JP5948602B2 - Water heater - Google Patents

Water heater Download PDF

Info

Publication number
JP5948602B2
JP5948602B2 JP2012044976A JP2012044976A JP5948602B2 JP 5948602 B2 JP5948602 B2 JP 5948602B2 JP 2012044976 A JP2012044976 A JP 2012044976A JP 2012044976 A JP2012044976 A JP 2012044976A JP 5948602 B2 JP5948602 B2 JP 5948602B2
Authority
JP
Japan
Prior art keywords
hot water
heat
heat recovery
bathtub
water
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
JP2012044976A
Other languages
Japanese (ja)
Other versions
JP2013181686A (en
Inventor
俊元 梶谷
俊元 梶谷
裕史 柴田
裕史 柴田
山本 照夫
照夫 山本
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Panasonic Intellectual Property Management Co Ltd
Original Assignee
Panasonic Intellectual Property Management Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Panasonic Intellectual Property Management Co Ltd filed Critical Panasonic Intellectual Property Management Co Ltd
Priority to JP2012044976A priority Critical patent/JP5948602B2/en
Publication of JP2013181686A publication Critical patent/JP2013181686A/en
Application granted granted Critical
Publication of JP5948602B2 publication Critical patent/JP5948602B2/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Landscapes

  • Heat-Pump Type And Storage Water Heaters (AREA)

Description

本発明は、熱回収機能を有する給湯装置に関するものである。   The present invention relates to a hot water supply apparatus having a heat recovery function.

従来、この種の給湯装置には、浴槽の湯を加温する追い焚き運転と浴槽の湯から熱を回収する熱回収運転を機能として備えたものがある(例えば、特許文献1参照)。   Conventionally, this type of hot water supply apparatus includes a reheating operation for heating the hot water in the bathtub and a heat recovery operation for recovering heat from the hot water in the bathtub (for example, see Patent Document 1).

図13は、熱回収運転を機能として有する給湯装置であり、1は貯湯槽、2はヒートポンプユニット、3は浴槽、4は熱交換器、5aは貯湯槽水搬送ポンプ、5bは浴槽水搬送ポンプ、6は熱回収分岐管、7は三方弁、8は高温水供給管、9は低温水供給管、10は給湯管、11は混合弁、12は浴槽水循環配管、13は開閉弁、14は給水管、15は給湯分岐管、16は熱交戻り管である。   FIG. 13 shows a hot water supply apparatus having a heat recovery operation as a function. 1 is a hot water storage tank, 2 is a heat pump unit, 3 is a bathtub, 4 is a heat exchanger, 5a is a hot water tank water transport pump, and 5b is a bath water transport pump. , 6 is a heat recovery branch pipe, 7 is a three-way valve, 8 is a high temperature water supply pipe, 9 is a low temperature water supply pipe, 10 is a hot water supply pipe, 11 is a mixing valve, 12 is a bath water circulation pipe, 13 is an on-off valve, 14 is A water supply pipe, 15 is a hot water supply branch pipe, and 16 is a heat exchange return pipe.

浴槽水循環配管12は、浴槽3の往き管と戻り管とを環状に接続して構成され、回路上に熱交換器4および浴槽水搬送ポンプ5bを備える。   The bathtub water circulation pipe 12 is configured by connecting the forward pipe and the return pipe of the bathtub 3 in an annular shape, and includes a heat exchanger 4 and a bathtub water conveyance pump 5b on the circuit.

また、混合弁11は、高温水供給管8と低温水供給管9とを入口側に接続し、給湯管10を出口側に接続するように構成され、開閉弁13を介して浴槽水循環配管12と接続される。さらに浴槽内の水温を検知する浴槽水温検知手段17が、浴槽水循環配管12の途中に設けられている。   The mixing valve 11 is configured to connect the high temperature water supply pipe 8 and the low temperature water supply pipe 9 to the inlet side, and connect the hot water supply pipe 10 to the outlet side, and the bathtub water circulation pipe 12 via the on-off valve 13. Connected. Further, a bathtub water temperature detecting means 17 for detecting the water temperature in the bathtub is provided in the middle of the bathtub water circulation pipe 12.

この給湯装置が風呂自動運転を行う場合は、まず、貯湯槽1に貯えられた湯と給水管14から供給される水とを混合弁11で所望温度の湯に混合して浴槽3へ給湯する。浴槽3へ給湯した後は、一定時間だけ湯の温度を一定に保つために保温動作を行う。   When this hot water supply apparatus performs bath automatic operation, first, hot water stored in the hot water storage tank 1 and water supplied from the water supply pipe 14 are mixed with hot water at a desired temperature by the mixing valve 11 to supply hot water to the bathtub 3. . After the hot water is supplied to the bathtub 3, a heat retaining operation is performed in order to keep the temperature of the hot water constant for a certain period of time.

保温動作は、浴槽湯温が一定温度以下に降下した場合におこない、貯湯槽水搬送ポンプ5aと浴槽水搬送ポンプ5bとを運転して、熱交換器4において、貯湯槽1内の湯(例えば約80℃)により浴槽3内の湯(例えば約35℃)を加温する。   The heat insulation operation is performed when the bath water temperature falls below a certain temperature. The hot water storage tank water transport pump 5a and the bath water transport pump 5b are operated, and the heat exchanger 4 performs hot water (for example, The hot water (for example, about 35 ° C.) in the bathtub 3 is heated by about 80 ° C.).

また、浴槽3の水温が一定温度以下に降下しているかどうかを判断するために、浴槽水搬送ポンプ5bのみを運転させる浴槽水温検知動作を間欠的に行う。   Moreover, in order to judge whether the water temperature of the bathtub 3 has fallen below the fixed temperature, the bathtub water temperature detection operation | movement which drives only the bathtub water conveyance pump 5b is performed intermittently.

浴槽水温検知手段17により浴槽3の水温が一定温度以下に降下していることが検知された場合には保温動作を行い、降下していない場合にはそのまま待機する。一定時間が経過した後には風呂自動運転を自動で終了する。   When the bath water temperature detecting means 17 detects that the water temperature of the bathtub 3 is lowered below a certain temperature, the heat retaining operation is performed, and when the bath water temperature detecting means 17 is not lowered, it waits as it is. After a certain period of time has elapsed, automatic bath operation is automatically terminated.

次に、追い焚き運転を行う場合は、貯湯槽水搬送ポンプ5aと浴槽水搬送ポンプ5bとが運転をおこなって、熱交換器4において、貯湯槽1内の湯(例えば約80℃)が浴槽3内の湯(例えば約35℃)を加温する。その結果、浴槽3内の水温は上昇し、貯湯槽1内に湯として貯えられている熱量(蓄熱量)は減少する。   Next, when the reheating operation is performed, the hot water storage tank water transfer pump 5a and the bathtub water transfer pump 5b operate, and the hot water (for example, about 80 ° C.) in the hot water storage tank 1 is stored in the bathtub in the heat exchanger 4. The hot water in 3 (for example, about 35 ° C.) is heated. As a result, the water temperature in the bathtub 3 rises, and the amount of heat (heat storage amount) stored as hot water in the hot water tank 1 decreases.

次に、熱回収運転を行う場合は、同様に貯湯槽水搬送ポンプ5aと浴槽水搬送ポンプ5bとが運転を行うが、熱交換器4において、貯湯槽1内の水(例えば約10℃)が浴槽3内の水(例えば約35℃)を冷却して熱を回収する。   Next, when the heat recovery operation is performed, the hot water storage tank water transfer pump 5a and the bathtub water transfer pump 5b operate similarly, but in the heat exchanger 4, the water in the hot water storage tank 1 (for example, about 10 ° C.). Cools the water (for example, about 35 ° C.) in the bathtub 3 and recovers heat.

また、貯湯槽1の水はヒートポンプユニット2にて所定温度、所定量まで沸き上げる沸き上げ運転を行う。   In addition, the water in the hot water tank 1 is heated and heated to a predetermined temperature and a predetermined amount by the heat pump unit 2.

給湯装置の動作は沸き上げ運転、前記熱回収運転を順に行う。   The operation of the hot water supply device is performed in the order of a boiling operation and the heat recovery operation.

特開2009−198115号公報JP 2009-198115 A

しかしながら、前記従来の構成では、貯湯槽を全量沸き上げずに運転終了した後、熱回収運転を行うため、熱回収運転が長く行われると、貯湯槽に必要量のお湯を貯湯することができなくなり、お湯の使用量が多い場合においては、お湯切れが発生する課題を有していた。   However, in the above-described conventional configuration, since the heat recovery operation is performed after the hot water tank is finished without boiling up, and the heat recovery operation is performed for a long time, the necessary amount of hot water can be stored in the hot water tank. When there is no hot water used, there is a problem that hot water runs out.

本発明は、前記従来の課題を解決するもので、沸き上げ運転中に熱回収運転を行う時は熱回収時間を短くすることで、貯湯槽に貯湯するお湯の必要量を確保して湯切れ防止する給湯装置を提供することを目的とする。   The present invention solves the above-described conventional problems, and shortens the heat recovery time when performing the heat recovery operation during the boiling operation, thereby ensuring the necessary amount of hot water to be stored in the hot water storage tank. It aims at providing the hot-water supply apparatus which prevents.

前記従来の課題を解決するために、本発明の給湯装置は、貯湯槽と、前記貯湯槽の水を加熱する加熱手段と、前記貯湯槽外に設けられ、前記加熱手段による沸き上げ運転の加熱温度よりも低温の熱源である浴槽と、前記貯湯槽内の湯水と前記浴槽内の湯水とを熱交換させ、前記浴槽の湯の有する熱を前記貯湯槽の湯水に回収する熱回収機能を含む熱交換器と、制御手段とを備え、前記沸き上げ運転中に前記熱回収運転を行なうときは、前記熱回収運転の運転時間を、前記沸き上げ運転中以外の前記熱回収運転の運転時間より短くすることを特徴とするものである。 Wherein in order to solve the conventional problems, the water heater of the present invention comprises a hot water tank, a heating means for heating the water in the hot water storage tank, provided outside the hot water tank, heating the boiling operation by the heating means It includes a heat recovery function for exchanging heat between the bathtub, which is a heat source having a temperature lower than the temperature , the hot water in the hot water tank and the hot water in the bathtub, and recovering the heat of the hot water in the bathtub to the hot water in the hot water tank a heat exchanger, and control means, when performing the heat recovery operation in the boiling operation, the operating time of the heat recovery operation, than the operating time of the heat recovery operation except during the water heating operation It is characterized by shortening.

これにより、加熱手段により沸き上げ運転を行っている時に熱回収運転の時間を短くして、貯湯槽に貯湯するお湯の必要量を確保し、湯切れ防止することができ、使用性の向上を実現した給湯装置を提供できる。   This shortens the time of the heat recovery operation when the heating operation is performed by the heating means, secures the necessary amount of hot water to be stored in the hot water tank, prevents the hot water from running out, and improves the usability. An realized hot water supply apparatus can be provided.

本発明によれば、沸き上げ運転中に熱回収運転を行う時は熱回収時間を短くすることで、貯湯槽に貯湯するお湯の必要量を確保して湯切れ防止することができ、使用性の向上を実現した給湯装置を提供できる。   According to the present invention, when performing the heat recovery operation during the boiling operation, by shortening the heat recovery time, the necessary amount of hot water to be stored in the hot water storage tank can be secured and the hot water can be prevented from running out. It is possible to provide a hot water supply apparatus that realizes the improvement of the above.

