JP3844650B2 - Water heater with remembrance - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to failure detection in a so-called canned and two-water channel hot water heater with reheating, in which a part of a heat exchanger for hot water supply and a heat exchanger for reheating are overlapped.
[0002]
[Prior art]
In recent years, for the purpose of space saving, a hot water supply heat exchanger that heats water flowing in a hot water supply line connected to a water pipe and a reheating heat exchange that heats hot water flowing in a reheating pipe connected to a bathtub A so-called one-can two-water channel hot water heater with a part of the heater installed has been developed.
[0003]
In such a water heater, when performing a reheating operation in which hot water stored in the bathtub is heated by the reheating heat exchanger while circulating in the reheating pipeline, the reheating heat exchanger is as described above. Since the hot water supply heat exchanger partially overlaps, the water staying in the hot water supply heat exchanger is also heated at the same time, so that hot hot water stays in the hot water supply heat exchanger.
[0004]
And if hot water supply is started in such a state, the hot water staying in the hot water supply heat exchanger will be discharged from the hot water supply pipe, giving unpleasant feeling to the user of the hot water. Therefore, a bypass pipe that communicates the upstream side and the downstream side of the portion heated by the hot water supply heat exchanger of the hot water supply pipe, the flow rate of water supplied to the hot water supply heat exchanger side, and the flow rate of water flowing to the bypass pipe side Hot water supplied from the hot water supply line by providing a flow ratio adjusting means (flow rate control valve, etc.) for adjusting the ratio of the hot water supplied from the bypass pipe to hot water discharged from the hot water heat exchanger. The process of lowering the temperature is being performed.
[0005]
Here, if the flow rate adjusting means breaks down and the water from the bypass pipe cannot be mixed into the hot water discharged from the hot water supply heat exchanger, the hot water discharged from the hot water heat exchanger at the start of hot water supply It will be supplied to the hot water supply pipe as it is. Therefore, conventionally, the presence or absence of a failure of the flow rate adjusting means is checked at the start of the follow-up operation or during the follow-up operation, and when the failure is detected, the execution of the follow-up is prohibited and this situation occurs. I tried to prevent this from happening.
[0006]
However, when the present inventors detect the presence or absence of a failure of the flow rate ratio adjusting means at the start of the follow-up operation or during the follow-up operation, the user's convenience may be deteriorated. I found out.
[0007]
[Problems to be solved by the invention]
The present invention has been made in view of the above-mentioned background, and in a single-can two-water channel hot water heater with a retouch, with a retouch that has improved the user-friendliness when detecting a failure of the flow rate adjusting means. The purpose is to provide a water heater.
[0008]
[Means for Solving the Problems]
The present invention has been made in order to achieve the above-mentioned object, and in order to replenish the bath, a reheating pipe line through which hot water stored in the bath is circulated and water supplied from the water supply are heated. A hot water supply line for supplying hot water, a reheating heat exchanger for heating the hot water flowing through the reheating pipe, and a part of the water that flows through the reheating heat exchanger overlapping with the reheating heat exchanger A hot water supply heat exchanger for heating the heating water, a heating means for heating the additional heat exchanger and the hot water supply heat exchanger, and an upstream side and a downstream side of a portion heated by the hot water supply heat exchanger in the hot water supply line A bypass pipe communicating with each other, a flow rate adjusting means for adjusting a ratio of a flow rate of water flowing to the bypass pipe side and a flow rate of water flowing to the hot water supply heat exchanger side, and the presence or absence of failure of the flow ratio adjusting means A failure detecting means for detecting the flow rate ratio adjusting means by the failure detecting means. When disabled is detected, to reheating with water heater improvement and a reheating inhibiting means for inhibiting the execution of reheating.
[0009]
And ,in front A hot water filling instructing means having a function of performing hot water filling processing for supplying hot water from the hot water supply pipe to the bathtub, and failure of the flow rate ratio adjusting means by the failure detecting means; Failure detection means for informing when the hot water filling process is detected, the failure detection means from the time when the hot water filling process is instructed to start until the hot water filling process is completed. And at least one of when the hot water filling process is completed, the presence or absence of a failure of the flow rate adjusting means is detected.
[0010]
According to the present invention, the replenishment prohibiting means has completed the hot water filling process from when the hot water filling process is instructed by the hot water filling instruction means until the hot water filling process is completed. The failure detection process is executed in at least one of the cases. When the failure detection process detects a failure of the flow rate adjusting means, the tracking prohibiting means prohibits execution of the tracking, and the failure notification means causes a failure of the flow rate adjusting means. It is informed.
