JP2013231547A - Bath device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To automatically restore a trouble of a water level sensor in a bath device capable of performing automatic bath operation.SOLUTION: A bath device has a sensor diagnostic program for "diagnosing whether a water level sensor is in a normally detectable state of water level" and a sensor initialization program for "initializing the water level sensor". When it is determined by the sensor diagnostic program that "the water level sensor is not in the normally detectable state of water level", the sensor initialization program is activated to initialize the water level sensor.

Description

  The present invention relates to a bath apparatus provided with a water level sensor. INDUSTRIAL APPLICABILITY The present invention is suitable as a bath device having a function of dropping hot water into a bathtub or retreating a bath.

Bath apparatuses having a function of dropping hot water into a bathtub or reheating hot water are widely used. In addition, a bath apparatus having a function called “automatic bath operation” and maintaining a constant level by monitoring the water level of the bathtub and the temperature of the hot water is also widely used.
These bath apparatuses have a recirculation circuit in which a bathtub and a heat exchanger are connected in a ring shape, and a bathtub circulation pump is provided in the recirculation circuit. It also has a burner that heats the heat exchanger.
And when the temperature of the hot water in a bathtub falls, a bathtub circulation pump is started, the hot water in a bathtub is circulated to the heat exchanger side, a burner is ignited, and hot water is heated.

In addition, in many cases, a bath apparatus having a function of performing “automatic bath operation” includes a water level sensor and monitors the water level of the bathtub. And when hot water in the bathtub decreases, hot water is automatically dropped.
Therefore, if the water level sensor breaks down, the water level in the bathtub cannot be detected accurately, the drop amount becomes excessive and hot water overflows from the bathtub, or the drop amount becomes excessive and the amount of hot water becomes insufficient. There was a problem.
Therefore, Patent Document 1 discloses an invention in which a failure of a water level sensor is detected and the bathtub circulation pump is driven on condition that the water level sensor is not broken. In addition, a configuration is disclosed in which a warning is given to a user when a water level sensor has failed.

JP-A-8-121870

According to the invention disclosed in Patent Document 1, since the bathtub circulation pump is driven only when the water level sensor is not broken, the idling of the pump is prevented.
However, in the invention described in Patent Document 1, a countermeasure when the water level sensor fails is not sufficiently studied. That is, in the invention disclosed in Patent Document 1, when it is found that the water level sensor is out of order, an alarm is issued as described above. A user who knows that the water level sensor is broken by an alarm will contact a dealer or the like to have it repaired, but during that time, the bath apparatus cannot be used.
That is, in the invention described in Patent Document 1, when a water level sensor failure is detected, the bath circulation pump cannot be driven, so that the bath cannot be retreated.
In many cases, when the hot water is dropped into the bathtub, the above-described bathtub circulation pump is driven. Therefore, when a malfunction of the water level sensor is detected, the hot water cannot be dropped into the bathtub. End up.

  Therefore, the present invention focuses on the above-mentioned problems of the prior art and proposes a bath apparatus capable of automatically repairing the malfunction of the water level sensor.

  Invention of Claim 1 for solving an above-described subject WHEREIN: In the bath apparatus provided with the water level sensor which detects the water level of a bathtub, it is the state in which the said water level sensor can detect a water level normally. It has a sensor diagnosis function for diagnosis and an initialization function for initializing the water level sensor, and if the water level cannot be detected normally as a result of the diagnosis by the sensor diagnosis function, the initialization function automatically In the bath apparatus, the water level sensor is initialized.

The bath apparatus of the present invention has a sensor diagnostic function for diagnosing whether or not the water level sensor is in a state where the water level can be normally detected. Here, the “sensor diagnosis function” is a function “diagnosis whether or not the water level sensor can normally detect the water level”, and it does not matter whether or not the water level sensor is out of order. Of course, if the water level sensor is faulty, it is not “a state where the water level sensor can detect the water level normally”, but even if the water level sensor is not faulty, Due to reasons, the water level may not be detected temporarily. The “sensor diagnostic function” of the present invention diagnoses a case where the water level cannot be detected temporarily although it is not a malfunction.
In the bath device of the present invention, when the water level sensor cannot normally detect the water level, the water level sensor is automatically initialized.
The “initialization” here is a process such as a general power reset, and does not mean that the internal software and data are completely erased. “Initialization” is not limited to initializing all areas and functions.
In many cases, this process (initialization process) returns the water level sensor to a normal state. Therefore, the water level sensor can accurately detect the water level of the bathtub, and the user can use the bath apparatus as usual.

