JP2014095519A - Hot water storage type water heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hot water storage type water heater capable of adjusting both a volume and a temperature of the hot water in a bathtub and recovering heat.SOLUTION: A hot water storage type water heater 1 comprises: a temperature detection sensor 52 which detects a water temperature in a bathtub 7; drainage devices 12 and 13 which drain the bathtub 7; a water level detection sensor 48 which detects a water level in the bathtub 7; heat recovery sections 25, 27, and 53 which recover heat from hot water in the bathtub 7 and transfer the same to a hot water storage tank 23; and a control device 28 which controls the drainage devices 12 and 13 and the heat recovery sections 25, 27, and 53. The control device 28 adjusts the water temperature in the bathtub 7 to a target temperature by activating the heat recovery sections 25, 27, and 53 when detecting that the hot water already exists in the bathtub 7 before filling the same with the hot water and that the water temperature in the bathtub 7 is not less than the target temperature. The control device 28 also adjusts the water level in the bathtub 7 to a target level by activating the drainage devices 12 and 13 when detecting that the water level is not less than the target water level.

Description

  The present invention relates to a hot water storage type hot water supply apparatus that can automatically change to a relatively low temperature hot water filling state with a small amount of hot water for half body bathing or the like in a state where hot water is already in a bathtub.

  The present invention

  There is a bath facility that can be automatically changed and adjusted to a hot water filled state in which the amount of hot water for half-body bathing is low and the temperature of the hot water is low in a state where hot water is already in the bathtub. Therefore, if the amount of hot water higher than the water level for half-body bathing is detected and the temperature of the hot water is higher than the target temperature, the drain tap is manually opened so that the water level in the bathtub becomes the water level for half-body bathing, and the water level in the bathtub is almost It is conceivable to supply water to the bathtub so that the temperature of the hot water in the bathtub becomes the temperature for half bath when the water level for half bathing is reached. However, in this case, there is a problem that the amount of heat of the hot water is wasted in order to adjust the temperature of the hot water.

  On the other hand, the prior art described in Patent Document 1 is known. This technology provides a heat pump type hot water supply apparatus that can be memorized and can recover heat from the remaining hot water in a bathtub. In order to recover heat, a heat pump circuit, a hot water heat exchanger provided in the heat pump circuit, a hot water storage tank for storing hot water boiled by the hot water heat exchanger, and hot water in the bathtub are memorized. A reheating circuit for heating in the heat exchanger is provided, and water that is heat-exchanged with the remaining hot water in the bathtub in the reheating heat exchanger is caused to flow into the bottom of the hot water storage tank.

  If the technique of this patent document 1 is used, in order to automatically change and adjust the hot water state for bathing in a state where the hot water has already been filled to the hot water state for half body bathing, Rather than lowering the temperature, the temperature of the hot water in the bathtub can be lowered by collecting the amount of heat from the bath in the hot water storage tank.

JP 2009-216266 A

  According to the technique of Patent Document 1, the amount of hot water in the bath can be recovered in the hot water storage tank using the heat recovery circuit, but the amount of hot water in the bathtub cannot be automatically adjusted.

  The present invention has been made paying attention to such problems existing in the prior art, and its purpose is to automatically adjust both the amount of hot water in the bathtub and the temperature of the hot water in the bathtub. The object is to provide a hot water storage type hot water supply apparatus capable of recovering heat.

  Descriptions of patent documents listed as prior art can be introduced or incorporated by reference as explanations of technical elements described in this specification.

  In order to achieve the above object, the present invention employs the following technical means. That is, in the invention described in the present application, a water heater (3) that boils hot water, a hot water storage tank (23) that stores hot water boiled by the water heater (3), and water in a bathtub (7) of a bathroom. Temperature detection means (52) for detecting the temperature of the water, drainage means (12, 13) for automatically draining the water in the bathtub (7), and water level detection means (48) for detecting the water level in the bathtub (7) ), Heat recovery means (25, 27, 53) for recovering the amount of hot water in the bathtub (7) in the hot water storage tank (23), drainage means (12, 13) and heat recovery means (25, 27, 53) ), And when the hot water filling operation into the bathtub (7) is started, the hot water already exists in the bathtub (7). In the case where the temperature detecting means (52) detects the temperature exceeding the target temperature from the hot water in the bathtub (7) The temperature recovery means (S005, S007) for adjusting the temperature of the water in the bathtub (7) by operating the heat recovery means (25, 27, 53) and the hot water filling operation are started. When hot water is already present in the bathtub (7), when the water level detection means (48) detects a water level exceeding the target water level, the drainage means (12, 13) is operated to (7) having a water level adjusting means (S006) for adjusting the water level within the target water level.

  According to this invention, the control device (28) can perform drainage of the bathtub (7) in cooperation with the drainage means (12, 13), and by the heat recovery means (25, 27, 53). Since the amount of heat of the bathtub (7) can be collected in the hot water storage tank (23), the amount of heat of the hot water in the bathtub (7) is not wasted compared with the case of cooling by adding water. ) Can be adjusted to a target temperature for half-body bathing. Moreover, since the bathtub water level can be automatically adjusted using the drainage means (12, 13), it does not accidentally drain too much. Therefore, the water level of the bathtub (7) can be quickly adjusted to a water level suitable for half-body bathing without wasting the amount of heat of hot water in the bathtub (7).

  In the invention described in the present application, the control device (28) detects the completion of the bath temperature adjustment for detecting that the adjustment of the temperature of the water in the bath (7) by the temperature adjusting means (S005, S007) is completed. Means (S071), and after detecting that the adjustment is completed by the bathtub temperature adjustment completion detecting means (S071), the water level adjusting means (S006) adjusts the water level in the bathtub (7) to the target water level. It is characterized by doing.

According to this invention, the heat recovery means (25, 27, 53) is first operated to adjust the temperature of the water in the bathtub (7) to the target temperature, and then the bathtub ( 7) Since the water level in the tank is adjusted so as to become the target water level, it is possible to recover heat from the hot water in the bath (7) with a large amount of water, that is, a large amount of heat. 28) When hot water filling operation is started and hot water is already present in the bathtub (7), when the water level detecting means (48) has not detected a water level exceeding the target water level, It has a water replenishing means (S008) for replenishing hot water having a target temperature from the tank (23) into the bathtub (7).

