JP2014202449A - Water heat exchanger - Google Patents

Water heat exchanger Download PDF

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JP2014202449A
JP2014202449A JP2013080710A JP2013080710A JP2014202449A JP 2014202449 A JP2014202449 A JP 2014202449A JP 2013080710 A JP2013080710 A JP 2013080710A JP 2013080710 A JP2013080710 A JP 2013080710A JP 2014202449 A JP2014202449 A JP 2014202449A
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water
refrigerant
channel
hot water
heat exchanger
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JP5894958B2 (en
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初彦 河村
Hatsuhiko Kawamura
初彦 河村
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Rinnai Corp
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Rinnai Corp
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Abstract

PROBLEM TO BE SOLVED: To provide a technique capable of performing drainage by a simple method for a water heat exchanger.SOLUTION: A water heat exchanger disclosed in the present specification comprises: a first water channel constituted by a spirally wound tubular body, and including an upper opening and a lower opening; a second water channel constituted by a spirally wound tubular body, and including an upper opening and a lower opening; a water connection channel connecting the upper opening of the first water channel to that of the second water channel; a water inlet channel introducing water to the lower opening of the first water channel; a water outlet channel discharging the water from the lower opening of the second water channel; and an air release channel connected to the water connection channel, and including an air release valve.

Description

本発明は、水熱交換器に関する。   The present invention relates to a water heat exchanger.

特許文献1に水熱交換器が開示されている。この水熱交換器は、主に内側コイル体と外側コイル体から構成されている。内側コイル体と外側コイル体はそれぞれ、水が流れる水用パイプと冷媒が流れる冷媒用パイプを、上下方向に交互に積み重ねるようにらせん状に捲回して形成されている。この水熱交換器では、内側コイル体の水用パイプの最下部と外側コイル体の水用パイプの最上部が水接続管で接続されている。同様に、内側コイル体の冷媒用パイプの最下部と外側コイル体の冷媒用パイプの最上部が冷媒接続管で接続されている。   Patent Document 1 discloses a water heat exchanger. This water heat exchanger is mainly composed of an inner coil body and an outer coil body. Each of the inner coil body and the outer coil body is formed by spirally winding water pipes through which water flows and refrigerant pipes through which refrigerant flows so as to be alternately stacked in the vertical direction. In this water heat exchanger, the lowermost part of the water pipe of the inner coil body and the uppermost part of the water pipe of the outer coil body are connected by a water connection pipe. Similarly, the lowermost part of the refrigerant pipe of the inner coil body and the uppermost part of the refrigerant pipe of the outer coil body are connected by a refrigerant connection pipe.

特開2004−226036号公報JP 2004-226036 A

冬季などの外気温が低い状況で、水熱交換器の内部に水が滞留していると、水が凍結してしまうおそれがある。そのため、水熱交換器を長期間使用しない場合には、水熱交換器から水抜きをしておく必要がある。   If the water stays inside the water heat exchanger when the outside air temperature is low such as in winter, the water may freeze. Therefore, when the water heat exchanger is not used for a long time, it is necessary to drain water from the water heat exchanger.

特許文献1の水熱交換器において水抜きをする場合、水頭圧のみによって水を完全に除去することが困難であり、エアブロー等による残水除去処理が必須となる。より簡便な手法で水熱交換器から水抜きを行うことが可能な技術が期待されている。   When draining water in the water heat exchanger of Patent Document 1, it is difficult to completely remove water only by water head pressure, and residual water removal processing by air blow or the like is essential. A technique capable of draining water from a water heat exchanger by a simpler method is expected.

本明細書は、上記の課題を解決する技術を提供する。本明細書では、水熱交換器において、簡便な手法で水抜きを行うことが可能な技術を提供する。   The present specification provides a technique for solving the above problems. In this specification, the technique which can drain water with a simple method in a water heat exchanger is provided.

本明細書が開示する水熱交換器は、らせん状に捲回された管体から構成されており、上側開口と下側開口を有する第1水流路と、らせん状に捲回された管体から構成されており、上側開口と下側開口を有する第2水流路と、第1水流路の上側開口と第2水流路の上側開口の間を接続する水接続流路と、第1水流路の下側開口へ水を導入する水導入流路と、第2水流路の下側開口から水を導出する水導出流路と、水接続流路に接続されており、空気開放弁を有する空気開放流路を備えている。   The water heat exchanger disclosed in the present specification is composed of a spirally wound tube, a first water flow path having an upper opening and a lower opening, and a spirally wound tube. A second water flow path having an upper opening and a lower opening, a water connection flow path connecting the upper opening of the first water flow path and the upper opening of the second water flow path, and the first water flow path A water introduction passage for introducing water into the lower opening of the water, a water outlet passage for extracting water from the lower opening of the second water passage, and an air having an air release valve connected to the water connection passage An open channel is provided.

