JP5927495B2 - Water heater - Google Patents

Description

  The present invention relates to a hot water supply apparatus having a heat recovery function.

  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).

  FIG. 17 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.

  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. 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.

  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.

  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.).

  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. 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.

  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 in the hot water storage tank 1 (for example, about 80 ° C.) 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.

  Finally, in the case of performing the heat recovery operation, the hot water tank water transfer pump 5a and the bath water transfer pump 5b are similarly operated. In the heat exchanger 4, the water in the hot water tank 1 (for example, about 10 ° C.) Cools the water (for example, about 35 ° C.) in the bathtub 3 and recovers heat.

  As a result, the water temperature in the bathtub 3 drops and the amount of heat (heat storage amount) stored as hot water in the hot water tank 1 increases, so that the amount of heat heated up by the heat pump unit 2 can be reduced.

In addition, as one of the methods for controlling such operation, there is a method of setting a time until the heat recovery operation is started after stopping the automatic bath operation, and performing the heat recovery operation when this time expires. (For example, refer to Patent Document 2).

  FIG. 18 shows a control block of a conventional hot water supply apparatus described in Patent Document 2.

  The operation control means 18 operates the timer 20 which measures the time until the heat recovery operation is started after the bath automatic operation detection unit 19 detects the stop of the automatic bath operation, and the preset time has expired. The heat recovery operation control means 21 starts the heat recovery operation.

JP 2009-198115 A JP 2007-278578 A

  However, in the conventional configuration, the description relating to the hot water tank side flow rate control in the heat recovery operation is not disclosed.

  Therefore, depending on the temperature of the hot water storage tank or bathtub at the heat recovery operation start timing set by the user, the temperature in the hot water storage tank is agitated and the medium temperature water enters the heat pump unit, resulting in a decrease in energy savings as a result. Had.

  The present invention solves the above-described conventional problems, and an object thereof is to provide a hot water supply device with high energy saving performance by performing an efficient heat recovery operation.

  In order to solve the conventional problems, a hot water supply apparatus of the present invention includes a hot water tank, a bathtub, a heat exchanger for exchanging heat between hot water in the hot water tank and hot water in the bathtub, and in the hot water tank. And a control means for transporting the hot water of the bath to the heat exchanger and returning the hot water to the hot water tank again, and starting the operation at the time of heat recovery operation for recovering the heat of the hot water of the bathtub into the hot water of the hot water tank To a predetermined time, the transport amount of the transport means is made smaller than a predetermined flow rate, and then changed to a predetermined flow rate.

  Thereby, an efficient heat recovery operation can be performed without stirring the temperature in the hot water tank.

  ADVANTAGE OF THE INVENTION According to this invention, a hot water supply apparatus with high energy saving property can be provided by performing efficient heat recovery driving | operation.

Configuration diagram of hot water supply apparatus in Embodiment 1 of the present invention Block diagram of heat recovery operation control means of the hot water supply device Conceptual diagram of the control method for bath automatic operation and heat recovery operation of the water heater Conceptual diagram of control method for reheating operation and heat recovery operation of the water heater Circuit configuration diagram showing the direction of water and hot water when hot water is supplied to the bathtub during automatic bath operation of the hot water supply device Circuit configuration diagram showing the flow direction of water and hot water during warming operation and chasing operation during bath automatic operation of the hot water supply device Circuit configuration diagram showing the flow direction of water and hot water during bath water temperature detection operation during automatic bath operation of the water heater Circuit configuration diagram showing the flow direction of water and hot water during the heat recovery operation of the water heater The figure which showed the change of the temperature distribution in the hot water tank by the heat recovery operation of the hot water supply device The figure which showed the efficiency of the heat pump unit of the water heater The figure which showed the relationship between the heat recovery amount of the hot water supply device and the input of the heat pump unit Flow chart of heat recovery operation control operation of the hot water supply device Flow chart of pump operation of heat recovery operation of the hot water supply device The block diagram of the hot-water supply apparatus in Embodiment 2 of this invention Circuit configuration diagram showing the flow direction of water and hot water during the heat recovery operation Circuit configuration diagram showing the flow direction of water and hot water during the same boiling operation Configuration diagram of conventional hot water supply equipment Control block diagram of the water heater

