JP5838660B2 - Heat pump water heater - Google Patents

Description

  The present invention relates to a heat pump hot water supply apparatus, and particularly to a technology that can detect refrigerant leakage from a condensation heat exchanger at an early stage when a flammable refrigerant is used.

  Conventionally, a refrigerant circulation circuit in which a compressor, a condensation heat exchanger, an expansion means, and an evaporative heat exchanger are connected in order through a refrigerant circulation pipe, and water supplied to the condensation heat exchanger by a feed water pump is compressed by the compressor. 2. Description of the Related Art There is known a heat pump hot water supply apparatus including a hot water supply circuit that uses heat exchange heat to a target boiling temperature with a high-pressure refrigerant and is used for hot water supply. In such a heat pump hot water supply apparatus, a compressor, a condensing heat exchanger, an expansion means, and an evaporating heat exchanger that constitute the refrigerant circulation circuit are housed in a housing and configured as an outdoor unit (for example, (See Patent Document 1 or Patent Document 2).

  In Patent Document 1, the interior of an outdoor unit cabinet is partitioned into a left fan chamber and a right machine room by a separator placed between them so as to partition each other, and a hot water supply unit cabinet is placed on the outdoor unit cabinet. The condensing heat exchanger and the pump are housed on the left side, and the hot water control box is housed on the right side. An evaporation heat exchanger is disposed in the fan chamber, and a compressor and expansion means are disposed in the machine chamber.

  Further, in Patent Document 2, a condenser heat exchanger is built in the bottom side portion in the casing, and the upper side portion of the bottom side portion is separated from the left fan chamber and the right side by a separator sandwiched in the same manner as described above. The machine room is partitioned and separated from each other.

  Furthermore, in the heat pump device, it has also been proposed to accommodate the heat exchanger in a foam insulation container (see, for example, Patent Document 3).

Japanese Patent Laid-Open No. 3-1057 Japanese Patent No. 46651338 JP 2005-147619 A

  However, in the conventional heat pump hot water supply apparatus, in the unlikely event that the refrigerant leaks from the condensation heat exchanger, there is a disadvantage that it is not possible to grasp the occurrence of the refrigerant leakage unless a considerable amount of refrigerant leaks. . In other words, if the refrigerant used is not flammable, even if some refrigerant leakage occurs, there will be no inconvenience as long as it does not hinder the refrigeration cycle function. There was essentially no means to detect. For this reason, even if refrigerant leakage occurs, the refrigerant leaks by a considerable amount, causing an abnormality in the refrigeration cycle, and the temperature sensor detection value of the refrigerant circulation circuit becomes an abnormal value due to the abnormality of the refrigeration cycle. By showing, it was only possible to grasp the suspicion of refrigerant leakage for the first time. For this reason, even if a refrigerant leak occurs from the condensation heat exchanger, it takes time to detect the occurrence of the refrigerant leak, and as a result, a considerable amount of refrigerant is lost until the detection. It was supposed to allow leakage of the above refrigerant.

  However, when a flammable refrigerant is used as a refrigerant to be charged and used in a heat pump hot water supply apparatus, early detection of the occurrence of refrigerant leakage becomes a particularly important issue.

  The present invention has been made in view of such circumstances, and an object of the present invention is to promptly and reliably prevent occurrence of refrigerant leakage from the condensation heat exchanger in a heat pump water heater using a flammable refrigerant. An object of the present invention is to provide a heat pump hot water supply device that can be detected.