  According to a second aspect of the present invention, the water level sensor requires electric power for activation, and the initialization function temporarily stops power supply to the water level sensor and supplies power again. The bath apparatus according to claim 1, wherein the bath apparatus is characterized in that

A water level sensor incorporating an electronic device such as an IC may cause malfunction due to noise or the like. This defect is often repaired by initialization. Here, in order to initialize a water level sensor incorporating an electronic device such as an IC, the supply of power is once stopped and then the power is turned on again.
That is, a water level sensor incorporating an electronic device such as an IC usually requires electric power to operate the electronic device. The built-in electronic device is initialized by temporarily stopping the power supply described above and then performing the power supply again.

  The invention according to claim 3 is provided on the condition that the water level sensor has a standby terminal and / or a standby signal input unit, and a predetermined voltage or signal is input to the standby terminal and / or the standby signal input unit. 3. The bath according to claim 1, wherein the initialization function temporarily stops input to the standby terminal and / or the standby signal input unit and performs input again. 4. Device.

  Some water level sensors have a standby terminal and a standby signal input section. The water level sensor having such a structure is initialized by temporarily stopping input to the standby terminal or the like and performing input again.

  In the invention according to claim 4, the water level sensor is capable of inputting a reference voltage or a reference signal, and the water level sensor is initialized when the reference voltage or the reference signal is changed to a predetermined condition. The bath apparatus according to any one of claims 1 to 3, wherein the bath apparatus is executed.

The water level sensor employed in the bath apparatus of the present invention can input a reference voltage or a reference signal. Here, the reference voltage and the reference signal are a voltage or signal that is input to correct the output, or a voltage or signal that determines a measurement range or the like.
The former voltage or the like is a voltage or the like that may be input to a water level sensor that detects the water level by pressure. That is, a water level sensor that detects the water level of a bathtub based on the pressure in the reheating pipe is known. This type of water level sensor needs to correct the pressure difference based on the drop when there is a drop in the installation position of the bathtub and the installation position of the bath apparatus. The reference voltage is a voltage input to correct this drop difference.
Some water level sensors can change the measurement width and measurement accuracy, and the latter reference voltage is included in this category.

  A fifth aspect of the present invention is the bath apparatus according to any one of the first to fourth aspects, wherein the diagnosis for the water level sensor is executed before performing the water level detection process by the water level sensor.

  In the bath apparatus of the present invention, since the diagnosis for the water level sensor is executed before the water level detection process by the water level sensor is performed, no error occurs in the detected water level.

  A sixth aspect of the present invention is the bath apparatus according to any one of the first to fifth aspects, wherein diagnosis of the water level sensor and / or initialization of the water level sensor is periodically executed.

  In the bath apparatus of the present invention, since the diagnosis or the like for the water level sensor is periodically executed, the water level sensor is always kept in a state where the water level can be accurately detected.

  According to the seventh aspect of the present invention, the water level of the bathtub is periodically detected by the water level sensor, and the diagnosis and / or initialization of the water level sensor for the water level sensor is executed during a time period when the water level of the bathtub is not detected. The bath apparatus according to any one of claims 1 to 6, wherein

  In the bath apparatus according to the present invention, diagnosis or the like is executed in a time zone in which the water level of the bathtub is not detected, so that there is no inconvenience to the normal operation of the bath apparatus.

  In addition, it is desirable that the water level sensor is activated after a power-on to the bath apparatus itself (claim 8).

  If it is a bath device that performs an initial operation for initializing and / or confirming the operation of some or all of each component device after turning on the power, it is triggered by the completion of the initial operation of some or all of the component devices. It is desirable to activate the water level sensor.

  The invention according to claim 9 devised from this point of view is that the bath apparatus performs an initial operation for initializing and / or confirming operation of some or all of the constituent devices after the power is turned on. The bath apparatus according to any one of claims 1 to 8, wherein the water level sensor is activated when the initial operation of part or all of the equipment is completed.

  The bath device of the present invention has an effect of automatically repairing a malfunction of the water level sensor. Therefore, the user can use the bath device continuously.