上記の水熱交換器では、空気開放弁を開弁することで、水頭圧のみを利用して、水接続流路と、第1水流路と、第2水流路から、水導入流路と水導出流路を介して速やかに水抜きを行うことができる。エアブロー等の残水除去処理を行うことなく、簡便な手法で水抜きを行うことができる。   In the above-described water heat exchanger, by opening the air release valve, only the water head pressure is used, and the water introduction channel and the water from the water connection channel, the first water channel, and the second water channel. Water can be quickly drained through the outlet channel. Water can be drained by a simple method without performing residual water removal treatment such as air blow.

上記の水熱交換器は、第1水流路によって区画される内側の空間に第2水流路が収容されているように構成することができる。   Said water heat exchanger can be comprised so that the 2nd water flow path may be accommodated in the inner space divided by the 1st water flow path.

上記の水熱交換器によれば、第1水流路によって区画される内側の空間を有効に活用して、省スペース化を図ることができる。   According to said water heat exchanger, space saving can be achieved by utilizing effectively the inner space divided by the 1st water flow path.

上記の水熱交換器は、らせん状に捲回された管体から構成されており、上側開口と下側開口を有する第1冷媒流路と、らせん状に捲回された管体から構成されており、上側開口と下側開口を有する第2冷媒流路と、第1冷媒流路の上側開口と第2冷媒流路の上側開口を接続する冷媒接続流路と、第2冷媒流路の下側開口へ冷媒を導入する冷媒導入流路と、第1冷媒流路の下側開口から冷媒を導出する冷媒導出流路をさらに備えており、第1水流路と第1冷媒流路は、互いの外表面を接触した状態で、一体的に捲回されており、第2水流路と第2冷媒流路は、互いの外表面を接触した状態で、一体的に捲回されているように構成することができる。   The water heat exchanger is composed of a spirally wound tubular body, and is composed of a first coolant channel having an upper opening and a lower opening, and a spirally wound tubular body. A second refrigerant passage having an upper opening and a lower opening, a refrigerant connection passage connecting the upper opening of the first refrigerant passage and the upper opening of the second refrigerant passage, and a second refrigerant passage A refrigerant introduction channel for introducing the refrigerant into the lower opening; and a refrigerant outlet channel for deriving the refrigerant from the lower opening of the first refrigerant channel. The first water channel and the first refrigerant channel are: The second water flow path and the second refrigerant flow path seem to be integrally wound while being in contact with each other's outer surface. Can be configured.

上記の水熱交換器によれば、水との熱交換によって冷媒を凝縮させる凝縮器を、簡素な構成で実現することができる。   According to said water heat exchanger, the condenser which condenses a refrigerant | coolant by heat exchange with water is realizable with a simple structure.

本明細書が開示する水熱交換器によれば、簡便な手法で水抜きを行うことができる。   According to the water heat exchanger disclosed in this specification, water can be drained by a simple method.

水熱交換器28が組み込まれた給湯システム2の構成を模式的に示す図である。It is a figure which shows typically the structure of the hot water supply system 2 in which the water heat exchanger 28 was integrated. 水熱交換器28の外観を示す斜視図である。FIG. 3 is a perspective view showing an external appearance of a water heat exchanger 28. 図2のA−A断面についての横断面図である。It is a cross-sectional view about the AA cross section of FIG.

(実施例)
図1は、水熱交換器28が組み込まれた給湯システム2を示している。給湯システム2は主に、ヒートポンプ4と、貯湯槽8と、循環ポンプ10と、混合弁12と、バーナ加熱装置14と、バイパス弁16と、制御装置18を備えている。給湯システム2は、上水道や井戸等の給水源から供給される水を、ヒートポンプ4および/またはバーナ加熱装置14を加熱源として加熱し、給湯設定温度に調温された湯を給湯する。
(Example)
FIG. 1 shows a hot water supply system 2 in which a water heat exchanger 28 is incorporated. The hot water supply system 2 mainly includes a heat pump 4, a hot water storage tank 8, a circulation pump 10, a mixing valve 12, a burner heating device 14, a bypass valve 16, and a control device 18. The hot water supply system 2 heats water supplied from a water supply source such as a water supply or a well using the heat pump 4 and / or the burner heating device 14 as a heating source, and supplies hot water adjusted to a hot water supply set temperature.

ヒートポンプ4は、冷媒(例えばR410AといったHFC冷媒や、R744といったCO冷媒)を循環させるための冷媒循環路20と、蒸発器22と、ファン24と、圧縮機26と、水熱交換器28(凝縮器に相当する)と、膨張弁30を備えている。 The heat pump 4 includes a refrigerant circulation path 20 for circulating a refrigerant (for example, an HFC refrigerant such as R410A and a CO 2 refrigerant such as R744), an evaporator 22, a fan 24, a compressor 26, and a water heat exchanger 28 ( And an expansion valve 30.