  According to this invention, when the water level detecting means (48) has not detected a water level exceeding the target water level, a predetermined amount of hot water is replenished from the hot water storage tank (23) into the bathtub (7). Thus, the water level in the bathtub (7) can be made higher than the target water level.

  In the invention described in the present application, after detecting that the adjustment is completed by the bathtub temperature adjustment completion detecting means (S071), the water replenishing means (S008) supplies hot water at the target temperature from the hot water storage tank (23) in the bathtub (7). It is characterized by rehydrating water.

  According to this invention, after detecting that the adjustment is completed by the bathtub temperature adjustment completion detecting means (S071), the water replenishing means (S008) supplies hot water of the target temperature from the hot water storage tank (23) into the bathtub (7). Since the water is replenished, heat can be recovered from the hot water before the water is replenished, so that the temperature of the hot water to be replenished can be lowered as compared with the case where heat is recovered from the water after the water is replenished. By the way, when recovering heat from the hot water after replenishing the water, even if the hot water at the target temperature is replenished in the bathtub (7), the hot water is cooled by heat recovery, so it is necessary to replenish the hot water exceeding the target temperature in the bathtub (7). is there.

  In addition, the code | symbol in parentheses described in a claim and each said means is an example which shows the correspondence with the specific means as described in embodiment mentioned later easily, and limits the content of invention is not.

It is a whole block diagram of the hot-water supply apparatus of 1st Embodiment of this invention. It is a block diagram of the tank unit in the said embodiment. It is a main flowchart in the said embodiment. It is a flowchart of the hot water filling type confirmation in the said embodiment. It is a flowchart which judges the presence or absence of the remaining hot water in the said embodiment. It is a flowchart of the heat recovery control in the said embodiment. It is a flowchart of the automatic drainage control in the said embodiment. It is a flowchart of the automatic water replenishment control in the said embodiment. It is explanatory drawing of the display screen of the remote apparatus in 2nd Embodiment of this invention. It is explanatory drawing of the display screen of the remote apparatus in 3rd Embodiment of this invention. It is a whole block diagram except the water heater which shows 4th Embodiment of this invention. It is a whole block diagram except the water heater which shows 5th Embodiment of this invention.

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

  Not only combinations of parts that clearly indicate that the combination is possible in each embodiment, but also the embodiments are partially combined even if they are not clearly specified unless there is a problem with the combination. It is also possible.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described in detail with reference to FIGS. In FIG. 1, a hot water heater 3 of a hot water storage type hot water supply apparatus 1 is composed of a heat pump, and is connected to a pipe portion serving as a heat pump going-out portion 4 and a heat pump return portion 5, which are connection portions with a tank unit 2.

  Hot water is supplied from the tank unit 2 to the hot water supply port 6 via a hot water supply pipe. A circulation circuit 8 is connected from the tank unit 2 to the bathtub 7 in the bathroom, and is connected to the bathtub 7 and circulates the bathtub water by a bath pump 53 described later. A bathtub adapter 11 that is installed at a predetermined height from the bottom of the bathtub 7 and connects the circulation circuit 8 to the bathtub 7 is provided in the bathtub 7.

  A driving device 13 that opens and closes the drain plug 12 that drains the water in the bathtub 7 through the wire 13a is provided on the side surface of the bathtub 7, and the drain plug 12 and the driving device 13 constitute drain means 12 and 13 that constitute drain means. Is configured. The drive device 13 can drive the drain plug 12 by a signal from the bathroom remote device (bathroom remote control) 15 and opens and closes the drain plug 12. Reference numeral 16 denotes a kitchen remote device (kitchen remote control).

  The water heater 3 and the tank unit 2 are installed outdoors. In the water heater 3 and the tank unit 2, tap water is provided with a stop cock 18, a pressure reducing valve 20, a check valve 21 for water supply, and a valve. 22 or the like. A bathroom remote controller 15 functioning as a remote device placed in the bathroom and a main remote controller 16 serving as a remote device placed in the kitchen are connected to a pipe 59 including a communication line and a power line from a control device 28 (to be described later) in the tank unit 2. , 60 are supplied with control signals and power. It is also possible to use a power supply superposition type wiring in which a communication line and a power supply line are combined.

  In FIG. 2 which shows the whole structure of the tank unit 2, the hot water storage tank 23 is enclosed by the heat insulating material 23a in order to store and heat-warm the hot water which the water heater 3 boiled. Tap water is supplied from the water pipe 17 to the bottom of the hot water storage tank 23, and hot water circulates from the heat pump return section 5 to the hot water storage tank 23 through the check valve 26, the primary side of the external heat exchanger 25, and the memory pump 27. It is supposed to be.

  Seven can thermistors 24 are arranged in the hot water storage tank 23 to measure the temperature of hot water in each part in the hot water storage tank 23. A control device 28 is disposed in the vicinity of the hot water storage tank 23 and is supplied with a signal from the can body thermistor 24 and the like. The control device 28 can be constituted by a hot water storage ECU. The outside air temperature sensor 29 includes a thermistor that detects the outside air temperature (Tam). A relief valve 31 is connected to the upper part of the hot water storage tank 23. 32 is a heat pump three-way valve (heat recovery three-way valve), 33 is an intermediate temperature water mixing valve, 34 is an intermediate temperature water thermistor, 35 is an additional temperature thermistor, 36 is an additional temperature primary thermistor, 37 is a hot water supply mixing valve, 38 is a hot water supply counter, 41 is a hot water supply thermistor, 42 is a bath mixing valve, 43 is a hot water solenoid valve (also simply referred to as an electromagnetic valve 43), 45 is a bath counter for measuring the amount of hot water supply, and 46 and 47 are check valves.

  A water level sensor 48 connected to the circulation circuit 8 detects the water pressure and measures the water level. 51 is a flow sensor (flow switch) constituting water flow detection means, and 52 is a bath circulation thermistor constituting bath circulation temperature detection means, which also serves as a freezing temperature detection means (freezing temperature detection thermistor). 53 is a bath pump. In the circulation circuit 8, the remaining hot water in the bathtub 7 is circulated through the secondary side of the external heat exchanger 25, so that it is possible to carry out remedy and heat recovery. Therefore, a part of the circulation circuit 8 also serves as a part of the memory circuit 55 that circulates and heats the water in the bathtub 7 by the bath pump 53.