In order to achieve the above object, in the present invention, a refrigerant circulation circuit in which a compressor, a condensation heat exchanger, an expansion means, and an evaporative heat exchanger are sequentially connected by a refrigerant circulation pipe is provided in the casing. As a target, the heat pump water heater using a flammable refrigerant was provided with the following specific items. That is, a horizontal partition plate is disposed so as to partition the top space in the housing in the vertical direction over the entire length range in the left-right direction, while the evaporative heat exchanger and the air blowing means are disposed in the lower space of the horizontal partition plate. A vertical partition plate is disposed so as to be separated from each other in the left-right direction between the blower chamber and the machine chamber in which the compressor and the expansion means are disposed. The condensing heat exchanger is disposed with respect to the top space in a state where the periphery is covered with a heat insulating member, and both of the heat insulating member and the horizontal partition plate penetrate downwardly for refrigerant and hot water. An opening for passing the pipe is formed in communication with the lower space . In addition, a cylindrical passage portion extending downward through the opening portion with respect to the lower space in a state of surrounding the refrigerant and hot water pipes passing through the opening portion, the passage portion having an upper end opening thereof is provided. The opening is formed on the inner bottom surface of the heat retaining member, and the lower end opening is formed integrally with the heat retaining member so as to protrude downward. Then, the lower position of the lower end opening in the front Symbol passage portion, it was decided to dispose the gas sensor for detecting the presence of a flammable refrigerant (claim 1).

In the case of the present invention, the partition space is partitioned so as to partition the top space in the housing, and the condensation heat exchanger is installed in this top space, so that a refrigerant leak from the condensation heat exchanger should occur. Even if it does, early detection of the refrigerant | coolant leakage using the leaked combustible refrigerant | coolant having a heavier specific gravity than air is attained. In other words, when refrigerant leaks from the condensation heat exchanger, the opening is formed so as to penetrate both the heat retaining member and the horizontal partition plate downward, so that the leaked combustible refrigerant passes through the opening and the passage. Tomo When flows down quickly to the lower space Te, it becomes possible to reliably guided to the flammable refrigerant toward the gas sensor is disposed at a lower position of the lower end opening in the passage portion. Thereby, to obtain achieving early detection of refrigerant leaks, ing to be obtained even achieving reliabilized leakage amount of suppression and early deal with the early detection. In addition, by providing the passage portion, it is possible to reliably guide and guide the flow of the flammable refrigerant so that the flammable refrigerant flows down from the opening toward the gas sensor. This can be further improved.

  A guide surface having a downward slope toward the opening can be formed on the inner bottom surface of the heat retaining member of the present invention (claim 2). By doing so, since the combustible refrigerant leaked from the condensation heat exchanger is guided toward the opening along the induction surface, it is possible to quickly collect the leaked combustible refrigerant in the opening, More accurate detection of refrigerant leakage detection and associated leakage reduction

Further, by arranging the control device to the upper position of the lower space, the lower end opening of the passage, can be extended so as to be positioned below at least the control device (claim 3). By doing so, it is possible to prevent the occurrence of a malfunction caused by the contact between the combustible refrigerant and the electronic circuit in the control device, and to protect the control device.

As described above, according to the heat pump hot water supply apparatus of the present invention, the top space in the housing is partitioned by the horizontal partition plate, and the condensation heat exchanger is installed in the top space. Even if a refrigerant leak from the condensing heat exchanger occurs, early detection of the refrigerant leak can be performed using the fact that the leaked combustible refrigerant has a higher specific gravity than air. That is, since an opening that penetrates both the heat retaining member and the horizontal partition plate downward is formed, if a refrigerant leak occurs from the condensation heat exchanger, the leaked combustible refrigerant is removed from the opening and the passage. to together to be able to drop quickly flows into the lower space through, it is possible to reliably guided to the flammable refrigerant toward the gas sensor is disposed at a lower position of the lower end opening in the passage portion. This makes it possible to achieve early detection of refrigerant leaks, Accordingly, ing so it is possible to ensure reduction of the leakage amount of suppression and early action. In addition, by providing the passage portion, the flow of the flammable refrigerant can be guided and guided reliably so that the flammable refrigerant flows down from the opening toward the gas sensor, and the reliability of the early detection of the refrigerant leak is further improved. Can be improved. I follow the case of using a flammable refrigerant as a refrigerant, the early detection of refrigerant leak, it is possible to prevent and avoid the serious disadvantages occur.