本発明の実施の形態1における給湯装置の構成図(沸き上げ運転時の水および湯の流れ方向を示す図)Configuration diagram of hot water supply apparatus in Embodiment 1 of the present invention (a diagram showing the flow direction of water and hot water during boiling operation) 同熱回収運転制御手段のブロック図Block diagram of the heat recovery operation control means 同風呂自動運転と熱回収運転の制御方法概念図Conceptual diagram of control method for automatic bath operation and heat recovery operation 同追い焚き運転と熱回収運転の制御方法概念図Conceptual diagram of the control method for the chasing operation and heat recovery operation 同風呂自動運転中の浴槽への給湯時の水および湯の流れ方向を示した回路構成図Circuit configuration diagram showing the flow of water and hot water when hot water is supplied to the bathtub during automatic bath operation 同風呂自動運転中の保温動作時および追い焚き運転時の水および湯の流れ方向を示した回路構成図Circuit configuration diagram showing the flow direction of water and hot water during warm-up operation and chasing operation during automatic bath operation 同風呂自動運転中の浴槽水温検知運転時の水および湯の流れ方向を示した回路構成図Circuit configuration diagram showing the flow direction of water and hot water during bath water temperature detection operation during automatic bath operation 同熱回収運転時の水および湯の流れ方向を示した回路構成図Circuit configuration diagram showing the flow direction of water and hot water during the heat recovery operation 同熱回収運転による貯湯槽内の温度分布の変化を示した図The figure which showed the change of the temperature distribution in the hot water tank by the heat recovery operation 同ヒートポンプユニットの効率を示した図Diagram showing the efficiency of the heat pump unit 同熱回収量とヒートポンプユニットの入力の関係を示した図Diagram showing the relationship between the heat recovery amount and heat pump unit input 同熱回収運転制御動作のフローチャートFlow chart of the heat recovery operation control operation 従来の給湯装置の構成図Configuration diagram of conventional hot water supply equipment

第1の発明は、貯湯槽と、前記貯湯槽の水を加熱する加熱手段と、前記貯湯槽外に設けられ、前記加熱手段による沸き上げ運転の加熱温度よりも低温の熱源である浴槽と、前記貯湯槽内の湯水と前記浴槽内の湯水とを熱交換させ、前記浴槽の湯の有する熱を前記貯湯槽の湯水に回収する熱回収機能を含む熱交換器と、制御手段とを備え、前記沸き上げ運転中に前記熱回収運転を行なうときは、前記熱回収運転の運転時間を、前記沸き上げ運転中以外の前記熱回収運転の運転時間より短くすることを特徴とする給湯装置である。 A first invention is a hot water tank, a heating means for heating the water in the hot water storage tank, provided outside the hot water storage tank, a tub is cold heat source than the heating temperature of the heating operation by the heating means, A heat exchanger including a heat recovery function for heat exchange between hot water in the hot water tank and hot water in the bathtub, and recovering the heat of the hot water in the bathtub to the hot water in the hot water tank, and a control means, When performing the heat recovery operation during the boiling operation , the operation time of the heat recovery operation is shorter than the operation time of the heat recovery operation other than during the boiling operation. .

これにより、加熱手段により沸き上げ運転を行っている時に、前記熱交換器による熱回収運転の時間を短くして、貯湯槽に貯湯するお湯の必要量を確保し、湯切れ防止することができ、使用性の向上を実現した給湯装置を提供できる。 This makes it possible to shorten the time of the heat recovery operation by the heat exchanger and to secure the necessary amount of hot water to be stored in the hot water tank and to prevent the hot water from running out when the boiling operation is performed by the heating means. A hot water supply device that realizes improved usability can be provided.

第2の発明は、前記熱回収運転停止後の、前記沸き上げ運転時における入力が略最小となるように、前記熱回収運転を停止させることを特徴とする給湯装置である。 A second aspect of the invention is a hot water supply apparatus , wherein the heat recovery operation is stopped so that an input at the time of the boiling operation after the heat recovery operation is stopped is substantially minimized.

これにより、熱回収運転中の貯湯槽の温度分布に基づき、第1の加熱手段によって所定の貯湯量を沸き上げるための消費熱量(消費電力)が最小となる時点を判断して、第2の加熱手段による熱回収運転を停止するので、本来の目的であるシステム全体としての効率向上を実現し、省エネルギー性を高める効果がある。   Thus, based on the temperature distribution of the hot water storage tank during the heat recovery operation, the time point at which the heat consumption (power consumption) for boiling up the predetermined hot water storage amount by the first heating means is minimized is determined. Since the heat recovery operation by the heating means is stopped, the efficiency of the entire system, which is the original purpose, is improved, and there is an effect of improving energy saving.

第3の発明は、前記加熱手段はヒートポンプユニットで、前記熱交換器に前記浴槽内の湯水が循環するように接続された浴槽循環路と、前記貯湯槽内の略上部の湯が前記熱交換器に流れるように切換手段を介して前記熱交換器に接続された熱交往き管と、前記熱交換器で前記浴槽の湯水と熱交換された湯水が再び前記貯湯槽内へ戻るように前記貯湯槽に接続された熱交戻り管と、前記貯湯槽の略下部の湯水が前記熱交換器に流れるように、前記ヒートポンプユニット、前記切換手段を順に介して前記熱交換器に接続された熱回収往き管と、前記ヒートポンプユニットにて加熱された湯水が前記貯湯槽内に戻るように、前記切換手段から前記貯湯槽に接続された沸き上げ戻り管とを備え、前記熱回収運転を行うときには、前記熱回収往き管、前記ヒートポンプユニット、前記切換手段、前記熱交換器、前記熱交戻り管の順に前記貯湯槽からの湯水が流れるように、また、前記沸き上げ運転を行うときには、前記熱回収往き管、前記ヒートポンプユニット、前記切換手段、前記沸き上げ戻り管の順に前記貯湯槽からの湯が流れるように、前記制御手段が前記切換手段を切り換える構成としたことを特徴とする給湯装置である。 A third invention is characterized in that the heating means is a heat pump uni Tsu DOO, and connected bath circulation path so hot water is circulated in said bath to the heat exchanger, a substantially upper portion of the hot water in the hot water storage tank wherein A heat transfer pipe connected to the heat exchanger via switching means so as to flow to the heat exchanger, and hot water exchanged with the hot water in the bathtub by the heat exchanger returns to the hot water storage tank again. The heat exchange return pipe connected to the hot water storage tank and the hot water in the lower part of the hot water storage tank are connected to the heat exchanger via the heat pump unit and the switching means in order so that hot water flows to the heat exchanger. And a heating return pipe connected from the switching means to the hot water tank so that the hot water heated by the heat pump unit returns to the hot water tank, and the heat recovery operation is performed. When performing the heat recovery forward pipe, the front Heat pump unit, said switching means, said heat exchanger, said heat交戻Ri tube of the as hot water from the hot water tank flows in the forward, also when performing a raising operation-out the boiling, the heat recovery forward pipe, the heat pump unit The hot water supply apparatus is characterized in that the control means switches the switching means so that hot water from the hot water tank flows in the order of the switching means and the boiling return pipe.

これにより、熱回収時に使用する配管の一部を貯湯槽内の湯水の沸き上げ運転時にも使用する構成とし、低コスト化を実現した給湯装置を提供できる。 Thus, a portion of the pipe to be used for heat recovery is also configured to use when hot water boiling operation in the hot water tank, it is possible to provide a water heater which realizes cost reduction.

以下、本発明の実施の形態について、図面を参照しながら説明する。なお、この実施の形態によって本発明が限定されるものではない。   Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(実施の形態1)
図1は本発明の実施の形態1における給湯装置の構成を示す図である。
(Embodiment 1)
FIG. 1 is a diagram showing a configuration of a hot water supply apparatus according to Embodiment 1 of the present invention.

図1において、給湯装置は、貯湯槽1と、この貯湯槽1の水を加熱する加熱手段としてのヒートポンプユニット2と、熱回収を行う対象の浴槽3と、浴槽3の水と貯湯槽1の水とを熱交換するように構成された熱交換器4と、貯湯槽1に接続された給水管14と、貯
湯槽1の略上部に接続された第1の出湯管22と、第1の出湯管22と給水管14とが接続された位置の間、すなわち、高さ方向において貯湯槽1の胴部略中央部に接続された第2の出湯管23とから構成されている。
In FIG. 1, a hot water supply apparatus includes a hot water tank 1, a heat pump unit 2 as a heating means for heating the water in the hot water tank 1, a bathtub 3 to be subjected to heat recovery, water in the bathtub 3, and the hot water tank 1. A heat exchanger 4 configured to exchange heat with water, a water supply pipe 14 connected to the hot water tank 1, a first hot water pipe 22 connected to substantially the upper part of the hot water tank 1, and a first It is comprised from the position where the hot water pipe 22 and the water supply pipe 14 were connected, ie, the 2nd hot water pipe 23 connected to the trunk | drum approximate center part of the hot water storage tank 1 in the height direction.

また、給湯装置は、第1の出湯管22と第2の出湯管23とが入口側に接続された高温水混合弁24と、この高温水混合弁24の出口側に接続され、貯湯槽1内の高温水を供給する高温水供給管8と、給水管14から分岐され、貯湯槽1内または給水管14からの低温水を供給する低温水供給管9と、これら高温水供給管8と低温水供給管9とを入口側に接続された混合弁11と、この混合弁11の出口側に接続された給湯管10と、給湯管10の途中に接続された開閉弁13から構成されている。   The hot water supply device is connected to the high temperature water mixing valve 24 in which the first hot water discharge pipe 22 and the second hot water discharge pipe 23 are connected to the inlet side, and to the outlet side of the high temperature water mixing valve 24. A high-temperature water supply pipe 8 for supplying high-temperature water therein, a low-temperature water supply pipe 9 branched from the water supply pipe 14 and supplying low-temperature water in the hot water tank 1 or from the water supply pipe 14, and these high-temperature water supply pipes 8 The mixing valve 11 is connected to the low temperature water supply pipe 9 on the inlet side, the hot water supply pipe 10 is connected to the outlet side of the mixing valve 11, and the on-off valve 13 is connected in the middle of the hot water supply pipe 10. Yes.

また、貯湯槽1内の略上部の湯が前記熱交換器4に流れるように切換手段32を介して前記熱交換器4に接続された熱交往き管33と、前記熱交換器4で浴槽3の湯と熱交換した貯湯槽1の湯水を再び貯湯槽1へ戻すように、貯湯槽1の高さ方向において第1の出湯管22と第2の出湯管23との間の位置で、貯湯槽1の略中央部とに接続された熱交戻り管16とから構成されている。   Further, the hot water pipe 33 connected to the heat exchanger 4 through the switching means 32 so that the hot water in the upper part of the hot water tank 1 flows to the heat exchanger 4, and the heat exchanger 4 has a bathtub. The hot water of the hot water tank 1 exchanged with the hot water of No. 3 is returned to the hot water tank 1 again, at a position between the first hot water discharge pipe 22 and the second hot water discharge pipe 23 in the height direction of the hot water storage tank 1, It is comprised from the heat exchanger return pipe 16 connected to the approximate center part of the hot water tank 1.