  When hot water is supplied to the bathtub 7, the hot water is supplied via the hot water storage tank 23 → the intermediate temperature water mixing valve 33 → the bath mixing valve 42 → the electromagnetic valve 43 → the bath counter 45 → the secondary side of the external heat exchanger 25 → the bathtub adapter 11. Flowing. The hot water supply path 44 includes a circuit from the hot water storage tank 23 to the intermediate temperature water mixing valve 33 → the bath mixing valve 42 → the electromagnetic valve 43 → the bath counter 45, the memory circuit 55 and the circulation circuit 8.

  If there is remaining hot water in the bathtub 7, the flow sensor 51 detects the flow of water flowing through the circulation circuit 8 when the bath pump 53 is rotated, whereby the presence or absence of remaining hot water can be confirmed. Therefore, the bath pump 53 and the flow sensor 51 are parts constituting the remaining hot water detection means.

  The bath circulation thermistor 52 measures the temperature of the water flowing through the circulation circuit 8 and detects the temperature related to the possibility of freezing of the circulation circuit 8 and the temperature detection means that detects the temperature of the remaining hot water in the hot water bath. 52.

  The control device 28 (hot water storage ECU) controls the driving device 13 of the drainage means 12 and 13. The control device 28 closes the drain plugs 12 of the draining means 12 and 13 if the remaining hot water detection means parts 51 and 53 do not detect the remaining hot water when the freezing temperature detection means 52 is below a predetermined temperature. Then, a predetermined amount of water is poured into the bathtub 7, the bath pump 53 is driven, and the freeze prevention operation is performed in which the water in the bathtub 7 is circulated through the circulation circuit 8 for a predetermined time.

  A flow sensor 51 that is installed in the circulation circuit 8 and detects the presence or absence of a water flow flowing from the bathtub 7 through the circulation circuit 8 constitutes a water flow detection means 51. As described above, the control device 28 drives the bath pump 53 of the circulation circuit 8 and detects the presence or absence of remaining hot water in the bathtub 7 by the water flow detection means 51.

  The circulation circuit 8 includes a bath circulation thermistor 52 that constitutes a bath circulation temperature detection means 52 that detects a bath circulation temperature that is a temperature of a water flow in the circulation circuit 8. In accordance with the detected bath circulation temperature, the length of the driving time that is the time for which the bath pump 53 is driven and the length of the waiting time that is the time for which the bath pump 53 is not driven are set. .

  As described above, the bathtub adapter 11 that is installed at a predetermined height from the bottom in the bathtub 7 and connects the circulation circuit 8 to the bathtub 7 is provided. When the freezing temperature detection means 52 for detecting the temperature related to the possibility of freezing is below a predetermined temperature, there is no water in the bathtub 7 until the bathtub adapter water level, which is the water level until the bathtub adapter 11 is submerged. Then, the control device 28 closes the drain plug 12 and injects water into the bathtub 7 to the bathtub adapter water level, and then performs the freeze prevention operation.

  The circulation circuit 8 is connected to the hot water storage tank 23 through a part of the hot water supply path 55. The hot water storage tank 23 stores hot water at midnight when the hot water heater 3 is operated at an inexpensive late-night electricity rate. In the freeze prevention operation, the control device 28 can inject a predetermined amount of hot water mixed with the hot water in the hot water storage tank 23 into the bathtub 7 through the circulation circuit 8 as necessary. In this case, the hot water storage tank 23 connected to the circulation circuit 8 stores hot water in the middle of the night by the hot water heater 3 operated at an inexpensive late-night electricity rate, and the circulation circuit 8 is stored in the hot water storage tank 23 in the freeze prevention operation. A predetermined amount of hot water mixed with hot water is poured into the bathtub 7 (not essential). According to this, the possibility of freezing is high at midnight, and hot water stored at an inexpensive late-night electricity rate can be used for freezing prevention operation at this time. Since the temperature of water is rising, the antifreezing effect is enhanced.

  Among the remote devices 15 and 16 in FIG. 1 that supply an operation signal to the control device 28 and display the control state of the control device 28, communicate with the drive device 13 that opens and closes the drain plug 12 from the bathroom remote device (bathroom remote control) 15. Both signals and power are supplied by wiring 56. According to this, since the communication signal and power supply to the drive device 13 are supplied from the remote device 15, the extra wiring near the bathtub 7 can be reduced. In addition, since there is no need to connect the driving device 15 and the control device 28 with long wires, it is possible to improve noise resistance and workability. Furthermore, since the control device 28 is separated from the drive device 13 via the remote device 15, the drive device 13 does not directly affect the control device 28 such as noise. The wiring 59 between the control device 28 and the bathroom remote device 15 includes a communication line and a power line. The wiring 60 between the control device 28 and the kitchen remote device 16 also includes a communication line and a power line.

(Operation of the first embodiment)
Hereinafter, a specific description will be given based on a flowchart executed in the control device 28. In FIG. 3, when the main flow is started, in step S001, it is determined whether or not the control state of the water heater 1 is the half bath mode. In this case, in 1st Embodiment, it is determined whether the half body bath switch in the remote devices 15 and 16 was turned ON manually by the user. When the half bath switch is turned on and the half bath mode is set, in step S002, whether or not there is a predetermined amount of remaining hot water in the bathtub 7 and the type of hot water filling are checked.

  Although details of step S002 will be described later, seven control sections from A to G are determined by this step S002, and any one flag of the control section is set. Next, the process proceeds to steps S003, S004, S005, S006, S007, S008, and S009 relating to any of the control categories A to G for which the flag is set.

