the low temperature side refrigeration cycle 7 and the high temperature side refrigeration cycle 13 are controlled so as to be operated under optimum operating conditions.

  The flow of the refrigerant during the heating operation of the binary refrigeration cycle apparatus 100 is shown by solid line arrows in FIG.

  First, in the low temperature side refrigeration cycle 7, the low temperature side refrigerant passes through the low temperature side four-way valve 2, the low temperature side flow path of the intermediate heat exchanger 5, the low temperature side expansion device 4a, and the heat source side heat exchanger 3 from the low temperature side compressor 1a. It passes sequentially and returns from the low temperature side four-way valve 2 to the low temperature side compressor 1a. Similarly, in the high temperature side refrigeration cycle 6b, the high temperature side refrigerant is compressed by the high temperature side compressor 1b, the high temperature side refrigerant is the high temperature side four-way valve 2b, the use side heat exchanger 7, the high temperature side expansion device 4b, and the intermediate heat exchange. It passes through the high temperature side flow path of the vessel 5 in sequence and returns from the high temperature side four-way valve 2b to the high temperature side compressor 1b.

  At this time, the low temperature side refrigerant evaporates in the heat source side heat exchanger 3 and condenses on the low temperature side of the intermediate heat exchanger 5. Further, the high temperature side refrigerant is condensed in the use side heat exchanger 7 to supply warm heat to the hot water or brine in the use side piping 18 on the use side, and the high temperature side expansion of the intermediate heat exchanger 5 is performed on the high temperature side. The liquid refrigerant decompressed by the apparatus 4b evaporates and absorbs the condensation heat of the low-temperature side refrigerant as the evaporation heat.

  In the use side pipe 18, the use side fluid fed by the feed pump 10 flows.

  Here, when the temperature of the utilization side fluid flowing into the utilization side heat exchanger 7 is extremely low, the temperature of the high temperature side refrigerant in the utilization side heat exchanger 7 becomes lower than the predetermined temperature Tb1, and the high temperature side compressor 1b The compression ratio decreases. If the compressor is operated in a state where the compression ratio is lowered, the reliability of the compressor is lowered.

  As shown in the block diagram of FIG. 2, the controller 23 provided in the electrical component box 22 of the two-way refrigeration cycle apparatus 100 includes a water temperature sensor 15, an outside air temperature sensor 16, a high temperature side refrigerant temperature sensor 17a, 17b and the flow control valve 14 are connected.

  When the temperature of the utilization side fluid supplied from the heat utilization device to the utilization side heat exchanger 7 is low, the flow control valve 14 of the bypass passage 13 is opened, and the utilization side fluid flowing out from the utilization side heat exchanger 7 is removed. Utilization of intermediate temperature by feeding from the outlet side branch part 12b to the inlet side branch part 12a via the bypass passage 13 and newly mixing with the usage side fluid flowing into the usage side heat exchanger 7 from the connection port body 23a It is made to flow into the utilization side heat exchanger 7 as a side fluid.

  Next, the control of the flow control valve 14 in the controller 23 will be described with reference to the flowchart of FIG.

  First, during operation of the two-way refrigeration cycle apparatus 100, the controller 23 detects the outside air temperature T 0 detected by the outdoor temperature sensor 16 and the use side fluid temperature sensor 15 provided on the inlet side of the use side heat exchanger 7. It is determined whether or not the difference (Tw−T0) from the temperature Tw of the use-side fluid detected in step S is equal to or lower than a predetermined temperature Ta (step S201).

  Here, when the difference between the detected outside air temperature T0 and the temperature Tw of the use side fluid is larger than the predetermined temperature Ta (No in step S201), the flow control valve 14 of the bypass circuit 13 is closed (step S205) and used. All the use-side fluid flowing out from the side heat exchanger 7 is sent to the heat-using device.