蒸発器22は、ファン24によって送風された外気と冷媒循環路20内の冷媒との間で熱交換を行う、気液熱交換器である。蒸発器22には、膨張弁30を通過後の低圧低温の液体状態にある冷媒が供給される。蒸発器22は、冷媒と外気とを熱交換させることによって、冷媒を加熱する。冷媒は、加熱されることにより気化し、比較的高温で低圧の気体状態となる。   The evaporator 22 is a gas-liquid heat exchanger that exchanges heat between the outside air blown by the fan 24 and the refrigerant in the refrigerant circulation path 20. The evaporator 22 is supplied with a refrigerant in a low-pressure and low-temperature liquid state after passing through the expansion valve 30. The evaporator 22 heats the refrigerant by exchanging heat between the refrigerant and the outside air. The refrigerant is vaporized by being heated, and is in a gas state at a relatively high temperature and a low pressure.

圧縮機26には、蒸発器22を通過後の冷媒が供給される。即ち、圧縮機26には、比較的高温で低圧の気体状態の冷媒が供給される。圧縮機26によって冷媒が圧縮されることにより、冷媒は高温高圧の気体状態となる。圧縮機26は、圧縮後の高温高圧の気体状態の冷媒を、水熱交換器28に送り出す。   The refrigerant after passing through the evaporator 22 is supplied to the compressor 26. That is, the compressor 26 is supplied with a relatively high temperature and low pressure gaseous refrigerant. When the refrigerant is compressed by the compressor 26, the refrigerant is in a high-temperature and high-pressure gaseous state. The compressor 26 sends the compressed high-temperature and high-pressure gaseous refrigerant to the water heat exchanger 28.

水熱交換器28には、圧縮機26から送り出された高温高圧の気体状態の冷媒が供給される。水熱交換器28は、冷媒循環路20内の冷媒と給湯用水循環路6内の水(以下では給湯用水ともいう)との間で熱交換を行う、液液熱交換器である。冷媒は、水熱交換器28での熱交換の結果、熱を奪われて凝縮する。これにより、冷媒は、比較的低温で高圧の液体状態となる。   The water heat exchanger 28 is supplied with a high-temperature and high-pressure gaseous refrigerant sent from the compressor 26. The water heat exchanger 28 is a liquid-liquid heat exchanger that performs heat exchange between the refrigerant in the refrigerant circuit 20 and the water in the hot water supply water circuit 6 (hereinafter also referred to as hot water supply water). As a result of the heat exchange in the water heat exchanger 28, the refrigerant is deprived of heat and condensed. Thereby, a refrigerant | coolant will be in a high-pressure liquid state with a comparatively low temperature.

膨張弁30には、水熱交換器28を通過後の比較的低温で高圧の液体状態の冷媒が供給される。冷媒は、膨張弁30を通過することによって減圧され、低温低圧の液体状態となる。膨張弁30を通過した冷媒は、上記の通り、蒸発器22に送られる。   The expansion valve 30 is supplied with a relatively low-temperature and high-pressure liquid refrigerant after passing through the water heat exchanger 28. The refrigerant is depressurized by passing through the expansion valve 30, and becomes a low-temperature and low-pressure liquid state. The refrigerant that has passed through the expansion valve 30 is sent to the evaporator 22 as described above.

ヒートポンプ4において、圧縮機26を作動させると、冷媒循環路20内の冷媒は、蒸発器22、圧縮機26、水熱交換器28、膨張弁30の順に循環する。ヒートポンプ4が動作すると、水熱交換器28において、給湯用水循環路6内の給湯用水が加熱される。   When the compressor 26 is operated in the heat pump 4, the refrigerant in the refrigerant circuit 20 circulates in the order of the evaporator 22, the compressor 26, the water heat exchanger 28, and the expansion valve 30. When the heat pump 4 is operated, the hot water supply water in the hot water supply water circulation path 6 is heated in the water heat exchanger 28.

貯湯槽8は、ヒートポンプ4によって加熱された給湯用水を貯える。貯湯槽8は密閉型であり、断熱材によって外側が覆われている。貯湯槽8内には満水まで給湯用水が貯留される。   The hot water storage tank 8 stores hot water supply water heated by the heat pump 4. The hot water tank 8 is a closed type, and the outside is covered with a heat insulating material. Hot water supply water is stored in the hot water tank 8 until it is full.