  In particular, according to claim 2, by forming a guide surface that is inclined downward toward the opening on the inner bottom surface of the heat retaining member, the flammable refrigerant leaked from the condensation heat exchanger is guided along the guide surface. It can be directed towards the opening, thereby allowing the leaked combustible refrigerant to be quickly collected in the opening. For this reason, it is possible to achieve more certainty such as earlier detection of refrigerant leakage and suppression of the leakage amount associated therewith.

According to the third aspect , when the control device is disposed at the upper position of the lower space, the combustible refrigerant can be obtained by extending the lower end opening of the passage portion so as to be positioned at least below the control device. Therefore, it is possible to protect the control device by preventing the occurrence of a malfunction caused by contact with the electronic circuit or the like in the control device.

It is a schematic diagram of the heat pump hot-water supply apparatus which concerns on embodiment of this invention. It is a perspective view which shows the external appearance of the outdoor unit in which the refrigerant circuit of FIG. 1 was accommodated. It is a front view of the outdoor unit of FIG. FIG. 3 is a cross-sectional explanatory view corresponding to the cross section taken along line AA of FIG. 2, in which details are omitted and the present invention is shown in principle. FIG. 5A is a partially omitted enlarged cross-sectional explanatory view taken along line BB in FIG. 4, and FIG. 5B is a diagram corresponding to FIG. 5A showing another embodiment. It is the elements on larger scale of FIG. 4 shown in the state which abbreviate | omitted one part about the heat retention container and the condensing heat exchanger accommodated in this. It is a perspective view which shows an inside in the state which removed the top | upper surface panel, front panel, and right side panel of the outdoor unit of FIG. It is a disassembled perspective view which shows the state which removed the top | upper surface panel and decomposed | disassembled the heat insulation container and the condensing heat exchanger accommodated in this.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic diagram of a heat pump hot water supply apparatus according to an embodiment of the present invention. This heat pump hot-water supply device is a combination of the refrigerant circulation circuit 1 and the hot-water supply circuit 2, and can heat and heat the water in the hot-water supply circuit 2 using a refrigeration cycle. The refrigerant circulation circuit 1 includes a compressor 11, a condensation heat exchanger (condenser) 12, an expansion valve 13 as an expansion means, and an evaporation heat exchanger (evaporator) 14 connected in order by a refrigerant circulation pipe 15. These are housed in a case 5 to be described later and configured in the form of an outdoor unit 4 (see, for example, FIG. 2 or FIG. 3). As the refrigerant to be circulated in the refrigerant circuit 1, a combustible refrigerant, for example, an HC refrigerant such as propane is used. In the following description, what is simply described as “refrigerant” is this combustible refrigerant. The hot water supply circuit 2 includes a hot water storage tank 21, a water circulation pipe 22 that circulates hot water stored in the hot water storage tank 21 with the condensation heat exchanger, and water from the bottom of the hot water storage tank 21. And a water supply pump 23 that leads from the condensing heat exchanger 12 to the top of the hot water storage tank 21 after heating, and is configured as, for example, a hot water storage unit. Then, the refrigerant circulation circuit 1 and the hot water supply circuit 2 are controlled by the controller 3 so that the water is heated to the target boiling temperature in the condensation heat exchanger 12 and stored in the hot water storage tank 21. The target boiling temperature is directly input and set to the remote controller 31 or is set based on the set hot water temperature input to the remote controller 31.

  The compressor 11 is operated by an electric motor, and the operation of the compressor 11 is controlled by the controller 3 with the rotation speed as an operation control amount. By being compressed by the compressor 11, the refrigerant in a high-temperature gas phase state is discharged from the compressor 11 to the refrigerant circulation pipe 15, the discharge temperature is detected by the discharge temperature sensor 16, and the detected discharge temperature is output to the controller 3. Will be.

  The condensation heat exchanger 12 is configured such that a part of the refrigerant circulation pipe 15 is passed through the inside, and a part of the water circulation pipe 22 is passed through the inside from the reverse direction to exchange heat therebetween. That is, the high-temperature gas-phase refrigerant discharged from the compressor 11 to the refrigerant circulation pipe 15 and the water supplied from the bottom of the hot water storage tank 21 by the water supply pump 23 are heat-exchanged, and the water is heat-exchanged and heated. Thus, the refrigerant whose heat has been removed by the heat exchange condenses.