  On the other hand, when the difference between the outside air temperature T0 and the temperature Tw of the use-side fluid is equal to or lower than the predetermined temperature Ta (Yes in step S201), the flow control valve 14 of the bypass circuit 13 is opened by a predetermined opening (step S202). ), A part of the utilization side fluid flowing out from the utilization side heat exchanger 7 is sent to the utilization side fluid inlet of the utilization side heat exchanger 7 via the bypass circuit 13. As a result, the high-temperature use-side fluid that has flowed out of the use-side heat exchanger 7 is mixed with the low-temperature use-side fluid supplied from the heat-using device, becomes an intermediate temperature, and flows into the use-side heat exchanger 7.

  Next, the average temperature of the high-temperature side refrigerant temperatures Ts1 and Ts2 on the inflow side and the outflow side is calculated to the use-side heat exchanger 7 detected by the two high-temperature side refrigerant temperature sensors 17a and 17b, and this average temperature is calculated on the high temperature side. This is an approximate value of the refrigerant condensation temperature Ts. Then, it is determined whether or not the condensation temperature Ts is within a range of predetermined temperatures Tb1 to Tb2 (where Tb1 <Tb2) (steps S203 and S204).

  That is, it is determined whether or not the condensing temperature Ts of the high-temperature side refrigerant is equal to or higher than Tb1 (step S203). When the condensing temperature Ts of the high-temperature side refrigerant is lower than Tb1 (No in step S203), the flow control valve 14 is increased (step S206), and then the process returns to step S203.

  On the other hand, when the condensation temperature Ts of the high-temperature side refrigerant is equal to or higher than Tb1 (Yes in Step S203), it is determined whether or not the condensation temperature Ts of the high-temperature side refrigerant is equal to or lower than Tb2 (Step S204). When the condensation temperature Ts of the high temperature side refrigerant is higher than Tb2 (No in step S204), the opening degree of the flow control valve 14 is decreased (step S207), and the process returns to step S203.

  Thereafter, when the condensing temperature Ts of the high-temperature side refrigerant of the use side heat exchanger 7 is within the range of the predetermined temperatures Tb1 to Tb2 (Yes in Step S203 and Yes in Step S204), the opening degree of the flow control valve 14 is maintained. However, the process returns to step S201.

  As described above, when the temperature condition becomes a low compression ratio operation from the temperature difference between the outdoor air temperature that is an external heat source and the use side fluid temperature that flows into the use side heat exchanger, the flow control valve 14 is opened, the utilization side fluid after heating is mixed with the utilization side fluid supplied to the utilization side heat exchanger 7, and the temperature of the utilization side fluid flowing into the utilization side heat exchanger is increased. It is possible to avoid the temperature condition that causes the compression ratio operation.

  Further, by detecting the temperature of the high-temperature side refrigerant in the use side heat exchanger 7, it is determined whether the operation is at a low compression ratio, and the opening degree of the flow control valve 14 provided in the bypass passage 13 is controlled. Thereby, the temperature of the utilization side fluid supplied to the utilization side heat exchanger 7 can be raised to the optimal temperature which does not become a low compression ratio operation.

  By performing the configuration and control as described above, a decrease in the condensation temperature of the use side heat exchanger 7 can be suppressed, and a decrease in the compression ratio can be suppressed. Thereby, the fall of the reliability of the compressor which occurs in a low compression ratio state can be prevented, and the reliability fall of the two-way refrigerating cycle apparatus 100 can be prevented by extension.

  As in the above-described embodiment, the two-stage refrigeration cycle apparatus 100 is configured by dividing the first casing and the second casing, so that the installation location can be flexibly handled. For example, when a sufficient outdoor installation space cannot be secured, the first housing having the heat source side heat exchanger 3 is arranged outdoors, and the second housing having the use side heat exchanger is arranged indoors. Can do.

  In the above embodiment, the low-temperature side casing 8a and the high-temperature side casing 8b are separately configured. However, the present invention is not limited to this, and a single casing may include a high-temperature refrigeration cycle and a low-temperature refrigeration cycle. good.

