JP2012072949A - Water heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water heater with a refrigeration cycle that exhibits high efficiency both in a normal cycle and a gas injection cycle.SOLUTION: A control unit 100 controls the operation of a heat pump cycle 9 and a second expansion valve 6, to enable a normal cycle operation where refrigerants circulate through the heat pump cycle 9 and a gas injection cycle operation where refrigerants circulate through both the heat pump cycle 9 and the gas injection cycle 8. The control unit 100 implements the gas injection cycle when the outside air temperature is lower than a predetermined outside air determination temperature, and when supply of water circulating through a radiator 2 or refrigerants circulating through the heat pump cycle 9 satisfy predetermined gas injection criteria.

Description

  The present invention provides a hot water supply apparatus including a refrigeration cycle having a gas injection cycle for injecting a gas refrigerant into a compressor.

  Conventionally, for example, a technique described in Patent Document 1 is known as a refrigeration cycle having this type of gas injection function. The prior art described in Patent Document 1 is a two-stage compression refrigeration cycle apparatus including a low-stage compressor and a high-stage compressor, and a discharge side of a low-stage compressor and an intake side of a high-stage compressor. And a gas injection pipe connecting the liquid receiver to the middle of the pipe, and the saturated gas refrigerant of the liquid receiver is sucked into the high-stage compressor. A refrigeration cycle apparatus having such a gas injection function contributes to improving the efficiency of the refrigeration cycle, and is particularly useful for measures against heating loads in cold regions.

JP 2007-10282 A

  In the above prior art, the gas injection cycle operation is performed during cooling or heating operation. However, when the related art is applied to a heating device and a hot water supply device, for example, when the gas injection cycle operation is performed when the outside air temperature is high and the boiling water temperature is low, the discharge refrigerant temperature of the compressor decreases. End up. For this reason, the heating capacity cannot be ensured, and for example, it is difficult to obtain a high heating capacity or to boil high-temperature hot water, and the efficiency due to being carried out in a situation where the gas injection cycle operation is not suitable. There is a problem of deterioration.

  Then, an object of this invention is to provide the hot water supply apparatus provided with the refrigerating cycle which can exhibit high efficiency in each of a normal cycle and a gas injection cycle.

In order to achieve the above object, the following technical means are adopted. That is, the invention relating to the hot water supply apparatus according to claim 1 includes a compressor (1) having a low-pressure suction part (1a) for sucking low-pressure refrigerant and an intermediate-pressure suction part (1b) for sucking intermediate-pressure gas refrigerant. ), A radiator (2) that heat-exchanges the refrigerant discharged from the compressor and the water flowing through the circulation circuit (41) to heat the water, and a first decompression device that decompresses the refrigerant downstream of the radiator (4) A refrigeration cycle device (9) configured by annularly connecting an evaporator (5) for evaporating the decompressed refrigerant and an intermediate pressure branched from between the radiator and the first decompression device A gas injection cycle (8) including a gas injection flow path (8a) connected to the suction section (1b), a second pressure reducing device (6) for depressurizing a refrigerant flowing through the gas injection flow path (8a), and a refrigeration Cycle device (9) and second decompression device (6) It is possible to perform normal cycle operation in which the refrigerant circulates in the refrigeration cycle device (9) and gas injection cycle operation in which the refrigerant circulates in both the refrigeration cycle device (9) and the gas injection cycle (8) by controlling the operation. A control device (100),
When the outside air temperature is equal to or lower than a predetermined outside air determination temperature, the control device (100) further includes a gas injection in which a supply water flowing through the radiator (2) or a refrigerant circulating through the refrigeration cycle apparatus is determined in advance. When the determination condition is satisfied, a gas injection cycle operation is performed.

  According to the present invention, the gas injection cycle operation is performed only when the outside air temperature is a low temperature that is equal to or lower than the outside air judgment temperature and when the predetermined gas injection judgment condition is satisfied. be able to. Thereby, the hot water supply apparatus can perform the operation switching which can exhibit high efficiency in each of the normal cycle and the gas injection cycle. Therefore, gas injection cycle operation is performed only under conditions that exert advantageous effects from the viewpoint of heating capacity and efficiency, and otherwise, heating and hot water supply are performed by normal cycle operation, so that the capacity is maximized. A hot water supply device is obtained.

  The invention according to claim 2 is characterized in that the predetermined gas injection determination condition is satisfied when the temperature of the water supply flowing into the radiator (2) is equal to or higher than a predetermined water supply determination temperature. According to the present invention, a region that is good at gas injection cycle operation can be appropriately detected by simple determination, which contributes to optimal cycle operation control.

  The invention described in claim 3 is characterized in that the predetermined gas injection determination condition is satisfied when the temperature of the refrigerant at the outlet of the radiator (2) is equal to or higher than a predetermined high-pressure refrigerant determination temperature. According to the present invention, a region that is good at gas injection cycle operation can be appropriately detected by simple determination using the refrigerant temperature at the radiator outlet as a determination parameter, which contributes to optimal cycle operation control. Furthermore, since control using the refrigerant temperature at the radiator outlet related to the high-pressure side of the refrigerant is performed, it is possible to contribute to the ease of manufacturing the control program specifications in the hot water supply apparatus.