  The expansion valve 13 depressurizes the refrigerant condensed in the condensation heat exchanger 12. The operation of the expansion valve 13 is controlled by the controller 3 using the opening degree as an operation control amount.

  The evaporative heat exchanger 14 includes a fan 14a that is rotated by a fan motor and blows outside air. The outside air and the refrigerant depressurized by the expansion valve 13 exchange heat to evaporate the refrigerant. It is made to convert into a gaseous-phase state. The refrigerant temperature immediately after leaving the evaporating heat exchanger 14 is detected by the evaporating heat exchanger outlet temperature sensor 17 as the evaporating heat exchanger temperature, and the detected evaporating heat exchanger outlet temperature is output to the controller 3. Become. And the refrigerant | coolant which changed into the gaseous-phase state with the heat exchanger in the evaporative heat exchanger 14 is compressed again in the said compressor 11, and becomes a high-temperature gaseous-phase state.

  On the other hand, in the hot water supply circuit 2, when the water in the hot water storage tank 21 is pumped to the condensation heat exchanger 12 by the operation of the water supply pump 23, before the heat exchange heating by the incoming water temperature sensor 24 in front of the inlet of the condensation heat exchanger 12. The detected incoming water temperature is output to the controller 3. In addition, when the hot water is heated by heat exchange by passing through the condensation heat exchanger 12, the boiling temperature is detected by the hot water temperature sensor 25 on the outlet side of the condensation heat exchanger 12, and the detected boiling temperature is determined by the controller. 3 is output. In addition, the outside air temperature is detected by the outside air temperature sensor 26 and output to the controller 3. The hot water heated by the condensation heat exchanger 12 is returned to the top side of the hot water storage tank 21 and stored, and is used for subsequent hot water supply. If the amount of hot water in the hot water storage tank 21 is reduced by hot water supply, water is supplied accordingly.

  Next, the configuration of the outdoor unit 4 that is a characteristic part in the present embodiment will be described. 2, FIG. 5 (a) and FIG. 6 show examples of the basic structure of the outdoor unit 4, and FIGS. 7 and 8 show examples of the specific structure. Yes. Hereinafter, a detailed description will be given with reference to the basic structural examples of FIGS. 4, 5A, and 6 and the specific structural examples of FIGS.

  The outdoor unit 4 has a main component incorporated in a housing 5 having a substantially rectangular parallelepiped shape. The housing 5 includes a bottom panel 51, a front panel 52, a back panel 53 (see FIG. 5 or 8), a right side panel 54, a left side panel 55, and a top panel 56 placed on the legs 50 and 50. Configured. A vertical partition plate 57 extending in the vertical direction from the bottom panel 51 to a position near the top panel 56 is stood in the housing 5, while the horizontal partition plate 58 is joined to the upper end of the vertical partition plate 57 on the right side. It is provided between the surface panel 54 and the left side panel 55 so as to expand in the left-right direction. The left blowing chamber 61 and the right machine chamber 62 are partitioned by the vertical partition plate 57 in a state of being separated from each other in the left-right direction, and the upper heating chamber 63 is separated from the lower blowing chamber 61 by the horizontal partition plate 58. It is partitioned from the machine room 62 in a state of being partitioned from each other in the vertical direction. With the horizontal partition plate 58 as a boundary, the heating chamber 63 above the horizontal partition plate 58 is partitioned and formed as a space having a considerably lower inner height than the blower chamber 61 and the machine chamber 62 on the lower side, and the horizontal partition plate 58 is formed. The lower blower chamber 61 and the machine chamber 62 are defined as spaces that occupy most of the inner height in the housing 5.