  1st invention transfers a hot water storage tank, a bathtub, the hot water in the said hot water tank, and the hot water in the said bathtub, and the hot water in the said hot water tank to the said heat exchanger again. In a heat recovery operation that includes a transport unit that returns the hot water in the hot water storage tank and a control unit, and recovers the heat of the hot water in the bathtub into the hot water in the hot water storage tank, The hot water supply apparatus is characterized in that the flow rate is made lower than a predetermined flow rate and then changed to a predetermined flow rate.

  As a result, the temperature in the hot water tank is not stirred, and an efficient heat recovery operation without waste is possible.

  2nd invention is equipped with the heating means which heats the hot water in the said hot water storage tank, The said heat recovery operation is stopped so that the input at the time of the heating operation of the said heating means after the said heat recovery operation stop may become substantially the minimum It is characterized by making it.

  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 heating means is judged to be minimum, and the heat recovery operation is stopped. Therefore, it is possible to improve the efficiency of the entire system, which is the original purpose, and to improve energy saving.

  3rd invention is equipped with the several hot water storage temperature detection means which detects the water temperature of the said hot water storage tank, and stops the said heat | fever collection | recovery driving | operation based on at least 1 detection temperature among these hot water storage temperature detection means. In the heat recovery operation, by optimizing the stop of the heat recovery operation, it is possible to provide a hot water supply device with improved system efficiency and energy saving.

According to a fourth aspect of the present invention, there is provided a water supply pipe connected to the hot water storage tank, a high temperature water supply pipe connected to supply high temperature water of the hot water storage tank, and the lower part of the hot water storage tank or to supply low temperature water. A low-temperature water supply pipe connected to the water supply pipe; a mixing valve for connecting the high-temperature water supply pipe and the low-temperature water supply pipe to the inlet side to mix the high-temperature water and the low-temperature water; and the heat exchange A hot water supply connected to the outlet side of the mixing valve and the bathtub circulation pipe so as to supply hot water of a predetermined temperature to the bathtub. A pipe, an on-off valve connected in the middle of the hot water supply pipe, a hot water branch pipe branched upstream of the on-off valve and connected to the heat exchanger, and heat exchange with hot water in the bathtub in the heat exchanger The heat exchanger and the storage so that the hot water in the hot water storage tank is returned to the hot water storage tank again. A heat exchange return pipe connected to the tank, a first transfer pump for circulating hot water in the hot water storage tank and the heat exchanger, and a second transfer pump for circulating hot water in the bathtub and the heat exchanger; The opening / closing valve is closed, and the mixing valve is adjusted to an opening degree for supplying the hot water from the low temperature water supply pipe to the hot water pipe in preference to the hot water from the high temperature water supply pipe, and
The heat recovery operation is performed by operating the first transfer pump and the second transfer pump.

  As a result, the three functions of hot water supply, reheating, and heat recovery can be realized with the minimum configuration of piping and valves, and the installation space in the casing of the hot water tank can be saved and the apparatus can be downsized. Can be planned. In addition, since the three functions of hot water supply, chasing, and heat recovery can be realized by controlling the opening of the mixing valve, there is an effect that the control is simplified and malfunctions such as malfunctions are reduced.