給湯用水循環路6は、上流端が貯湯槽8の下部に接続されており、ヒートポンプ4の水熱交換器28を通過して、下流端が貯湯槽8の上部に接続されている。給湯用水循環路6には、循環ポンプ10が取り付けられている。ヒートポンプ4を動作させて、かつ循環ポンプ10を駆動すると、貯湯槽8の下部の給湯用水が水熱交換器28に送られて、水熱交換器28で加熱された給湯用水が貯湯槽8の上部に戻される。貯湯槽8の内部には、低温の給湯用水の層の上に高温の給湯用水の層が積み重なった温度成層が形成される。   The hot water supply water circulation path 6 has an upstream end connected to the lower part of the hot water storage tank 8, passes through the water heat exchanger 28 of the heat pump 4, and has a downstream end connected to the upper part of the hot water storage tank 8. A circulation pump 10 is attached to the hot water supply water circulation path 6. When the heat pump 4 is operated and the circulation pump 10 is driven, the hot water supply water at the lower part of the hot water tank 8 is sent to the water heat exchanger 28, and the hot water water heated by the water heat exchanger 28 is supplied to the hot water tank 8. Returned to the top. Inside the hot water storage tank 8, a temperature stratification is formed in which a layer of high-temperature hot water supply water is stacked on a layer of low-temperature hot water supply water.

給水路34は、上流端が外部の給水源に接続されており、給湯用水を受け入れる。給水路34の下流側は、貯湯槽導入路36と貯湯槽バイパス路38に分岐している。貯湯槽導入路36の下流端は、貯湯槽8の下部に接続されている。貯湯槽バイパス路38の下流端は、混合弁12に接続されている。貯湯槽導出路40は、上流端が貯湯槽8の上部に接続されている。貯湯槽導出路40の下流側は、混合弁12に接続されている。   The upstream end of the water supply channel 34 is connected to an external water supply source and receives hot water supply water. The downstream side of the water supply path 34 branches into a hot water tank introduction path 36 and a hot water tank bypass path 38. The downstream end of the hot water tank introduction path 36 is connected to the lower part of the hot water tank 8. The downstream end of the hot water tank bypass passage 38 is connected to the mixing valve 12. An upstream end of the hot water tank outlet 40 is connected to the upper part of the hot water tank 8. A downstream side of the hot water tank outlet 40 is connected to the mixing valve 12.

混合弁12は、貯湯槽導出路40を流れる貯湯槽8の上部からの高温の給湯用水と、貯湯槽バイパス路38を流れる給水路34からの低温の給湯用水を混合して、第1給湯路42へ送り出す。混合弁12では、貯湯槽導出路40から第1給湯路42へ流れる給湯用水の流量と、貯湯槽バイパス路38から第1給湯路42へ流れる給湯用水の流量の割合を調整する。第1給湯路42の下流側は、バーナ加熱路44とバーナバイパス路46に分岐している。バーナ加熱路44には、バーナ加熱装置14が取り付けられている。バーナ加熱装置14は、ガス等の燃料を燃焼させてバーナ加熱路44を流れる給湯用水を加熱する。バーナバイパス路46にはバイパス弁16が取り付けられている。バーナ加熱路44とバーナバイパス路46は、それぞれの下流端で合流して、第2給湯路48の上流端に接続している。第2給湯路48から台所の給湯栓や浴室のシャワー等の給湯箇所へ、給湯設定温度に調温された給湯用水が供給される。   The mixing valve 12 mixes the hot water for hot water from the upper part of the hot water tank 8 flowing through the hot water tank outlet path 40 and the low temperature hot water from the water path 34 for flowing through the hot water tank bypass path 38 to the first hot water path. 42. In the mixing valve 12, the ratio of the flow rate of hot water flowing from the hot water tank outlet path 40 to the first hot water path 42 and the flow rate of hot water flowing from the hot water tank bypass path 38 to the first hot water path 42 are adjusted. The downstream side of the first hot water supply passage 42 branches into a burner heating passage 44 and a burner bypass passage 46. A burner heating device 14 is attached to the burner heating path 44. The burner heating device 14 burns fuel such as gas and heats hot water supply water flowing through the burner heating path 44. A bypass valve 16 is attached to the burner bypass 46. The burner heating path 44 and the burner bypass path 46 merge at their downstream ends and are connected to the upstream end of the second hot water supply path 48. Water for hot water adjusted to a hot water supply set temperature is supplied from the second hot water supply path 48 to a hot water supply location such as a kitchen hot water tap and a shower in the bathroom.

制御装置18は、ファン24、圧縮機26、膨張弁30、循環ポンプ10、混合弁12、バーナ加熱装置14、バイパス弁16等の動作を制御する。   The control device 18 controls operations of the fan 24, the compressor 26, the expansion valve 30, the circulation pump 10, the mixing valve 12, the burner heating device 14, the bypass valve 16, and the like.

以下では給湯システム2が行う、蓄熱運転および給湯運転について説明する。   Hereinafter, the heat storage operation and the hot water supply operation performed by the hot water supply system 2 will be described.