Control category A is “no hot water type and no learning of bathtub cross-sectional area”
Control section B is “a hot water filling control section (no remaining hot water and learning) or (no remaining hot water and no refilling)”
Control category C is “There is a remaining hot water type, heat recovery, and automatic drainage”
Control category D is “There is a remaining hot water type, no heat recovery, and automatic drainage”
Control category E is “Hot water type with residual hot water, heat recovery, and no automatic drainage”
Control category F is “Hot water type with residual hot water, no heat recovery, and no automatic drainage”
Control category G is "Hot water type is residual hot water and no water replenishment"
The control sections will be described in detail below. In the control section A, the hot water is poured into the bathtub 7 up to the reference water level (water level at which the bathtub adapter 11 is submerged) WB previously known in step S003. Next, pouring of a preset water level (same as the target water level WO specified by the user) preset in step S004 is performed. In the control section B, the set water level is poured in step S004.

  In the control section C, heat recovery described later is performed in step S005, and then automatic draining described later is performed in step S006. In the control section D, automatic drainage described later is performed in step S006. In the control section E, heat recovery described later is performed in step S007, and then automatic water replenishment described later is performed in step S008.

  In the control section F, automatic water replenishment described later is performed in step S008. In the control section G, none of heat recovery, automatic drainage, automatic water refilling, and pouring up to the set water level is performed, and the process proceeds to the next step S009.

  In step S009, the temperature of the remaining hot water in the bathtub 7 is compared with the target temperature to determine whether the bathtub temperature is lower than the target temperature. When the bath temperature is lower than the target temperature, the temperature is retraced in step S010, the temperature of the remaining hot water in the bath 7 is increased, and the process proceeds to the next step S011. In step S009, when the bathtub temperature is not lower than the target temperature, the process proceeds to the next step S011. As is well known, the memorial service rotates the memorial pump 27 and the bath pump 53 to exchange heat between the hot water in the bathtub 7 and the hot water in the hot water tank 23 via the heat exchanger 25.

  In the next step S011, it is determined whether the hot water filling type is (no remaining hot water and no supplementary water) or (with residual hot water and no supplementary water). When the hot water filling type is (no remaining hot water and no supplementary water) or (with residual hot water and no supplementary water), the process proceeds to step S012, and the water level of the residual hot water in the bathtub 7 is confirmed. In this water level confirmation, the current water level in the bathtub 7 is stored in the water level sensor 48 that detects the water pressure.

  Next, in step S013, it is determined whether the hot water filling type is no remaining hot water and learning is not performed. When the hot water filling type is no remaining hot water and no learning, the bathtub cross-sectional area is learned in step S014. The learning of the bathtub cross-sectional area is also performed by the same control as in the prior art from steps S003, S004, and S009 to S014 in FIG.

  Specifically, when pouring from the reference water level to the set water level, the volume of the hot water is determined by the integrated value of the bath counter 45, and the change in the water level in the bathtub 7 is also determined, so that the bathtub cross-sectional area is obtained, step S0147 The stored bathtub cross-sectional area is stored (learned). This bathtub cross-sectional area is used to calculate how much water should be replenished when the hot water in the bathtub 7 is reduced. In step S011, if the hot water filling type is (no remaining hot water and no supplementary water) or (no remaining hot water and no supplementary water), the process is immediately terminated without checking the water level.

(Residual bath check and hot water type check control)
Next, details of the bathtub remaining hot water confirmation and the hot water filling type confirmation in step S002 of FIG. 3 will be described with reference to FIGS. When the flowchart of FIG. 4 is started, the bath pump 53 is turned on and rotated in step S021. And it is determined whether there is any remaining hot water in the bathtub 7 in step S022. If there is a predetermined amount of remaining hot water, the bath pump 53 is turned off in step S023.

  Furthermore, it progresses to step S024 and sets the temperature of the remaining hot water in the bathtub 7 as the same as the bath circulation temperature. Next, in step S025, it is determined whether or not water refilling into the bathtub 7 is possible. If replenishment is possible by injecting water into the bathtub 7 as seen from the value of the water level sensor 48, it is determined in step S026 whether the temperature of the remaining hot water in the bathtub 7 is higher than (predetermined target temperature + 1 ° C.). . If the temperature of the remaining hot water in the bathtub 7 is higher than (predetermined target temperature + 1 ° C.), it is determined in step S027 whether the remaining hot water level in the bathtub 7 is higher than the target water level WO.

  If the water level of the remaining hot water in the bathtub 7 is higher than the target water level WO, in step S028, the hot water type is set to the control category C, that is, the hot water type is residual hot water, and there is heat recovery. It is determined that there is drainage, and a flag for control section C is set. In step S027, when the water level of the remaining hot water in the bathtub 7 is not higher than the target water level WO, in step S029, the hot water type is set to the control category E, that is, the hot water type is residual hot water, and heat recovery is performed. Yes, it is further determined that there is no automatic drainage, and a flag for control section E is set.

  If refilling is not possible in step S025, the process proceeds to step S031, and the hot water filling type is determined to be the control category G, that is, the hot water filling type is remaining hot water and no refilling, and the flag of the control zone G is set. Stand up. If the temperature of the remaining hot water in the bathtub 7 is not higher than (predetermined target temperature + 1 ° C.) in step S026, the process proceeds to step S032, and it is determined whether the current bathtub water level is higher than the target water level WO. If the bathtub water level is higher than the target water level WO, in step S033, the hot water type is determined to be control category D, that is, the hot water type is residual hot water and there is no heat recovery, and further automatic drainage is performed. Set the flag of section D. If the bathtub water level is not higher than the target water level WO in step S032, the hot water filling type is determined in step S034 as control category F, that is, with remaining hot water and without heat recovery, and further without automatic drainage. Then, the control section F flag is set.

  If there is no remaining hot water in the bathtub 7 in step S022, it is determined in step S035 whether water can be refilled. This water replenishment means that the water level sensor 48 is normal and water can be replenished because it can be seen that the current water level has dropped from the target water level. If water replenishment is possible, it is determined in step S036 whether the bathtub cross-sectional area has been learned and the learning value is stored. If the bathtub cross-sectional area is learned and the learning value is stored, in step S037, the hot water type is the control category B, that is, the hot water type is (no remaining hot water and learning) or (remaining hot water). No control and no water replenishment), and flag control section B.