また、貯湯槽1内の湯水を加熱して、再び貯湯槽1内に貯湯する沸き上げ運転時には、図1に示すように、前記加熱手段であるヒートポンプユニット2にて所定温度に加熱された湯が、前記貯湯槽1の略上部に戻るように、前記貯湯槽1の略下部に接続された熱回収往き管35が、前記ヒートポンプユニット2、前記三方弁37を順に介して、前記切換手段32に接続され、前記切換手段32は、前記貯湯槽1の略上部に接続された沸き上げ戻り管36に接続される。   Further, during a boiling operation in which hot water in the hot water tank 1 is heated and stored in the hot water tank 1 again, the hot water heated to a predetermined temperature by the heat pump unit 2 as the heating means, as shown in FIG. However, the heat recovery forward pipe 35 connected to the substantially lower part of the hot water tank 1 is connected to the switching means 32 via the heat pump unit 2 and the three-way valve 37 in this order so that it returns to the substantially upper part of the hot water tank 1. The switching means 32 is connected to a boiling return pipe 36 connected to a substantially upper part of the hot water tank 1.

また、熱回収運転時には、図8に示すように、前記貯湯槽1の略下部の湯水が前記熱交換器4に流れるように、前記貯湯槽1の略下部に接続された熱回収往き管35が、前記加熱手段であるヒートポンプユニット2、三方弁37を順に介して、前記沸き上げ運転時に対して流路を切り換えた前記切換手段32に接続され、前記切換手段32は、前記熱交戻り管16に接続される。   Further, during the heat recovery operation, as shown in FIG. 8, the heat recovery outlet pipe 35 connected to the substantially lower part of the hot water tank 1 so that the hot water in the lower part of the hot water tank 1 flows to the heat exchanger 4. Is connected to the switching means 32 that switches the flow path with respect to the boiling operation time through the heat pump unit 2 and the three-way valve 37 that are the heating means in order, and the switching means 32 is connected to the heat return pipe. 16 is connected.

さらに、給湯装置は、貯湯槽1と熱交換器4の第1の流路内の水を循環させる第1の搬送ポンプとしての貯湯槽水搬送ポンプ5aと、熱交換器4の第2の流路内へ浴槽3の水が循環するように接続された浴槽水循環配管12と、浴槽3と熱交換器4の第2の流路内の水を循環させる第2の搬送ポンプとしての浴槽水搬送ポンプ5bとから構成されている。   Furthermore, the hot water supply device includes a hot water tank water transfer pump 5a as a first transfer pump that circulates water in the first flow path of the hot water tank 1 and the heat exchanger 4, and a second flow of the heat exchanger 4. Bathtub water conveyance as a second conveyance pump for circulating water in the second flow path of the bathtub 3 and the heat exchanger 4 and the bathtub water circulation pipe 12 connected so that the water of the bathtub 3 circulates in the road And a pump 5b.

ここで熱交戻り管16は、貯湯槽1の上下方向において第1の出湯管22と第2の出湯管23の間の位置で貯湯槽1に接続される。浴槽3への給湯の際は浴槽水循環配管12を利用する。   Here, the heat exchange return pipe 16 is connected to the hot water tank 1 at a position between the first hot water pipe 22 and the second hot water pipe 23 in the vertical direction of the hot water tank 1. When hot water is supplied to the bathtub 3, the bathtub water circulation pipe 12 is used.

また、浴室内もしくは洗面、台所に設置されたリモコン25には、使用者が任意に熱回収運転を起動するための熱回収運転起動スイッチ26を設け、浴槽水循環配管12には、浴槽湯量検知手段として水圧を測定することにより浴槽3の湯の水位を検知する水位センサ27と、浴槽3の水温を検知するための浴槽水温検知手段17とを設けており、貯湯槽1には、貯湯槽1内の水温を検知するための複数の貯湯温検知手段28a〜28eを設けている。   The remote controller 25 installed in the bathroom, in the bathroom, or in the kitchen is provided with a heat recovery operation start switch 26 for the user to arbitrarily start the heat recovery operation. The water level sensor 27 for detecting the water level of the hot water in the bathtub 3 by measuring the water pressure and the bath water temperature detecting means 17 for detecting the water temperature of the bathtub 3 are provided. A plurality of hot water storage temperature detecting means 28a to 28e are provided for detecting the water temperature inside.

また、浴槽水循環配管12には浴槽水検出手段31が設けてあり、浴槽水を循環した場合に浴槽水の有無を検出することができる。浴槽水検出手段31はフロースイッチもしくは流量センサでも用いることが可能である。   Moreover, the bathtub water circulation piping 12 is provided with the bathtub water detection means 31, and when the bathtub water is circulated, the presence or absence of the bathtub water can be detected. The bathtub water detection means 31 can also be used as a flow switch or a flow sensor.

さらに、これら複数の貯湯温検知手段28a〜28eと水位センサ27と浴槽水温検知手段17の出力および熱回収運転起動スイッチ26の操作に基づいて、浴槽3への給湯およびそれ以降予め設定された時間だけ浴槽水の保温と水量維持を行う風呂自動運転を制御する給湯制御手段としての風呂自動運転制御手段29と、浴槽3内の水を加熱する追い焚き運転を制御する追い焚き運転制御手段30と、貯湯槽1に浴槽3の水の熱を回収する熱回収運転を制御する熱回収運転制御手段21とからなる運転制御手段18を設けている。   Furthermore, based on the outputs of the plurality of hot water storage temperature detection means 28a to 28e, the water level sensor 27, the bath water temperature detection means 17 and the operation of the heat recovery operation start switch 26, the hot water supply to the bathtub 3 and the time set in advance thereafter Only bath automatic operation control means 29 as hot water supply control means for controlling automatic bath operation for maintaining the temperature of the bathtub water and maintaining the amount of water, and reheating operation control means 30 for controlling the reheating operation for heating the water in the bathtub 3. The hot water storage tank 1 is provided with operation control means 18 including heat recovery operation control means 21 for controlling the heat recovery operation for recovering the heat of the water in the bathtub 3.

図2は熱回収運転制御手段21のブロック図を示し、水位センサ27の出力および風呂自動運転制御手段29の動作状態あるいは熱回収運転起動スイッチ26などから熱回収運転制御手段21が起動した場合、熱回収運転の開始を判断する熱回収運転開始判断部50と、ヒートポンプユニット2による沸上運転を制御する沸上運転制御手段(図示せず)から貯湯後の給湯利用に必要な貯湯熱量を取得する所要貯湯熱量取得部51と、貯湯温検知手段28a〜28eにより貯湯温度分布を測定する貯湯温度分布測定部52と、これら所要貯湯熱量取得部51と貯湯温度分布測定部52で得られた結果に基づいて必要な沸上熱量を算出する必要沸上熱量算出部53と、貯湯温度分布測定部52による現在の温度分布と必要沸上熱量算出部53から沸上完了時の温度分布を推定する沸上完了時貯湯温度分布推定部55とからなる。   FIG. 2 shows a block diagram of the heat recovery operation control means 21. When the heat recovery operation control means 21 is activated from the output of the water level sensor 27 and the operation state of the bath automatic operation control means 29 or the heat recovery operation start switch 26, The heat recovery operation start determination unit 50 that determines the start of the heat recovery operation and the boiling operation control means (not shown) that controls the boiling operation by the heat pump unit 2 acquire the amount of stored hot water necessary for hot water use after hot water storage. The required hot water storage heat quantity acquisition unit 51, the hot water storage temperature distribution measurement part 52 that measures the hot water temperature distribution by the hot water temperature detection means 28a to 28e, and the results obtained by the required hot water storage heat quantity acquisition part 51 and the hot water temperature distribution measurement part 52 From the required boiling heat quantity calculation unit 53 that calculates the required boiling heat quantity based on the current temperature distribution and the required boiling heat quantity calculation unit 53 from the hot water storage temperature distribution measurement unit 52 Consisting boiling on the as hot-water temperature distribution estimating unit 55 for estimating the temperature distribution during the upper completion.

また、熱回収運転開始判断部50には、熱回収運転時間上限タイマー57を有し、ヒートポンプユニット2による沸上運転を制御する沸上運転制御手段(図示せず)が動作時、熱回収運転要求がきたときには、沸上運転制御手段を停止して熱回収運転を動作させ、熱回収運転時間上限タイマー57の上限時間を沸き上げ運転中以外の熱回収時間より短くする。   The heat recovery operation start determination unit 50 has a heat recovery operation time upper limit timer 57, and when the boiling operation control means (not shown) for controlling the boiling operation by the heat pump unit 2 is in operation, the heat recovery operation When requested, the boiling operation control means is stopped and the heat recovery operation is operated, and the upper limit time of the heat recovery operation time upper limit timer 57 is made shorter than the heat recovery time other than during the boiling operation.

さらに、貯湯温度分布測定部52による現在の温度分布から沸上完了時貯湯温度分布推定部54での沸き上げ完了時の推定温度分布に至る間のヒートポンプユニット2への入力を推定する沸上所要入力推定部55と、この沸上所要入力推定部55による入力推定値の時間変化に基づいて貯湯槽水搬送ポンプ5a、浴槽水搬送ポンプ5bとを制御するポンプ制御部56とからなる。   Further, the boiling required for estimating the input to the heat pump unit 2 from the current temperature distribution by the hot water storage temperature distribution measuring unit 52 to the estimated temperature distribution at the completion of boiling by the hot water storage temperature distribution estimating unit 54 at the completion of boiling. The input estimation part 55 and the pump control part 56 which controls the hot water tank water conveyance pump 5a and the bathtub water conveyance pump 5b based on the time change of the input estimated value by this boiling required input estimation part 55 are comprised.

以上のように構成された給湯装置について、以下その動作、作用を説明する。   About the hot water supply apparatus comprised as mentioned above, the operation | movement and an effect | action are demonstrated below.

一般的な家庭での湯の利用における基本的な動作として、朝には貯湯槽1にその日使う分の湯が貯えられており、活動している時間帯に順次給湯に利用される。給湯利用中に貯湯量が不足する場合には必要に応じてヒートポンプユニット2を運転し、追加で貯湯運転を行うこともある。   As a basic operation in the use of hot water in a general home, hot water for the day is stored in the hot water tank 1 in the morning, and is sequentially used for hot water supply during an active time. When the amount of hot water storage is insufficient during use of hot water, the heat pump unit 2 may be operated as necessary, and an additional hot water storage operation may be performed.

近年では、浴槽3への給湯から保温までを自動で行う風呂自動運転の機能を備えている給湯装置が多くなっている。風呂自動運転制御手段29により浴槽3への給湯および保温運転を行う場合は、貯湯槽1内に貯えられている湯を用いて浴槽3へ給湯し、浴槽水温が低下した場合には、貯湯槽1内に貯えられている湯の熱を利用して保温運転をおこない、浴槽水温を予め設定された温度に保つ。また、追い焚き運転制御手段30により追い焚き運転をおこなって浴槽3内の湯を加温する場合も、貯湯槽1内に貯えられている湯の熱を利用して行う。   In recent years, there have been an increasing number of hot water supply apparatuses having a function of automatic bath operation that automatically performs from hot water supply to the bathtub 3 to heat insulation. When the bath automatic operation control means 29 performs hot water supply to the bathtub 3 and heat insulation operation, the hot water stored in the hot water storage tank 1 is used to supply hot water to the bathtub 3, and when the bath water temperature decreases, the hot water storage tank A heat insulation operation is performed using the heat of hot water stored in 1, and the bath water temperature is maintained at a preset temperature. In addition, when the reheating operation is performed by the reheating operation control means 30 and the hot water in the bathtub 3 is heated, the heat of the hot water stored in the hot water tank 1 is used.