(蓄熱運転)
蓄熱運転では、貯湯槽8内の給湯用水をヒートポンプ4で加熱し、高温となった給湯用水を貯湯槽8に戻す。蓄熱運転を開始する際には、制御装置18はファン24および圧縮機26を駆動してヒートポンプ4を動作させるとともに、循環ポンプ10を駆動する。圧縮機26の駆動により、冷媒循環路20内の冷媒は、蒸発器22、圧縮機26、水熱交換器28、膨張弁30の順に循環する。また、循環ポンプ10の駆動により、給湯用水循環路6内を貯湯槽8内の給湯用水が循環する。即ち、貯湯槽8の下部に存在する給湯用水が給湯用水循環路6内に導入され、導入された給湯用水が水熱交換器28で加熱され、加熱された給湯用水が貯湯槽8の上部に戻される。これにより、貯湯槽8に高温の給湯用水が貯められる。貯湯槽8の内部が高温の給湯用水で満たされた満蓄状態となると、蓄熱運転を終了する。
(Heat storage operation)
In the heat storage operation, the hot water in the hot water storage tank 8 is heated by the heat pump 4, and the hot water for hot water is returned to the hot water storage tank 8. When starting the heat storage operation, the control device 18 drives the fan 24 and the compressor 26 to operate the heat pump 4 and drives the circulation pump 10. By driving the compressor 26, the refrigerant in the refrigerant circuit 20 circulates in the order of the evaporator 22, the compressor 26, the water heat exchanger 28, and the expansion valve 30. Further, the hot water supply water in the hot water storage tank 8 circulates in the hot water supply water circulation path 6 by driving the circulation pump 10. That is, the hot water supply water existing in the lower part of the hot water storage tank 8 is introduced into the hot water supply water circulation path 6, the introduced hot water supply water is heated by the water heat exchanger 28, and the heated hot water supply water is placed in the upper part of the hot water storage tank 8. Returned. As a result, hot water supply water is stored in the hot water tank 8. When the hot water storage tank 8 is fully charged with hot hot water, the heat storage operation is terminated.

(給湯運転)
給湯運転は、給湯設定温度に調温された給湯用水を第2給湯路48に供給する運転である。給湯運転は、上記の蓄熱運転と並行して行うこともできる。給湯栓やシャワーでの給湯用水の供給が開始されると、給水路34からの水圧によって、給水路34から貯湯槽8の下部に給湯用水が流入する。同時に、貯湯槽8の上部の給湯用水が、貯湯槽導出路40、第1給湯路42、バーナ加熱路44、バーナバイパス路46を介して、第2給湯路48に供給される。制御装置18は、貯湯槽8から貯湯槽導出路40に供給される給湯用水の温度が、給湯設定温度より高い場合には、混合弁12を駆動して貯湯槽バイパス路38から第1給湯路42に低温の給湯用水を導入する。制御装置18は、第2給湯路48に供給される給湯用水の温度が、目標とする給湯設定温度となるように、混合弁12の開度を調整する。一方、制御装置18は、貯湯槽8から貯湯槽導出路40に供給される給湯用水の温度が、給湯設定温度より低い場合には、バーナ加熱装置14によって給湯用水の加熱を行う。制御装置18は、第2給湯路48に供給される給湯用水の温度が、目標とする給湯設定温度となるように、バーナ加熱装置14の出力を制御する。
(Hot water operation)
The hot water supply operation is an operation in which hot water supply water adjusted to a hot water supply set temperature is supplied to the second hot water supply passage 48. The hot water supply operation can also be performed in parallel with the above heat storage operation. When the supply of hot water using a hot water tap or shower is started, the hot water flows into the lower part of the hot water tank 8 from the water supply channel 34 due to the water pressure from the water supply channel 34. At the same time, hot water supply water in the upper part of the hot water storage tank 8 is supplied to the second hot water supply path 48 via the hot water tank outlet path 40, the first hot water supply path 42, the burner heating path 44, and the burner bypass path 46. When the temperature of the hot water supplied from the hot water storage tank 8 to the hot water tank outlet path 40 is higher than the set hot water temperature, the control device 18 drives the mixing valve 12 to connect the first hot water path from the hot water tank bypass path 38. Into 42, low-temperature hot water supply water is introduced. The control device 18 adjusts the opening degree of the mixing valve 12 so that the temperature of the hot water supply water supplied to the second hot water supply passage 48 becomes the target hot water supply set temperature. On the other hand, the control device 18 heats the hot water supply water by the burner heating device 14 when the temperature of the hot water supply water supplied from the hot water storage tank 8 to the hot water tank lead-out path 40 is lower than the hot water supply set temperature. The control device 18 controls the output of the burner heating device 14 so that the temperature of the hot water supply water supplied to the second hot water supply passage 48 becomes the target hot water supply set temperature.

