JP6658068B2 - Water heater - Google Patents

Description

  The present invention relates to a hot water supply device.

  The bath water heater disclosed in Patent Literature 1 below is as follows. The current water level in the bathtub is compared with the maintenance target water level, and if the current water level is lower than the maintenance target water level, water filling is performed so as to maintain the maintenance target water level. At the time of filling water, the filling amount is accumulated and counted by the filling flow sensor. When the cumulative water replenishment amount reaches the cumulative upper limit water replenishment amount calculated by the product of the bathtub capacity or the set hot water amount and one or more predetermined coefficient β, the water filling control valve is closed to refill the water refill. Stop. Further, the upper limit water replenishment amount for one refilling water filling is calculated by a product of a set filling water amount and a predetermined coefficient α of 0 or more and 1 or less.

JP-A-2003-42534

  Many water level sensors in bath water heaters detect the water level in a bathtub based on the pressure of a hot water supply pipe leading to the bathtub. In a case where an air pool is generated in the hot water supply pipe, there is a possibility that an error occurs in the water level detected by the water level sensor with respect to the actual water level in the bathtub. In such a case, it is difficult to surely prevent the hot water from overflowing from the bathtub when filling the hot water, that is, adding water, based on the water level detected by the water level sensor.

  The present invention has been made to solve the above-described problem, and has as its object to provide a hot water supply device that can reliably prevent hot water from overflowing from a bathtub during a hot water operation.

The hot water supply apparatus according to the present invention includes a means for detecting a water level in the bathtub, a means for acquiring a value of a bathtub cross-sectional area that is a cross-sectional area obtained by cutting a space in the bathtub along a horizontal plane, and a method for detecting a water level in the bathtub when the water level decreases. and means for controlling the adding hot water operation for replenishing the hot water, the the, the means for controlling the hot water added, the first replenishment amount calculated from the value of the reduction amount and tub sectional area of the water level, the tub cross section If more than a second supply amount that has been determined to be smaller as the value is smaller, supplemented with water in an amount corresponding to the second supply amount, otherwise, in an amount corresponding to the first supply amount it is intended to replenish the hot water.

  ADVANTAGE OF THE INVENTION According to the hot-water supply apparatus of this invention, it becomes possible to prevent that hot water overflows from a bathtub at the time of a hot water operation.

It is a figure which shows the hot-water supply apparatus of Embodiment 1. FIG. 2 is a block diagram of the hot water supply apparatus according to Embodiment 1. It is a figure which shows the relationship between the maximum amount of added hot water and the bathtub cross-sectional area. 5 is a flowchart illustrating a control routine for a filling operation and a hot water operation automatically performed by the hot water supply device of the first embodiment. 5 is a flowchart illustrating a control routine for a filling operation and a hot water operation automatically performed by the hot water supply device of the first embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. Elements common to the drawings are denoted by the same reference numerals, and redundant description will be simplified or omitted. The present disclosure may include any combination of configurations that can be combined among the configurations described in the following embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a hot water supply apparatus according to the first embodiment. Hot water supply apparatus 1 of the present embodiment shown in FIG. 1 is a hot water supply type hot water supply apparatus. Hot water supply device 1 includes a heat source unit 2 and a tank unit 3. The heat source device 2 is an example of a heating unit that heats water. The heat source device 2 may be a heat pump type heating device. The tank unit 3 is equipped with a hot water storage tank 10, a hot and cold water mixing valve 11, a control device 30, and the like.

  The outgoing pipe 12 connects between a lower part of the hot water storage tank 10 and an inlet of the heat source unit 2. A circulation pump 14 is connected in the middle of the going pipe 12. The return pipe 16 connects between the outlet of the heat source unit 2 and the upper part of the hot water storage tank 10. During the operation of accumulating hot water in the hot water storage tank 10, the operation is as follows. The heat source unit 2 and the circulation pump 14 are operated. The low-temperature water taken out from the lower part of the hot water storage tank 10 is sent to the heat source device 2 through the going pipe 12. Hot water, that is, high-temperature water, heated by the heat source unit 2 is sent to the tank unit 3 through the return pipe 16 and flows into the upper part of the hot water storage tank 10. Hot water is accumulated in the hot water storage tank 10 from top to bottom.