これら一日の給湯などの熱利用が終わる時点で貯湯槽1内の湯は大部分が給水と置換され、その後の深夜に再び次の利用のための貯湯するための加熱運転がおこなわれる。このとき、入浴のために浴槽3に供給された湯は、給湯利用終了時には貯湯槽1内の水温に対して比較的高温で残されていることが多いので、熱回収運転制御手段21が、ヒートポンプユニット2による深夜の沸上運転の前、あるいは運転中に熱回収運転をおこなって貯湯
槽1内に熱を回収する。
Most of the hot water in the hot water storage tank 1 is replaced with hot water at the time when heat use such as hot water supply for one day is completed, and a heating operation for storing hot water for the next use is performed again at midnight thereafter. At this time, the hot water supplied to the bathtub 3 for bathing is often left at a relatively high temperature with respect to the water temperature in the hot water tank 1 at the end of use of the hot water supply. A heat recovery operation is performed before or during the midnight boiling operation by the heat pump unit 2 to recover heat in the hot water tank 1.

次に、風呂自動運転、追い焚き運転、および熱回収運転の制御方法について説明する。風呂自動運転制御手段29は、浴槽3へ所定量の湯を所定温度で自動で給湯し、その後、浴槽水温を予め設定された時間だけ予め設定された温度に保つように間欠的に保温動作を行う(風呂自動運転)。   Next, a control method for bath automatic operation, chasing operation, and heat recovery operation will be described. The bath automatic operation control means 29 automatically supplies a predetermined amount of hot water to the bathtub 3 at a predetermined temperature, and then intermittently performs a heat retaining operation so as to maintain the bath water temperature at a preset temperature for a preset time. Perform (automatic bath operation).

風呂自動運転をおこなっている間は、保温動作を行う必要があるかないかを判断するために、定期的に浴槽湯温を検出するための浴槽湯温検知動作を行う。浴槽水温の検知は浴槽水温検知手段17でおこない、その結果、浴槽水温が予め設定された温度より所定温度以上(例えば1K以上)低い場合には、保温運転をおこなって浴槽水温を保ち、所定温度未満の場合には、保温運転をおこなわない。   During bath automatic operation, in order to determine whether or not it is necessary to perform a heat retaining operation, a bath water temperature detecting operation is periodically performed to detect the bath water temperature. The bath water temperature is detected by the bath water temperature detection means 17, and as a result, when the bath water temperature is lower than a preset temperature by a predetermined temperature or more (for example, 1K or more), a heat insulation operation is performed to maintain the bath water temperature. If it is less than 1, do not keep warm.

この際、風呂自動運転と熱回収運転の関係は、どちらも同等であり、使用者による熱回収運転起動スイッチ26の操作で、熱回収運転制御手段21が起動した場合は、熱回収運転開始の指示を受けて熱回収運転は行う。   At this time, the relationship between the automatic bath operation and the heat recovery operation is the same. When the heat recovery operation control means 21 is activated by the operation of the heat recovery operation start switch 26 by the user, the heat recovery operation starts. Heat recovery operation is performed in response to instructions.

ただし、風呂自動運転を優先とし、使用者による熱回収運転起動スイッチ26の操作で熱回収運転開始の指示を受けても熱回収運転制御手段21は熱回収運転を行わず、一旦待機を行い、ふろ自動運転が終了した後に、熱回収運転を行うように制御することも可能である。   However, automatic bath operation is prioritized, and even if a heat recovery operation start switch 26 is instructed by the user to receive a heat recovery operation start instruction, the heat recovery operation control means 21 does not perform the heat recovery operation, It is also possible to control to perform the heat recovery operation after the automatic bath operation is completed.

逆に、熱回収運転中に風呂自動運転制御手段29が風呂自動運転開始の指示を受けた場合にも、使用者による、風呂自動運転操作を優先として、熱回収運転制御手段21は熱回収運転を停止し、風呂自動運転制御手段29が風呂自動運転を開始する(図3に概念図を示す)。   Conversely, even when the bath automatic operation control means 29 receives an instruction to start the bath automatic operation during the heat recovery operation, the heat recovery operation control means 21 gives priority to the bath automatic operation operation by the user and the heat recovery operation control means 21 performs the heat recovery operation. The bath automatic operation control means 29 starts the bath automatic operation (conceptual diagram is shown in FIG. 3).

追い焚き運転制御手段30は、浴槽3内の湯を循環加温し、浴槽水温検知手段17が検知する浴槽水温が所定の温度になる、または動作開始から所定の時間経過すると終了する(追い焚き運転)。   The reheating operation control means 30 circulates and warms the hot water in the bathtub 3 and ends when the bath water temperature detected by the bath water temperature detection means 17 reaches a predetermined temperature or when a predetermined time elapses from the start of the operation (refreshing). operation).

追い焚き運転制御手段30が追い焚き運転を行っている間も、追い焚き運転と熱回収運転との関係は、使用者による操作を優先とし、使用者による熱回収運転起動スイッチ26の操作で熱回収運転制御手段21が起動した場合は、追い焚き中でも熱回収運転開始の指示を受けて、熱回収運転は行うように制御する。   While the reheating operation control means 30 is performing the reheating operation, the relationship between the reheating operation and the heat recovery operation is given priority to the operation by the user, and the heat recovery operation start switch 26 is operated by the user. When the recovery operation control means 21 is activated, control is performed so that the heat recovery operation is performed in response to an instruction to start the heat recovery operation even during chasing.

ただし、追い焚き運転を行っている間は、追い焚き運転を優先とし、熱回収運転制御手段21は熱回収運転を行わず、追い焚き運転が終了した後に、熱回収運転を行うように制御することも可能である。   However, during the reheating operation, the renewal operation is given priority, and the heat recovery operation control means 21 does not perform the heat recovery operation, and performs control so that the heat recovery operation is performed after the reheating operation is completed. It is also possible.

逆に、熱回収運転中に追い焚き運転制御手段30が追い焚き運転の指示を受けた場合にも、追い焚き運転を優先として、熱回収運転制御手段21は熱回収運転を停止し、追い焚き運転制御手段30が追い焚き運転を開始する(図4に概念図を示す)。   Conversely, even when the reheating operation control means 30 receives an instruction for reheating operation during the heat recovery operation, the recuperation operation is given priority, and the heat recovery operation control means 21 stops the heat recovery operation and retreats. The operation control means 30 starts a chasing operation (a conceptual diagram is shown in FIG. 4).

各々の運転を行う場合の弁およびポンプの動作と、それに伴う水および湯の流れについて図5〜図8を用いて説明する。図中、流れのある経路は太線で示してある。   The operation of the valve and the pump when performing each operation and the flow of water and hot water associated therewith will be described with reference to FIGS. In the figure, the flow path is indicated by a bold line.

まず、風呂自動運転制御手段29が風呂自動運転を行うときの動作について説明する。最初に浴槽3へ給湯を行う場合における回路中の水および湯の流れを図5に示す。貯湯槽1からは、第1の出湯管22と第2の出湯管23からの湯を高温水混合弁24で混合して
高温水供給管8へ供給する。
First, the operation when the bath automatic operation control means 29 performs bath automatic operation will be described. FIG. 5 shows the flow of water and hot water in the circuit when hot water is first supplied to the bathtub 3. From the hot water storage tank 1, hot water from the first hot water discharge pipe 22 and the second hot water discharge pipe 23 is mixed by the high temperature water mixing valve 24 and supplied to the high temperature water supply pipe 8.

この高温水供給管8に供給された湯と給水管14から低温水供給管9へと供給される給水とが混合弁11にて給湯所望温度の湯に混合され、給湯管10へと供給される。ここで、高温水混合弁24から高温水供給管8に供給される湯の温度は、上記の給湯所望温度よりも所定温度以上高い温度(たとえば給湯所望温度が40℃の場合に45℃以上)に調節されている。   The hot water supplied to the high-temperature water supply pipe 8 and the water supplied from the water supply pipe 14 to the low-temperature water supply pipe 9 are mixed with hot water having a desired hot water supply temperature by the mixing valve 11 and supplied to the hot water supply pipe 10. The Here, the temperature of the hot water supplied from the high-temperature water mixing valve 24 to the high-temperature water supply pipe 8 is a temperature higher than the above-mentioned desired hot water supply temperature by a predetermined temperature or more (for example, 45 ° C. or more when the desired hot water supply temperature is 40 ° C.). It is adjusted to.

開閉弁13は開かれ、給湯管10へと供給された所望温度の湯は、浴槽水循環配管12より浴槽3へと給湯される。なお、高温水混合弁24と混合弁11の開度は、それぞれ出口側に接続された高温水供給管8と給湯管10に供給される湯の温度に基づいてフィードバック制御されるのが一般的であり、高温水混合弁24については第1の出湯管22と第2の出湯管からの湯、混合弁11については高温水供給管8からの湯と低温水供給管9からの給水の温度により変化する。   The on-off valve 13 is opened, and hot water having a desired temperature supplied to the hot water supply pipe 10 is supplied to the bathtub 3 from the bathtub water circulation pipe 12. The opening degree of the high temperature water mixing valve 24 and the mixing valve 11 is generally feedback controlled based on the temperature of hot water supplied to the high temperature water supply pipe 8 and the hot water supply pipe 10 respectively connected to the outlet side. For the high temperature water mixing valve 24, the hot water from the first outlet pipe 22 and the second outlet pipe, and for the mixing valve 11, the hot water from the high temperature water supply pipe 8 and the temperature of the feed water from the low temperature water supply pipe 9. It depends on.

浴槽3内の湯を保温する場合における回路中の水および湯の流れを図6に示す。貯湯槽水搬送ポンプ5aと浴槽水搬送ポンプ5bとが運転を開始し、貯湯槽水搬送ポンプ5aの運転により、貯湯槽1の略上部より高温のお湯が第1の出湯管22から熱交往き管33を経て切換手段32へと湯が供給され、熱交換器4へと供給される。   FIG. 6 shows the flow of water and hot water in the circuit when the hot water in the bathtub 3 is kept warm. The hot water storage tank water transfer pump 5a and the bathtub water transfer pump 5b start operation, and hot water from the hot water tank 1 is heated from the first outlet pipe 22 by the operation of the hot water storage tank water transfer pump 5a. Hot water is supplied to the switching means 32 through the pipe 33 and supplied to the heat exchanger 4.

このとき、熱交換器4にて浴槽水循環配管12を循環する浴槽3の湯を加熱して、浴槽水温を上昇させる。一方、熱交換器4を出て比較的低温となった湯は熱交戻り管16を経て貯湯槽1の略中央部へと還流する。   At this time, the hot water of the bathtub 3 circulating through the bathtub water circulation pipe 12 is heated by the heat exchanger 4 to raise the bathtub water temperature. On the other hand, the hot water that has left the heat exchanger 4 and has a relatively low temperature returns to the substantially central portion of the hot water tank 1 through the heat exchange return pipe 16.