(水熱交換器の構成)
図2および図3に示すように、水熱交換器28は、内側熱交換部50と外側熱交換部52を備えている。内側熱交換部50は、外側熱交換部52によって区画される内側の空間に収容されている。
(Configuration of water heat exchanger)
As shown in FIGS. 2 and 3, the water heat exchanger 28 includes an inner heat exchange part 50 and an outer heat exchange part 52. The inner heat exchange unit 50 is accommodated in an inner space partitioned by the outer heat exchange unit 52.

内側熱交換部50は、水が流れる内側水配管54と、冷媒が流れる内側冷媒配管56を、互いの外表面で接触させた状態でらせん状に捲回して形成されている。外側熱交換部52は、水が流れる外側水配管58と、冷媒が流れる外側冷媒配管60を、互いの外表面で接触させた状態でらせん状に捲回して形成されている。内側水配管54および内側冷媒配管56と、外側水配管58および外側冷媒配管60では、逆向きに捲回されている。図2および図3に示す例では、内側水配管54および内側冷媒配管56は、下方から上方に向けて左巻きに捲回されており、外側水配管58および外側冷媒配管60は、下方から上方に向けて右巻きに捲回されている。なお、内側水配管54および内側冷媒配管56と、外側水配管58および外側冷媒配管60を、同じ向きに捲回する構成としてもよいが、図2および図3に示すように、逆向きに捲回する構成とすると、配管レイアウトをよりコンパクトにすることができる。   The inner heat exchanging unit 50 is formed by spirally winding an inner water pipe 54 through which water flows and an inner refrigerant pipe 56 through which a refrigerant flows in contact with each other on the outer surface. The outer heat exchange section 52 is formed by spirally winding an outer water pipe 58 through which water flows and an outer refrigerant pipe 60 through which refrigerant flows in contact with each other on the outer surface. The inner water pipe 54 and the inner refrigerant pipe 56, and the outer water pipe 58 and the outer refrigerant pipe 60 are wound in opposite directions. In the example shown in FIGS. 2 and 3, the inner water pipe 54 and the inner refrigerant pipe 56 are wound left-handed from below to above, and the outer water pipe 58 and the outer refrigerant pipe 60 are upward from below. It is wound to the right. The inner water pipe 54 and the inner refrigerant pipe 56, and the outer water pipe 58 and the outer refrigerant pipe 60 may be wound in the same direction, but as shown in FIG. 2 and FIG. When it is configured to rotate, the piping layout can be made more compact.

内側水配管54の上側開口と外側水配管58の上側開口は、水接続配管62によって接続されている。内側冷媒配管56の上側開口と外側冷媒配管60の上側開口は、冷媒接続配管64によって接続されている。   The upper opening of the inner water pipe 54 and the upper opening of the outer water pipe 58 are connected by a water connection pipe 62. The upper opening of the inner refrigerant pipe 56 and the upper opening of the outer refrigerant pipe 60 are connected by a refrigerant connection pipe 64.

外側水配管58の下側開口には、水導入配管66が接続されている。内側水配管54の下側開口には、水導出配管68が接続されている。水熱交換器28に流れ込む給湯用水は、水導入配管66を介して外側水配管58に流入し、外側水配管58を下方から上方に向けて流れて、水接続配管62を介して内側水配管54に流入し、内側水配管54を上方から下方に向けて流れて、水導出配管68から送り出される。   A water introduction pipe 66 is connected to the lower opening of the outer water pipe 58. A water outlet pipe 68 is connected to the lower opening of the inner water pipe 54. Hot water for hot water flowing into the water heat exchanger 28 flows into the outer water pipe 58 via the water introduction pipe 66, flows from the lower water pipe 58 upward from below, and passes through the water connection pipe 62 to the inner water pipe. 54 flows into the inner water pipe 54 from the upper side to the lower side, and is sent out from the water outlet pipe 68.

内側冷媒配管56の下側開口には、冷媒導入配管70が接続されている。外側冷媒配管60の下側開口には、冷媒導出配管72が接続されている。水熱交換器28に流れ込む冷媒は、冷媒導入配管70を介して内側冷媒配管56に流入し、内側冷媒配管56を下方から上方に向けて流れて、冷媒接続配管64を介して外側冷媒配管60に流入し、外側冷媒配管60を上方から下方に向けて流れて、冷媒導出配管72から送り出される。   A refrigerant introduction pipe 70 is connected to the lower opening of the inner refrigerant pipe 56. A refrigerant outlet pipe 72 is connected to the lower opening of the outer refrigerant pipe 60. The refrigerant flowing into the water heat exchanger 28 flows into the inner refrigerant pipe 56 through the refrigerant introduction pipe 70, flows from the lower refrigerant pipe 56 upward from below, and flows through the refrigerant connection pipe 64 to the outer refrigerant pipe 60. , Flows through the outer refrigerant pipe 60 from the upper side to the lower side, and is sent out from the refrigerant outlet pipe 72.