  According to the invention of claim 4, the control device (100) is a refrigerant when the feed water temperature flowing into the radiator (2) is equal to or higher than a predetermined feed water judgment temperature, and at the outlet of the evaporator (5). When the temperature is equal to or lower than a predetermined low-pressure refrigerant determination temperature, the gas injection cycle operation is performed. According to the present invention, the region that is good at the gas injection cycle operation can be appropriately detected by simple determination using the refrigerant temperature at the outlet of the evaporator as a determination parameter, which contributes to the operation control of the optimum cycle. Furthermore, since control is performed using the refrigerant temperature at the evaporator outlet related to the low-pressure side of the refrigerant, it is possible to produce a control program specification that makes it easier to clearly detect the good situation of the gas injection cycle.

  According to the fifth aspect of the present invention, the control device (100) is configured so that the supply water temperature flowing into the radiator (2) is equal to or higher than a predetermined supply water determination temperature and the refrigerant of the evaporator (5) The gas injection cycle operation is performed when the pressure is equal to or lower than a predetermined low-pressure refrigerant determination pressure. According to the present invention, a region that is good at gas injection cycle operation can be appropriately detected by simple determination using the refrigerant pressure of the evaporator as a determination parameter, which contributes to optimal cycle operation control. Furthermore, since the control using the refrigerant pressure of the evaporator related to the low pressure side is performed, it is possible to produce a control program specification that can clearly detect the special situation of the gas injection cycle, compared to the case of using the refrigerant temperature.

The invention according to claim 6 is a first internal heat exchanger (3) for exchanging heat between the refrigerant flowing between the radiator and the first pressure reducing device and the refrigerant flowing between the evaporator and the compressor,
A second internal heat exchanger that exchanges heat between the refrigerant flowing between the radiator and the first internal heat exchanger and the refrigerant flowing between the second decompression device and the compressor in the gas injection flow path (8a). (7).

  According to this invention, by providing the first internal heat exchanger that exchanges heat between the high-pressure refrigerant and the low-pressure refrigerant, the low-pressure refrigerant is heated to improve efficiency, and the refrigerant that flows out of the radiator By providing the second internal heat exchanger for heat exchange, the enthalpy difference in the evaporator can be increased, which contributes to an improvement in efficiency (COP).

  In addition, the code | symbol in the bracket | parenthesis of each said means is an example which shows a corresponding relationship with the specific means of embodiment mentioned later.

It is a block diagram which shows schematic structure of the hot water supply apparatus of 1st Embodiment to which this invention is applied. It is the flowchart which showed the switching control of the driving cycle which concerns on 1st Embodiment. It is the flowchart which showed the switching control of the driving cycle which concerns on 2nd Embodiment. It is the flowchart which showed the switching control of the driving cycle which concerns on 3rd Embodiment. It is the flowchart which showed the switching control of the driving cycle which concerns on 4th Embodiment.

  A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration.

(First embodiment)
A first embodiment, which is an embodiment of the present invention, will be described with reference to FIGS. Drawing 1 is a lineblock diagram showing the schematic structure of the hot-water supply device of a 1st embodiment. FIG. 2 is a flowchart showing operation cycle switching control according to the first embodiment.

  As shown in FIG. 1, the hot water supply apparatus of the present embodiment is mainly composed of a heat pump unit 10 that is a heating apparatus, and a tank unit 40 that performs hot water supply and heating using a heating operation by the heat pump unit 10. System.

  That is, when the hot water is discharged to a bathtub or shower, or when heated by the floor heating panel 48, the amount of hot water stored in the tank 40a of the tank unit 40 by the heat pump unit 10 is used to adjust the temperature of the hot water in the tank 40a. The hot water in the tank 40a is supplied to the hot water channel of the floor heating panel 48 to perform floor heating. And the hot water supply device gives priority to energy saving by utilizing the heating operation performed in a predetermined low-priced time zone (for example, late-night fee time zone) that is a cheaper price system than the daytime electricity rate. The amount of heat that satisfies the request is stored in the tank 40a.

The heat pump unit 10 includes a heat pump cycle 9 which is an example of a refrigeration cycle apparatus and a gas injection cycle 8, and is a vapor compression refrigeration cycle using CO ₂ as a refrigerant. The heat pump cycle 9 is connected to a compressor 1 having a low-pressure suction part 1a for sucking low-pressure refrigerant and an intermediate-pressure suction part 1b for sucking intermediate-pressure gas refrigerant, and a refrigerant discharged from the compressor 1 and a tank 40a. The heat radiator 2 that heat-exchanges the water flowing through the heated circulation circuit 41 and heats the water, and the first expansion valve 4 that depressurizes the refrigerant on the downstream side of the radiator 2 (first decompression device). And the evaporator 5 for evaporating the refrigerant decompressed by the first expansion valve 4 are connected in a ring shape. The gas injection cycle 8 is a circuit including a gas injection flow path 8 a that branches from between the radiator 2 and the first expansion valve 4 and is connected to the intermediate pressure suction portion 1 b of the compressor 1. The gas injection flow path 8a is provided with a second expansion valve 6 (second pressure reducing device) that depressurizes the refrigerant flowing through the gas injection flow path 8a.