  The fifth invention comprises a water supply pipe connected to the hot water tank, a high temperature water supply pipe connected to supply high temperature water of the hot water tank, and a heating means for heating the hot water in the hot water tank, A heat transfer pipe connected to the heat exchanger via switching means so that hot water in the upper part of the hot water tank flows to the heat exchanger, and heat exchange with hot water in the bathtub is performed in the heat exchanger. The heating means, the switching means, and the heat exchange return pipe connected to the hot water tank so that the hot water returns to the hot water tank again, and the hot water at the lower part of the hot water tank flows to the heat exchanger. And a heating recovery pipe connected to the heat exchanger via the heating means, and boiling water connected from the switching means to the hot water tank so that the hot water heated by the heating means returns to the hot water tank. It has a return pipe and control means, and has the hot water of the bathtub by the heat exchanger When the heat recovery operation is performed to recover the hot water in the hot water tank, the hot water from the hot water tank flows in the order of the heat recovery forward pipe, the heating means, the switching means, the heat exchanger, and the heat exchange return pipe. As described above, when performing the heating operation in which the heating means heats the hot water in the hot water storage tank, the heat recovery outlet pipe, the heating means, the switching means, and the boiling return pipe are arranged in this order from the hot water storage tank. The hot water supply apparatus is characterized in that the control means switches the switching means so that hot water flows.

  Thereby, it can be set as the structure which uses a part of piping used at the time of heat recovery also at the time of the boiling operation of the hot water in a hot water tank, and can provide the hot water supply apparatus which implement | achieved cost reduction.

  6th invention is the position where the said 1st tap pipe was connected in the up-down direction of the said hot water storage tank, and the 1st hot water pipe connected to the said hot water supply pipe and connected to the substantially upper part of the said hot water storage tank And a second hot water discharge pipe connected between the water supply pipe and the position where the water supply pipe is connected, and the heat exchange return pipe is located in the vertical direction of the hot water storage tank and the hot water storage tank of the second hot water discharge pipe. It is characterized by being connected to the hot water storage tank at a position higher than the connection position.

  As a result, it is possible to effectively use water at a medium temperature (hereinafter referred to as medium hot water) between the hot water at the upper part of the hot water tank and the cold water at the lower part, which is unavoidable in the temperature stratified hot water tank. 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.

  In addition, flowing the warm water generated by the heat recovery into the relatively upper part of the hot water tank means that the hot water that moves below the hot water tank while increasing the temperature of the hot water that is below the inflow position of the hot water recovered. Since it can be used for hot water supply through the hot water outlet, the amount of heat stored in the hot water can be used to the maximum extent possible. At the same time, when the heating means is a heat pump unit, the medium temperature water in the hot water tank that reduces the boiling efficiency can be reduced, so that the efficiency of the entire system can be prevented from being reduced. Realize high energy savings.

Furthermore, normally, the time period during which the heat recovery operation is performed is midnight, but assuming a case where a user's bathing is detected during the heat recovery operation, a bath water reheating operation is required from that point. At this time, the middle temperature water is effectively used at the time of hot water supply before that, and the water in the upper part of the hot water tank remains relatively high even at midnight, so that the reheating performance can be secured. In addition, the rise in the water temperature at the bottom of the hot water tank is small because the medium temperature water is returned to the relatively upper part of the hot water tank, so when the heat recovery operation is resumed after the user completes bathing, the temperature of the water flowing into the heat pump unit Efficient operation is performed while being kept low, and energy efficiency is not impaired.

  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.

(Embodiment 1)
FIG. 1 is a diagram showing a configuration of a hot water supply apparatus according to the first embodiment of the present invention.

  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 Between the position where the hot water pipe 22 and the water supply pipe 14 are connected, that is, in the height direction, the second hot water pipe 23 connected to the substantially central part of the trunk of the hot water storage tank 1, and the first hot water pipe 22 A second hot water outlet pipe 23 is provided with a high-temperature water mixing valve 24 connected to the inlet side.