It is a piping system diagram of the bath apparatus of the embodiment of the present invention. It is a block diagram which shows the relationship between the control apparatus of the bath apparatus of FIG. 1, and an electric equipment. It is a block diagram which shows the relationship between the water level sensor of the bath apparatus of FIG. 1, and its periphery. It is a time chart which shows the relationship between the drive voltage which concerns on the water level sensor of the bath apparatus of FIG. 1, the terminal voltage of a standby terminal, and the starting condition of a water level sensor. It is a modification of the time chart which shows the relationship between the drive voltage which concerns on the water level sensor of the bath apparatus of FIG. 1, the terminal voltage of a standby terminal, and the starting condition of a water level sensor. It is a flowchart which shows operation | movement of the bath apparatus of FIG. It is a block diagram which shows the relationship between the water level sensor in other embodiment of this invention, and its periphery. It is a time chart which shows the relationship between the drive voltage which concerns on the water level sensor in embodiment shown in FIG. 7, the terminal voltage of a standby terminal, and the starting condition of a water level sensor. It is a flowchart which shows operation | movement of the bath apparatus in other embodiment of this invention. It is a flowchart which shows operation | movement of the bath apparatus in other embodiment of this invention. It is a flowchart which shows operation | movement of the bath apparatus in other embodiment of this invention.

Embodiments of the present invention will be further described below.
The bath apparatus 1 of this embodiment incorporates the combustion apparatus 2 of the 1 can 2 water channel type like FIG.
As shown in FIG. 1, the combustion apparatus 2 includes two heat exchangers 10 and 11 in one combustion space (can body 8). One of the two systems of heat exchangers 10 and 11 is a hot water supply heat exchanger 11, and the other is a reheating heat exchanger 10.

The combustion device 2 includes a plurality of burners 12. The plurality of burners 12 are divided into five systems. A solenoid valve 14 is provided for each system.
A gas proportional valve 15 is provided on the upstream side of the electromagnetic valve 14, and the amount of fuel gas supplied to each burner 12 can be controlled.
A blower 16 is attached to the upstream part (lower part) of the can body 8.

  The bath apparatus 1 includes a hot water supply circuit 20 and a reheating circuit (circulation piping) 21. A drop channel 23 is provided between the two.

The hot water supply circuit 20 is the same as that known in the art, and communicates with a water supply unit 25 that receives the supply of water from the outside, passes through a hot water supply heat exchanger 11, and a hot water supply heat exchanger 11. The hot water flowing through the hot water channel 26 is mixed with the hot water flowing through the bypass channel 27 by the hot water mixing valve 13, adjusted to a desired temperature, and discharged from the hot water supply port 28. Is. The hot water supply circuit 20 is provided with temperature sensors 65 and 66.
A hot water supply / hot water flow rate adjustment valve 17 is provided at a part of the hot water supply circuit 20 and downstream of the hot water mixing valve 13.

The reheating circuit (circulation piping) 21 forms a recirculation flow path 18 including the bathtub 5, a bath return flow path 30 for returning hot water from the bathtub 5 side to the reheating heat exchanger 10, and reheating A bath outlet channel 31 is provided for supplying hot water from the heat exchanger 10 side to the bathtub 5 side.
The bath return channel 30 is provided with a water level sensor 33, a bathtub circulation pump 32, a temperature sensor 62, and the like.
The water level sensor 33 detects the water level of the bathtub 5, and is specifically a pressure sensor.

The water level sensor 33 employed in the present embodiment has a member (not shown) that is deformed by pressure such as a diaphragm, and includes a detection unit 40 (FIG. 3) that detects the amount of deformation of the diaphragm or the like. The detection unit 40 is, for example, a strain gauge, and changes electrical characteristics such as electrical resistance according to deformation.
The detection unit 40 applies a predetermined voltage and outputs a change in resistance as a change in voltage. Further, the water level sensor 33 employed in the present embodiment has a temperature compensation function and a height compensation function. That is, the water level sensor 33 employed in the present embodiment includes a signal control unit 41 in addition to the detection unit 40 described above, and the detection value of the detection unit 40 is corrected by the signal control unit 41. The corrected voltage appears at the output terminal 38 through the output unit 37.

Here, the signal control unit 41 is an electronic circuit including an IC, in which predetermined software is written. For this reason, troubles may occur due to noise or the like. Some of the operations of the signal control unit 41 are irregularly performed due to software reasons.
These problems are often recovered by initializing the water level sensor 33. The term “initialization” here does not mean that the internal software or data is completely erased, but means that the operation of the control unit is reset like a normal power reset.