  Further, the heat pump cycle 9 is provided with a first internal heat exchanger 3 for exchanging heat between the refrigerant flowing between the radiator 2 and the first expansion valve 4 and the refrigerant flowing between the evaporator 5 and the compressor 1. It has been. Further, the heat pump unit 10 heats the refrigerant flowing between the radiator 2 and the first internal heat exchanger 3 and the refrigerant flowing between the second expansion valve 6 and the compressor 1 in the gas injection flow path 8a. A second internal heat exchanger 7 to be replaced is provided. Moreover, the evaporator 5 is a structure which heat-exchanges a refrigerant | coolant and external air, and the fan (not shown) which ventilates external air is arrange | positioned in the vicinity.

  An outside air temperature sensor 27 is provided at or near the outer wall of the outdoor unit of the heat pump unit 10 to detect the outside air temperature around the heat pump unit 10. The heat pump cycle 9 includes sensors 21 to 24 that detect the refrigerant temperature at each installation location. That is, the refrigerant discharge temperature sensor 23 is provided in the outlet-side flow path of the compressor 1 and detects the discharge refrigerant temperature discharged from the compressor 1. The radiator outlet refrigerant temperature sensor 21 is provided in the outlet-side flow path of the radiator 2 and detects the refrigerant temperature that has flowed out of the radiator 2. The evaporator outlet refrigerant temperature sensor 22 is provided in the outlet-side flow path of the evaporator 5 and detects the refrigerant temperature that has flowed out of the evaporator 5. The intermediate pressure refrigerant temperature sensor 24 is provided on the inlet side of the intermediate pressure suction portion 1 b of the compressor 1, and is depressurized by the second expansion valve 6 in the intermediate pressure refrigerant temperature sucked into the compressor 1 or in the gas injection cycle 8. The temperature of the gas refrigerant is detected.

  The refrigerant discharge pressure sensor 30 is provided in the outlet-side flow path of the compressor 1 and detects the discharge refrigerant pressure discharged from the compressor 1. The evaporator pressure sensor 31 is provided at the outlet of the evaporator 5 and detects the refrigerant pressure flowing through the evaporator 5. The intermediate pressure refrigerant pressure sensor 32 is provided on the inlet side of the intermediate pressure suction portion 1 b of the compressor 1, and is depressurized by the second expansion valve 6 in the intermediate pressure refrigerant pressure sucked into the compressor 1 or in the gas injection cycle 8. The pressure of the gas refrigerant is detected.

  The tank 40a is a metal tank excellent in corrosion resistance, and a heat insulating material (not shown) is disposed on the outer peripheral portion thereof, so that hot water for hot water supply can be kept warm for a long time. A plurality of tank thermistors 26, which are sensors for detecting the amount of hot water and the temperature of the stored hot water, are provided on the outer wall surface of the tank 40a, and the plurality of tank thermistors 26 are arranged at equal intervals in the vertical direction. Arranged in order from the top. The detected temperature signals of these tank thermistors 26 are respectively input to the input circuit of the control device 100, and can detect the temperature of the fluid in the tank and the amount of hot water at each water level. Therefore, the control device 100 can detect the boundary position between the hot water heated in the upper part of the tank 40a and the water before heated in the lower part of the tank 40a based on the temperature information from the tank thermistor 26. The amount of heat stored in the tank 40a can be calculated by calculating the detection result of the temperature of the predetermined water level and the amount of hot water with a predetermined program.

  Further, the tank 40a is heated so that hot water heated by the heat pump unit 10 is circulated in a circuit connecting the water supply pipe 45 for supplying tap water to the inside of the tank 40a and the radiator 2 and the inside of the tank 40a. The circulation circuit 41 is connected to a piping system including a hot water supply pipe 46 connected to the hot water supply terminal.

  The heating circulation circuit 41 is a circuit formed by connecting the upper and lower parts of the tank 40a and the water flow passage of the radiator 2, and includes a pump 42 for forcibly circulating the water in the tank 40a, and a heating circulation circuit 47. And three-way valves 43 and 44 capable of switching the flow path of the hot water stored in the tank 40a. Furthermore, the radiator water supply temperature sensor 25 is provided in the inlet-side flow path of the radiator 2 in the heating circuit 41 and detects the temperature of the water supplied to the radiator 2 from the tank 40a. The radiator outlet water temperature sensor 20 is provided in the outlet side flow path of the radiator 2 in the heating circuit 41 and detects the water temperature heated by the radiator 2 and returned to the tank 40a.