浴槽3内の水温を検知するための浴槽水温検知動作を行う場合における回路中の水および湯の流れを図7に示す。浴槽水搬送ポンプ5bが運転を開始し、浴槽水循環配管12内を浴槽3内の湯が循環する。このとき、貯湯槽水搬送ポンプ5aは運転をおこなわない。浴槽水温検知手段17が浴槽水温を検知し、保温動作をするかしないかを判断する。   FIG. 7 shows the flow of water and hot water in the circuit when the bathtub water temperature detection operation for detecting the water temperature in the bathtub 3 is performed. The bathtub water conveyance pump 5b starts operation, and the hot water in the bathtub 3 circulates in the bathtub water circulation pipe 12. At this time, the hot water tank water transfer pump 5a does not operate. The bathtub water temperature detection means 17 detects the bathtub water temperature and determines whether or not to perform a heat retaining operation.

次に、追い焚き運転制御手段30が追い焚き運転を行う場合の動作であるが、追い焚き運転を行う場合における回路中の水および湯の流れは風呂自動運転制御手段29が保温動作を行う場合と同じで図6に示す通りであるので省略する。   Next, the operation when the reheating operation control means 30 performs the reheating operation, the flow of water and hot water in the circuit when the reheating operation is performed, when the bath automatic operation control means 29 performs the heat retaining operation. Since this is the same as shown in FIG.

最後に、熱回収運転制御手段21が、浴槽3に残された湯の熱回収運転を行う場合における回路中の水および湯の流れを図8に示す。浴槽水搬送ポンプ5bを運転させ、その後、貯湯槽水搬送ポンプ5aの運転させ、熱回収運転を開始すると、貯湯槽1の略下部からの湯水が前記熱交換器4に流れるように、熱回収往き管35、前記加熱手段であるヒートポンプユニット2、三方弁37を順に介して前記熱交換器4に接続された熱回収往き管35から供給される。   Finally, FIG. 8 shows the flow of water and hot water in the circuit when the heat recovery operation control means 21 performs the heat recovery operation of the hot water remaining in the bathtub 3. When the bath water transfer pump 5b is operated, and then the hot water tank water transfer pump 5a is operated and the heat recovery operation is started, the heat recovery is performed so that the hot water from the substantially lower portion of the hot water tank 1 flows to the heat exchanger 4. The heat is supplied from the heat recovery forward pipe 35 connected to the heat exchanger 4 through the forward pipe 35, the heat pump unit 2 as the heating means, and the three-way valve 37 in this order.

このとき、貯湯槽1の略下部から供給された湯水は上記記載の経路への供給により、熱交換器4へと供給される。供給された湯水は、熱交換器4にて浴槽水循環配管12を循環する浴槽3の湯と熱交換をおこなって熱を回収する。一方、熱交換器4を出て比較的高温となった湯は熱交戻り管16を経て貯湯槽1へと還流する。   At this time, the hot water supplied from the substantially lower part of the hot water tank 1 is supplied to the heat exchanger 4 by the supply to the above-mentioned path. The supplied hot water performs heat exchange with the hot water in the bathtub 3 circulating through the bathtub water circulation pipe 12 in the heat exchanger 4 to recover heat. On the other hand, the hot water leaving the heat exchanger 4 and having a relatively high temperature returns to the hot water storage tank 1 through the heat exchange return pipe 16.

なお、浴槽水搬送ポンプ5bによる湯の搬送量を貯湯槽水搬送ポンプ5aによる湯水の搬送量より大きくすることで、浴槽水搬送ポンプ5bによる必要流量が確保されて、浴槽3内の温度分布が均一化され、浴槽3から安定的に熱回収を行うことができるとともに、貯湯槽水搬送ポンプ5aによる搬送流量が過大になって、貯湯槽1内の湯水が攪拌されることなく、温度成層を保持できるため、後述する貯湯槽1内の湯水の沸き上げ運転を効率
的に行うことが可能となる。
In addition, the required flow volume by the bathtub water conveyance pump 5b is ensured by making the conveyance amount of the hot water by the bathtub water conveyance pump 5b larger than the conveyance amount of the hot water by the hot water tank water conveyance pump 5a, and the temperature distribution in the bathtub 3 is It is made uniform and heat can be stably recovered from the bathtub 3, and the flow rate by the hot water tank water transfer pump 5a becomes excessive, so that the hot water in the hot water tank 1 is not stirred and the temperature stratification is performed. Since it can hold | maintain, it becomes possible to perform the boiling operation of the hot water in the hot water storage tank 1 mentioned later efficiently.

熱回収運転をおこなった場合の貯湯槽1内の温度分布は図9に示す40、41、42の順に変化する。つまり、浴槽3と熱交換されて熱交戻り管16から貯湯槽1に流入する水43の温度は貯湯槽1の貯湯温よりも低い場合が多く、貯湯槽水搬送ポンプ5aの作用によって貯湯槽1の湯と混合しつつ貯湯槽1の下方に向けて移動する。   The temperature distribution in the hot water tank 1 when the heat recovery operation is performed changes in the order of 40, 41, and 42 shown in FIG. That is, the temperature of the water 43 that is heat-exchanged with the bathtub 3 and flows into the hot water tank 1 from the heat exchange return pipe 16 is often lower than the hot water temperature of the hot water tank 1, and the hot water tank is operated by the hot water tank water transfer pump 5a. It moves toward the lower side of the hot water tank 1 while being mixed with the hot water of No. 1.

第2の出湯管23の接続位置は熱交戻り管16の接続位置よりも下部にあるので、給湯が発生すると、下がってきた中温の水44を第2の出湯管23から出湯し、第1の出湯管からの高温水46と混合して利用することができる。図9に示す45は、熱回収後に給湯が発生した場合の温度分布を示している。このように第2の出湯管23が熱交戻り管16の貯湯槽への接続位置よりも下にあることで、回収した熱を効果的に利用することができる。   Since the connection position of the second hot water discharge pipe 23 is lower than the connection position of the heat exchange return pipe 16, when hot water is generated, the intermediate temperature water 44 that has come down is discharged from the second hot water discharge pipe 23, and the first It can be used by mixing with hot water 46 from the hot water pipe. Reference numeral 45 shown in FIG. 9 indicates a temperature distribution when hot water is generated after heat recovery. Thus, since the 2nd hot water discharge pipe 23 exists below the connection position to the hot water storage tank of the heat exchange return pipe 16, the collect | recovered heat | fever can be utilized effectively.

また、ヒートポンプユニット2の沸き上げ運転中に熱回収運転を開始する場合は、沸き上げ運転を停止して、沸き上げの残加熱量から必要な加熱時間を計算し、加熱時間が所定値以下であれば、熱回収運転時間上限タイマー57の上限時間を沸き上げ運転中以外の熱回収時間より短くする。これにより、貯湯槽水搬送ポンプ5aの能力を低下させて、熱回収時間を短く制御して、貯湯槽1の沸き上げ時間を増やし、貯湯槽1に貯湯するお湯の量を増加させることにより、お湯の必要量を確保して、湯切れを防止する。   In addition, when the heat recovery operation is started during the heating operation of the heat pump unit 2, the heating operation is stopped, the necessary heating time is calculated from the remaining heating amount of the heating, and the heating time is less than a predetermined value. If so, the upper limit time of the heat recovery operation time upper limit timer 57 is made shorter than the heat recovery time other than during the boiling operation. This reduces the capacity of the hot water tank water transfer pump 5a, controls the heat recovery time short, increases the boiling time of the hot water tank 1, and increases the amount of hot water stored in the hot water tank 1. Secure the necessary amount of hot water to prevent running out of hot water.

給湯の発生が比較的少なく、使い切れないで残った中温の水は、ヒートポンプユニット2で再加熱して利用することになるが、ヒートポンプユニット2の運転効率は、図10に示すように加熱前の水温が高いほど低下する。   The occurrence of hot water supply is relatively small, and the medium-temperature water that remains without being used up is reheated and used by the heat pump unit 2, but the operating efficiency of the heat pump unit 2 is as shown in FIG. The higher the water temperature, the lower it.

図9に示した貯湯槽1の温度分布からわかるように、熱回収運転後のヒートポンプユニット2による必要加熱量は、浴槽3からの回収熱量が増加するほど少なくなるものの、それと同時にヒートポンプユニット2で加熱する前の水温は高くなって、再加熱時の運転効率は低下するので、できるだけ多くの熱回収を行うことが必ずしも省エネルギーにつながらない。   As can be seen from the temperature distribution of the hot water tank 1 shown in FIG. 9, the required heating amount by the heat pump unit 2 after the heat recovery operation decreases as the amount of recovered heat from the bathtub 3 increases. Since the water temperature before heating becomes high and the operation efficiency at the time of reheating is reduced, it is not necessarily energy saving to perform as much heat recovery as possible.

すなわち、ヒートポンプユニット2への入力(消費熱量あるいは消費電力)は、所要貯湯熱量を得るための熱回収前の必要加熱量から熱回収運転によって得られた回収熱量を減じたものを、ヒートポンプユニット2による貯湯運転中の平均効率で除したものとなり、この値は図11に示すように、回収熱量に対して最小値を有する場合がある。   That is, the input (heat consumption or power consumption) to the heat pump unit 2 is obtained by subtracting the recovered heat amount obtained by the heat recovery operation from the necessary heat amount before heat recovery for obtaining the required hot water storage heat amount. As shown in FIG. 11, this value may have a minimum value for the recovered heat amount.

したがって、浴槽3からの熱回収運転を、熱回収運転停止後に行われる再加熱運転において、ヒートポンプユニット2への入力が略最小となる時点で停止することが、より高い省エネルギー効果を得るために必要である。   Therefore, in order to obtain a higher energy saving effect, it is necessary to stop the heat recovery operation from the bathtub 3 at the time when the input to the heat pump unit 2 becomes substantially minimum in the reheating operation performed after the heat recovery operation is stopped. It is.

最小値となる時点を見つける具体的な方法としては、所定の時間間隔で測定される貯湯槽1の温度分布に基づいて予想されるヒートポンプユニット2への入力値の刻々の変化の推移を求めて、その値の減少度合いが小さいか減少しなくなる、あるいは増加に転じることで判断する。   As a specific method for finding the time point at which the minimum value is reached, the change of the input value to the heat pump unit 2 that is predicted based on the temperature distribution of the hot water tank 1 measured at predetermined time intervals is obtained. Judgment is made when the degree of decrease in the value is small or no longer decreases, or starts to increase.

図10に示したように、貯湯槽1内の湯水をヒートポンプユニット2にて加熱する場合、貯湯槽1からヒートポンプユニット2に水を搬送させる部位の温度(本実施の形態においては、貯湯槽1の下部の温度)が低くなるにつれて、ヒートポンプユニット2の運転効率は高くなるが、浴槽3からの熱回収運転時、浴槽3から熱回収した水が貯湯槽1内に流入してくることで、貯湯槽1からヒートポンプユニット2に水を搬送させる部位の温度が
上昇し始める状態が存在する。
As shown in FIG. 10, when the hot water in the hot water tank 1 is heated by the heat pump unit 2, the temperature at the site where water is transported from the hot water tank 1 to the heat pump unit 2 (in this embodiment, the hot water tank 1 The operating efficiency of the heat pump unit 2 increases as the temperature of the lower part of the heat pump unit 2 decreases. However, when the heat recovery operation from the bathtub 3 is performed, the water recovered from the bathtub 3 flows into the hot water tank 1. There is a state in which the temperature of the part that transports water from the hot water tank 1 to the heat pump unit 2 starts to rise.