  The ventilation chamber 61 is provided with the evaporative heat exchanger 14 and the fan 14a, and the machine chamber 62 is provided with the compressor 11, the expansion valve 13, and the controller 3 (see FIG. 4 or FIG. 7). In 63, the condensing heat exchanger 12 is accommodated in the heat retaining member 7, and is disposed so as to extend over the upper sides of both the blower chamber 61 and the machine chamber 62 so as to extend substantially in the left-right direction. The evaporative heat exchanger 14 is formed in a plate shape (see the black portion in FIG. 7) bent in a L shape in plan view, and is arranged from the inner surface of the left side panel 55 along the inner surface of the back panel 53. The end portion 141 (see FIG. 4 or 5A) is extended to a position closer to the machine room 62. The fan 14a (see FIG. 4 or FIG. 7) is disposed near the inner surface of the front panel 52 in the blower chamber 61, and exhausts from an opening 521 (see FIG. 2 or FIG. 3) of the front panel 52. . The controller 3 is disposed at the lower surface position of the horizontal partition plate 58 and is installed at the topmost position in the machine room 62. A gas sensor 8 (see FIG. 4 or FIG. 8) is disposed at a predetermined position on the bottom side (bottom panel 51 side) of the machine chamber 62. The gas sensor 8 is installed at a predetermined position determined in relation to the positions of an opening 581 and a passage portion 73 described later, and detects the presence of a leaked combustible refrigerant and outputs it to the controller 3. Yes.

  An opening 581 that allows the machine chamber 62 and the heating chamber 63 to communicate with each other is formed in the horizontal partition plate 58 that is located at one end side of the horizontal partition plate 58 and above the machine chamber 62, and passes through the opening 581. A passage portion 73 (see FIG. 4 or FIG. 8), which will be described later, is inserted from the top to the bottom and extended to the machine chamber 62 side. The heat retaining member 7 covers and heats the condensation heat exchanger 12, and is formed of, for example, expanded polystyrene (EPS) or expandable AS resin. The heat retaining member 7 includes a tray-shaped lower heat retaining member 71 and a lid-shaped upper heat retaining member 72, and covers the lower heat retaining member 71 with the upper heat retaining member 72 from above in a state where the condensation heat exchanger 12 is accommodated. Thus, the condensation heat exchanger 12 can be covered in a substantially sealed state. The lower heat retaining member 71 is integrally formed with a cylindrical passage portion 73 that protrudes downward and extends from a position on one end side (right rear end side in the figure). The passage 73 has an upper end opening 731 that opens to the inner bottom surface of the lower heat retaining member 71, and a lower end opening 732 that extends toward the gas sensor 8 in the machine chamber 62. The water circulation pipe 22 and the refrigerant circulation pipe 15 from the condensation heat exchanger 12 are piped to the machine room 62 through the passage portion 73. In addition, although it is preferable from a viewpoint of protection of the controller 3 which is an electronic device (control apparatus) to open the lower end opening part 732 at least to the position below the controller 3, it extended to the position as close as possible toward the gas sensor 8. Opening at the position is preferable from the viewpoint of guiding a leaked refrigerant described later.

  The lower heat retaining member 71 includes a support portion 710 (see FIG. 6) for horizontally supporting the condensing heat exchanger 12, and descends toward the upper end opening 731 on the whole or a part of its inner bottom surface. A guide surface 711 formed to be a slope with a slope is provided. As the refrigerant circulation pipe 15 that passes through the passage portion 73, a pipe 151 that connects the compressor 11 in the machine chamber 62 (see also FIG. 4 or FIG. 7) to the condensation heat exchanger 12 in the heating chamber 63. (Refer to FIG. 1 as well) and a pipe 152 connecting the condensation heat exchanger 12 to the expansion valve 13 in the machine room 11. Similarly, as the water circulation pipe 22 passing through the passage portion 73, water is supplied from the connection port 221 installed in the right side panel 54 at the lower position of the machine chamber 62 to the condensation heat exchanger 12 in the heating chamber 63. The piping 223 to supply and the piping 224 which supplies the hot water from the condensation heat exchanger 12 to the connection port 222 installed in the vicinity of the connection port 221 are comprised. Pipes extending from a hot water storage unit (not shown) are connected to both connection ports 221 and 222.