  Further, a high temperature water supply pipe 8 connected to the outlet side of the high temperature water mixing valve 24 for supplying high temperature water in the hot water tank 1 and a water supply pipe 14 are branched, and the low temperature from the hot water tank 1 or the water supply pipe 14 is reduced. A low-temperature water supply pipe 9 for supplying water, a mixing valve 11 connected to the high-temperature water supply pipe 8 and the low-temperature water supply pipe 9 on the inlet side, and a hot water supply pipe 10 connected to the outlet side of the mixing valve 11 An on-off valve 13 connected in the middle of the hot water supply pipe 10, a hot water supply branch pipe 15 branched upstream of the on-off valve 13 and connected to the first flow path of the heat exchanger 4, and the heat exchanger 4 A heat exchanger return pipe 16 connected to the first flow path of the heat exchanger 4 and the hot water tank 1 so as to return the water of the hot water tank 1 heat-exchanged with the water of the bathtub 3 to the hot water tank 1 again, and the hot water tank 1 and a hot water tank water transport pump 5a as a first transport pump for circulating water in the first flow path of the heat exchanger 4, and a heat exchanger The bathtub water circulation pipe 12 connected so that the water of the bathtub 3 circulates in the second flow path of the second, and the second transport pump for circulating the water in the second flow path of the bathtub 3 and the heat exchanger 4 As a bathtub water conveyance pump 5b.

  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. Moreover, the hot water supply pipe 10 is connected in the middle of the bathtub water circulation pipe 12, and this hot water supply pipe 12 is used when hot water is supplied to the bathtub 3.

  The remote controller 25 installed in the bathroom is provided with an infrared sensor 26 as a human body detecting means and a heat recovery operation start switch 27 for the user to arbitrarily start the heat recovery operation. The plurality of hot water temperature detecting means 28a to 28e for detecting the water temperature in the hot water tank 1 and the bathtub water circulation pipe 12 are provided with a bath water temperature detecting means 17 for detecting the water temperature of the bathtub 3.

  Further, based on the outputs of the plurality of hot water storage temperature detection means 28a to 28e, the infrared sensor 26, the bath water temperature detection means 17 and the operation of the heat recovery operation start switch 27, 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.

FIG. 2 shows a block diagram of the heat recovery operation control means 21, the output of the infrared sensor 26, the operation state of the automatic bath operation control means 29, or the start time of the heat recovery operation preset by the heat recovery operation control means 21, Is a heat recovery operation start determination unit 31 that determines the start of the heat recovery operation from the heat recovery operation start switch 27 and the like, and a boiling operation control means (not shown) that controls the boiling operation by the heat pump unit 2. The required hot water storage amount acquisition unit 32 for acquiring the hot water storage amount necessary for hot water use, the hot water temperature distribution measurement unit 33 for measuring the hot water temperature distribution by the hot water temperature detection means 28a to 28e, the required hot water storage amount acquisition unit 32 and the hot water temperature. Based on the result obtained by the distribution measuring unit 33, the required boiling heat amount calculating unit 34 for calculating the required boiling heat amount and the current temperature by the hot water storage temperature distribution measuring unit 33 From cloth and required heating-up heat quantity calculating section 34 and a heating-up the as hot-water temperature distribution estimating unit 35 for estimating the temperature distribution during heating-up completion.

  Further, the boiling required input for estimating the input to the heat pump unit 2 from the current temperature distribution by the hot water storage temperature distribution measuring unit 33 to the estimated temperature distribution at the completion of boiling by the hot water storage temperature distribution estimating unit 35 at the completion of boiling. It has the estimation part 36 and the pump control part 37 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 36.

  About the hot water supply apparatus comprised as mentioned above, the operation | movement and an effect | action are demonstrated below.

  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.

  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. 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 finished, and hot water storage operation 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 midnight boiling operation by the heat pump unit 2 to recover heat in the hot water tank 1.

  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).

  During bath automatic operation, bath water temperature detection operation for detecting bath water temperature periodically is performed in order to determine whether or not it is necessary to perform heat insulation operation. The bath water temperature is detected by the bath water temperature detecting 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.

During this preset time, automatic bath operation is prioritized, and the heat recovery operation control means 21 is automatically operated or the heat recovery operation start switch 27 is operated by the user to receive an instruction to start the heat recovery operation. Control is performed so that the heat recovery operation is performed after a preset time has elapsed without performing the recovery operation. On the contrary, 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 stops the heat recovery operation, giving priority to the bath automatic operation. The automatic operation control means 29 starts bath automatic operation (conceptual diagram is shown in FIG. 3).