  The hot water supply pipe 4 connects the upper part of the hot water storage tank 10 and the hot water inlet of the hot water mixing valve 11. The water supply pipe 7 is connected to a water source such as a tap. Water supplied from a water source enters the tank unit 3 through the water supply line 7. A downstream portion of the water supply pipe 7 branches in the tank unit 3 and is connected to a lower portion of the hot water storage tank 10 and a water inlet of the hot and cold water mixing valve 11, respectively. One end of a hot water supply pipe line 5 is connected to an outlet of the hot and cold water mixing valve 11.

  The tank unit 3 and the bathtub 60 in the bathroom are connected via a first pipe 6 and a second pipe 8. One end of the first conduit 6 and one end of the second conduit 8 are connected to a bathtub 60. In the tank unit 3, the other end of the first conduit 6, the other end of the second conduit 8, and the other end of the hot water supply conduit 5 communicate with each other.

  A flow control valve 13 and a flow sensor 17 are provided in the middle of the hot water supply line 5. The flow rate adjusting valve 13 adjusts the flow rate of hot water passing through the hot water supply conduit 5. The flow rate sensor 17 detects the flow rate of hot water passing through the hot water supply pipe 5. A water level sensor 15 is provided in a portion of the first conduit 6 inside the tank unit 3. The water level sensor 15 can detect the water level in the bathtub 60 based on the water pressure in the first pipe 6. The water level sensor 15 does not detect the water level based on the bottom of the bathtub 60. The water level sensor 15 detects the water level of the bathtub 60 based on its own mounting position. At a position where the first conduit 6, the second conduit 8, and the hot water supply conduit 5 join, a temperature sensor 19 for detecting the temperature of the hot water is provided.

  The control device 30 controls the operations of the heat source device 2, the hot and cold water mixing valve 11, and the flow control valve 13. The control device 30 is connected to a remote control device 35 outside the tank unit 3 so as to be capable of bidirectional data communication by wire communication or wireless communication. Remote control device 35 is an example of a user interface. Remote control device 35 may be installed in a bathroom with bathtub 60.

  When supplying hot water to the bathtub 60, the operation is as follows. The flow control valve 13 is opened. Hot water supplied from the upper part of the hot water storage tank 10 by the hot water supply pipe 4 and low temperature water supplied by the water supply pipe 7 are mixed by the hot water mixing valve 11. The mixed hot water passes through the hot water supply pipe 5, flows into the first pipe 6 and the second pipe 8 and flows into the bath 60.

  The first pipe 6 and the second pipe 8 may form a circulation circuit for circulating bath water in the bathtub 60. A pump (not shown) for circulating bath water may be provided in the first pipe 6 or the second pipe 8. A heating means such as a heat exchanger for heating bath water may be provided in the first pipe 6 or the second pipe 8. By circulating the bath water in the first conduit 6 and the second conduit 8 while heating the bath water by the heating means, the bath water in the bath tub 60 may be additionally heated.

  FIG. 2 is a block diagram of hot water supply apparatus 1 of the first embodiment. As shown in FIG. 2, the control device 30 includes a heat source device drive unit 20, a mixing valve drive unit 21, a flow rate control valve drive unit 22, a first AD (analog-digital) conversion unit 23, a pulse detection unit 24, and a second AD conversion. The communication device includes a unit 25, a control unit 26, a storage unit 27, and a communication circuit unit 28. The remote control device 35 includes an operation unit 31 such as a button for receiving a user operation, and a display unit 33 including a liquid crystal display or the like. The remote controller 35 may further include an audio output unit capable of outputting audio guidance. The user can input various settings or reservations for various operations or operations of the water heater 1, an execution command, a stop command, and the like to the remote controller 35.

  The control device 30 controls the heat source device 2, the hot and cold water mixing valve 11, and the flow rate adjustment based on the command and information input by the user to the remote control device 35 and the information detected by the water level sensor 15, the flow rate sensor 17, and the temperature sensor 19. The operation of the valve 13 is controlled.