  In step S035, if the measured value of the water level sensor 48 is unknown or the like and the water cannot be refilled (the bath water level is unknown), the process proceeds to step S038 and the hot water type is set to the control category B, that is, the hot water type is (remaining hot water). Without control and with learning) or without residual hot water and without refilling, and flag control section B. If there is no learning of the bathtub cross-sectional area in step S036, in step S039, the hot water filling type is determined to be the control category A, that is, the hot water filling type is no remaining hot water and no learning is performed. Set a flag.

(Judgment control for remaining hot water)
Next, FIG. 5 shows details of the determination of the presence or absence of remaining hot water in step S022 of FIG. In FIG. 5, the bath pump 53 is turned on and rotates in step S041. In step S042, when there is residual hot water in the bathtub 7 and the bath pump 53 is rotated, the flow of water flowing through the circulation circuit 8 is confirmed by the flow sensor (flow switch) 51 and the flow switch is turned on. Determine whether.

  Next, in step S043, it is determined whether δ seconds have elapsed after the flow sensor 51 is turned on. When the flow sensor 51 detects the flow of water and is turned on, if the predetermined value δ seconds elapses in the state in which the flow sensor 51 is turned on in step S043, a remaining hot water flag is set in step S044. In step S045, the bath pump 53 is turned off.

  If the flow sensor 51 is not turned on in step S042, it is confirmed in step S046 that a predetermined value γ seconds has passed in advance, and it is determined in step S047 that there is no remaining hot water, and the flag is lowered. In addition, after the bath pump 53 is turned on, if there is no remaining hot water even after a predetermined value δ seconds or longer has passed for some reason, it is determined that there is no remaining hot water. The above steps S041 to S047 constitute the remaining hot water detection means. Here, δ is larger than γ (δ> γ).

(Heat recovery control)
Next, FIG. 6 shows the details of the heat recovery control (heat recovery means), which is the details of steps S005 and S007 in FIG. In FIG. 6, when the heat recovery control is started, the bathtub temperature adjustment completion flag is set to the flag OFF state in step S051. Next, in step S052, whether the temperature of the remaining hot water in the bathtub 7 is larger than the temperature obtained by adding 1 ° C. to the temperature detected by the lowest can body thermistor 24a in the hot water storage tank 23 in FIG. 2 (bath temperature> Th24a temperature). + 1 ° C). If it is determined that (bath temperature> Th24a temperature + 1 ° C.), the heat recovery three-way valve 32 is switched to the heat recovery side in step S053.

  Next, in step S054, the bath pump 53 is turned on and rotated, and in step S055, the memory pump 27 is turned on and rotated. Next, in step S056, when the bath pump 53 is rotated, it is determined whether the flow of water flowing through the circulation circuit 8 has not been confirmed by the flow sensor (flow switch) 51 (no water flow). In this case, if the flow sensor (flow switch) 51 continues to be in the OFF state for a predetermined period of time, it is determined that there is no water flow.

  If there is a water flow, it is determined in step S057 whether the temperature of the remaining hot water in the bathtub 7 is equal to or lower than a temperature obtained by adding 1 ° C. to a predetermined target temperature (tub temperature ≦ target temperature + 1 ° C.). If the temperature of the remaining hot water in the bathtub 7 is equal to or lower than the temperature obtained by adding 1 ° C. to the predetermined target temperature, the bathtub temperature adjustment completion flag is set to the flag ON state in step S058. For example, when the bath temperature is 42 ° C. and the target temperature is 40 ° C., heat recovery is performed, and when the bath temperature reaches 41 ° C., the bath temperature adjustment completion flag is set to the flag ON state. In addition, the arrow of the piping of FIG. 2 has shown the direction of the flow at the time of heat recovery.

  Next, in step S059, the remedy pump 27 is turned off to stop the rotation, and in step S061, the bath pump 53 is also turned off to stop the rotation. In step S062, the heat recovery three-way valve 32 is switched to the boiling side.

  When it is determined in step S052 that the temperature of the remaining hot water in the bathtub 7 is not higher than the temperature obtained by adding 1 ° C. to the detected temperature of the lowest can body thermistor 24a in the hot water storage tank 23 (determination is NO) In the case), it is determined that the temperature of hot water in the hot water storage tank 23 is too high to recover heat, and the process proceeds to step S059.

  In step S056, when the bath pump 53 is rotated and the flow of water flowing through the circulation circuit 8 cannot be confirmed by the flow sensor 51 (when it is determined that there is no water flow), the pump is protected. The process immediately proceeds to step S059.

(Automatic drainage control)
Next, the automatic drainage control in step S006 of FIG. 3 will be described using FIG. When the automatic drainage control is started, it is determined in step S071 whether the bathtub temperature completion flag is in the ON state. That is, when the temperature of the remaining hot water in the bathtub 7 is smaller than the temperature obtained by adding 1 ° C. to the predetermined target temperature, the bathtub temperature adjustment completion flag is set to the flag ON state in step S058 of FIG. This flag ON state is confirmed.

  If the bathtub temperature completion flag is in the ON state, in step S072, the driving device 13 performs an operation of opening the drain plug 12 of FIG. 1 through the wire 13a. Next, in step S073, it is determined whether the water level in the bathtub 7 is equal to or lower than a predetermined target water level WO (tub water level ≦ target water level).

  When the water level in the bathtub 7 is small (tub water level ≦ target water level), the operation of closing the drain plug 12 is performed by the drive device 13 via the wire 13a in step S074. On the other hand, in step S071, the temperature of the remaining hot water in the bathtub 7 is not lower than the temperature obtained by adding 1 ° C. to the predetermined target temperature, and the bathtub temperature adjustment completion flag is set to the flag ON state in step S058 of FIG. If not, the temperature could not be adjusted by heat recovery, and it is necessary to cool the hot water in the bathtub 7 by injecting water.

  In this case, in step S075, the hot water solenoid valve 43 in FIG. 2 is opened, and water is poured into the bathtub 7 in step S076. In step S077, it is determined whether or not the total amount of pouring (water pouring amount) counted by the bath counter 45 is equal to or greater than a preset pouring amount α liter. After the pouring is continued until the amount of pouring reaches the preset pouring amount α liter, the solenoid valve 43 is closed in step S078.