上記のように、水熱交換器28においては、給湯用水と冷媒が対向流として流れる。このような構成とすることで、冷媒から給湯用水への伝熱量を多くすることができる。   As described above, in the water heat exchanger 28, the hot water supply water and the refrigerant flow as counterflows. With such a configuration, the amount of heat transferred from the refrigerant to the hot water supply water can be increased.

水接続配管62には、空気開放配管74が接続されている。空気開放配管74には空気開放弁76が設けられている。   An air release pipe 74 is connected to the water connection pipe 62. An air release valve 76 is provided in the air release pipe 74.

冬季などの外気温が低い状況で、内側水配管54、外側水配管58、水接続配管62、水導入配管66、水導出配管68等の内部に給湯用水が滞留していると、給湯用水が凍結してしまうおそれがある。そのため、給湯システム2を長期間使用しない場合には、水熱交換器28から水抜きをしておく必要がある。   If hot water stays inside the inner water pipe 54, the outer water pipe 58, the water connection pipe 62, the water introduction pipe 66, the water outlet pipe 68, etc. in a situation where the outside air temperature is low such as in the winter season, There is a risk of freezing. Therefore, when the hot water supply system 2 is not used for a long period of time, it is necessary to drain water from the water heat exchanger 28.

本実施例の水熱交換器28では、空気開放弁76を開くことによって、内側水配管54、外側水配管58、水接続配管62に残存している給湯用水を、水頭圧を利用して、水導入配管66と水導出配管68から速やかに水抜きすることができる。エアブロー等の残水除去処理を必要とすることなく、確実に水抜きを行うことができる。   In the water heat exchanger 28 of the present embodiment, by opening the air release valve 76, hot water supply water remaining in the inner water pipe 54, the outer water pipe 58, and the water connection pipe 62 is utilized using the water head pressure. Water can be quickly drained from the water introduction pipe 66 and the water outlet pipe 68. Water drainage can be reliably performed without requiring residual water removal treatment such as air blow.

以上、本発明の実施例について詳細に説明したが、これらは例示に過ぎず、特許請求の範囲を限定するものではない。特許請求の範囲に記載の技術には、以上に例示した具体例を様々に変形、変更したものが含まれる。   As mentioned above, although the Example of this invention was described in detail, these are only illustrations and do not limit a claim. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.

上記の実施例では、水熱交換器28を流れる水が給湯用水(水道水または井戸水)である場合について説明したが、これ以外でも、水熱交換器28を流れる水に凍結のおそれがあり、水熱交換器28を長期間使用しない場合に水抜きをすることが好ましいものであれば、水熱交換器28を流れる水はどのようなものであってもよい。   In the above embodiment, the case where the water flowing through the water heat exchanger 28 is hot water supply water (tap water or well water) has been described, but the water flowing through the water heat exchanger 28 may be frozen. As long as it is preferable to drain water when the water heat exchanger 28 is not used for a long period of time, any water flowing through the water heat exchanger 28 may be used.

本明細書または図面に説明した技術要素は、単独であるいは各種の組合せによって技術的有用性を発揮するものであり、出願時請求項記載の組合せに限定されるものではない。また、本明細書または図面に例示した技術は複数目的を同時に達成し得るものであり、そのうちの一つの目的を達成すること自体で技術的有用性を持つものである。   The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings can achieve a plurality of objects at the same time, and has technical usefulness by achieving one of the objects.

2 給湯システム
4 ヒートポンプ
6 給湯用水循環路
8 貯湯槽
10 循環ポンプ
12 混合弁
14 バーナ加熱装置
16 バイパス弁
18 制御装置
20 冷媒循環路
22 蒸発器
24 ファン
26 圧縮機
28 水熱交換器
30 膨張弁
34 給水路
36 貯湯槽導入路
38 貯湯槽バイパス路
40 貯湯槽導出路
42 第1給湯路
44 バーナ加熱路
46 バーナバイパス路
48 第2給湯路
50 内側熱交換部
52 外側熱交換部
54 内側水配管
56 内側冷媒配管
58 外側水配管
60 外側冷媒配管
62 水接続配管
64 冷媒接続配管
66 水導入配管
68 水導出配管
70 冷媒導入配管
72 冷媒導出配管
74 空気開放配管
76 空気開放弁
2 Hot-water supply system 4 Heat pump 6 Hot-water supply water circulation path 8 Hot water storage tank 10 Circulation pump 12 Mixing valve 14 Burner heating device 16 Bypass valve 18 Control device 20 Refrigerant circulation path 22 Evaporator 24 Fan 26 Compressor 28 Water heat exchanger 30 Expansion valve 34 Water supply path 36 Hot water tank introduction path 38 Hot water tank bypass path 40 Hot water tank outlet path 42 First hot water path 44 Burner heating path 46 Burner bypass path 48 Second hot water path 50 Inner heat exchanger 52 Outer heat exchanger 54 Inner water pipe 56 Inner refrigerant pipe 58 Outer water pipe 60 Outer refrigerant pipe 62 Water connection pipe 64 Refrigerant connection pipe 66 Water introduction pipe 68 Water outlet pipe 70 Refrigerant inlet pipe 72 Refrigerant outlet pipe 74 Air release pipe 76 Air release valve