したがって、浴槽3からの熱回収運転時に、貯湯槽1のヒートポンプユニット2に水を搬送させる部位の温度を測定し、その温度の上昇度合いが増加に転じる付近で、浴槽3からの熱回収運転動作を停止させることで、熱回収運転後の加熱運転時におけるヒートポンプユニット2の運転効率の略最大を実現できるのである。   Therefore, at the time of the heat recovery operation from the bathtub 3, the temperature of the part that transports water to the heat pump unit 2 of the hot water tank 1 is measured, and the heat recovery operation operation from the bathtub 3 is performed in the vicinity where the increase in the temperature starts to increase. By stopping the operation, it is possible to achieve substantially the maximum operating efficiency of the heat pump unit 2 during the heating operation after the heat recovery operation.

上記を勘案して湯切れがなく、高い省エネルギー効果を得るための熱回収運転制御手段21の制御方法について説明する。   Considering the above, a control method of the heat recovery operation control means 21 for obtaining a high energy saving effect without running out of hot water will be described.

図12は熱回収運転制御手段21の動作のフローチャートである。使用者による熱回収運転起動スイッチ26の操作を行った場合、あるいは風呂自動運転制御手段29による風呂自動運転終了後の所定時間経過後などで自動で熱回収する設定を行うことも可能である。熱回収運転の開始を熱回収運転開始判断部50が判断すると、浴槽3内に水(お湯)があるかどうかを行うために、浴槽水搬送ポンプ5bを駆動させる。   FIG. 12 is a flowchart of the operation of the heat recovery operation control means 21. It is also possible to make a setting for automatically recovering heat when the user operates the heat recovery operation start switch 26 or when a predetermined time elapses after the bath automatic operation control means 29 ends. When the heat recovery operation start determination unit 50 determines the start of the heat recovery operation, the bathtub water conveyance pump 5b is driven to determine whether or not there is water (hot water) in the bathtub 3.

このとき浴槽水検出手段31により、浴槽3内の水(お湯)の有無を検出し(ステップ1)、浴槽3内に水(お湯)があると判断した場合はステップ3へ、浴槽3内に水(お湯)がないと判断した場合は、熱回収運転を開始しないで終了する(ステップ2)。   At this time, the presence or absence of water (hot water) in the bathtub 3 is detected by the bathtub water detection means 31 (step 1). If it is determined that there is water (hot water) in the bathtub 3, go to step 3; If it is determined that there is no water (hot water), the heat recovery operation is terminated without starting (step 2).

ここで、浴槽内に水(お湯)があるかどうかを行うために、最初に水位センサ27によって浴槽の湯量に比例する水位を検知し(ステップ1)、ここで予め設定された水位以下であれば、熱回収運転を開始しないで終了する(ステップ2)ことも可能である。   Here, in order to determine whether or not there is water (hot water) in the bathtub, first, the water level sensor 27 detects a water level proportional to the amount of hot water in the bathtub (step 1), and if it is below the preset water level. For example, the heat recovery operation can be terminated without starting (step 2).

ステップ1で浴槽水検出手段31により、浴槽3内の水(お湯)があると判断した場合、もしくはステップ1で水位が予め設定された水位を超えており、浴槽3内に十分に水(お湯)があると判断した場合、ヒートポンプユニット2が沸き上げ運転中であるか判断し、(ステップ3)沸き上げ運転中であれば、沸き上げ運転を停止する(ステップ4)。   When the bathtub water detection means 31 determines in step 1 that there is water (hot water) in the bathtub 3, or the water level exceeds a preset water level in step 1, and sufficient water (hot water) is contained in the bathtub 3. ), It is determined whether the heat pump unit 2 is in a boiling operation. (Step 3) If the heating pump unit 2 is in a boiling operation, the boiling operation is stopped (Step 4).

次に、所要貯湯熱量取得部51で取得された所要貯湯熱量と貯湯温検知手段28a〜28eにより測定された現在の貯湯槽1の温度分布、およびヒートポンプユニット2の沸き上げ温度等の運転条件から貯湯運転完了時の貯湯槽1内の温度分布を予測し、それを現在の温度分布と比較して、その時点からヒートポンプユニット2で加熱する場合の残りの加熱量Qrおよび必要加熱時間T1を求める(ステップ5)。   Next, from the required hot water storage amount acquired by the required hot water storage amount acquisition unit 51, the current temperature distribution of the hot water tank 1 measured by the hot water storage temperature detection means 28a to 28e, and the operating conditions such as the boiling temperature of the heat pump unit 2. The temperature distribution in the hot water tank 1 at the time of completion of the hot water storage operation is predicted, compared with the current temperature distribution, and the remaining heating amount Qr and the required heating time T1 when the heat pump unit 2 heats from that point are obtained. (Step 5).

ヒートポンプユニット2の必要加熱時間T1と所定値Taを比較し(ステップ6)所定値Taより長ければ、熱回収上限運転時間TrをTr1まで低下させる。(ステップ7)
逆に、ヒートポンプユニット2が沸き上げ中でない場合やヒートポンプユニット2の必要加熱時間T1と所定値Ta比較し(ステップ6)所定値Taより短ければ、熱回収上限運転時間Trはそのままとする(ステップ8)。
The required heating time T1 of the heat pump unit 2 is compared with a predetermined value Ta (step 6), and if it is longer than the predetermined value Ta, the heat recovery upper limit operation time Tr is reduced to Tr1. (Step 7)
On the contrary, when the heat pump unit 2 is not being heated or when the required heating time T1 of the heat pump unit 2 is compared with the predetermined value Ta (step 6), if the heat pump unit 2 is shorter than the predetermined value Ta, the heat recovery upper limit operation time Tr is left as it is (step 8).

次に、測定された現在の温度分布から、予測された貯湯運転完了時の温度分布に達するまでの間にヒートポンプユニット2で沸き上げる前の平均水温を推定する(ステップ9)。   Next, the average water temperature before boiling in the heat pump unit 2 is estimated from the measured current temperature distribution until reaching the predicted temperature distribution at the time of completion of the hot water storage operation (step 9).

さらにステップ9で求めた平均水温と図10で示したヒートポンプユニット2の特性とから貯湯運転時の平均効率を求め、ステップ5で求めた残りの加熱量Qrをこの平均効率で除して、貯湯運転時の入力Qinを推定する(ステップ10)。   Further, the average efficiency during hot water storage operation is obtained from the average water temperature obtained in step 9 and the characteristics of the heat pump unit 2 shown in FIG. 10, and the remaining heating amount Qr obtained in step 5 is divided by this average efficiency to obtain hot water storage water. The input Qin during operation is estimated (step 10).

Qinは前回の評価時刻において求めた値であるQin−fとの差を求め、それが予め
定めた偏差qより小さい場合、すなわち推定入力の変化が次第に小さくなって最小値と判断し、熱回収上限運転時間Tr(Tr1)に達すれば(ステップ11)、ステップ2で貯湯槽水搬送ポンプ5aと浴槽水搬送ポンプ5bとを停止して熱回収運転を終了する。QinとQin−fとの差がq以上の場合で熱回収上限運転時間Tr(Tr1)に達してなければ熱回収運転を継続し(ステップ12)、次の評価時刻になれば(ステップ13)、以上の動作を繰り返す。
Qin obtains the difference from Qin−f, which is the value obtained at the previous evaluation time, and if it is smaller than the predetermined deviation q, that is, the estimated input change gradually becomes smaller and is judged to be the minimum value, and heat recovery When the upper limit operation time Tr (Tr1) is reached (step 11), the hot water storage tank water transfer pump 5a and the bath water transfer pump 5b are stopped in step 2 to end the heat recovery operation. If the difference between Qin and Qin−f is greater than or equal to q and the heat recovery upper limit operation time Tr (Tr1) has not been reached, the heat recovery operation is continued (step 12), and if the next evaluation time is reached (step 13). Repeat the above operation.

なお、補足として熱回収運転開始後一回目の動作時は、ステップ11での比較はおこなわずにステップ12を実行する。   As a supplement, at the first operation after the start of the heat recovery operation, step 12 is executed without performing the comparison at step 11.

ここで、浴槽水検出手段31により、浴槽3内の水(お湯)の有無を検出する動作を説明したが、浴槽水検出手段31により、ステップ1では熱回収運転が開始された後で浴槽3内の水(お湯)がないと判断した場合にも、熱回収運転は停止されることになる(ステップ2)。   Here, although the operation of detecting the presence or absence of water (hot water) in the bathtub 3 has been described by the bathtub water detection means 31, the bathtub 3 is detected after the heat recovery operation is started in step 1 by the bathtub water detection means 31. Even when it is determined that there is no water (hot water) inside, the heat recovery operation is stopped (step 2).

また、熱回収運転の開始時の浴槽3内の水の検出に水位による動作を説明したが、同様に熱回収運転が開始された後で水位が予め設定された水位以下となった場合にも、熱回収運転は停止されることになる(ステップ2)。これにより、浴槽3内の水(お湯)が途中でなくなった場合に熱回収運転を停止させることができる。   Moreover, although the operation | movement by a water level was demonstrated to the detection of the water in the bathtub 3 at the time of the start of heat recovery driving | operation, also when a water level becomes below the preset water level after heat recovery driving | operation starts similarly, The heat recovery operation is stopped (step 2). Thereby, when the water (hot water) in the bathtub 3 runs out on the way, the heat recovery operation can be stopped.

熱回収運転停止後、ヒートポンプユニット2の沸き上げ中に熱回収運転を行った場合(ステップ14)はヒートポンプユニット2の沸き上げを再度開始する(ステップ15)。   After the heat recovery operation is stopped, when the heat recovery operation is performed during the boiling of the heat pump unit 2 (step 14), the heating of the heat pump unit 2 is started again (step 15).

以上が動作の説明であるが、浴槽3の湯量によらない熱回収運転の停止は、ヒートポンプユニット2の入力の最小値の判断を減少度合いが小さくなったことと、熱回収上限運転時間でおこなっている。この方法以外に、評価時刻間の入力の差qが0となる場合、またはqの符号が前回の評価時刻と逆になる場合、すなわち推定入力が増加に転じるときを最小値として用い、かつ熱回収上限運転時間で熱回収運転を停止してもよい。   The above is the explanation of the operation, but the stop of the heat recovery operation that does not depend on the amount of hot water in the bathtub 3 is performed with the determination that the minimum value of the input of the heat pump unit 2 is reduced and the heat recovery upper limit operation time. ing. In addition to this method, when the input difference q between the evaluation times is 0, or when the sign of q is opposite to the previous evaluation time, that is, when the estimated input starts to increase, the minimum value is used. The heat recovery operation may be stopped within the recovery upper limit operation time.