As described above, the water level sensor 33 according to the present embodiment includes the signal control unit 41 in addition to the detection unit 40 described above. Then, the signal control unit 41 performs temperature compensation and height compensation on the voltage signal output from the detection unit 40, and corrects the voltage signal output from the detection unit 40.
More specifically, the output signal is corrected by the signal control unit 41 so that an accurate water level can be detected regardless of changes in temperature and hot water temperature.

  Further, the water level sensor 33 employed in the present embodiment can correct a pressure difference caused by a difference between the ground height at the position where the bathtub 5 is installed and the ground height at the position where the bath apparatus 1 is installed (high Compensation). Height compensation is performed by changing the reference voltage.

  That is, the water level sensor 33 includes a reference voltage application terminal 45 and a reference voltage input unit 46, and a reference voltage is input from the outside. The input reference voltage is input from the reference voltage input unit 46 to the signal control unit 41.

  In the water level sensor 33 employed in the present embodiment, the signal voltage output from the output terminal 38 changes by changing the reference voltage (Vref). That is, the reference voltage (Vref) is a kind of bias voltage. When the reference voltage (Vref) is increased, the signal voltage (Vo) is shifted upward, and when the reference voltage (Vref) is decreased, the signal voltage (Vo) is increased. Shift downward.

Furthermore, the water level sensor 33 requires power input to the detection unit 40 and power consumed by the signal control unit 41, and has a power input terminal 50 and a power input unit 51.
The power input to the detection unit 40 and the power consumed by the signal control unit 41 enter the power input unit 51 through the power input terminal 50 and are further input from the power input unit 51 to the detection unit 40 and the signal control unit 41.

Further, the water level sensor 33 employed in the present embodiment is activated on condition that a predetermined standby voltage is applied to the signal control unit 41, and includes a standby terminal 52 and a standby voltage input unit (standby signal input unit). 53.
The standby voltage is applied to the signal control unit 41 via the standby terminal 52 and the standby voltage input unit 53.

The water level sensor 33 employed in the present embodiment is driven by applying a predetermined voltage to the power input terminal 50 and the standby terminal 52.
Conversely, when the voltage of either the power input terminal 50 or the standby terminal 52 disappears, the operation stops.
When a predetermined voltage is applied again to both the power input terminal 50 and the reference voltage application terminal 45 in the stop state, the water level sensor 33 is restarted. The water level sensor 33 is initialized when restarting.

Next, the entire electric circuit of the bath apparatus 1 of the present embodiment will be described.
The bath apparatus 1 according to the present embodiment includes a power supply circuit unit 60 and a control device 61 as shown in FIG. The power supply circuit unit 60 is a DC power supply for driving the control device 61 and the water level sensor 33.

That is, the power supply circuit unit 60 supplies DC power to the control device 61 and the water level sensor 33.
Here, paying attention to the connection between the power supply circuit unit 60 and the water level sensor 33, the power supply circuit unit 60 and the power supply input terminal 50 of the water level sensor 33 are connected by a power line 68 as shown in FIG. A switch transistor 67 is provided in the middle.
In the present embodiment, the standby voltage of the water level sensor 33 is also supplied from the power supply circuit unit 60 as shown in FIG.
That is, in this embodiment, the reset IC 70 is provided as a unique member. The reset IC 70 is supplied with power from the power supply circuit unit 60 to the power supply unit 71. However, since the switching transistor 67 is interposed between the power supply unit 71 of the reset IC 70 and the power supply circuit unit 60, the power supply unit 71 of the reset IC 70 and the power input terminal of the water level sensor 33 are provided. 50 in parallel.
The output terminal (output terminal of the operational amplifier) 72 of the reset IC 70 is connected to the standby terminal 52 of the water level sensor 33.

The control device 61 controls each device described above, and a drive signal is transmitted to each device. It also receives signals from each device and performs predetermined processing.
FIG. 2 shows only representative devices connected to the control device 61, but more devices are actually controlled by the control device 61.

If it demonstrates according to FIG. 2, the water level sensor 33, the temperature sensors 62, 65, 66, the hot-water supply hot water flow rate adjustment valve 17, the hot-water mixing valve 13, and the air blower 16 are connected to the control apparatus 61 in this embodiment.
In the present embodiment, as described above, the circuit for supplying power to the water level sensor 33 includes the switching transistor 67, and the signal of the control device 61 is input to the base of the transistor 67.
That is, in the present embodiment, the power supply circuit unit 60 and the power input terminal 50 of the water level sensor 33 are connected by the power line 68, and a switching transistor 67 is provided in the middle. Therefore, the power supplied to the water level sensor 33 can be interrupted by a signal from the control device 61. Further, by turning off the switching transistor 67, the power supplied to the reset IC 70 is also cut off.