  The mutual positional relationship between the gas sensor 8 and the passage portion 73 (lower end opening 732) is set as follows. That is, if the refrigerant leaks from the condensation heat exchanger 12, the refrigerant has a higher specific gravity than air, so the leaked refrigerant is guided to the guide surface 711 of the lower heat retaining member 71 and flows to the upper end opening 731. The inside of the passage portion 73 flows downward from the upper end opening 731. The refrigerant that has flowed down from the lower end opening 732 accumulates at the bottom of the machine chamber 62. Therefore, if there is the gas sensor 8 at a site that has flowed down from the lower end opening 732, refrigerant leakage can be detected quickly. Therefore, as illustrated in FIG. 5A, the gas sensor 8 is disposed below the machine chamber 62 located below the passage portion 73 (that is, below the lower end opening 732 of the passage portion 73). . Specifically, the gas sensor 8 is installed at the upper surface position of the bottom panel 51 or near the upper surface of the bottom panel 51. Here, FIG. 5A shows an example in which the gas sensor 8 is installed at a position directly below the passage portion 73 (the lower end opening 732). What is necessary is just to install in the site | part contained in the downward area | region of the lower end opening part 732 of the channel | path part 73. FIG.

  In the case of the above embodiment, the heating chamber 63 is partitioned and formed in the top space in the housing 5 by the horizontal partition plate 58, and the condensation heat exchanger 12 is installed in the heating chamber 63 that is the top space. Even if a refrigerant leak from the condensation heat exchanger 12 occurs, it is possible to easily detect the refrigerant leak at an early stage by utilizing the fact that the refrigerant has a higher specific gravity than air. . When the refrigerant leak is detected, the guide surface 711 is provided on the inner bottom surface of the lower heat retaining member 71 of the heat retaining member 7 that covers the condensation heat exchanger 12, so that the leaked refrigerant is directed toward the upper end opening 731 of the passage portion 73. It can be quickly guided and collected. On top of that, a passage 73 that guides from the upper end opening 731 to the lower end opening 732 is provided, so that the refrigerant flow is guided so that the refrigerant collected in the upper end opening 731 flows down toward the gas sensor 8. Therefore, the certainty for early detection of refrigerant leakage can be further improved. In addition, since the leaked refrigerant is allowed to flow down only in the passage portion 73, the control device which is various electronic devices or electric devices such as the controller 3 disposed above the lower end opening 732 is used for the refrigerant. In the unlikely event that a malfunction occurs due to contact with an electronic circuit or the like in the control device, it becomes possible to prevent the occurrence of a malfunction. As described above, even if a refrigerant leak occurs from the condensation heat exchanger 12, it becomes possible to detect the refrigerant leak at an early stage, and accordingly, the refrigerant leakage amount can be suppressed and early countermeasures can be ensured. Will be able to. Therefore, when a flammable refrigerant is used as the refrigerant, it is possible to prevent the occurrence of a serious inconvenience by detecting the refrigerant leakage at an early stage.

  Further, the condensing heat exchanger 12 is blown by forming the opening portion 581 and the passage portion 73 inserted therethrough at one end portion position of the heating chamber 63, that is, at the right rear end position near the back panel 53 of the horizontal partition plate 58. Since it can be arranged in a state where it extends in the left-right direction over the upper sides of both the chamber 61 and the machine room 62, that is, the condensing heat exchanger 12 extends longer along the substantially entire length of the horizontal partition plate 58 in the left-right direction. In particular, the height of the condensation heat exchanger 12 itself in the vertical direction is made thinner, and the required height of the housing 5 is made lower, so that the outdoor unit 4 can be made more compact. Will be able to.