また、測定される貯湯槽1の温度の値の測定誤差等により、推定入力は最小値に至る間に増減のあることも多い。したがって、最近の数回の評価時刻における推定入力を記憶しておき、その移動平均値を用いて最小値に達したかどうかを判断することによって、最小値に達したかどうかの判定精度をより高められる場合もある。   In addition, the estimated input often increases or decreases while reaching the minimum value due to a measurement error of the temperature value of the hot water tank 1 to be measured. Therefore, by storing the estimated input at the latest several evaluation times, and determining whether the minimum value has been reached by using the moving average value, the determination accuracy of whether the minimum value has been reached is further improved. Can be increased.

さらには、以上説明したような、その都度温度分布を評価して入力を求める方法は精度が高いものの計算が煩雑となり、熱回収運転制御手段21の負荷が大きい。   Furthermore, as described above, the method of evaluating the temperature distribution each time and obtaining the input is highly accurate, but the calculation is complicated and the load on the heat recovery operation control means 21 is large.

その場合は、入力に対して最も影響を与える位置の貯湯温の変化を予め把握しておき、その位置に対応する貯湯温検知手段28a〜28eのうち、いずれかの温度が上昇し始めたときや所定の温度上昇がみられたとき、あるいは、たとえば貯湯温検知手段28dの検知温度が上昇し、かつ貯湯温検知手段28eの検知温度は上昇しない間は熱回収運転を継続するというように、二つ以上の温度の組み合わせに応じて停止の判断をしてもよい。   In that case, when a change in hot water storage temperature at a position that most affects the input is grasped in advance, and one of the hot water storage temperature detection means 28a to 28e corresponding to that position starts to rise. When the predetermined temperature rise is observed or, for example, while the detection temperature of the hot water storage temperature detection means 28d is increased and the detection temperature of the hot water storage temperature detection means 28e is not increased, the heat recovery operation is continued. The stop may be determined according to a combination of two or more temperatures.

具体的には、比較的貯湯槽1の下部に近い温度が上昇してくることを検出して熱回収運転を停止させることによってもヒートポンプユニット2の効率を損なうことが少なくなって所望の効果を得ることができる。さらに、貯湯槽1のより上部の温度の変化を考慮すれば、熱回収運転による回収熱量の確保を同時に評価でき、精度は向上する。   Specifically, it is possible to reduce the efficiency of the heat pump unit 2 by reducing the heat recovery operation by detecting that the temperature relatively close to the lower portion of the hot water tank 1 is rising. Can be obtained. Furthermore, if the change of the temperature of the upper part of the hot water tank 1 is taken into consideration, it is possible to simultaneously evaluate the amount of recovered heat by the heat recovery operation, and the accuracy is improved.

このように、本発明の実施の形態によれば、浴槽3に湯がないか、または少ない状態では熱回収運転をせず、熱回収運転自体ができないか、しても効果が得られない条件での運
転を防止できる。
As described above, according to the embodiment of the present invention, there is no hot water in the bathtub 3, or the heat recovery operation is not performed in a state where the amount is small, and the heat recovery operation itself cannot be performed or the effect is not obtained Driving in can be prevented.

このとき、熱回収運転を開始するタイミングで湯がないか少ない場合には熱回収運転を開始せず、また熱回収運転中に湯が減少してそのような状態になった場合にも即座に熱回収運転を停止する。さらに、湯量が回復すれば熱回収運転を改めて開始、あるいは再開することにより、省エネルギー性を損なわない運転ができる。   At this time, if there is no or little hot water at the timing of starting the heat recovery operation, the heat recovery operation is not started, and even if the hot water decreases during the heat recovery operation and becomes such a state immediately. Stop heat recovery operation. Furthermore, if the amount of hot water is recovered, the heat recovery operation can be started or restarted, whereby an operation that does not impair the energy saving performance can be performed.

熱回収運転の再開は、湯量が回復してから所定の時間が経過することなどで自動でもおこなわれるが、使用者が浴槽3の湯量を確認して熱回収運転起動スイッチ26を操作することによって即座に再開することができるので、時間経過による浴槽3からの無駄な放熱が抑えられ、省エネルギー性が高まる。   The resumption of the heat recovery operation is automatically performed when a predetermined time elapses after the amount of hot water has recovered, but the user confirms the amount of hot water in the bathtub 3 and operates the heat recovery operation start switch 26. Since it can be restarted immediately, useless heat radiation from the bathtub 3 over time is suppressed, and energy saving is improved.

また、風呂自動運転と追い焚き運転と熱回収運転を実現するための配管系の構成において、前記熱交換器4により前記浴槽3の湯の有する熱を前記貯湯槽1の湯水に回収する熱回収運転を行うときには、前記熱回収往き管35、前記加熱手段であるヒートポンプユニット2、前記切換手段32、前記熱交換器4、前記熱交戻り管16の順に前記貯湯槽1からの湯水が流れるように構成することで、熱回収時に使用する配管の一部を、上述した貯湯槽内の湯水の沸き上げ運転時にも使用する構成とすることができ、低コスト化を実現した給湯装置を提供できる。   Further, in the configuration of the piping system for realizing the automatic bath operation, the reheating operation, and the heat recovery operation, the heat recovery for recovering the heat of the hot water in the bathtub 3 to the hot water in the hot water tank 1 by the heat exchanger 4. When the operation is performed, the hot water from the hot water tank 1 flows in the order of the heat recovery forward pipe 35, the heat pump unit 2 as the heating means, the switching means 32, the heat exchanger 4, and the heat exchange return pipe 16. With this configuration, a part of the piping used at the time of heat recovery can be configured to be used also during the boiling operation of the hot water in the hot water storage tank described above, and a hot water supply device that realizes cost reduction can be provided. .

また、筐体内に新たな部材の設置スペースを確保する必要がなく、重量や材料の増加、さらには待機電力の増大もなく、省資源、省エネルギーにも寄与する。また、併せて熱交換器4は熱交換効率の高いプレート式とするとともに、貯湯槽1の熱交戻り管16の接続位置近傍に設置することで、熱交換器4自体をコンパクトにした上で最小限の配管長として、同様に省資源となる。   In addition, it is not necessary to secure an installation space for a new member in the housing, and there is no increase in weight, material, and standby power, contributing to resource and energy savings. In addition, the heat exchanger 4 is a plate type with high heat exchange efficiency, and is installed near the connection position of the heat exchange return pipe 16 of the hot water tank 1 to make the heat exchanger 4 itself compact. As a minimum pipe length, it will save resources as well.

そして、熱回収運転を行う際には、所要貯湯熱量を沸き上げるためのヒートポンプユニット2への入力が最小となる時点および、湯切れが発生しない熱回収上限運転時間で熱回収運転を停止することによって、本来の目的であるシステム全体としての効率向上と湯切れ防止を実現し、省エネルギー性を高めることができる。   When performing the heat recovery operation, the heat recovery operation is stopped at the time when the input to the heat pump unit 2 for boiling up the required hot water storage amount is minimum and the heat recovery upper limit operation time at which hot water does not run out. As a result, it is possible to improve the efficiency of the entire system, which is the original purpose, and to prevent running out of hot water, and to improve energy saving.

構成としては、貯湯槽1下部の水を取り出して熱交換器4で加熱し、貯湯槽1の比較的上部へ戻しているが、熱回収運転による貯湯槽1内の温度分布はこの取り出し位置や戻し位置の違いによって変わる。   As a configuration, the water in the lower part of the hot water tank 1 is taken out and heated by the heat exchanger 4 and returned to the relatively upper part of the hot water tank 1. It depends on the difference in the return position.

さらに、貯湯槽水搬送ポンプ5aの能力制御によって熱回収の速度なども制御でき、これら構成や制御の違いに応じて運転効率も変化する。   Furthermore, the heat recovery speed and the like can be controlled by controlling the capacity of the hot water tank water transfer pump 5a, and the operation efficiency changes depending on the difference in configuration and control.

したがって、この実施の形態では、使われ方や貯湯槽1の容量などを考慮して適切な取り出し位置や戻り位置を設定したり、貯湯槽水搬送ポンプ5aの能力制御をおこなえるといった最適化設計の自由度が高いために複数の異なる機種に適用しやすく、その結果、多くの使用者に提供することによって大きな省エネルギー効果を得ることができる。   Therefore, in this embodiment, an optimized design is made such that an appropriate take-out position and return position can be set in consideration of usage, the capacity of the hot water tank 1, and the capacity control of the hot water tank water transfer pump 5a can be performed. Since the degree of freedom is high, it can be easily applied to a plurality of different models, and as a result, a large energy saving effect can be obtained by providing it to many users.

さらに、貯湯槽1からの給湯において、第1の出湯管22と第2の出湯管23とからの湯を高温水混合弁24で適切に混合して貯湯槽1内の中温水を有効に利用するとともに、熱交戻り管16の貯湯槽1への接続位置を第2の出湯管23よりも上にすることによって、温度成層型の貯湯槽において不可避な貯湯槽上部の高温水と下部の低温水との間にできる中温水を有効に利用できる結果、同じ蓄熱量でも貯湯槽下方に低温の水が多く確保できることから浴槽水からの回収熱量を大きくできる。   Furthermore, in hot water supply from the hot water tank 1, hot water from the first hot water discharge pipe 22 and the second hot water discharge pipe 23 is appropriately mixed by the high temperature water mixing valve 24 to effectively use the medium temperature water in the hot water storage tank 1. In addition, by making the connection position of the heat exchange return pipe 16 to the hot water storage tank 1 higher than the second hot water discharge pipe 23, the hot water in the upper part of the hot water tank and the lower temperature in the lower part are inevitable in the temperature stratified hot water tank. As a result of the effective use of the medium-temperature water that can be formed between the water and the water, the amount of heat recovered from the bath water can be increased because a large amount of low-temperature water can be secured below the hot water tank even with the same heat storage amount.

また、熱回収により発生した中温水を貯湯槽1の比較的上部に流入させることは、増加しながら貯湯槽1下方に移動する中温水を、熱回収した湯の流入位置よりも下にある第2の出湯管23を通じて給湯に利用できるので、貯湯された湯の熱量を最大限有効に使うことができる。   In addition, the flow of the intermediate warm water generated by the heat recovery into the relatively upper portion of the hot water storage tank 1 means that the intermediate warm water that moves below the hot water storage tank 1 while increasing is lower than the inflow position of the hot recovered hot water. Since it can be used for hot water supply through the two hot water outlet pipes 23, the amount of stored hot water can be used to the maximum extent possible.

同時にヒートポンプユニット2の沸き上げ効率の低下を招く貯湯槽1内の中温水が減少することでシステム全体の効率低下を防ぐことができ、熱量の有効利用による良好な使い勝手と高い省エネルギー性とを実現する。   At the same time, the medium temperature water in the hot water tank 1 that reduces the heating efficiency of the heat pump unit 2 is reduced, so that the efficiency of the entire system can be prevented from being lowered. To do.

さらに、浴槽水がないかまたは少ない場合に熱回収運転を始めると、第2の出湯管23と熱交戻り管16を適切な位置に設置することによって中温水をうまく利用して貯湯槽1下部に多くの低温の水を確保する構成にもかかわらず、貯湯槽水搬送ポンプ5aを作動させることによって貯湯槽内に中温水を増大させることになる。   Further, when the heat recovery operation is started when there is no or little bath water, the second hot water discharge pipe 23 and the heat exchange return pipe 16 are installed at appropriate positions, so that the hot water can be used well and the lower part of the hot water tank 1 In spite of the configuration of securing a large amount of low-temperature water, the hot water storage tank 5 is operated to increase the amount of hot water in the hot water storage tank.