  The heating circulation circuit 47 is a circuit formed by connecting the upper and lower parts of the tank 40a and the hot water passage of the floor heating panel 48, and includes a pump 49 that forcibly circulates hot water in the tank 40a. Yes. When performing floor heating, in order to circulate the hot water in the tank 40a to the heating circulation circuit 47, the three-way valve 43 and the three-way valve 44 both close the passage on the heating circulation circuit 41 side and heat the circulation circuit 47. Open the side passage. On the contrary, when the hot water in the tank 40a is heated and stored by the heat pump unit 10, the three-way valve 43 and the three-way valve 44 are both for heating in order to circulate the hot water in the tank 40a to the heating circuit 41. The passage on the circulation circuit 41 side is opened and the passage on the heating circulation circuit 47 side is closed.

  The hot water supply apparatus includes a control device 100 that controls various operations. The control device 100 performs various operations using input signals to which detection signals from various sensors 20 to 27, 30 to 32, etc., signals from various switches on the remote controller 50, and the like are input, and signals from the input circuits. And an output circuit for outputting a control signal for controlling each device constituting the hot water supply device based on a calculation result by the microcomputer. The microcomputer has a built-in ROM, RAM, etc. as storage means for storing detection data of each thermistor, various calculation results, and the like, and has a preset control program and an updatable control program.

  The control device 100 transmits a control signal to the heat pump unit 10 and the tank unit 40 to thereby discharge the compressor 1, the opening degrees of the first expansion valve 4 and the second expansion valve 6, and the three-way valves 43 and 44. In addition to controlling the opening and closing of the passages, the flow rates by the pumps 42 and 49, etc., the operation states of the units 10 and 40 are received. The control device 100 performs normal cycle operation, gas injection cycle operation, heating operation for storing hot water in the tank 40a, hot water supply operation, floor heating operation, and the like, which will be described later.

  Next, the operation of the hot water supply device will be described. First, a normal cycle operation in which the second expansion valve 6 is closed will be described. The normal cycle operation is an operation in which a refrigerant flow that circulates in the heat pump cycle 9 is formed, and the outside air temperature is higher than, for example, 7 ° C., or the water supply temperature (hereinafter, simply referred to as the water supply to the radiator 2 from the tank 40a). This operation is carried out when at least one of the water supply temperature is less than 35 ° C., for example. In the normal cycle operation, the second expansion valve 6 is closed and the gas refrigerant is not injected into the intermediate pressure suction portion 1b of the compressor 1 through the gas injection cycle 8.

  The refrigerant sucked into the compressor 1 is discharged as high-pressure refrigerant, and is radiated to the heating circuit 41 side by the radiator 2 to decrease the temperature. At this time, if the high-pressure side refrigerant pressure is equal to or higher than the critical pressure, the refrigerant radiates heat at a reduced temperature without undergoing a gas-liquid phase transition in a supercritical state. If the high-pressure side refrigerant pressure is equal to or lower than the critical pressure, the refrigerant radiates heat while liquefying. Heat supplied from the refrigerant is supplied to the water in the heating circuit 41 on the load side to heat the hot water supply water. The high-pressure and low-temperature refrigerant flowing out of the radiator 2 after heating passes through the first internal heat exchanger 3 and is cooled by exchanging heat with the low-pressure refrigerant flowing out of the evaporator 5.

  The high-pressure refrigerant that has passed through the first internal heat exchanger 3 is reduced in pressure to a low-pressure gas-liquid two-phase state by the first expansion valve 4. The decompressed refrigerant flows into the evaporator 5, where it absorbs heat from the air outside the heat pump unit 10 and is evaporated into gas. The low-pressure refrigerant that has exited the evaporator 5 passes through the first internal heat exchanger 3, exchanges heat with the high-pressure refrigerant that passes through the high-pressure channel, and is superheated into gas, and then is sucked into the compressor 1. Cycles to form a normal cycle.

  On the other hand, when the outside air temperature is, for example, 7 ° C. or lower and the feed water temperature is, for example, 35 ° C. or higher, the operation is performed so that the refrigerant flows through the gas injection cycle 8. This is called gas injection operation. In this operation, the second expansion valve 6 is opened, and gas refrigerant is injected into the intermediate pressure suction portion 1b of the compressor 1 through the gas injection flow path 8a.

  During the gas injection cycle operation, a part of the refrigerant flowing out of the radiator 2 branches to the gas injection flow path 8a, and is reduced to an intermediate pressure by the second expansion valve 6 to be in a gas-liquid two-phase state. Heat is exchanged with the high-pressure refrigerant that has passed through the heat exchanger 7 and has flowed out of the radiator 2, and is heated to become gas refrigerant and flows into the intermediate pressure suction portion 1b of the compressor 1. The gas refrigerant that has flowed into the intermediate pressure suction portion 1 b joins with the refrigerant sucked from the low pressure suction portion 1 a of the compressor 1 and is compressed by the compressor 1.

  Thus, during the gas injection cycle operation, the compressor 1 sucks the low-pressure refrigerant and the intermediate-pressure refrigerant, so that the suction pressure of the compressor 1 rises and contributes to reducing the compression work. Therefore, since the COP (efficiency) of the heat pump cycle is improved, for example, if the compression work is made equal, the heat dissipation capability in the radiator 2 can be improved, and the heating capability and the like can be improved. Further, in the second internal heat exchanger 7, the high-pressure refrigerant flowing out of the radiator 2 and the gas refrigerant exchange heat, so that the enthalpy difference in the evaporator 5 can be increased, and the efficiency can be improved.