  The heat source unit driving unit 20 controls the operation of the heat source unit 2 under the control of the control unit 26. The mixing valve drive unit 21 controls the operation of the hot and cold water mixing valve 11 under the control of the control unit 26. The flow control valve drive unit 22 controls the operation of the flow control valve 13 under the control of the control unit 26. The first AD converter 23 converts the analog detection signal sent from the water level sensor 15 into a digital signal and sends it to the controller 26. The pulse detection unit 24 detects a pulse signal sent from the flow sensor 17 and sends a detection result to the control unit 26. The second AD converter 25 converts the analog detection signal sent from the temperature sensor 19 into a digital signal and sends the digital signal to the controller 26.

  The control unit 26 includes a boiling control unit 26a, a hot water filling control unit 26b, and a hot water control unit 26c. The boiling control unit 26a controls the operation of the heat source unit driving unit 20 so that a required amount of hot water is stored in the hot water storage tank 10. The hot water controller 26b obtains the detected temperature of the temperature sensor 19 based on the signal sent from the second AD converter 25, and calculates the detected temperature and the set temperature of the hot water specified or input by the user from the remote controller 35. The operation of the mixing valve drive unit 21 is controlled based on this, and the temperature of the hot water when filling the bathtub 60 is controlled. The hot water control unit 26b obtains the detected hot water amount of the flow rate sensor 17 based on the signal sent from the pulse detecting unit 24, and based on the detected hot water amount and the set hot water amount designated or input by the user from the remote control device 35. The operation of the flow rate control valve drive unit 22 is controlled to control the amount of hot water when filling the bathtub 60. The hot water controller 26c controls the temperature and the amount of hot water to be supplied during a hot water operation for supplying hot water to the bathtub 60.

  The control program of the control unit 26 is stored in the storage unit 27 in advance. In addition, the storage unit 27 stores in advance information about a water level drop amount that is a trigger for starting the adding hot water operation and information about a maximum adding hot water amount to be described later. The water level drop amount that serves as a trigger for starting the hot water operation may be, for example, 4 cm or more. The storage unit 27 also stores information on the amount of hot water designated by the user from the remote control device 35 (hereinafter referred to as “hot water setting hot water amount”) and the water level in the bathtub 60 at the completion of hot water filling (hereinafter, “hot water”). (Tension completion water level) is stored.

  The communication circuit unit 28 controls communication with the remote controller 35, that is, transmission and reception of information, under the control of the control unit 26.

  In the following description, a cross-sectional area obtained by cutting the space in the bathtub 60 along a horizontal plane is referred to as a “tub cross-sectional area”. FIG. 3 is a diagram showing the relationship between the maximum amount of hot water and the cross-sectional area of the bathtub. The relationship shown in FIG. 3 is stored in the storage unit 27. The maximum amount of added hot water is a value determined as an upper limit value of the amount of hot water supplied to bathtub 60 in one addition hot water operation. It is determined that the smaller the bathtub cross-sectional area is, the smaller the maximum amount of added hot water becomes. In the present embodiment, it is determined that the maximum amount of added hot water increases in direct proportion to the bathtub cross-sectional area. The maximum amount of hot water in the present embodiment is an example of the “second supply amount”.

  FIG. 4 is a flowchart showing a control routine in the hot water filling operation and the adding hot water operation automatically performed by hot water supply apparatus 1 of the first embodiment. When this routine is executed, it is assumed that a sufficient amount of hot water has already been accumulated in hot water storage tank 10.

  In step S1 of FIG. 4, when a user operation for instructing the start of filling is input to the remote control device 35, the remote control device 35 issues a filling start instruction to the hot water supply temperature and the hot water set hot water amount set by the user. The information is transmitted to the control device 30 together with the information. The process moves from step S1 to step S2.

  In step S2, the filling controller 26b controls the operations of the mixing valve driver 21 and the flow rate control valve driver 22. Thereby, the respective opening degrees of the hot and cold water mixing valve 11 and the flow control valve 13 are controlled, and the hot water of the temperature set by the user is started to be supplied to the bathtub 60.