< Reference form>
Contact name in the upper Symbol embodiment, although be formed integrally with the passage portion 73 to the lower heat insulating member 71, as the reference embodiment, to form a passage separately, adhesion to the lower heat insulating member 71 You may make it combine by means, such as. Or you may make it connect the channel | path part formed in the different body to the opening part 581 with respect to the horizontal partition plate 58, and it connects with the lower side. Further, for example, as illustrated in FIG. 5B, the lower portion of the opening 581 is surrounded by a plate-like wall member 591 such as a thin resin plate so as to form a closed space so as to define the passage portion 59. It may be. In this case, the lower end edge of the plate-like wall member 591 constituting the passage portion 59 may be joined to the upper surface of the bottom panel 51, and the gas sensor 8 may be installed in a region surrounded by the plate-like wall member 591.

<Other embodiments>
In addition, this invention is not limited to the said embodiment, Various other embodiments are included. That is, as the condensation heat exchanger 12 disposed in the heating chamber 63, the pipe for flowing water and the pipe for flowing the refrigerant are constituted by a double pipe or a pair of pipes in contact with each other. The heat exchanger may be configured by other types of heat exchangers.

  In the above-described embodiment, the heat retaining member 7 for covering the condensation heat exchanger 12 is configured by a pair of members divided vertically such as a lower heat retaining member 71 and an upper heat retaining member 72. It may be divided.

Further, in the above embodiment, the guide plane 711 of the inner bottom surface of the lower portion heat insulating member 71 is not essential, only the formation of the passage portion 73 having an upper opening 731 that communicates with the opening 581 and which is omitted this It can also be. Even in this case, because the refrigerant has leaked from the condensing heat exchanger 12 of the lower heat insulating member 71 then accumulated on the inner bottom surface of the lower heat insulating member 71, chill flows drop from the top opening 731, as described above, the gas sensor 8 makes it possible to detect the occurrence of refrigerant leakage at an early stage.

DESCRIPTION OF SYMBOLS 1 Refrigerant circulation circuit 5 Case 7 Thermal insulation member 8 Gas sensor 11 Compressor 12 Condensing heat exchanger 13 Expansion valve (expansion means)
14 Evaporative Heat Exchanger 14a Fan (Blower Unit)
15 Refrigerant circulation pipe 57 Vertical partition plate 58 Horizontal partition plate 61 Blower chamber 62 Machine chamber 63 Heating chamber (top space)
151,152 Piping (Piping for refrigerant)
223,224 piping (pipe for hot water)
581 Opening 711 Guide surface 731 Upper end opening (opening)
732 Lower end opening (opening)

Claims (3)

In a heat pump hot water supply apparatus comprising a refrigerant circulation circuit in which a compressor, a condensing heat exchanger, an expansion means, and an evaporating heat exchanger are sequentially connected by a refrigerant circulation pipe, and using a combustible refrigerant as a refrigerant,
A horizontal partition plate is disposed so as to partition the top space in the housing in the vertical direction over the entire length range in the left-right direction, while the evaporative heat exchanger and the air blowing means are disposed in the lower space of the horizontal partition plate. A vertical partition plate is disposed so as to be separated from each other in the left-right direction between the air blowing chamber and the machine chamber in which the compressor and the expansion means are disposed,
The condensation heat exchanger is disposed in a state where the periphery is covered with a heat insulating member with respect to the top space,
In the heat retaining member and the horizontal partition plate, an opening for penetrating both of them downward and passing the piping for refrigerant and hot water is formed in communication with the lower space,
A cylindrical passage portion extending downward through the opening with respect to the lower space in a state of surrounding the refrigerant and hot water pipes passing through the opening,
The passage portion is formed integrally with the heat retaining member so that the upper end opening portion opens on the inner bottom surface of the heat retaining member, and the lower end opening portion protrudes downward and extends.
A gas sensor that detects the presence of a flammable refrigerant is disposed at a position below the lower end opening of the passage .
A heat pump hot water supply apparatus characterized by that. It is a heat pump hot-water supply apparatus of Claim 1, Comprising:
A heat pump hot water supply apparatus, wherein a guide surface that is inclined downward toward the opening is formed on an inner bottom surface of the heat retaining member. The heat pump hot water supply device according to claim 1 or 2 ,
A control device is disposed at an upper position of the lower space,
The passage portion is a heat pump hot water supply device that is extended so that a lower end opening thereof is positioned at least below the control device.

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