[0011]
Thereby, before starting bathing, it can be made to recognize that the malfunction of the said flow rate ratio adjustment means produced and the execution of a chasing was prohibited. Therefore, inconvenience that occurs when the failure detection process is performed at the start of the chasing or during chasing, that is, the user who bathed felt the warm water stored in the bathtub and instructed the chasing Sometimes, the failure detection process is executed to detect a failure of the flow rate adjusting means, and accordingly, the follow-up prohibiting means prohibits the execution of the follow-up, so that the follow-up cannot be performed. It is possible to prevent the inconvenience that would result in having to take a bath with patience.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
An example of an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is an overall configuration diagram of a hot water heater with a reheating device according to the present invention, FIG. 2 is a control block diagram of the hot water heater with a reheating device shown in FIG. 1, FIG. 3 is an explanatory diagram of an operating range of a bypass valve, and FIGS. 5 is a flowchart of a bypass servo failure detection process.
[0017]
Referring to FIG. 1, a water heater 1 is connected to a water pipe (not shown) by a hot water supply pipe 2 and is connected to a bathtub 4 by a reheating pipe 3. The hot water heater 1 has a function of heating and supplying hot water supplied from the water pipe via the hot water supply pipe 2 and a function of heating and chasing the hot water stored in the bathtub 4.
[0018]
The entire operation of the water heater 1 is controlled by the controller 4, and the first burner 5 (corresponding to the heating means of the present invention) that operates according to the control signal from the controller 4 and the heating capability is lower than that of the first burner. The second burner 6 (corresponding to the heating means of the present invention), the reheating heat exchanger 7 and the hot water supply heat exchanger 8 heated by the first burner 5 and the second burner 6, and the water pipe to the hot water supply line 2 A bypass pipe 9 for bypassing the hot water supply heat exchanger 8 to mix a part of the supplied water with hot water discharged from the hot water supply heat exchanger 8, and the opening degree of the bypass pipe 9 is adjusted by a control signal from the controller 4. Bypass servo 10, hot water thermistor 11 that detects the temperature of hot water downstream of the junction X between the hot water supply pipe 2 and the bypass pipe 9 and outputs a detection signal to the controller 4, hot water near the outlet of the hot water heat exchanger 8 Detect temperature The heat exchange thermistor 12 that outputs the detection signal to the controller 4, the water amount sensor 13 that detects the flow rate of the water supplied from the water supply to the hot water supply pipe 2 and outputs the detection signal to the controller 4, and the hot water supply pipe 2 A hot water servo 14 for adjusting the flow rate of the hot water is provided.
[0019]
Further, the water heater 1 includes a hot water relay pipe 30 that connects the hot water supply pipe 2 and the follow-up pipe 3, and a hot water solenoid valve 15 that operates by a control signal from the controller 4 to open and close the hot water relay pipe 30. A check valve 16 that allows passage of hot water in the direction from the hot water relay pipe 30 to the hot water relay pipe 30 and disables passage of hot water in the direction from the hot water relay pipe 30 to the hot water pipe 3, controller 4 is operated by a control signal from the pump 4 to circulate hot water stored in the bathtub 4 in the tracking pipe 3, and the temperature of hot water supplied from the bathtub 4 to the tracking pipe 3 (= stored in the bathtub). A bath thermistor 18 that detects the temperature of the hot water and outputs a detection signal to the controller 4, a bath water flow switch 19 that detects the presence or absence of hot water flowing in the tracking pipe 3 and outputs a detection signal to the controller 4, and hot water supply From pipe 2 to hot water filled relay pipe 30 Comprising a hot water sensor 20 that outputs a detection signal by detecting the flow rate of the hot water supplied to the bathtub 4 via the fired line 3 to the controller 4.