この場合は熱回収の効果が得られない上に、ヒートポンプユニット2での沸き上げの際に効率を低下させてしまうが、予め浴槽湯量を検知して熱回収運転の実行を判断するので、第2の出湯管23と熱交戻り管16の接続位置の最適化によって得られる高い省エネルギー性を損なわない。   In this case, the effect of heat recovery cannot be obtained, and the efficiency is lowered when the heat pump unit 2 is heated. However, since the amount of hot water in the bath is detected in advance to determine the execution of the heat recovery operation, The high energy-saving property obtained by optimizing the connection position of the hot water return pipe 23 and the heat exchange return pipe 16 is not impaired.

すなわち、熱回収運転を適切に制御し、湯切れがなく、高い省エネルギー性能を実現した給湯装置を提供することができるものである。   That is, it is possible to provide a hot water supply apparatus that appropriately controls the heat recovery operation, does not run out of hot water, and realizes high energy saving performance.

以上のように、本発明にかかる給湯装置は、浴槽の湯からの熱回収運転に際し、湯量を考慮して適切な制御を行うので、家庭用の給湯装置に適用できるほか、業務用などの規模の大きい用途にも適用し、実用性に優れた給湯装置の制御方式を提供できる。   As described above, the hot water supply apparatus according to the present invention performs appropriate control in consideration of the amount of hot water during the operation of recovering heat from the hot water in the bathtub, so that it can be applied to a hot water supply apparatus for home use and a scale for business use. It can be applied to large applications and can provide a practical hot water control system.

1 貯湯槽
2 ヒートポンプユニット(第1の加熱手段)
3 浴槽(第1の加熱手段による加熱温度よりも低温の熱源)
4 熱交換器(第2の加熱手段)
5a 貯湯槽水搬送ポンプ
5b 浴槽水搬送ポンプ
8 高温水供給管
9 低温水供給管
10 給湯管
11 混合弁
12 浴槽水循環配管
13 開閉弁
14 給水管
16 熱交戻り管
17 浴槽水温検知手段
18 運転制御手段
21 熱回収運転制御手段
22 第1の出湯管
23 第2の出湯管
24 高温水混合弁
25 リモコン
26 熱回収運転起動スイッチ
27 水位センサ
28 貯湯温検知手段
29 風呂自動運転制御手段
30 追い焚き運転制御手段
31 浴槽水検出手段
32 切換手段
33 熱交往き管
35 熱回収往き管
36 沸き上げ戻り管
37 三方弁
1 Hot water storage tank 2 Heat pump unit (first heating means)
3 Bathtub (heat source lower in temperature than the heating temperature by the first heating means)
4 Heat exchanger (second heating means)
5a Hot water tank water transfer pump 5b Bath water transfer pump 8 High temperature water supply pipe 9 Low temperature water supply pipe 10 Hot water supply pipe 11 Mixing valve 12 Bath water circulation pipe 13 Open / close valve 14 Water supply pipe 16 Heat exchange return pipe 17 Bath water temperature detection means 18 Operation control Means 21 Heat recovery operation control means 22 First outlet pipe 23 Second outlet pipe 24 Hot water mixing valve 25 Remote control 26 Heat recovery operation start switch 27 Water level sensor 28 Hot water storage temperature detection means 29 Bath automatic operation control means 30 Reheating operation Control means 31 Bath water detection means 32 Switching means 33 Heat exchange pipe 35 Heat recovery forward pipe 36 Heating return pipe 37 Three-way valve

Claims (3)

貯湯槽と、前記貯湯槽の水を加熱する加熱手段と、前記貯湯槽外に設けられ、前記加熱手段による沸き上げ運転の加熱温度よりも低温の熱源である浴槽と、前記貯湯槽内の湯水と前記浴槽内の湯水とを熱交換させ、前記浴槽の湯の有する熱を前記貯湯槽の湯水に回収する熱回収機能を含む熱交換器と、制御手段とを備え、前記沸き上げ運転中に前記熱回収運転を行なうときは、前記熱回収運転の運転時間を、前記沸き上げ運転中以外の前記熱回収運転の運転時間より短くすることを特徴とする給湯装置。 And the hot water storage tank, a heating means for heating the water in the hot water tank, the hot water storage tank outside the provided and tub is cold heat source than the heating temperature of the boiling operation by the heating means, hot water of the hot water storage tank and hot water in said bathtub is heat exchanger, a heat exchanger comprising a heat recovery function for recovering the heat of the hot water of the bathtub to the hot water of the hot water storage tank, and control means, in said boiling operation and when performing the heat recovery operation, water heater, characterized in that the operating time of the heat recovery operation will be shorter than the operating time of the heat recovery operation except during the boiling operation. 前記熱回収運転停止後の、前記沸き上げ運転時における入力が略最小となるように、前記熱回収運転を停止させることを特徴とする請求項1に記載の給湯装置。 The hot water supply apparatus according to claim 1, wherein the heat recovery operation is stopped so that an input during the boiling operation after the heat recovery operation is stopped is substantially minimized. 前記加熱手段はヒートポンプユニットで、前記熱交換器に前記浴槽内の湯水が循環するように接続された浴槽循環路と、前記貯湯槽内の略上部の湯が前記熱交換器に流れるように切換手段を介して前記熱交換器に接続された熱交往き管と、前記熱交換器で前記浴槽の湯水と熱交換された湯水が再び前記貯湯槽内へ戻るように前記貯湯槽に接続された熱交戻り管と、前記貯湯槽の略下部の湯水が前記熱交換器に流れるように、前記ヒートポンプユニット、前記切換手段を順に介して前記熱交換器に接続された熱回収往き管と、前記ヒートポンプユニットにて加熱された湯水が前記貯湯槽内に戻るように、前記切換手段から前記貯湯槽に接続された沸き上げ戻り管とを備え、前記熱回収運転を行うときには、前記熱回収往き管、前記ヒートポンプユニット、前記切換手段、前記熱交換器、前記熱交戻り管の順に前記貯湯槽からの湯水が流れるように、また、前記沸き上げ運転を行うときには、前記熱回収往き管、前記ヒートポンプユニット、前記切換手段、前記沸き上げ戻り管の順に前記貯湯槽からの湯が流れるように、前記制御手段が前記切換手段を切り換える構成としたことを特徴とする請求項1または2に記載の給湯装置。 The heating means is a heat pump uni Tsu bets, so that a connected bath circulation path so hot water is circulated in said bath to the heat exchanger, a substantially upper portion of the hot water in the hot water storage tank flows into the heat exchanger A heat transfer pipe connected to the heat exchanger via the switching means, and connected to the hot water storage tank so that the hot water exchanged with the hot water of the bathtub by the heat exchanger returns to the hot water storage tank again. A heat recovery return pipe connected to the heat exchanger via the heat pump unit and the switching means in order so that the hot water at the lower part of the hot water tank flows to the heat exchanger; A heating return pipe connected from the switching means to the hot water storage tank so that hot water heated by the heat pump unit returns to the hot water storage tank, and when performing the heat recovery operation, Outward pipe, heat pump Knit, said switching means, said heat exchanger, said heat交戻Ri tube of the as hot water from the hot water tank flows in the forward, also when performing a raising operation-out the boiling, the heat recovery forward pipe, the heat pump unit, The hot water supply apparatus according to claim 1 or 2, wherein the control means switches the switching means so that hot water from the hot water tank flows in the order of the switching means and the boiling return pipe.
JP2012044976A 2012-03-01 2012-03-01 Water heater Active JP5948602B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP2012044976A JP5948602B2 (en) 2012-03-01 2012-03-01 Water heater

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2012044976A JP5948602B2 (en) 2012-03-01 2012-03-01 Water heater

Publications (2)

Publication Number Publication Date
JP2013181686A JP2013181686A (en) 2013-09-12
JP5948602B2 true JP5948602B2 (en) 2016-07-06

Family

ID=49272475

Family Applications (1)

Application Number Title Priority Date Filing Date
JP2012044976A Active JP5948602B2 (en) 2012-03-01 2012-03-01 Water heater

Country Status (1)

Country Link
JP (1) JP5948602B2 (en)

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP6493369B2 (en) * 2016-11-30 2019-04-03 ダイキン工業株式会社 Water heater
JP6555237B2 (en) * 2016-11-30 2019-08-07 ダイキン工業株式会社 Water heater

Family Cites Families (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP3663828B2 (en) * 1997-05-21 2005-06-22 松下電器産業株式会社 Heat pump bath water supply system
JP2005049094A (en) * 2004-11-12 2005-02-24 Matsushita Electric Ind Co Ltd Water heater
JP4937052B2 (en) * 2007-09-12 2012-05-23 三菱電機株式会社 Hot water storage water heater
JP5215692B2 (en) * 2008-03-07 2013-06-19 東芝キヤリア株式会社 Heat pump water heater
JP2010014293A (en) * 2008-07-01 2010-01-21 Denso Corp Hot water supply device

Also Published As

Publication number Publication date
JP2013181686A (en) 2013-09-12

Similar Documents

Publication Publication Date Title
JP5919475B2 (en) Water heater
JP5948602B2 (en) Water heater
JP2013032863A (en) Water heater
JP6628643B2 (en) Hot water supply system
JP5903654B2 (en) Water heater
JP5903540B2 (en) Water heater
JP2013036708A (en) Water heater
JP5909637B2 (en) Water heater
JP5879504B2 (en) Water heater
JP5126433B1 (en) Water heater
JP4710511B2 (en) Hot water storage water heater
JP5934907B2 (en) Water heater
JP5163822B1 (en) Water heater
JP6111409B2 (en) Water heater
JP5942087B2 (en) Water heater
JP2013032892A (en) Hot water supply apparatus
JP5126431B1 (en) Water heater
JP2013036709A (en) Water heating apparatus
JP5106567B2 (en) Hot water storage hot water supply system
CN102434911A (en) Control method and device for hot water circulation
JP5927495B2 (en) Water heater
JP5942088B2 (en) Water heater
JP2013024533A (en) Water heater
JP5942089B2 (en) Water heater
JP5927494B2 (en) Water heater

Legal Events

Date Code Title Description
A621 Written request for application examination

Free format text: JAPANESE INTERMEDIATE CODE: A621

Effective date: 20150209

A711 Notification of change in applicant

Free format text: JAPANESE INTERMEDIATE CODE: A711

Effective date: 20150312

A131 Notification of reasons for refusal

Free format text: JAPANESE INTERMEDIATE CODE: A131

Effective date: 20151117

A977 Report on retrieval

Free format text: JAPANESE INTERMEDIATE CODE: A971007

Effective date: 20151120

A521 Written amendment

Free format text: JAPANESE INTERMEDIATE CODE: A523

Effective date: 20151216

TRDD Decision of grant or rejection written
A01 Written decision to grant a patent or to grant a registration (utility model)

Free format text: JAPANESE INTERMEDIATE CODE: A01

Effective date: 20160426

A61 First payment of annual fees (during grant procedure)

Free format text: JAPANESE INTERMEDIATE CODE: A61

Effective date: 20160509

R151 Written notification of patent or utility model registration

Ref document number: 5948602

Country of ref document: JP

Free format text: JAPANESE INTERMEDIATE CODE: R151