  Next, in step S079, the temperature of the bathtub 7 is confirmed. For this purpose, the bath circulation thermistor 52 detects the temperature of the water flowing through the circulation circuit 8 by driving the bath pump 53. Next, in step S081, it is determined whether the bath temperature is equal to or lower than a temperature obtained by adding 1 ° C. to a predetermined target temperature. When the bath temperature is low and (tub temperature ≦ target temperature + 1 ° C.), the bath temperature completion flag is turned on in step S082.

  In step S073, when the water level in the bathtub 7 is not less than or equal to the predetermined target water level, the process returns to step S072 and the state where the drain plug 12 is opened is continued. In step S077, when the pouring integrated amount (water pouring amount) counted by the bath counter 45 is not equal to or more than the above-described pouring setting amount α liter, the process returns to step S076 and the water pouring state is continued. Furthermore, in step S081, when the bath temperature is not equal to or lower than the predetermined target temperature plus 1 ° C., the process returns to step S075 and the water injection state is continued.

In step S077, the predetermined pouring set amount α liter may be a fixed value such as 10 liters or may be obtained from the following formula 1.
(Formula 1) α = (bath temperature-target temperature) × (bath water level × bath cross-sectional area) / (target temperature-water injection temperature)
The bathtub water level is a value measured by the water level sensor 48. When the pouring set amount α liter is a fixed value, the calculation flow is repeated several times on the flowchart (S081 → S075), and an appropriate drainage amount is obtained. It becomes an appropriate amount of drainage without going through the loop of calculation several times.

(Automatic rehydration control)
Next, the automatic water replenishment control in step S008 of FIG. 3 will be described using FIG. When the automatic water replenishment control is started, it is determined in step S091 whether the bathtub temperature adjustment completion flag is ON. If the bathtub temperature adjustment completion flag is ON, the hot water solenoid valve 43 of FIG. 2 is opened in step S092. In step S093, hot water having a target temperature adjusted by the bath mixing valve 42 is poured into the bathtub 7. In step S094, it is determined whether the water injection amount measured by the bath counter 45 has reached β liters.

If the water injection amount has reached β liter, the solenoid valve 43 is closed in step S095. In step S094, if the water injection amount is not β liters or more, the process returns to step S093. If the bathtub temperature adjustment completion flag is not ON in step S091, the process proceeds to step S096. The pouring temperature γ is obtained from Equation 2.
(Formula 2) γ = (target water level × target temperature−bath water level × bath temperature) / (target water level−bath water level)
Next, in step S097, the electromagnetic valve 43 is opened, and hot water of γ ° C. is poured into the bathtub 7 in step S098. This water injection is performed because the amount of hot water is small, not for cooling. Furthermore, in step S099, the accumulated pouring amount (water injection amount) counted by the bath counter 45 is equal to or greater than the value obtained by subtracting the bathtub water level from the target water level (the unit is liters; L). Determine.

  If the determination result in step S099 is YES, the solenoid valve 43 is closed in step S100, and the bathtub temperature is confirmed in step S101. As a result, when the bathtub temperature becomes equal to or lower than the value obtained by adding 1 ° C. to the target temperature in step S102, the process proceeds to step S103, and the bathtub temperature adjustment completion flag is set to ON.

  In the above step S099, when the accumulated pouring amount is not equal to or greater than the value obtained by subtracting the bath water level from the target water level, the bath pouring is continued by returning to step S098. In Step S102, when the bath temperature does not become equal to or lower than the value obtained by adding 1 ° C. to the target temperature, the process returns to Step S098 to continue pouring hot water.

(Operational effects of the first embodiment)
In the first embodiment, the water heater 3 that boils hot water, the hot water storage tank 23 that stores the water boiled by the water heater 3, and the temperature detection means 52 that detects the temperature of the water in the bathtub 7 of the bathroom. And draining means 12 and 13 for automatically draining the water in the bathtub 7, a water level detecting means 48 for detecting the water level in the bathtub 7, and heat recovery for recovering the amount of hot water in the bathtub 7 in the hot water storage tank 23. Means 25, 27, 53 and a control device 28 for controlling the drainage means 12, 13 and the heat recovery means 25, 27, 53 are provided.

  When the hot water filling operation into the bathtub 7 is started, the control device 28 is configured such that when the hot water already exists in the bathtub 7, the temperature detection means 52 exceeds the target temperature from the hot water in the bathtub 7. Is detected, the temperature recovery means 25, 27, 53 are operated to adjust the temperature of the water in the bathtub 7 to the target temperature. Further, when the hot water filling operation is started and the hot water is already present in the bathtub 7, the control device 28, when the water level detecting means 48 detects a water level exceeding the target water level, 13 is operated to have a water level adjusting means S006 for adjusting the water level in the bathtub 7 to the target water level.

  According to this, the control device 28 can perform drainage of the bathtub 7 in cooperation with the drainage means 12, 13, and the heat recovery means 25, 27, 53 can convert the heat amount of the bathtub 7 to the hot water storage tank 23. Therefore, the temperature of the bathtub 7 can be adjusted to a target temperature for half-body bathing without wasting the amount of heat of the hot water in the bathtub 7 as compared with the case of cooling by adding water.

  Moreover, since the bathtub water level can be automatically adjusted using the drainage means 12 and 13, it does not accidentally drain too much like when draining manually. Therefore, the water level of the bathtub 7 can be quickly adjusted to a water level suitable for half-body bathing without wasting the heat quantity of the hot water of the bathtub 7.

Further, the control device 28 includes a bath temperature adjustment completion detection unit S071 that detects that the adjustment of the temperature of the water in the bathtub 7 by the temperature adjustment units S005 and S007 to the target temperature is completed,
After detecting that the temperature adjustment has been completed by the bathtub temperature adjustment completion detection means S071, the water level adjustment means S006 adjusts the water level in the bathtub 7 so as to reach the target water level.

According to this, after the heat recovery means 25, 27, 53 are actuated first to adjust the temperature of the water in the bathtub 7 to the target temperature, the water level in the bathtub 7 exceeding the target water level is reached. Since the target water level is adjusted, heat can be recovered from the hot water in the bathtub 7 having a large amount of water, that is, a large amount of heat. Furthermore, when the hot water filling operation is started, the control device 28 is already in the bathtub. In the case where hot water is present in the tank 7, when the water level detection means 48 has not detected a water level exceeding the target water level, the water supply tank S23 has a water replenishing means S008 for replenishing the bathtub 7 with hot water at the target temperature. .