  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). While the reheating operation control means 30 is performing the reheating operation, the renewal operation is prioritized, and the heat recovery operation control means 21 does not perform the heat recovery operation. After the reheating operation is completed, the heat recovery operation is performed. Control to do.

  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).

  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.

  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. 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. 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.

  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 the hot water storage tank water transfer pump 5a starts operation from the upper part of the hot water storage tank 1 through the first hot water discharge pipe 22 through the high temperature water mixing valve 24. Hot water is supplied to the hot water supply pipe 8 and further supplied to the hot water supply pipe 10 via the mixing valve 11.

  At this time, the on-off valve 13 is closed and the hot water supplied to the hot water supply pipe 10 is supplied to the hot water supply branch pipe 15 to heat the hot water in the bathtub 3 circulating through the bathtub water circulation pipe 12 in the heat exchanger 4. Increase the bath water temperature. On the other hand, the hot water that has left the heat exchanger 4 and has become relatively cold returns to the hot water tank 1 through the heat exchange return pipe 16.

  At this time, the opening degree of the high temperature water mixing valve 24 and the mixing valve 11 is such that the first hot water outlet pipe 22 and the high temperature water supply pipe 8 side are fully opened, and the hot water in the upper part of the hot water tank 1 is supplied to the heat exchanger 4. It is generally controlled so that a certain amount of hot water or water flows from the second hot water outlet pipe 23 and the low temperature water supply pipe 9 and mixes them.

  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 on-off valve 13 is closed and 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.

  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.

  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 heat recovery operation is started, water is supplied from a substantially lower portion of the hot water tank 1 to the low-temperature water supply pipe 9 by the operation of the hot water tank water transfer pump 5 a, and supplied to the hot water supply pipe 10 through the mixing valve 11.

  At this time, the on-off valve 13 is closed, and the water supplied to the hot water supply pipe 10 is supplied to the hot water supply branch pipe 15 and exchanges heat with the hot water of the bathtub 3 circulating through the bathtub water circulation pipe 12 in the heat exchanger 4. Go and recover heat. On the other hand, the water that has left the heat exchanger 4 and has reached a relatively high temperature returns to the hot water tank 1 through the heat exchange return pipe 16. At this time, the opening degree of the mixing valve 11 is generally controlled so that the low temperature water supply pipe 9 side is fully opened, but a certain amount of hot water flows from the high temperature water supply pipe 8 and mixes. There may be.

  The temperature distribution in the hot water tank 1 when the heat recovery operation is performed changes in the order of 38, 39, and 40 shown in FIG. That is, the temperature of the water 41 that exchanges heat 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 caused by the action of 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.

  Since the connection position of the second hot water discharge pipe 23 is below the connection position of the heat exchanger return pipe 16, when hot water is generated, the medium temperature water 42 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 43 from the hot water outlet pipe.

  Reference numeral 44 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.

  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.

  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.

  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.

  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. 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.

  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.

  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.

  A control method of the heat recovery operation control means 21 for obtaining a high energy saving effect in consideration of the above will be described.

  FIG. 12 is a flowchart of the operation of the heat recovery operation control means 21. When the heat recovery operation start determination unit 31 determines the start of the heat recovery operation, such as the operation of the heat recovery operation start switch 27 by the user or the elapse of a predetermined time after the completion of the automatic bath operation by the automatic bath operation control means 29, first Then, the presence or absence of a bather is detected by the infrared sensor 26 (step 1). If a bather is detected here, the heat recovery operation is not started and the process ends (step 2).

  If no bather is detected in step 1, the required hot water storage amount acquired by the required hot water storage amount acquisition unit 31, the current temperature distribution of the hot water tank 1 measured by the hot water storage temperature detection means 28 a to 28 e, and the heat pump unit 2 Predict the temperature distribution in the hot water storage tank 1 when the hot water storage operation is completed from the operating conditions such as the boiling temperature, compare it with the current temperature distribution, and the remaining heating amount when heating with the heat pump unit 2 from that point Qr is obtained (step 3).