  Further, on the heating circuit 41 side, the heat radiated from the refrigerant in the radiator 2 is guided from the lower part of the tank 40a by the pump 42 and is conveyed to the heating circuit 41 side of the radiator 2 or the like. It is given to the load side medium. The heated load-side medium flows into the upper part of the tank 40a and is stored in the tank 40a.

  The control operation of the water heater having the above configuration will be described with reference to FIG. FIG. 2 is a flowchart showing operation cycle switching control in the hot water supply apparatus. Each step shown in FIG. 2 is executed by the control device 100. First, in step 10, the outside air temperature Toa detected by the outside air temperature sensor 27 is not more than a preset outside air determination temperature KToa (for example, 7 ° C. or less), and the water supply temperature Twi detected by the radiator water supply temperature sensor 25. Is equal to or higher than a preset water supply determination temperature KTwi (for example, 35 ° C. or higher) (one of the gas injection determination conditions) is determined. Step 10 is a step of determining whether or not the gas injection cycle operation can be performed by determining whether or not the current state is an operation state in which the efficiency can be improved by the gas injection cycle.

  If it is determined in step 10 that any one of the conditions is not satisfied, that is, “NO”, it is determined that the above-described normal cycle operation is performed, the second expansion valve 6 is fully closed, The opening degree of the first expansion valve 4 is controlled (step 20).

  Then, if both conditions are satisfied in step 10, that is, it is determined as “YES”, the second expansion valve 6 is opened, the first expansion valve 4 and the first expansion valve 4 are set so as to perform the above-described gas injection cycle operation. The opening degree of the second expansion valve 6 is controlled (step 30). Thereafter, while the present control is continued, the control device 100 continuously performs the determination in step 10 and performs the normal cycle operation or the gas injection cycle operation based on the determination in step 10. .

  The opening control of the first expansion valve 4 and the second expansion valve 6 in the normal cycle operation and gas injection cycle operation will be described. Based on operation command information transmitted from the remote controller 50, for example, information such as heating capacity and boiling temperature, and information on detection signals from the radiator water supply temperature sensor 25, the outside air temperature sensor 27, etc., the target value of the intake superheat degree is determined. Then, control is performed so that the suction superheat degree during operation becomes the target suction superheat degree. For example, the first expansion valve is set so that the suction superheat degree calculated using the suction refrigerant temperature of the compressor 1 and the evaporative refrigerant temperature detected by the evaporator outlet refrigerant temperature sensor 22 becomes a predetermined target suction superheat degree. 4 is controlled.

  Further, by using the temperature of the intermediate pressure refrigerant detected by the intermediate pressure refrigerant temperature sensor 24 and the intermediate pressure of the suction refrigerant detected by the intermediate pressure refrigerant pressure sensor 32, the degree of dryness for determining the gas state of the refrigerant is determined, The opening degree of the second expansion valve 6 is controlled so that the gas state (evaporation state) of the refrigerant has an appropriate degree of superheat, and the amount of refrigerant is adjusted. In addition, when the refrigerant discharge temperature sensor 23 is detected, the outlet refrigerant temperature can be used for the opening degree control of the second expansion valve 6. For example, when the opening degree of the second expansion valve 6 is increased, the discharge refrigerant temperature of the compressor 1 is reduced.

  The effects brought about by the hot water supply apparatus of the present embodiment will be described below. In the hot water supply device, the control device 100 controls the operation of the heat pump cycle 9 and the second expansion valve 6, and the normal cycle operation in which the refrigerant circulates in the heat pump cycle 9 and the refrigerant in the heat pump cycle 9 and the gas injection cycle 8. The gas injection cycle operation that circulates both can be performed. When the outside air temperature is equal to or lower than a predetermined outside air determination temperature, the control device 100 further satisfies a predetermined gas injection determination condition for water supplied through the radiator 2 or refrigerant circulating through the heat pump cycle 9. When the gas injection cycle operation is carried out.

  According to this, the gas injection cycle operation is performed only when the outside air temperature is a low temperature and when the usage condition where a predetermined gas injection determination condition is satisfied is satisfied. As a result, the gas injection cycle operation is performed under conditions that are good in terms of heating capacity and efficiency, and in other cases, heating and hot water supply are performed by normal cycle operation, so that the capacity of the heat pump unit 10 is maximized. A hot water supply device is obtained.

  Further, the predetermined gas injection determination condition is satisfied when the temperature Twi of the water supplied into the radiator 2 is equal to or higher than a predetermined water supply determination temperature KTwi. As described above, the processing using the feed water temperature Twi as a determination parameter makes it possible to easily detect a region where the gas injection cycle operation is good and the execution timing of the operation simply and with good accuracy.