[0020]
In addition, the water heater 1 controls the operation of the first burner 5 and the second burner 6, so that the fuel gas is supplied to and shut off from the first burner 5 and the second burner 6 in accordance with a control signal from the controller 4. A gas proportional valve 22 that adjusts the supply flow rate of the fuel gas in accordance with a control signal from the controller 4, a fuel gas supply to the first burner 5 in accordance with a control signal from the controller 4 The first gas solenoid valve 23 that switches between shutoff and the control signal from the controller 4, the second gas solenoid valve 24 that switches between supply and shutoff of the fuel gas to the second burner 6 according to the control signal from the controller 4 Combustion fan 25 for supplying combustion air to the first burner 5 and the second burner 6, and ignition for generating a spark discharge by a high voltage applied from the igniter 26 according to a control signal from the controller 4 The lug 27, the frame rod 28 that detects the presence or absence of a combustion flame in the second burner 6 and outputs a detection signal to the controller 4, and the water at the highest temperature in the hot water supply pipe 2 in the hot water supply heat exchanger 8. And a water pipe thermistor 29 that outputs a detection signal to the controller 4.
[0021]
The water pipe thermistor 29 is provided to prevent the water staying in the hot water supply heat exchanger 8 from being heated and abnormally heated when only the reheating operation is performed alone. When the detected temperature exceeds a predetermined upper limit temperature, the controller 4 stops the combustion of the first burner 5 and the second burner 6.
[0022]
The controller 4 transmits and receives various signals to and from the remote controller 40 installed in a bathroom or the like.
[0023]
Next, referring to FIG. 2, the controller 4 includes a hot water supply control means 50 for performing hot water supply control for supplying hot water at a target hot water supply temperature from the hot water supply pipe 2, and the hot water stored in the bathtub 4 to the target reheating temperature. A reheating control means 51 for performing a reheating operation for increasing the temperature and a filling control means 52 for performing a filling operation for supplying hot water at a target filling temperature to the bathtub 4 by the target filling amount are provided.
[0024]
Further, the remote controller 40 includes a temperature setting switch 41 for setting the hot water supply temperature, a hot water filling switch 42 for instructing start / stop of the hot water filling operation (corresponding to the hot water filling instruction means of the present invention), and the start / A follow-up switch 43 for instructing a stop, a buzzer 44 (including the function of the failure notification means of the present invention), and a display 45 (including the function of the failure notification means of the present invention) for displaying a hot water supply temperature, a hot water temperature, etc. Is provided.
[0025]
The bypass servo 10 includes a bypass valve 61 (corresponding to the flow rate adjusting means of the present invention) and a stepping motor 60 that drives the bypass valve 61 and changes the valve opening position of the bypass valve 61. The provided motor control means 54 controls the angular position of the stepping motor 60 via the motor driver 55.
[0026]
The motor control means 54 outputs a pulse signal corresponding to the target angular position of the stepping motor 60 (corresponding to the target valve opening position of the bypass valve) to the motor driver 55, and the motor driver 55 sets the number of pulses of the pulse signal. A motor drive signal for rotating the stepping motor 60 by the corresponding rotation angle is output to the stepping motor 60.
[0027]
Here, the rotation angle of the stepping motor 60 corresponding to one pulse of the pulse signal is defined in advance, and the motor control means 54 adjusts the number of output pulses by the position counter 56 according to the rotation direction of the stepping motor 60. And accumulate. Then, the motor control means 54 grasps the angular position of the stepping motor 60 from the count value of the position counter 56.
[0028]
Further, a limit sensor 62 that is turned on when the angular position of the stepping motor 60 falls within a predetermined range is provided in the vicinity of the stepping motor 60, and the controller 4 includes a bypass that detects whether or not the bypass valve 61 has failed. A valve failure detection means 53 (corresponding to the failure detection means of the present invention), and a follow-up prohibition means 57 for prohibiting the execution of a follow-up operation when a failure of the bypass valve 61 is detected by the bypass valve failure detection means 53. Is provided.
[0029]
The hot water supply control means 50 controls the combustion amount of the first burner 5 and the second burner 6 so that hot water at the target hot water supply temperature set by the remote controller 40 is supplied from the hot water supply pipe 2. When the hot water supply control means 50 detects from the detection signal of the water amount sensor 13 that a curan (not shown) connected to the downstream side of the hot water supply pipe 2 is opened and water supply from the water pipe is started, the combustion fan 25, the supply of combustion air is started, and a high voltage is applied from the igniter 26 to the spark plug 27 to cause a spark discharge, and the original gas solenoid valve 21 and the second gas solenoid valve 23 are The valve is opened and the second burner 6 is ignited.