  Next, the average water temperature before boiling in the heat pump unit 2 is estimated from the measured current temperature distribution until the predicted temperature distribution at the time of completion of the hot water storage operation is reached (step 4).

  Further, the average efficiency during hot water storage operation is obtained from the average water temperature obtained in step 4 and the characteristics of the heat pump unit 2 shown in FIG. 4, and the remaining heating amount Qr obtained in step 3 is divided by this average efficiency to obtain hot water storage water. The input Qin during operation is estimated (step 5).

  Qin obtains a difference from Qin−f which is a value obtained at the previous evaluation time, and when it is smaller than a predetermined deviation q, that is, when a change in estimated input gradually becomes smaller and it is determined to be a minimum value (step) 6) In Step 2, the hot water tank water transfer pump 5a and the bathtub water transfer pump 5b are stopped to end the heat recovery operation. When the difference between Qin and Qin−f is equal to or greater than q, the heat recovery operation is continued, and when the next evaluation time comes (step 8), the above operation is repeated.

  As a supplement, step 7 is executed without performing the comparison in step 6 at the first operation after the start of the heat recovery operation.

  Here, the case where the bather is detected at the start of the heat recovery operation has been described. However, in step 1, the heat recovery operation is also stopped when the bather is detected after the heat recovery operation is started. (Step 2).

  Further, although not shown in this flowchart, when the bathing is over and the infrared sensor 26 no longer detects the human body, the heat recovery operation is restarted by performing this procedure again, and the above operation is performed.

  FIG. 13 is a flowchart of the pump operation of the heat recovery operation control means 21. In FIG. 13, when there is an instruction to start the heat recovery operation by a remote control operation or the like by the user, the process proceeds from STEP 1 to STEP 2 to operate the hot water tank water transfer pump 5 a and the bath water transfer pump 5 b, and the bathtub 3 After the hot water or water is conveyed to the heat exchanger 4 via the bathtub water conveyance pump 5b, it is returned to the bathtub 3.

  Moreover, the hot water conveyed from the bathtub 3 by the bathtub water conveyance pump 5b and the water conveyed from the lower part of the hot water tank 1 by the hot water tank water conveyance pump 5a are heat-exchanged by the heat exchanger 4, whereby the hot water stored from the bathtub 3 is stored. The tank 1 is operated for heat recovery. At this time, the hot water tank water transfer pump 5a is driven at a flow rate smaller than the predetermined flow rate until a predetermined time (STEP 3).

  When this heat recovery operation is continued and a predetermined time (for example, 5 minutes) has elapsed, the process proceeds to STEP 4 to drive the hot water tank water transport pump 5a at a predetermined flow rate.

  The process proceeds from STEP4 to STEP5, and the heat recovery operation is terminated by stopping the hot water tank water transfer pump 5a and the bathtub water transfer pump 5b.

  As described above, according to the first embodiment of the present invention, the hot water storage tank side flow rate is decreased for a predetermined time from the start of operation by changing the hot water tank side flow rate to a predetermined flow rate higher than that after a predetermined time has elapsed. Since the temperature inside the tank 1 is not stirred, efficient heat recovery operation without waste is possible, and energy saving can be improved.

(Embodiment 2)
FIG. 14 is a diagram showing a configuration of a hot water supply apparatus according to the second embodiment of the present invention.

  In FIG. 14, the difference from the first embodiment is that a switching means 51 is provided, and a reheating branch branched from the first outlet pipe 22 through the switching means 51 to the primary inlet of the heat exchanger 4. A heat transfer pipe 52 serving as a flow path for operation is connected, and a lower part of the hot water tank 1 and the switching means 51 are connected via a heat pump unit 2 by a heat recovery forward pipe 53.

  Further, the upper part of the hot water tank 1 and the switching means 51 are connected by a boiling return pipe 54, and the hot water tank water transfer pump 5 a is disposed in the heat exchange return pipe 16.