Further, in step S2, hot water controller 26b calculates a bathtub cross-sectional area. The calculation result is stored in the storage unit 27. The method of calculating the bathtub cross-sectional area may be, for example, as follows. Hot water supply to the bathtub 60 is performed a plurality of times in a predetermined amount Qs (for example, every 20 L). At each hot water supply, the water level data change amount Hs is detected by the water level sensor 15, and the bathtub cross-sectional area A is calculated by the following equation (i) from the hot water supply amount at each time and the water level at that time.
A = Qs ÷ Hs (i)

  In the above case, the value of the bathtub cross-sectional area A calculated each time may be stored in the storage unit 27 in association with the water level detected by the water level sensor 15 at that time. By doing so, it is possible to control the bathtub 60 having a shape in which the bathtub cross-sectional area changes according to the water level with higher accuracy. The operation of calculating the bathtub cross-sectional area as described above may be performed only at the time of the first hot water filling after the installation of hot water supply device 1. The process moves from step S2 to step S3.

  In step S3, the hot water controller 26b determines whether or not the amount of hot water supplied to the bathtub 60 has become equal to or greater than the hot water set hot water, based on the signal sent from the pulse detector 24. If the amount of hot water supplied to bathtub 60 has not yet reached the set hot water amount, step S3 is repeated. If the amount of hot water supplied to bathtub 60 is equal to or greater than the set hot water amount, the process proceeds from step S3 to step S4. In step S4, the filling control unit 26b controls the operation of the flow control valve driving unit 22, closes the flow control valve 13, and stops hot water supply. The process moves from step S4 to step S5.

  In step S5, the filling controller 26b calculates the filling water level based on a signal sent from the water level sensor 15 via the first AD converter 23. The calculated value of the filling water level is stored in the storage unit 27. The process moves from step S5 to step S6. In step S6, the hot water controller 26b transmits a predetermined signal indicating the end of the hot water to the additional hot water controller 26c. The process moves from step S6 to step S7.

  The hot water controller 26c receives the above signal and starts operating. In step S7, the hot water controller 26c performs the following. From the storage unit 27, the value of the water level decrease amount and the value of the filling water level that serve as a trigger for starting the adding hot water operation are read. Based on the signal sent from the first AD converter 23, the current water level of the bathtub 60 is calculated. It is determined whether or not the difference in water level between the hot water filling completion water level and the current water level is equal to or greater than the above water level drop amount. In the present embodiment, it is determined whether or not the current water level of bathtub 60 has decreased by 4 cm or more from the water level at which the filling has been completed. When it is determined in this step S7 that the water level difference is less than 4 cm, the step S7 is repeated. When it is determined that the water level difference is 4 cm or more, the process proceeds from step S7 to step S8.

In step S8, the additional hot water controller 26c calculates the additional hot water amount V0 as follows. Using the value of the bathtub cross-sectional area A obtained in the above step S2, the value of the hot water filling completion water level Hc obtained in the step S5, and the current water level of the bathtub 60 obtained in the step S7, that is, the value of the current water level H0. The additional hot water amount V0 is calculated by the following equation (ii).
V0 = A × (Hc−H0) (ii)

As an example, when the bathtub cross-sectional area A is 0.66 m ² , the filling water level Hc is 0.45 m, and the current water level H0 is 0.41 m, the added hot water quantity V0 is calculated as follows.
V0 = 0.66 m ² × (0.45 m−0.41 m) = 0.0264 m ³
(Hc-H0) corresponds to the amount of decrease in the water level of the bathtub 60. The hot water amount V0 in the present embodiment is an example of a “first supply amount” calculated from the water level decrease amount (Hc−H0) and the bathtub sectional area A.

  If an air pool occurs in the first conduit 6 in which the water level sensor 15 is arranged, the water level detected by the water level sensor 15 may deviate from the actual water level in the bathtub 60. In such a case, the water level drop (Hc−H0) may be detected excessively as compared with the actual water level drop. As the value of the water level drop (Hc-H0) increases, the value of the added hot water amount V0 calculated in step S8 increases. If the water level drop amount (Hc-H0) is detected to be excessively large compared to the actual water level drop amount, the value of the hot water quantity V0 becomes excessively large as compared with the actually required amount. In such a case, if the amount of hot water corresponding to the added hot water amount V0 is supplied to the bathtub 60, the hot water may overflow from the bathtub 60.