  According to the hot water supply apparatus of the present embodiment, hot water heated by the heat pump unit 10 that performs normal cycle operation and gas injection cycle operation according to the above determination process is stored in the tank 40a and stored in the tank 40a. The amount of heat is used to supply hot water required for hot water supply terminals and other heating equipment such as floor heating. Thus, both the hot water supply and heating functions can be provided by a single hot water supply device without requiring both a heat pump cycle exclusively for hot water operation and a heat pump cycle exclusively for heating operation. Moreover, the installation space and cost of the hot water supply device can be reduced.

(Second Embodiment)
In the second embodiment, another control mode for the flowchart of the operation cycle switching control described in the first embodiment will be described with reference to FIG. FIG. 3 is a flowchart showing operation cycle switching control according to the second embodiment. In addition, the hot water supply apparatus which implements the flowchart of 2nd Embodiment is the structure similar to the hot water supply apparatus demonstrated in 1st Embodiment,
The operation and effect, and the execution procedure of normal cycle operation and gas injection cycle operation are also the same.

  Each step shown in FIG. 3 is executed by the control device 100. As shown in FIG. 3, first, in step 10a, the outside air temperature Toa detected by the outside air temperature sensor 27 is not more than a preset outside air determination temperature KToa (for example, 7 ° C. or less), and a radiator outlet refrigerant temperature sensor. It is determined whether or not both of the refrigerant temperatures Trex flowing out of the radiator 2 detected in 21 are equal to or higher than a preset high-pressure refrigerant determination temperature KTlex (one of gas injection determination conditions) are satisfied. Step 10a is a step of determining whether or not the gas injection cycle operation can be performed by determining whether or not the current state is an operation state where the efficiency can be improved by the gas injection cycle.

  Then, if any one of the conditions is not satisfied in step 10a, that is, if it is determined as “NO”, it is determined that the above normal cycle operation is performed, the second expansion valve 6 is fully closed, The opening degree of the first expansion valve 4 is controlled as described above (step 20).

  Then, if both conditions are satisfied in step 10a, that is, if it is determined as “YES”, the second expansion valve 6 is opened so that the above-described gas injection cycle operation is performed, and the first expansion valve 4 and The opening degree of the second expansion valve 6 is controlled as described above (step 30). Thereafter, while the present control is continued, the control device 100 continuously performs the determination in step 10a, and performs the normal cycle operation or the gas injection cycle operation based on the determination in step 10a. .

  According to the present embodiment, the predetermined gas injection determination condition is satisfied when the refrigerant temperature Trex at the outlet of the radiator 2 is equal to or higher than a predetermined high-pressure refrigerant determination temperature KTlex. According to such a determination process, it is possible to simplify the timing of performing the gas injection cycle operation by determining the refrigerant temperature Trex at the outlet of the radiator 2 as a determination parameter for a situation where the effect of the gas injection cycle operation is obtained. It can be detected appropriately with good accuracy. Furthermore, since control using the refrigerant temperature Trex at the outlet of the radiator 2 related to the high pressure side of the refrigerant is performed, it is easy to create a control program specification in the hot water supply apparatus. Further, since the refrigerant temperature Trex on the high pressure side is used as a determination parameter, there is an effect that it is possible to detect refrigerant leakage in the cycle.

(Third embodiment)
In the third embodiment, another control mode for the flowchart of the operation cycle switching control described in the first embodiment will be described with reference to FIG. FIG. 4 is a flowchart showing operation cycle switching control according to the third embodiment. In addition, the hot water supply apparatus which implements the flowchart of 3rd Embodiment is the structure similar to the hot water supply apparatus demonstrated in 1st Embodiment,
The operation and effect, and the execution procedure of normal cycle operation and gas injection cycle operation are also the same.

  Each step shown in FIG. 4 is executed by the control device 100. As shown in FIG. 4, first, in step 10b, the feed water temperature Twi detected by the radiator feed water temperature sensor 25 is equal to or higher than a preset feed water determination temperature KTwi (for example, 35 ° C. or higher), and the evaporator outlet refrigerant. Both the refrigerant temperature Teex flowing out of the evaporator 5 detected by the temperature sensor 22 is not more than a preset low-pressure refrigerant determination temperature KTeex (for example, 5 ° C. or less) (one of gas injection determination conditions) are satisfied. It is determined whether or not. Step 10b is a step of determining whether or not the gas injection cycle operation can be performed by determining whether or not the current state is an operation state in which the efficiency can be improved by the gas injection cycle.

  Then, if any one of the conditions is not satisfied in step 10b, that is, if it is determined as “NO”, it is determined that the above normal cycle operation is performed, the second expansion valve 6 is fully closed, The opening degree of the first expansion valve 4 is controlled as described above (step 20).

  And if both conditions are satisfied in Step 10b, that is, if it is determined as “YES”, the second expansion valve 6 is opened so that the above-described gas injection cycle operation is performed, and the first expansion valve 4 and The opening degree of the second expansion valve 6 is controlled as described above (step 30). Thereafter, while the present control is continued, the control device 100 continuously executes the determination in step 10b, and performs the normal cycle operation or the gas injection cycle operation based on the determination in step 10b. .