  About the hot water supply apparatus comprised as mentioned above, the operation | movement and an effect | action are demonstrated below. The entire operation is the same as that described in the first embodiment, and a portion in which the hot water path differs depending on the circuit will be described.

  When performing a heat recovery operation in which the heat of the hot water of the bathtub 3 is recovered by the heat exchanger 4 into the hot water of the hot water tank 1, the hot water of the bathtub 3 is used as the secondary flow path of the heat exchanger 4 as shown in FIG. The bathtub water conveyance pump 5b is operated in order to convey the water.

  Thereafter, from the lower part of the hot water storage tank 1, the hot water storage pipe 53, the heat pump unit 2, the switching means 51, the primary flow path of the heat exchanger 4, the heat exchange return pipe 16, and the substantially central part of the hot water storage tank 1 are sequentially stored. The hot water storage tank water conveyance pump 5a is operated so that the hot water from the tank 1 flows. Thereby, the heat which the hot water of the bathtub 3 has is collect | recovered by the hot water of the hot water tank 1.

  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.

  Also in the present embodiment, the hot water tank side flow rate by the hot water tank water transfer pump 5a is reduced for a predetermined time from the start of operation, and is changed to a higher predetermined flow rate after the predetermined time elapses.

  Further, when the boiling operation for heating the hot water in the hot water tank 1 is performed by the heat pump unit 2, as shown in FIG. 16, the flow direction of the switching means 51 is changed by the operation control means 18 during the heat recovery operation described above. Are switched to different directions and the pump provided in the heat recovery forward pipe 53 is operated, so that the heat recovery forward pipe 53, the heat pump unit 2, the switching means 51, the boiling return pipe 54, and the hot water storage are started from the lower part of the hot water storage tank 1. The hot water from the hot water storage tank 1 is made to flow to the upper part of the tank 1 in order, and the amount of hot water conveyed by the pump provided in the heat recovery forward pipe 53 is set so that the hot water after passing through the heat pump unit 2 reaches a predetermined boiling temperature. Control.

  Thereby, the water in the lower part of the hot water tank 1 is heated by the heat pump unit 2 and returned to the upper part of the hot water tank 1, and the hot water is stored in the hot water tank 1.

  In the case of the heat recovery operation, the hot water storage tank water transport pump 5a provided in the heat exchange return pipe 16 is used to transport the hot water in the lower part of the hot water tank 1 to the primary side of the heat exchanger 4. A pump provided in the heat recovery forward pipe 53 may be used.

  In this embodiment, since a considerable part of the flow path of the heat recovery operation and the boiling operation can be shared by using the switching means 51, the number of piping members to be used can be reduced, thus realizing resource saving and cost reduction. There is an effect that can be done.

  As described above, the hot water supply apparatus according to the present invention enables efficient heat recovery operation without waste and has the effect of improving energy saving. Therefore, the hot water supply apparatus can be applied to a domestic hot water supply apparatus, or for business use. It can be applied to large-scale applications.

1 Hot water tank 2 Heating means (heat pump unit)
3 Bathtub 4 Heat exchanger 5a First transfer pump (hot water storage tank transfer pump)
5b Second transfer pump (tub water transfer pump)
DESCRIPTION OF SYMBOLS 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 On-off valve 14 Water supply pipe 15 Hot water branch pipe 16 Heat exchange return pipe 17 Bath water temperature detection means 18 Operation control means 21 Heat recovery operation control means 22 1st tap pipe 23 2nd tap pipe 24 High temperature water mixing valve 25 Remote control 26 Human body detection means (infrared sensor)
27 Heat recovery operation start switch 28 Hot water storage temperature detection means 29 Bath automatic operation control means 30 Reheating operation control means 51 Switching means 52 Heat transfer pipe 53 Heat recovery forward pipe 54 Heating return pipe

Claims (6)