The control device 61 stores a program for causing the device to operate smoothly, in addition to a program for smoothly operating the above-described device.
That is, in the present embodiment, the control device 61 stores a sensor diagnosis program that “diagnoses whether or not the water level sensor can normally detect the water level”. Further, the control device 61 stores a sensor initialization program for “initializing the water level sensor”.

The sensor diagnosis program changes the reference voltage (Vref) applied to the water level sensor 33 and compares the output voltage (Vo) of the water level sensor 33 before and after the change.
That is, the bath apparatus 1 of this embodiment has a sensor diagnosis function, and can diagnose whether or not the water level sensor 33 can normally detect the water level.
Specifically, the current output voltage (Vo1) of the water level sensor 33 is stored, and thereafter the reference voltage (Vref) is changed. More specifically, the reference voltage (Vref) is increased to the upper limit. Then, the output voltage (Vom) of the water level sensor 33 in a state where the reference voltage (Vref) is raised is detected and compared with the output voltage (Vo1) before the change of the reference voltage (Vref) stored previously.
As described above, the reference voltage (Vref) is a kind of bias voltage. If the water level sensor 33 is normal, the signal voltage should shift upward when the reference voltage (Vref) is increased. .

  Therefore, the output voltages (Vo1) and (Vom) before and after the increase of the reference voltage (Vref) are compared, and if the latter output voltage (Vom) is higher, “the water level sensor can detect the water level normally. It is determined that it is in a state. Conversely, if the output voltages (Vo1) and (Vom) do not change before and after the increase of the reference voltage (Vref), or if the latter output voltage (Vom) is lower, “the water level sensor is normal. It is determined that the water level cannot be detected.

As described above, the controller 61 also stores a sensor initialization program for “initializing the water level sensor”.
Specifically, the sensor initialization program is a program for temporarily turning off the switching transistor 67 and immediately turning on the switching transistor 67 again.

When the switch transistor 67 is turned off by the sensor initialization program, the power supply circuit unit 60 and the power input terminal 50 of the water level sensor 33 are disconnected. As a result, the electric power for driving the water level sensor 33 disappears.
When the switching transistor 67 is turned off, the power supplied to the power supply unit 71 of the reset IC (op-amp) 70 is lost. As a result, there is no output from the reset IC 70 and the terminal voltage of the standby terminal 52 is lost. Disappears.
As a result, the water level sensor 33 is turned off.

  When the switching transistor 67 is turned on again immediately, both the power for driving the water level sensor 33 and the standby voltage are restored, and the water level sensor 33 is restarted. With the restart, the water level sensor 33 is initialized.

The change in voltage of each part when the water level sensor 33 is initialized is as shown in FIG. That is, when the switching transistor 67 is turned off while the water level sensor 33 is being driven, the voltage (Vcc) of the power input terminal 50 of the water level sensor 33 is rapidly reduced.
Further, since the power supply unit 71 of the reset IC 70 is in parallel with the power input terminal 50 of the water level sensor 33, the voltage supplied to the power supply unit 71 of the reset IC 70 also decreases, and the standby voltage also decreases.
When the voltage supplied to the power supply unit 71 of the reset IC 70 falls below the minimum operating voltage of the reset IC, the standby voltage disappears and the water level sensor 33 enters an off state.
In the sensor initialization program, the switching transistor 67 is immediately turned on, so the voltage (Vcc) of the power input terminal 50 of the water level sensor 33 and the voltage applied to the power supply unit 71 of the reset IC 70 are abrupt. To recover.
When the voltage applied to the power supply unit 71 of the reset IC 70 exceeds the minimum operating voltage of the reset IC, the standby voltage is restored and the water level sensor 33 is restarted. And the water level sensor 33 is initialized with a restart.

  In the present embodiment, the sensor diagnostic program described above and the sensor initialization program are related, and when the sensor diagnostic program determines that the water level sensor cannot normally detect the water level, The sensor initialization program is activated and the water level sensor 33 is initialized. Conversely, when it is determined that “the water level sensor is in a state where the water level can be normally detected”, the initialization of the water level sensor 33 is not executed.