  According to this, when the water level detection means 48 does not detect the water level exceeding the target water level, a predetermined amount of hot water is replenished from the hot water storage tank 23 into the bathtub 7 and the water level in the bathtub 7 is restored. Can be set to an appropriate value above the target water level.

  Next, after detecting that the temperature adjustment has been completed by the bath temperature adjustment completion detection means S071, the water replenishing means S008 replenishes the bathtub 7 with hot water at the target temperature from the hot water storage tank 23. According to this, since heat can be recovered from the hot water before replenishment, the temperature of the hot water to be replenished can be lowered as compared with the case where heat is recovered from the hot water after replenishment. Incidentally, if heat is recovered from the hot water after replenishing, even if hot water at the target temperature is replenished in the bathtub 7, the hot water is cooled by heat recovery, so that hot water exceeding the target temperature needs to be replenished in the bathtub 7.

  The heat recovery means 25, 27, 53 include a heat exchanger (25), a bath pump 53 that circulates the water in the bathtub 7 to the circulation circuit 8 through the secondary side of the heat exchanger 25, and a heat exchanger. 25, and a remedy pump 27 that circulates water flowing through the primary side of the hot water storage tank 23 until the temperature of the hot water in the bathtub 7 is equal to or lower than a target temperature plus a predetermined temperature (eg, 1 ° C.). The bath pump 53 and the memory pump 27 are driven.

  According to this, since the heat recovery means 25, 27, 53 are composed of the bath pump 53, the heat exchanger 25, and the remedy pump 27, the water in the bathtub 7 is removed from the heat exchanger 25 by the bath pump 53. Circulating to the secondary side and circulating the hot water in the hot water storage tank 23 to the primary side of the heat exchanger 25 by the memory pump 27, the temperature of the hot water in the bathtub 7 is equal to or lower than the target temperature plus a predetermined temperature. Until then, the amount of heat can be recovered in the hot water storage tank 27.

  Furthermore, the drainage means 12 and 13 are provided with a drainage plug 12 provided at the bottom of the bathtub 7 and a drive device 13 for opening and closing the drainage plug 12, and the control device 28 detects the bathtub 7 detected by the water level detection means 48. A control signal is supplied to the drive device 13 based on the water level. According to this, since the drain plug 12 provided at the bottom of the bathtub 7 can be automatically opened and closed in accordance with a control signal based on the water level of the bathtub 7 detected by the water level detection means 48, it is accidentally redundant. It does not discharge a large amount of hot water.

  Next, a water level detecting means 48 and a temperature detecting means 52 are provided in the circulation circuit 8. Therefore, the temperature of the hot water in the bathtub 7 can be detected by circulating the hot water in the bathtub 7, so that the temperature of the hot water in the bathtub 7 is not detected. Further, it is not necessary to provide the water level detection means 48 in the bathtub 7.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. In the following embodiments, the same components as those in the first embodiment described above are denoted by the same reference numerals, description thereof will be omitted, and different configurations and features will be described. In the first embodiment, the half-body bath switch is provided in the remote device, and when the half-body bath switch is manually turned on, the control after step S002 in FIG. 3 is started.

  However, in the second embodiment, as shown in FIG. 9, the user touches the menu switch including the pattern displayed on the display screen 16d of the kitchen remote device (main remote control) 16 of FIG. And change the menu. For this purpose, on the display screen (remote control screen) 16d shown in FIG. 9B, the up / down switch selects normal hot water filling or half bathing hot water filling, and the determination switch operation is performed.

  After the half bathing mode is determined, half bathing is performed by operating the hot water switch of the bathroom remote control 15 in FIG. It should be noted that the menu switch on the display screen 15d of the bathroom remote controller 15 may be touched with the user's finger to change the menu as in FIG.

  In the second embodiment, remote devices 15 and 16 having display screens 15d and 16d for supplying an operation signal to the control device 28 and displaying a control state of the control device 28 are provided. The display screens 15d and 16d of the remote devices 15 and 16 are provided with a setting screen for a low-temperature low-water leveling mode (for example, a half-body bathing mode) in which the set temperature is lower than the normal hot-water mode and the set water level is low. By operating the setting screen for the low temperature low water level filling mode, the setting can be changed from the normal hot water mode to the low temperature low water level filling mode.

  According to this, it is possible to change the setting from the normal hot water mode to the low temperature low water level mode by operating the setting screen of the low temperature low water level mode of the remote devices 15 and 16, so the mode can be easily changed. It is.

(Third embodiment)
Next, a third embodiment of the present invention will be described. Features different from the above-described embodiment will be described. 10, by touching the menu switch of the kitchen remote device (main remote control) 16 shown in FIG. 10 (a), the screen shown in FIGS. 10 (b) to 10 (d) can be displayed on the display screen 16d. it can.

  For example, in the screen of FIG. 10B, the set temperature is selected with the up / down switch and determined with the determination switch, and the set temperature (target temperature) in the half-body bath setting in FIG. Set to ° C. In addition, the set water level (target water level) for half-body bathing can be set to 100 liters (100 L) on the display screen 16d in FIG.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described. Features different from the above-described embodiment will be described. In FIG. 11, the difference from the first embodiment is that the driving device 13 for opening and closing the drain plug 12 for draining the water in the bathtub 7 receives the supply of the power line and the communication line from the control device 28 via the wiring 56a. It is a point.

  In the fourth embodiment, the driving device 13 that opens and closes the drain plug 12 includes communication means with the control device 28, and the control device 28 operates the opening and closing of the drain plug 12 through the driving device 13. According to this, since the drive device 13 can be directly controlled by the control device 28, the control signal can be directly supplied to the drive device 13 by utilizing the information in the control device 28.

  In addition, since the control device 28 has the wiring 56a for supplying both the communication signal and the power to the drive device 13 and the communication signal and the power for the drive device 13 are supplied from the control device 28, an extra portion in the vicinity of the bathtub 7 is provided. Wiring can be reduced.