A hot water tank, a bathtub, a heat exchanger for exchanging heat between the hot water in the hot water tank and the hot water in the bathtub, and the hot water in the hot water tank are transferred to the heat exchanger and returned to the hot water tank again. In a heat recovery operation that includes a transport means and a control means, and recovers the heat of the hot water in the bathtub into the hot water in the hot water storage tank, the transport amount of the transport means is less than a predetermined flow rate for a predetermined time from the start of the operation. And then, it changes so that it may become a predetermined flow volume. A heating means for heating the hot water in the hot water storage tank is provided, and the heat recovery operation is stopped so that an input at the time of the heating operation of the heating means after the heat recovery operation is stopped is substantially minimized. The hot water supply apparatus according to claim 1. The said heat recovery driving | operation is stopped based on at least one detection temperature among the said several hot water storage temperature detection means, provided with the several hot water storage temperature detection means which detects the water temperature of the said hot water storage tank. The hot water supply device described in 1. A hot water supply pipe connected to the hot water storage tank, a high temperature water supply pipe connected to supply hot water of the hot water storage tank, and a lower part of the hot water storage tank or the water supply pipe to supply low temperature water. A low-temperature water supply pipe, a mixing valve for connecting the high-temperature water supply pipe and the low-temperature water supply pipe to the inlet side to mix the high-temperature water and the low-temperature water, the heat exchanger and the bathtub A bathtub circulation pipe connected to circulate hot water, a hot water pipe connected to the outlet side of the mixing valve and the bathtub circulation pipe to supply hot water of a predetermined temperature to the bathtub, and the hot water pipe An on-off valve connected in the middle of the hot water, a hot water branch pipe branched upstream of the on-off valve and connected to the heat exchanger, and hot water of the hot water tank that exchanged heat with hot water of the bathtub by the heat exchanger Connected to the heat exchanger and the hot water tank so as to return it to the hot water tank again. A heat transfer return pipe, a first transfer pump that circulates hot water in the hot water storage tank and the heat exchanger, and a second transfer pump that circulates hot water in the bathtub and the heat exchanger. The valve is closed, the mixing valve is adjusted to an opening degree that supplies water from the low-temperature water supply pipe to the hot water pipe with priority over hot water from the high-temperature water supply pipe, and the first transport pump and The hot water supply device according to any one of claims 1 to 3, wherein the second transport pump is operated to perform the heat recovery operation. A hot water supply pipe connected to the hot water tank, a high temperature water supply pipe connected to supply hot water in the hot water tank, a heating means for heating hot water in the hot water tank, and an abbreviation in the hot water tank. A heat transfer pipe connected to the heat exchanger through switching means so that hot water in the upper part flows to the heat exchanger, and hot water that has been heat-exchanged with hot water in the bathtub by the heat exchanger is again the hot water storage. The heat exchange return pipe connected to the hot water tank so as to return to the tank, and the heat means through the heating means 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 heat recovery forward pipe connected to the exchanger, a boiling return pipe connected from the switching means to the hot water tank so that hot water heated by the heating means returns to the hot water tank, and a control means And the heat exchanger uses the heat exchanger to generate heat from the hot water in the bathtub. When performing a heat recovery operation for recovering in hot water, the hot water from the hot water tank flows in the order of the heat recovery forward pipe, the heating means, the switching means, the heat exchanger, and the heat exchange return pipe, When performing a boiling operation in which hot water in the hot water tank is heated by the heating means, hot water from the hot water tank flows in the order of the heat recovery forward pipe, the heating means, the switching means, and the boiling return pipe. The hot water supply apparatus according to any one of claims 1 to 3, wherein the control means switches the switching means. The hot water supply pipe communicates with the first hot water pipe connected to substantially the upper portion of the hot water storage tank, and the position where the first hot water discharge pipe is connected in the vertical direction of the hot water tank and the water supply pipe is connected. A second hot water pipe connected between the hot water storage tank and the heat exchange return pipe in a vertical direction of the hot water storage tank is higher than a connection position of the hot water storage tank of the second hot water pipe. The hot water supply device according to claim 4, wherein the hot water supply device is connected to the hot water storage tank at a position.

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