Claims (3)

らせん状に捲回された管体から構成されており、上側開口と下側開口を有する第1水流路と、
らせん状に捲回された管体から構成されており、上側開口と下側開口を有する第2水流路と、
第1水流路の上側開口と第2水流路の上側開口の間を接続する水接続流路と、
第1水流路の下側開口へ水を導入する水導入流路と、
第2水流路の下側開口から水を導出する水導出流路と、
水接続流路に接続されており、空気開放弁を有する空気開放流路を備える水熱交換器。
A first water flow path composed of a spirally wound tubular body, having an upper opening and a lower opening;
A second water flow path composed of a spirally wound tubular body, having an upper opening and a lower opening;
A water connection channel connecting the upper opening of the first water channel and the upper opening of the second water channel;
A water introduction channel for introducing water into the lower opening of the first water channel;
A water outlet channel for extracting water from the lower opening of the second water channel;
A water heat exchanger comprising an air release channel connected to a water connection channel and having an air release valve.
第1水流路によって区画される内側の空間に第2水流路が収容されている、請求項1の水熱交換器。   The water heat exchanger according to claim 1, wherein the second water flow path is accommodated in an inner space defined by the first water flow path. らせん状に捲回された管体から構成されており、上側開口と下側開口を有する第1冷媒流路と、
らせん状に捲回された管体から構成されており、上側開口と下側開口を有する第2冷媒流路と、
第1冷媒流路の上側開口と第2冷媒流路の上側開口を接続する冷媒接続流路と、
第2冷媒流路の下側開口へ冷媒を導入する冷媒導入流路と、
第1冷媒流路の下側開口から冷媒を導出する冷媒導出流路をさらに備えており、
第1水流路と第1冷媒流路は、互いの外表面を接触した状態で、一体的に捲回されており、
第2水流路と第2冷媒流路は、互いの外表面を接触した状態で、一体的に捲回されている、請求項1または2の水熱交換器。
A first refrigerant flow path comprising a spirally wound tubular body, having an upper opening and a lower opening;
A second refrigerant flow path comprising a spirally wound tubular body, having an upper opening and a lower opening;
A refrigerant connection channel connecting the upper opening of the first refrigerant channel and the upper opening of the second refrigerant channel;
A refrigerant introduction channel for introducing the refrigerant into the lower opening of the second refrigerant channel;
A refrigerant outlet channel for extracting the refrigerant from the lower opening of the first refrigerant channel;
The first water flow path and the first refrigerant flow path are wound integrally with the outer surfaces in contact with each other,
The water heat exchanger according to claim 1 or 2, wherein the second water flow path and the second refrigerant flow path are wound integrally with each other in contact with each other.
JP2013080710A 2013-04-08 2013-04-08 Water heat exchanger Active JP5894958B2 (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPWO2021130957A1 (en) * 2019-12-26 2021-07-01

Citations (4)

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Publication number Priority date Publication date Assignee Title
JPS50113849A (en) * 1974-02-19 1975-09-06
JP2005003209A (en) * 2003-06-09 2005-01-06 Matsushita Electric Ind Co Ltd Heat exchanger and heat pump water heater using the heat exchanger
JP2009243798A (en) * 2008-03-31 2009-10-22 Mitsubishi Electric Corp Heater for water for hot-water supply system, and hot-water supply system
JP2012241955A (en) * 2011-05-18 2012-12-10 Noritz Corp Water heater

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS50113849A (en) * 1974-02-19 1975-09-06
JP2005003209A (en) * 2003-06-09 2005-01-06 Matsushita Electric Ind Co Ltd Heat exchanger and heat pump water heater using the heat exchanger
JP2009243798A (en) * 2008-03-31 2009-10-22 Mitsubishi Electric Corp Heater for water for hot-water supply system, and hot-water supply system
JP2012241955A (en) * 2011-05-18 2012-12-10 Noritz Corp Water heater

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPWO2021130957A1 (en) * 2019-12-26 2021-07-01

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