In the present embodiment, in order to reliably prevent hot water from overflowing from bathtub 60 in the above-described case, the upper limit of hot water to be supplied to bathtub 60 in the hot water operation is limited by the maximum amount of hot water. . As described above, the smaller the bathtub cross-sectional area is, the smaller the maximum amount of added hot water is set. The rise in water level when an equal amount of hot water is supplied is greater as the bathtub cross-sectional area is smaller. For example, when supplemented with hot water 50L, while the tub cross section is level rise of 0.05m if 1.0 m ^2, tub sectional area of 0.1m if 0.5 m ² water level It will rise. Therefore, when an equal amount of hot water is supplied, the smaller the cross-sectional area of the bathtub, the higher the possibility that hot water overflows from bathtub 60. According to the present embodiment, when the bathtub cross-sectional area is small, the maximum amount of added hot water is smaller than when the bathtub cross-sectional area is large. For this reason, even if the bathtub cross-sectional area is small, it is possible to reliably prevent the hot water from overflowing from the bathtub 60.

As shown in FIG. 3, the present embodiment is as follows. For example, when the bathtub cross-sectional area is 0.5 m ² , the maximum amount of added hot water is 25 L. In this case, the water level rises when supplemented with water up to volume 25L in the bathtub 60 of the bath sectional area 0.5 m ² added becomes 0.05 m. When the bathtub cross-sectional area is 1.0 m ² , the maximum amount of added hot water is 50 L. In this case, the water level rises when supplemented with water up to volume 50L in the bathtub 60 of the bath sectional area 1.0 m ² added becomes 0.05 m. Thus, according to the present embodiment, it is possible to equalize the rise in water level when the maximum amount of hot water is supplied to bathtub 60, regardless of the value of the bathtub cross-sectional area. In addition, the water level rise of 0.05 m (= 5 cm) when the maximum amount of hot water is supplied to the bathtub 60 is larger than the water level drop amount (4 cm in the present embodiment) that is a trigger for starting the hot water operation. .

  The process moves from step S8 to step S9. In step S9, the value of the added hot water amount V0 calculated in step S8 is compared with the value of the added hot water amount Vm. The maximum amount of added hot water Vm is calculated by applying the value of the bathtub cross-sectional area A obtained in step S2 to the relationship of FIG. 3 stored in the storage unit 27. In the case where the bathtub 60 having a shape in which the bathtub cross-sectional area changes in accordance with the water level is used, when the water level of the bathtub 60 and the bathtub cross-sectional area A are stored in the storage unit 27 in association with each other, the following applies. It may be as follows. The value of the bathtub cross-sectional area A at the filling water level Hc or the current water level H0 is calculated. The maximum value Vm of the hot water is calculated by applying the value of the bathtub cross-sectional area A to the relationship shown in FIG.

  When the amount of added hot water V0 exceeds the maximum amount of added hot water Vm, the process proceeds from step S9 to step S10. In step S10, the amount Va of hot water to be replenished in the hot water operation is determined. In this case, the hot water amount Va is set to a value equal to the maximum hot water amount Vm. The process moves from step S10 to step S12.

  If the amount of added hot water V0 does not exceed the maximum amount of added hot water Vm, the process proceeds from step S9 to step S11. In step S11, the amount Va of hot water to be replenished in the hot water operation is determined. In this case, the added hot water amount Va is set to a value equal to the added hot water amount V0. The process moves from step S11 to step S13.

  In steps S12 and S13, the hot water controller 26c starts the hot water operation. That is, the hot water controller 26c controls the operations of the mixing valve driver 21 and the flow rate control valve driver 22. Thereby, the respective opening degrees of the hot and cold water mixing valve 11 and the flow rate control valve 13 are controlled, and hot water at a temperature set by the user is supplied to the bathtub 60. The process moves from step S12 to step S14. The process moves from step S13 to step S15.