  Moreover, in the said embodiment, although the fluid control means which controls the flow volume of the utilization side fluid which distribute | circulates the bypass passage 13 was set as control of the opening degree of the flow control valve 14, other control means may be used. For example, at least one of the inlet side branch portion 12a and the outlet side branch portion 12b may be a three-way valve, and the opening degree of the three-way valve may be controlled as a flow control valve.

  The present invention is not limited to the above embodiment. Furthermore, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiments of the present invention. For example, you may delete some components from all the components shown by embodiment of this invention. Furthermore, you may combine the component covering different embodiment suitably.

DESCRIPTION OF SYMBOLS 1a ... Low temperature side compressor, 1b ... High temperature side compressor, 2a ... Low temperature side four way valve, 2b ... High temperature side four way valve, 3 ... Heat source side heat exchanger, 4a ... Low temperature side expansion device, 4b ... High temperature side expansion device, 5 ... Intermediate heat exchanger, 6a ... Low temperature side refrigeration cycle, 6b ... High temperature side refrigeration cycle, 7 ... Usage side heat exchanger, 8a ... Low temperature side housing, 8b ... High temperature side housing, 9a, 9b ... Transition piping, DESCRIPTION OF SYMBOLS 10 ... Feed pump, 12a ... Inlet side branch part, 12b ... Outlet side branch part, 13 ... Bypass passage, 22 ... Electrical component box, 15 ... Usage side temperature detection means, 16 ... Outdoor air temperature sensor, 17a, 17b ... High temperature side refrigerant temperature sensor, 18 ... use side piping, 100 ... two-way refrigeration cycle apparatus

Claims (4)

A low temperature side refrigeration cycle comprising a heat source side heat exchanger that absorbs heat from an external heat source and a low temperature side compressor;
A high-temperature side refrigeration cycle comprising a utilization-side heat exchanger for supplying heat to the utilization side and a high-temperature side compressor;
An intermediate heat exchanger for exchanging heat between the refrigerant of the low temperature side refrigeration cycle and the high temperature side refrigeration cycle;
A housing in which at least the use-side heat exchanger is mounted;
Mounted on the housing, connected to the use side heat exchanger, and exchanges heat between the circulating use side fluid and the refrigerant of the high temperature side refrigeration cycle to supply to the use side; and to the use side pipe A bypass passage connected in parallel with the use side heat exchanger and for sending the use side fluid on the use side heat exchanger outlet side of the use side piping to the use side heat exchanger inlet side;
A dual refrigeration cycle apparatus comprising fluid control means for controlling a flow of a use-side fluid flowing through the bypass passage.   The fluid control means controls the flow of the use side fluid flowing through the bypass passage so that the condensation temperature of the refrigerant in the high temperature side refrigeration cycle is lowered and the high temperature side compressor does not operate at a low compression ratio. The two-stage refrigeration cycle apparatus according to claim 1.   The fluid control means includes: a utilization side fluid temperature detection means for detecting a utilization side fluid temperature flowing into the utilization side heat exchanger; and an external heat source temperature that is provided in the heat source side heat exchanger and detects the temperature of the external heat source. A flow rate control valve configured to change a flow rate in the bypass passage, and a use-side fluid temperature detected by the use-side fluid temperature detection unit, and a temperature of the external heat source detected by the external heat source temperature detection unit 2. The dual refrigeration cycle apparatus according to claim 1, wherein the flow rate control valve is controlled to be opened when a difference between the first flow rate control valve and the second flow rate becomes a predetermined value or less.   The fluid control means includes refrigerant temperature detection means for detecting a refrigerant temperature of a high temperature side refrigeration cycle flowing into the use side heat exchanger, and a flow rate control valve for changing a flow rate in the bypass passage, and the refrigerant temperature detection 2. The binary control according to claim 1, wherein when the condensing temperature of the refrigerant in the high temperature side refrigeration cycle detected by the means is lower than a predetermined temperature, control is performed to increase the opening of the flow control valve. Refrigeration cycle equipment.

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