[0030]
The hot water supply control means 50 adjusts the heating amount by the first burner 5 and the second burner 6 by the first gas solenoid valve 23, the second gas solenoid valve 24 and the gas proportional valve 22. And when the hot water control means 50 detects from the detection signal of the water quantity sensor 13 that the water supply from the water pipe to the hot water supply pipe 2 has been stopped by the user closing the curan, The first gas solenoid valve 23 and the second gas solenoid valve 24 are closed, the operation of the combustion fan 25 is stopped, and the hot water supply control is finished.
[0031]
Next, the chasing control means 51 starts chasing control in response to the chasing start instruction from the remote controller 40. The reheating control means 51 operates the pump 17 to circulate hot water in the bathtub 4 through the reheating pipe 3, and in this state, the first burner 5 and the second burner 6 perform the same as in the hot water supply control described above. The reheating heat exchanger 7 is heated to heat the hot water circulating in the reheating pipeline 3. As a result, the hot water stored in the bathtub 4 is gradually heated, and when the detected temperature of the bath thermistor 18 reaches the target tracking temperature set by the remote controller 40, the tracking control means 51 is provided with the first burner. 5 and the combustion of the second burner 6 are stopped, and the chasing control is finished.
[0032]
The chasing control means 51 checks whether or not the water flow is detected by the bath water flow switch 19 when the pump 17 is operated. When the water flow is detected by the bath water flow switch 19 and it can be determined that hot water is stored in the bathtub 4, the chasing control is executed.
[0033]
The hot water filling control means 52 starts the hot water filling control in response to the hot water filling start instruction from the remote controller 40. The hot water filling control means 52 first opens the hot water solenoid valve 15, thereby starting water supply from the water pipe to the hot water filling pipe line 2, and the hot water supply control means 50 sets the target hot water set by the remote controller 40. Hot water supply control at the tension temperature is started. Then, hot water at the target hot water temperature is supplied from the hot water supply pipe 2 to the bathtub 4 via the hot water filling relay pipe 30 and the tracking pipe 3.
[0034]
The hot water filling control means 52 grasps the amount of hot water stored in the bathtub 4 from the hot water supply flow rate detected by the hot water amount sensor 20 and the hot water supply time, and the hot water amount becomes the target hot water filling amount set by the remote controller 40. When reaching, the hot water solenoid valve 15 is closed and the hot water filling control is finished.
[0035]
Next, when only the chasing operation is performed alone, as described above, the hot water flowing in the chasing channel 3 is heated by the chasing heat exchanger 7, but overlaps with the chasing heat exchanger 7. Since the hot water supply heat exchanger 8 provided is also heated by the second burner 6, the water staying in the hot water supply heat exchanger 8 is also heated to a high temperature.
[0036]
When the hot water supply operation is started with the hot water remaining in the hot water supply heat exchanger 8 in this manner, the hot water is supplied from the hot water heat exchanger 8 to the hot water supply line, which is inconvenient for the user. It creates a feeling of pleasure. Therefore, the hot water supply control means 50 grasps the temperature of the hot water supplied from the hot water supply heat exchanger 8 based on the temperature detected by the heat exchanger thermistor 12, and when the hot water temperature is high, the hot water supply heat exchange is performed by the bypass valve 61. The ratio of the amount of water supplied to the water heater 8 side (= flow rate of hot water discharged from the hot water supply heat exchanger 12) and the flow rate of water supplied to the bypass pipe 9 side is adjusted, and both are mixed. The temperature of hot water supplied to the downstream side of the location X is lowered.
[0037]
However, when a failure of the bypass valve 61 occurs, the ratio of the amount of water supplied to the hot water supply heat exchanger 8 side and the flow rate of water supplied to the bypass pipe 9 side is adjusted in this way, It becomes impossible to lower the temperature of the hot water supplied to the downstream side.
[0038]
Therefore, when a failure of the bypass valve 61 is detected by the bypass valve failure detection means 53, the reheating prohibition means 57 prohibits the execution of the renewal operation, and the downstream of X of the hot water supply pipe line 2 from the hot water supply heat exchanger 8. This prevents the hot water from being supplied as it is.
[0039]
Referring to FIG. 3, the rotation operation range of stepping motor 60 is set to 0 ° to 540 ° according to the adjustment range of the opening degree of bypass valve 61, and motor control means 54 is normally set to 20 °. The angular position of the stepping motor 60 is controlled within a range of ˜405 °.