  In steps S14 and S15, the hot water control unit 26c determines whether or not the amount of hot water supplied to the bathtub 60 has become equal to or greater than the above-mentioned hot water amount Va based on the signal sent from the pulse detection unit 24. to decide. If it is determined in step S14 or S15 that the hot water supply amount has not yet reached the added hot water amount Va, step S14 or step S15 is repeated. If the hot water supply amount has reached the added hot water amount Va, the process proceeds from step S14 or step S15 to step S16. In step S16, the hot water control unit 26c controls the operation of the flow rate control valve drive unit 22, closes the flow rate control valve 13, and stops hot water supply. The process moves from step S16 to step S7. Accordingly, in step S7, if the current water level has not reached the water level 4 cm lower than the filling water level, that is, if the water level after the adding hot water operation is lower than the target water level, the processing in step S8 and subsequent steps is performed. Hot water operation is performed again. Therefore, the target water level can be reliably achieved.

  As described above, the present embodiment is as follows. If the added hot water amount V0 calculated from the water level drop amount (Hc-H0) and the bathtub cross-sectional area A exceeds the maximum added hot water amount Vm, an amount of hot water corresponding to the maximum added hot water amount Vm is used for the operation of the hot water operation. Sometimes replenished to bathtub 60. On the other hand, when the amount of added hot water V0 does not exceed the maximum amount of added hot water Vm, the amount of hot water corresponding to the amount of added hot water V0 is supplied to the bathtub 60 during the operation of the added hot water. By doing so, the following effects can be obtained. Even when the water level drop (Hc-H0) is detected to be too large as compared with the actual water level drop, it is possible to reliably prevent the hot water from overflowing from the bathtub 60. In particular, even when the bathtub 60 having a small bathtub cross-sectional area is used, it is possible to reliably prevent the hot water from overflowing from the bathtub 60.

In the case where the size of the bathtub 60 is large, if the maximum amount of hot water exceeds the hot water setting hot water amount, the upper limit of the amount of hot water supplied during the hot water operation is limited by the hot water setting hot water amount. You may. For example, in the example of FIG. 3, when the bathtub cross-sectional area is 2.5 m ² , the maximum amount of added hot water is 125 L. In this case, if the hot water setting hot water amount is 100 L, the upper limit of the hot water replenishment amount at the time of the hot water operation may be limited to 100 L equal to the hot water setting hot water amount.

Embodiment 2 FIG.
Next, a second embodiment will be described with reference to FIG. 5, but the description will focus on differences from the first embodiment described above, and description of the same or corresponding parts will be simplified or omitted. The device configuration of hot water supply apparatus 1 of the second embodiment is the same as that shown in FIG.

  FIG. 5 is a flowchart showing a control routine for hot water filling operation and hot water operation automatically performed by hot water supply apparatus 1 of the second embodiment. In the second embodiment, the number of times the hot water operation is continuously performed, that is, the number of times the hot water operation is repeated is limited. Further, in the second embodiment, when the adding hot water operation is continuously performed, that is, when the adding hot water operation is repeated, the replenishing amount of the hot water is smaller than the replenishing amount at the time of the previous adding hot water operation. I do.

  Steps S1 to S5 in FIG. 5 are the same as those in the first embodiment. In step S6, the hot water control unit 26b transmits a predetermined signal indicating the end of the hot water to the hot water control unit 26c. At this time, n = 0. This n means the number of repetitions (the number of times excluding the first time) when the adding hot water operation is continuously performed. Hereinafter, it is referred to as “the number of repetitions n”.

  Steps S7 to S9 in FIG. 5 are the same as those in the first embodiment. In steps S10 and S11, the amount Va of hot water to be replenished in the hot water operation is determined.

In the case of step S10, the added hot water amount Va is set to a value equal to a value obtained by multiplying the maximum added hot water amount Vm by the correction coefficient α. That is, the hot water quantity Va is calculated by the following equation (iii).
Va = Vm × α (iii)

In the case of step S11, the added hot water amount Va is set to a value equal to a value obtained by multiplying the added hot water amount V0 by the correction coefficient α. That is, the added hot water amount Va is calculated by the following equation (iv).
Va = V0 × α (iv)

  The initial value of the correction coefficient α is set to 1. Therefore, when the first adding hot water operation is performed after the completion of filling, the adding hot water amount Va is determined to be the same value as in the first embodiment.