  According to the present embodiment, the control device 100 is configured such that the feed water temperature Twi flowing into the radiator 2 is equal to or higher than a predetermined feed water determination temperature KTwi, and the refrigerant temperature Teex at the outlet of the evaporator 5 is a predetermined low pressure. It is satisfied when the refrigerant judgment temperature is equal to or lower than KTeex. According to such a determination process, the situation in which the effect of the gas injection cycle operation can be obtained is determined by setting the refrigerant temperature Teex at the outlet of the evaporator 5 as a determination parameter, thereby simplifying the execution timing of the gas injection cycle operation, and It can be detected appropriately with good accuracy. Further, by determining using the refrigerant temperature at the outlet of the evaporator 5, the state of the refrigerant on the low pressure side serves as a determination material, and therefore, it is possible to more clearly detect the special situation of the gas injection cycle.

(Fourth embodiment)
4th Embodiment demonstrates the other control form with respect to the flowchart of the switching control of the driving cycle demonstrated in 1st Embodiment with reference to FIG. FIG. 5 is a flowchart showing operation cycle switching control according to the fourth embodiment. In addition, the hot-water supply apparatus which implements the flowchart of 4th Embodiment is the structure similar to the hot-water supply apparatus demonstrated in 1st Embodiment,
The operation and effect, and the execution procedure of normal cycle operation and gas injection cycle operation are also the same.

  Each step shown in FIG. 5 is executed by the control device 100. As shown in FIG. 5, first, in step 10c, the water supply temperature Twi detected by the radiator water supply temperature sensor 25 is equal to or higher than a preset water supply determination temperature KTwi (for example, 35 ° C. or higher), and an evaporator pressure sensor. Both the pressure Pe of the refrigerant flowing through the evaporator 5 detected at 31 is not more than a preset low-pressure refrigerant determination pressure KPe (for example, 3.5 MPa or less) (one of the gas injection determination conditions) is satisfied. It is determined whether or not. Step 10c is a step of determining whether or not the gas injection cycle operation can be performed by determining whether or not the current state is an operation state in which the efficiency can be improved by the gas injection cycle.

  Then, if any one of the conditions is not satisfied in step 10c, that is, if it is determined as “NO”, it is determined that the above-described normal cycle operation is performed, the second expansion valve 6 is fully closed, The opening degree of the first expansion valve 4 is controlled as described above (step 20).

  Then, if both conditions are satisfied in step 10c, that is, if it is determined as “YES”, the second expansion valve 6 is opened so that the above-described gas injection cycle operation is performed, and the first expansion valve 4 and The opening degree of the second expansion valve 6 is controlled as described above (step 30). Thereafter, while the present control is continued, the control device 100 continuously performs the determination in step 10c, and performs the normal cycle operation or the gas injection cycle operation based on the determination in step 10c. .

  According to the present embodiment, the control device 100 is a low-pressure refrigerant in which the feed water temperature Twi flowing into the radiator 2 is equal to or higher than a predetermined feed water determination temperature KTwi and the refrigerant pressure Pe in the evaporator 5 is predetermined. It is satisfied when the pressure is equal to or lower than the determination pressure KPe. According to such a determination process, a situation in which the effect of the gas injection cycle operation is good can be obtained by using the refrigerant pressure Pe of the evaporator as a determination parameter, thereby making the execution timing of the gas injection cycle operation simple and favorable. It can be detected appropriately with accuracy. Furthermore, the determination using the refrigerant pressure of the evaporator 5 makes the determination of the gas injection cycle good condition because the refrigerant state on the low pressure side serves as a determination material.

(Other embodiments)
The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

  Each operation cycle described in the above embodiment is provided in the remote controller 50, and a user operates a button with a predetermined name that is intuitively easy to understand such as “efficiency priority”, “automatic”, and “automatic”. Thus, it is executed according to the calculation result of the control device 100.

  Moreover, each operation cycle demonstrated in the said embodiment performs a predetermined mode by the centralized control panel which enables centralized management of these operation | movement, for example in the several hot-water supply apparatus installed in the apartment house etc. May be implemented by transmitting a command to the hot water supply device.

  Further, the working refrigerant flowing through the heat pump cycle of the heat pump unit 10 is not limited to carbon dioxide, but may be other refrigerants such as Freon.

  Moreover, in the hot water supply apparatus of the said embodiment, although the single tank 40a is used, it is not limited to this, A some multi-can tank may be sufficient.