[0040]
Further, the limit sensor 62 has an open limit range (430 ° to 495 °) in which the bypass valve 61 is in a fully open position (an open position where all water supplied from the water pipe flows to the bypass pipe 9 side). However, since the stepping motor 60 rotates more than one rotation (360 °) by the time it reaches the open limit range, in addition to the open limit range, the stepping motor 60 is more than the open limit range. ° Even in the false limit range on the valve closing side.
[0041]
When the power supply to the controller 4 is started, the motor control means 54 first performs an origin finding process for the stepping motor 60. The origin search process is performed by operating the stepping motor 60 to a position where the bypass valve 61 is fully closed locked (hereinafter referred to as a fully closed lock position) to forcibly step out, and the motor control means 54 When the closed lock position is reached, the above-described position counter 56 is cleared. Thereby, the fully closed lock position is set to the origin position (0 ° position) of the stepping motor 60.
[0042]
When the target valve opening position of the bypass valve 61 is given from the hot water supply control means 50, the motor control means 54 calculates the target angular position of the stepping motor 60 according to the target valve opening position, and positions the stepping motor 60. The number of pulses required to operate from the current angular position grasped from the count value of the counter 56 to the target angular position is calculated.
[0043]
Then, the motor control means 54 outputs a pulse signal corresponding to the calculated number of pulses to the motor driver 55, and adds the output pulse number to the position counter 56 (when operating on the fully open side) or subtracts (to the fully closed side). If it works) and then add up. As a result, a motor drive signal is output from the motor driver 55 to the stepping motor 60, the stepping motor 60 rotates to the target angular position, and the valve opening position of the bypass valve 61 is controlled to the target valve opening position. Further, the angular position of the stepping motor 60 grasped from the count number of the position counter 56 becomes the target angular position.
[0044]
Thus, the stepping motor 60 according to the angular position of the stepping motor 60 (hereinafter referred to as the soft position) grasped from the count value of the position counter 56 by the motor control means 54 and the actual valve opening position of the bypass valve 61. The angular position of the stepping motor 60 is controlled so as to coincide with the angular position (hereinafter referred to as a hard position).
[0045]
Next, in general, when the follow-up operation is started or during the follow-up operation, the failure detection process of the bypass valve 61 is performed, and the execution of the follow-up operation is prohibited when the failure of the bypass valve 61 is detected. is doing. However, in this case, the following inconvenience occurs when the user takes a bath in a state where the hot water stored in the bathtub has been consumed over time after the hot water filling operation is completed.
[0046]
That is, when the user who has taken a bath feels the warmness of the hot water stored in the bathtub and operates the follow-up switch 43 of the remote controller 40 to instruct the start of the follow-up operation, the bypass valve failure detection means 53 causes the bypass valve 53 to Although the failure detection process is executed, if the failure of the bypass valve 53 is detected, the follow-up prohibition means 57 prohibits the execution of the follow-up operation. As a result, the user must take a bath with lukewarm water.
[0047]
Therefore, in the present embodiment, the bypass valve failure detection unit 53 detects the failure of the bypass valve 61 by the bypass valve failure detection unit 53 even when the hot water filling switch 42 of the remote controller 40 instructs the start of the hot water filling operation. Execute detection processing. Hereinafter, the failure detection process of the bypass valve 61 by the bypass valve failure detection means 53 and the prohibition process of the chasing operation by the chasing prohibition means 57 will be described according to the flowcharts shown in FIGS.
[0048]
Steps 1 to 5 in FIG. 4 and STEPs 20 to 22 in FIG. 4 are processes by the bypass valve failure detection means 53, and STEPs 30 to 32 in FIG. 5 are processes by the follow-up prohibition means 57.
[0049]
Referring to FIG. 4, when the user operates hot water filling switch 42 (see FIG. 2) of remote controller 40 to instruct the start of the hot water filling operation, bypass valve failure detection means 53 proceeds from STEP 1 to STEP 2. Then, when the limit sensor 62 is ON in the next STEP2, the process branches to STEP20.
[0050]
In STEP 20, when the soft position of the stepping motor 60 exceeds the open-side boundary (135 °) of the false limit range, that is, when the limit sensor 62 is ON within the open limit range, the tracking prohibiting means 57 In step 21, the stepping motor 60 is operated in the closing direction (0 ° side) of the bypass valve 61. Then, when the limit sensor 62 is turned off in subsequent STEP 22, that is, when the soft position of the stepping motor 60 is out of the open limit range, the process proceeds to STEP 3.