  Steps S12 to S16 in FIG. 5 are the same as those in the first embodiment. The process moves from step S16 to step S17. In step S17, the number of repetitions n is compared with a predetermined limit number K. The limit number K may be, for example, two. If the number of repetitions n exceeds the limit number K, the process moves from step S17 to step S21. If the process has proceeded to step S21, the processing of this routine is terminated, and thereafter, the hot water operation is not performed.

If the number of repetitions n does not exceed the limit number K, the process proceeds from step S17 to step S18. In step S18, the current water level is detected by the water level sensor 15. It is determined whether or not the detected current water level is equal to the detected water level before performing the hot water operation (hereinafter, referred to as “previous water level”). If the current water level is equal to the previous water level, the process moves from step S18 to step S19. In step S19, 1 is added to the number of repetitions n. That is, n = n + 1. Further, the correction coefficient α is calculated by the following equation (v). The process moves from step S19 to step S7.
α = 0.8 ⁿ (v)

  By calculating the correction coefficient α as described above, the following is obtained. When the adding hot water operation is continuously performed, that is, when the adding hot water operation is repeated, the adding hot water amount Va determined in step S10 or step S11 becomes 0.8 times the previous adding hot water operation. . Note that “0.8” in Expression (v) is an example numerical value, and can be replaced with another numerical value larger than 0 and smaller than 1.

  If the current water level is different from the previous water level in step S18, the process proceeds to step S20. In step S20, the number of repetitions n = 0, and the correction coefficient α = 1. The process moves from step S20 to step S7.

  Even though the hot water is supplied in the hot water operation, the water level sensor 15 may incorrectly detect the water level detected by the water level sensor 15 to be equal to the water level detected before the hot water operation is performed. In such a case, when returning to step S7, it is erroneously determined that the water level has not recovered, so that the adding hot water operation is continuously performed. In the case of the present embodiment, the number of repetitions in the case where the hot water operation is continuously performed in such a manner is limited. For this reason, even if the hot water operation is continuously performed due to the erroneous detection of the water level sensor 15, it is possible to surely prevent the hot water from overflowing from the bathtub 60. Further, the supply amount of hot water when the hot water operation is continuously performed is made smaller than the supply amount at the time of the previous hot water operation. For this reason, the overflow of hot water from the bathtub 60 can be suppressed more reliably.

  The above-mentioned limit number K is not limited to two, but may be one, three, or more. Control device 30 may change the value of limit number K according to the bathtub cross-sectional area. For example, when the bathtub cross-sectional area is small, the limit number K may be set to a larger value than when the bathtub cross-sectional area is large. When the user draws an equal amount of hot water from the bathtub 60, the smaller the bathtub cross-sectional area, the greater the water level drop. Therefore, when the user draws and consumes hot water from the bathtub 60, the smaller the bathtub cross-sectional area, the greater the number of necessary hot water operations. If the value of the limit number K is too small when the bathtub cross-sectional area is small, the required number of hot water operations may not be performed. On the other hand, when the bathtub cross-sectional area is small, by setting the limit number K to a larger value than when the bathtub cross-sectional area is large, it is possible to reliably perform the necessary number of add-on operations.

  Alternatively, when the bathtub cross-sectional area is small, the limit number K may be set to a smaller value than when the bathtub cross-sectional area is large. When the bathtub 60 is refilled with an equal amount of hot water, the smaller the bathtub cross-sectional area, the greater the rise in water level. For this reason, when unnecessary hot water operation is continuously performed due to erroneous detection of the water level sensor 15, the possibility that hot water overflows from the bathtub 60 as the bathtub cross-sectional area becomes smaller. For this reason, if the value of the limit number K is too large when the bathtub cross-sectional area is small, hot water may overflow from the bathtub 60 when unnecessary addition hot water operations are continuously performed. On the other hand, when the bathtub cross-sectional area is small, it is possible to reliably suppress the overflow of hot water from the bathtub 60 by setting the limit number K to a smaller value than when the bathtub cross-sectional area is large.