DESCRIPTION OF SYMBOLS 1 ... Compressor 1a ... Low pressure suction part 1b ... Intermediate pressure suction part 2 ... Radiator 3 ... 1st internal heat exchanger 4 ... 1st expansion valve (1st decompression device)
5 ... Evaporator 6 ... Second expansion valve (second decompression device)
8 ... Gas injection cycle 8a ... Gas injection flow path 9 ... Heat pump cycle (refrigeration cycle device)
41. Circulation circuit for heating (circulation circuit)
100 ... Control device

Claims (6)

A compressor (1) having a low-pressure suction part (1a) for sucking low-pressure refrigerant and an intermediate-pressure suction part (1b) for sucking intermediate-pressure gas refrigerant, a refrigerant discharged from the compressor and a circulation circuit (41 ) A heat radiator (2) for exchanging heat with water flowing through the heat generator, a first decompressor (4) for decompressing the refrigerant downstream of the radiator, and an evaporation for evaporating the decompressed refrigerant A refrigeration cycle apparatus (9) configured by annularly connecting a vessel (5);
A gas injection cycle (8) including a gas injection flow path (8a) branched from between the radiator and the first pressure reducing device and connected to the intermediate pressure suction portion (1b);
A second decompression device (6) for decompressing the refrigerant flowing through the gas injection flow path (8a);
The operation of the refrigeration cycle device (9) and the second decompression device (6) is controlled so that the refrigerant circulates through the refrigeration cycle device (9) and the refrigerant is the refrigeration cycle device (9). And a control device (100) capable of performing gas injection cycle operation for circulating both of the gas injection cycle (8),
With
When the outside air temperature is equal to or lower than a predetermined outside air determination temperature, the control device (100) further determines the supply water flowing through the radiator (2) or the refrigerant circulating through the refrigeration cycle device. When the gas injection determination condition is satisfied, the gas injection cycle operation is performed.   The hot water supply apparatus according to claim 1, wherein the predetermined gas injection determination condition is satisfied when a water supply temperature flowing into the radiator (2) is equal to or higher than a predetermined water supply determination temperature.   The hot water supply apparatus according to claim 1, wherein the predetermined gas injection determination condition is satisfied when the temperature of the refrigerant at the outlet of the radiator (2) is equal to or higher than a predetermined high-pressure refrigerant determination temperature. A compressor (1) having a low-pressure suction part (1a) for sucking low-pressure refrigerant and an intermediate-pressure suction part (1b) for sucking intermediate-pressure gas refrigerant, a refrigerant discharged from the compressor and a circulation circuit (41 ) A heat radiator (2) for exchanging heat with water flowing through the heat generator, a first decompressor (4) for decompressing the refrigerant downstream of the radiator, and an evaporation for evaporating the decompressed refrigerant A refrigeration cycle apparatus (9) configured by annularly connecting a vessel (5);
A gas injection cycle (8) including a gas injection flow path (8a) branched from between the radiator and the first pressure reducing device and connected to the intermediate pressure suction portion (1b);
A second decompression device (6) for decompressing the refrigerant flowing through the gas injection flow path (8a);
The operation of the refrigeration cycle device (9) and the second decompression device (6) is controlled so that the refrigerant circulates through the refrigeration cycle device (9) and the refrigerant is the refrigeration cycle device (9). And a control device (100) capable of performing gas injection cycle operation for circulating both of the gas injection cycle (8),
With
The control device (100) is configured such that the temperature of the water supply flowing into the radiator (2) is equal to or higher than a predetermined water supply determination temperature, and the temperature of the refrigerant at the outlet of the evaporator (5) is predetermined. The hot water supply apparatus, wherein the gas injection cycle operation is performed when the temperature is equal to or lower than a low-pressure refrigerant determination temperature. A compressor (1) having a low-pressure suction part (1a) for sucking low-pressure refrigerant and an intermediate-pressure suction part (1b) for sucking intermediate-pressure gas refrigerant, a refrigerant discharged from the compressor and a circulation circuit (41 ) A heat radiator (2) for exchanging heat with water flowing through the heat generator, a first decompressor (4) for decompressing the refrigerant downstream of the radiator, and an evaporation for evaporating the decompressed refrigerant A refrigeration cycle apparatus (9) configured by annularly connecting a vessel (5);
A gas injection cycle (8) including a gas injection flow path (8a) branched from between the radiator and the first pressure reducing device and connected to the intermediate pressure suction portion (1b);
A second decompression device (6) for decompressing the refrigerant flowing through the gas injection flow path (8a);
The operation of the refrigeration cycle device (9) and the second decompression device (6) is controlled so that the refrigerant circulates through the refrigeration cycle device (9) and the refrigerant is the refrigeration cycle device (9). And a control device (100) capable of performing gas injection cycle operation for circulating both of the gas injection cycle (8),
With
The control device (100) is a low pressure in which the coolant pressure in the evaporator (5) is a predetermined low pressure when the feed water temperature flowing into the radiator (2) is equal to or higher than a predetermined feed water determination temperature. The hot water supply apparatus that performs the gas injection cycle operation when the pressure is equal to or lower than a refrigerant determination pressure. A first internal heat exchanger (3) for exchanging heat between the refrigerant flowing between the radiator and the first pressure reducing device and the refrigerant flowing between the evaporator and the compressor;
Heat exchange is performed between the refrigerant flowing between the radiator and the first internal heat exchanger and the refrigerant flowing between the second decompression device and the compressor in the gas injection flow path (8a). A second internal heat exchanger (7);
The hot water supply device according to any one of claims 1 to 5, further comprising:

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