[0051]
STEP 3 to STEP 6 are for confirming whether or not the bypass valve 61 operates normally in the valve opening direction. The tracking prohibiting means 57 first sets the stepping motor 60 in the valve opening direction of the bypass valve 61 in STEP 3 ( 540 ° side). Then, in STEP 4, the process proceeds to STEP 5 after waiting for the soft position of the stepping motor 60 to exceed the open boundary of the false limit range.
[0052]
In the loop composed of STEP5 and STEP6, when the limit sensor 62 is turned ON in STEP5 before the soft position of the stepping motor 60 becomes the fully open position of the bypass valve 61 in STEP6, the soft position and the hard position of the stepping motor 60 are determined. It can be assumed that they match. Therefore, the chasing prohibition means 57 determines that the operation of the bypass valve 61 in the valve opening direction has been normally performed, and proceeds to STEP 7 in FIG.
[0053]
On the other hand, if the soft position of the stepping motor 60 becomes the fully open position of the bypass valve 61 in STEP 6 before the limit sensor 62 is turned on in STEP 5, it is assumed that the soft position and the hard position of the stepping motor 60 do not match. it can. Therefore, the tracking prohibiting means 57 determines that the bypass 61 is not operating properly in the valve opening direction and that the bypass valve 61 is malfunctioning, and proceeds to STEP 30 in FIG. 5, and the tracking prohibiting processing of STEP 30 to STEP 32 is performed. Execute.
[0054]
That is, the follow-up prohibiting means 57 stops the operation of the stepping motor 60 at STEP 30, prohibits the execution of the follow-up operation at STEP 31, and a failure of the bypass valve 61 occurs in the display 45 provided in the remote control 40 at STEP 32. An error is displayed to indicate this, and the buzzer 44 is sounded to notify the user that the bypass valve 61 has failed (corresponding to the notification of the occurrence of the failure of the present invention).
[0055]
Accordingly, before the hot water filling operation is completed, the user can be made aware that the bypass valve 61 has failed and the execution of the chasing operation has become impossible. And after a hot water filling operation is completed, the user can be encouraged to take a bath before the hot water stored in the bathtub is filled. Therefore, it is possible to prevent the inconvenience described above, that is, the inconvenience that the chasing operation is prohibited after the user starts bathing and the user has to endure the lukewarm water and bathe.
[0056]
Next, STEP 7 to STEP 10 in FIG. 5 are for confirming whether or not the bypass valve 61 operates normally in the valve closing direction. The tracking prohibiting means 57 first sets the stepping motor 60 to the bypass valve in STEP 7. 61 is operated in the valve closing direction (0 ° side). Then, if the limit sensor 62 is turned OFF in STEP 9 before the soft position of the stepping motor 60 is closed (0 ° side) from the closed boundary (70 °) of the false limit range in STEP 8, the tracking is performed. The prohibiting unit 57 determines that the operation of the bypass valve 61 in the valve closing direction has been normally executed, proceeds to STEP 10, stops the operation of the stepping motor 60, and ends the failure detection process of the bypass valve 61.
[0057]
On the other hand, when the soft position of the stepping motor 60 becomes less than the closed limit boundary of the false limit range before the limit sensor 62 is turned off at STEP 9, the follow-up prohibiting means 57 determines the closing direction of the bypass valve 61. It is judged that the operation to is bad and the bypass valve 61 is broken, and the routine proceeds to STEP 30. The tracking prohibiting means 57 executes the tracking prohibiting process of STEP30 to STEP32. In STEP 32, the failure of the bypass valve 61 may be notified, and the hot water filling operation may be prohibited.
[0058]
In the present embodiment, the bypass servo 10 that operates the bypass valve 61 with the stepping motor 60 is shown as the flow ratio adjusting means of the present invention. However, the bypass valve 61 may be operated with the servo motor. . Furthermore, the present invention can also be applied when a proportional solenoid valve is used as the flow rate adjusting means of the present invention.
[0059]
Further, in this embodiment, when the start of the filling operation is instructed by the operation of the filling switch 42, the failure detection process of the bypass valve 61 is executed. However, the remote controller 40 reserves the filling operation. If it has a function, the failure detection processing of the bypass valve 61 may be executed when the remote controller 40 instructs the controller 4 to start the hot water filling operation when the reservation time or reservation time is reached. (In this case, the remote controller 40 corresponds to the hot water filling instruction means of the present invention).