  Note that, when the control device 30 performs the adding hot water operation a plurality of times, the total amount of hot water supplied by the plurality of adding hot water operations exceeds the initial amount of hot water in the bathtub 60, that is, the hot water setting hot water amount. In this case, the additional hot water operation may be prohibited. By doing so, it is possible to reliably suppress overflow of hot water from the bathtub 60, and to prevent excessive consumption of hot water.

  The embodiments have been described above, but the present invention is not limited to these embodiments. For example, the hot water control unit may calculate the value of the bathtub cross-sectional area instead of the hot water filling unit. Further, the value of the bathtub cross-sectional area may be input to the remote controller 35 by a user or a contractor. Also, what to use as the heat source device can be appropriately selected. For example, when using a heater as a heat source unit, the heater may be arranged inside the hot water storage tank. Further, the present invention is not limited to the hot water supply device of the hot water storage type, and is applicable to a hot water supply device having an instantaneous water heater.

  Further, the control device 30 may be configured as follows, for example. The control device 30 may include, for example, a processing circuit including a processor and a memory as hardware resources. The control device 30 may realize each function described above by executing a program stored in the memory by the processor. In addition, some or all of the functions of the control device 30 may be realized by hardware.

DESCRIPTION OF SYMBOLS 1 Hot-water supply apparatus, 2 Heat source unit, 3 Tank unit, 4,5 Hot-water supply line, 6 First line, 7 Water supply line, 8 Second line, 10 Hot-water storage tank, 11 Hot-water mixing valve, 12 Outgoing pipe, 13 Flow control valve, 14 circulation pump, 15 water level sensor, 15 water level sensor, 16 return pipe, 17 flow sensor, 19 temperature sensor, 20 heat source device drive unit, 21 mixing valve drive unit, 22 flow control valve drive unit, 23 1st AD Conversion part, 24 pulse detection part, 25 second AD conversion part, 26 control part, 26a boiling control part, 26b filling control part, 26c adding hot water control part, 27 storage part, 28 communication circuit part, 30 control device, 31 Operation unit, 33 display unit, 35 remote control device, 60 bathtub

Claims (7)

Means for detecting the water level in the bathtub;
Means for obtaining a value of a bathtub cross-sectional area, which is a cross-sectional area obtained by cutting the space in the bathtub in a horizontal plane,
Means for controlling a hot water operation for supplying hot water into the bathtub when the water level drops,
With
The means for controlling the adding hot water operation, the first replenishment amount calculated from the water level drop amount and the value of the bathtub cross-sectional area , is determined so that the smaller the value of the bathtub cross-sectional area , the smaller the first replenishment amount two if it exceeds the replenishment amount, supplemented with an amount of water corresponding to the second supply amount, otherwise, the water heater for supplying hot water in an amount corresponding to the first supply amount.   The hot water supply apparatus according to claim 1, wherein when the water level after the adding hot water operation is lower than the target water level, the adding hot water operation is performed again.   The hot water supply apparatus according to claim 1 or 2, wherein the number of times that the adding hot water operation is continuously performed is limited. The replenishing amount of the hot water in the case where the adding hot water operation is continuously performed is reduced as compared with the replenishing amount in the previous adding hot water operation according to any one of claims 1 to 3. Water heater. The limited number of times for limiting the number of times that the adding hot water operation is continuously performed is larger when the value of the bathtub cross-sectional area is smaller than when the value of the bathtub cross-sectional area is larger. Item 6. The water heater according to any one of items 4. Wherein when the value of the tub cross section is small, as compared with the case where the value of the tub cross section is large, according claim 1, limit number is reduced to limit the number of times continuously carried out the added hot water operation Item 6. The water heater according to any one of items 4.   7. The method according to claim 1, wherein when the total amount of hot water replenished by the plurality of hot water operations exceeds the initial amount of hot water in the bathtub, the hot water operation is prohibited. 8. The hot water supply device as described.

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