(Fifth embodiment)
Next, a fifth embodiment of the present invention will be described. Features different from the above-described embodiment will be described. In FIG. 12, the difference from the first embodiment is that the drive device 13 for opening and closing the drain plug 12 for draining the water in the bathtub 7 is supplied with a communication line from the control device 28 via the wiring 56b, and the power line A point 56c is supplied to the driving device 13 from a waterproof outlet in or near the bathroom.

  In the fifth embodiment, the drive device 13 that opens and closes the drain plug 12 includes a wiring 56 a serving as a communication line between the control device 28 and the control device 28 via the drive device 13. Opening and closing is operated. According to this, since the drive device 13 can be directly controlled by the control device 28, the control signal can be directly supplied to the drive device 13 by utilizing the information in the control device 28.

(Other embodiments)
In the above-described embodiment, the preferred embodiment of the present invention has been described. However, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention. It is. The structure of the said embodiment is an illustration to the last, Comprising: The scope of the present invention is not limited to the range of these description. The scope of the present invention is indicated by the description of the scope of claims, and further includes meanings equivalent to the description of the scope of claims and all modifications within the scope.

  In each of the above embodiments, the half-body bath has been described. However, the present invention is not limited to the half-body bathing, and a predetermined bathing state in which the bathing is already performed is set at a lower set temperature or a set water level. Can be automatically changed and adjusted to a low-preferred hot-water filling state (which can be referred to as an economy bath hot-water filling mode or a low-temperature low-water hot water filling mode).

  Also in this case, the control device can open and close the drain plug of the bathtub in cooperation with the drainage means, and the heat recovery circuit connected to the bathtub can recover the heat amount of the bathtub to the hot water storage tank. Therefore, it is possible to change the temperature of the bathtub to the desired temperature and the amount of hot water without wasting the amount of heat of the bathtub hot water, and to automatically create a bathtub state suitable for each user's preference. Easy to use because it can. In addition, the temperature and amount of hot water for multiple people can be set and stored in advance, and the temperature and water level of the hot water in the bathtub can be changed and adjusted sequentially by switch operation or reserved operation according to the bathing timing of each person. It may be. Moreover, you may use a solenoid valve and a motor operated valve as a drainage means.

52 Temperature detection means 12, 13 Drainage means 48 Water level detection means 53 Bath pump 25, 27, 53 Heat recovery means S005, S007 Temperature adjustment means S006 Water level adjustment means (S006)
32 Three-way valve for heat recovery 27 Mourning pump 15, 16 Remote device

Claims (8)

A water heater (3) for boiling water,
A hot water storage tank (23) for storing hot water boiled by the water heater (3);
Temperature detecting means (52) for detecting the temperature of water in the bathtub (7) of the bathroom,
Drainage means (12, 13) for automatically draining water in the bathtub (7);
Water level detection means (48) for detecting the water level in the bathtub (7);
Heat recovery means (25, 27, 53) for recovering the amount of hot water in the bathtub (7) in the hot water storage tank (23);
A controller (28) for controlling the drainage means (12, 13) and the heat recovery means (25, 27, 53),
The control device (28)
When the hot water filling operation into the bathtub (7) is started, when the hot water already exists in the bathtub (7), the temperature detecting means (52) is detected from the hot water in the bathtub (7). When the temperature exceeding the target temperature is detected, the heat recovery means (25, 27, 53) is operated to adjust the temperature of the water in the bath to the target temperature (S005, S007)
When hot water filling operation is started and hot water already exists in the bathtub (7), when the water level detecting means (48) detects a water level exceeding the target water level, the draining means ( 12, 13) and a water level adjusting means (S 006) for adjusting the water level in the bathtub (7) to be the target water level. The control device (28) detects a bath temperature adjustment completion detecting means (S071) that detects that the temperature adjustment means (S005, S007) has completed the adjustment of the water temperature in the bathtub (7) to the target temperature. )
The water level adjusting means (S006) adjusts the water level in the bathtub (7) to the target water level after detecting that the adjustment is completed by the bathtub temperature adjustment completion detecting means (S071). The hot water storage type hot-water supply device according to claim 1.   When the hot water filling operation is started, when the hot water is already present in the bathtub (7), the control device (28) allows the water level detection means (48) to control the water level exceeding the target water level. The hot water storage hot water supply according to claim 2, further comprising a water replenishing means (S008) for replenishing hot water at the target temperature from the hot water storage tank (23) into the bathtub (7) when not detected. apparatus.   After the completion of the adjustment is detected by the bathtub temperature adjustment completion detection means (S071), the water replenishing means (S008) supplies hot water at the target temperature from the hot water storage tank (23) into the bathtub (7). The hot water storage type hot water supply apparatus according to claim 3, wherein water is replenished.   The heat recovery means (25, 27, 53) is a heat exchanger (25) through which water in the bathtub (7) and water in the hot water storage tank (23) flow, and water in the bathtub (7). A bath pump (53) that circulates in a circulation circuit (8) through the secondary side of the heat exchanger (25), and water flowing through the primary side of the heat exchanger (25) in the hot water storage tank (23). The bath pump (53) and the memorial pump (27) until the temperature of the hot water in the bathtub (7) is equal to or lower than the target temperature plus a predetermined temperature. 27) is driven, the hot water storage type hot water supply apparatus according to any one of claims 1 to 4. The drainage means (12, 13) includes a drain plug (12) provided at the bottom of the bathtub (7) and a drive device (13) for opening and closing the drain plug (12),
The said control apparatus (28) supplies a control signal to the said drive device (13) based on the water level of the said bathtub (7) which the said water level detection means (48) detected. The hot water storage type hot water supply apparatus according to any one of the above.   The hot water storage type hot water supply apparatus according to claim 5, wherein the water level detection means (48) and the temperature detection means (52) are provided in the circulation circuit (8). A remote device (15, 16) having a display screen (15d, 16d) for supplying an operation signal to the control device (28) and displaying a control state of the control device (28);
The display screen (15d, 16d) of the remote device (15, 16) is provided with a setting screen for a low temperature low water level filling mode in which the set temperature is lower than the normal hot water mode and the set water level is low,
The setting of the low temperature low water level filling mode can be changed to the low temperature low water level filling mode by operating the setting screen of the low temperature low water level filling mode. The hot water storage type hot water supply apparatus described.

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