[0060]
Further, in this embodiment, when the start of the filling operation is instructed by the operation of the filling switch 42, the failure detection process of the bypass valve 61 is executed. However, the start of the filling operation is instructed. The failure detection process of the bypass valve 61 may be executed after the hot water filling operation is finished or when the hot water filling operation is finished. Furthermore, the failure detection process of the bypass valve 61 may be executed both from when the start of the hot water operation is instructed until when the hot water operation is completed and when the hot water operation is ended. The failure of the bypass valve 61 can be reliably detected before the user takes a bath.
[0063]
During the hot water supply operation, the opening degree of the bypass valve 61 is adjusted by the hot water supply control means 50 in order to control the hot water supply temperature. Therefore, the failure detection process for opening and closing the bypass valve 61 cannot be executed during the hot water supply operation. Therefore, when it is time to execute the failure detection process during the hot water supply operation, the failure detection process may be stopped or the failure detection process may be executed after the hot water supply operation ends.
[0064]
In the present embodiment, since the bypass valve 61 is provided at the junction on the downstream side of the bypass pipe 9, the bypass valve 61 is connected to the junction on the upstream side of the bypass pipe 9 and the hot water supply heat exchanger 8. Compared with the case where it is provided in the hot water supply pipe 2 on the downstream side, deterioration of the bypass valve 61 due to heat can be suppressed.
[0065]
In the present embodiment, the burner using gas as fuel is shown as the heating means of the present invention. However, a burner using kerosene as fuel may be used, and heat may be exchanged by a heating wire. .
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a hot water heater with a reheating device of the present invention.
FIG. 2 is a control block diagram of the hot water heater with reheating shown in FIG.
FIG. 3 is an explanatory diagram of an operating range of a bypass valve.
FIG. 4 is a flowchart of a bypass servo failure detection process.
FIG. 5 is a flowchart of failure detection processing of a bypass servo.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Hot water heater with reheating, 2 ... Hot water supply pipe line, 3 ... Reheating water pipe line, 4 ... Bathtub, 5 ... 1st burner, 6 ... 2nd burner, 7 ... Reheating heat exchanger, 8 ... Hot water supply heat exchange 9 ... Bypass pipe, 10 ... Bypass servo, 11 ... Hot water thermistor, 12 ... Heat exchange thermistor, 13 ... Water quantity sensor, 14 ... Hot water quantity servo, 15 ... Hot water solenoid valve, 16 ... Check valve, 17 ... Pump, DESCRIPTION OF SYMBOLS 18 ... Bath thermistor, 19 ... Bath water flow switch, 20 ... Hot water sensor, 40 ... Remote control, 42 ... Hot water filling switch, 43 ... Reheating switch, 44 ... Buzzer, 45 ... Display, 53 ... Bypass valve failure detection means

Claims (1)

A chasing pipe for circulating hot water stored in the bath for chasing the bath, a hot water supply pipe for heating the water supplied from the water supply and supplying hot water, and the chasing pipe A reheating heat exchanger that heats the hot water flowing through the water supply, a hot water supply heat exchanger that partially heats the water flowing through the hot water supply line, and a reheating heat exchanger that partially overlaps the reheating heat exchanger, Heating means for heating the hot water supply heat exchanger, a bypass pipe communicating with the upstream side and the downstream side of the portion heated by the hot water supply heat exchanger in the hot water supply pipe, and water flowing to the bypass pipe side A flow rate ratio adjusting means for adjusting a ratio between the flow rate and the flow rate of the water flowing to the hot water heat exchanger side, a failure detecting means for detecting the presence or absence of a failure of the flow rate ratio adjusting means, and the flow rate ratio by the failure detecting means. Revocation prohibition that prohibits re-execution when a malfunction of the adjusting means is detected In reheating with water heater and means,
The reheating water heater has a function of performing a hot water filling process for supplying hot water from the hot water supply pipe to the bathtub, and a hot water filling instruction means for instructing start of the hot water filling process, and the failure detection means. And a failure notification means for notifying when a failure of the flow rate adjusting means is detected,
The failure detection means is at least one of a period from when the start of the hot water filling process is instructed by the hot water filling instruction means until the hot water filling process is completed, and when the hot water filling process is finished. On the other hand, a hot water heater with a renewal is characterized in that the presence or absence of a failure of the flow rate ratio adjusting means is detected.

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