Hereinafter, a series of these operations will be described with reference to the flowchart of FIG.
In the flowchart of FIG. 6, Step 2 to Step 5 are sensor diagnostic steps “diagnosis whether or not the water level sensor can normally detect the water level”.
In this embodiment, it is confirmed in step 1 whether or not bath automatic operation has been started. That is, the water level detection by the water level sensor 33 is executed when the bath automatic operation is being executed. Therefore, in the present embodiment, the series of operations described above are performed immediately after the bath automatic operation is started.
That is, in the bath automatic operation, the water level of the bathtub 5 is periodically detected in order to monitor the water level of the bathtub 5, and therefore, by performing the sensor diagnosis process immediately after the bath automatic operation is started, the water level sensor 33 is actually used. A sensor diagnosis process is performed before performing a water level detection process.

When it is confirmed in step 1 that the automatic bath operation has started, the process proceeds to step 2 and the current output voltage (Vo1) of the water level sensor 33 is stored.
Then, it transfers to step 3 and raises the reference voltage (Vref) of the water level sensor 33 to an upper limit.

In step 4, the output voltage (Vom) of the water level sensor 33 in a state where the reference voltage (Vref) is raised is stored.
Further, the process proceeds to step 5 where the previously stored output voltage (Vo1) is compared with the output voltage (Vom) of the water level sensor 33 in a state where the reference voltage (Vref) is raised.
If the latter output voltage (Vom) is not higher, it is determined that “the water level sensor cannot normally detect the water level”, and the process proceeds to step 8 where the water level sensor 33 is abnormal. Diagnose.
Thereafter, the process proceeds to step 9 where the counter is incremented by 1, and the process proceeds to step 10 to determine whether or not the integrated value of the counter has become a constant value. This constant value is the upper limit of the number of times the reset of the water level sensor 33 is repeated. For example, a number such as 5 times or 10 times is a common sense.

When the integrated value of the counter does not reach this value, the process proceeds to step 11 and the initialization process of the water level sensor 33 is performed. More specifically, the switching transistor 67 is temporarily turned off and immediately returned to the on state.
As a result, the standby voltage temporarily disappears, the water level sensor 33 is turned off, and then the water level sensor 33 is immediately restarted to perform initialization.

Thereafter, the process proceeds to step 12, and it is determined whether or not the bath automatic operation is continuing. If bath automatic operation is continuing, it will return to step 2 and will repeat the diagnostic process of the water level sensor 33 again.
If the water level sensor 33 begins to function normally as a result of the initialization of the water level sensor 33, step 5 is Yes, the process proceeds to step 6, the counter is reset, and the process proceeds to step 7. And perform normal operation.

  On the other hand, if the water level sensor 33 is not functioning normally even though the water level sensor 33 is initialized, the process proceeds to step 8 and the subsequent steps again, and the counter is incremented by 1 in step 9, and the process proceeds to step 10 to change the counter. It is determined whether or not the integrated value has become a constant value. Then, the process proceeds to step 11 where the water level sensor 33 is initialized again. Then, it returns to step 2 through step 12, and repeats the diagnostic process of the water level sensor 33 again.

  In this way, the initialization of the water level sensor 33 is repeated, and when the number of repetitions reaches a certain value, the possibility of recovery is no longer high, so the process proceeds to step 13 to report an abnormality and stop the entire bath apparatus 1 To do.

In the embodiment described above, power is supplied from the power supply circuit unit 60 to the power supply unit 71 of the reset IC 70, and the voltage supplied to the power supply unit 71 of the reset IC 70 falls below the minimum operating voltage of the reset IC 70. Adopted a configuration to eliminate the standby voltage.
However, the present invention is not limited to this configuration, and a configuration in which a comparison circuit is provided, the power supply circuit unit 60 is input to IN (plus) of the comparison circuit, and a constant signal voltage is input to IN (minus). Conceivable.
According to this configuration, as shown in FIG. 5, when the voltage supplied from the power supply circuit unit 60 falls below the upper limit threshold, the terminal voltage at the standby terminal 52 disappears, and the water level sensor 33 is turned off.

  Immediately after that, when the switching transistor 67 is turned on again and the voltage supplied from the power supply circuit unit 60 exceeds the upper limit threshold, both the standby voltages are restored and the water level sensor 33 is restarted. With the restart, the water level sensor 33 is initialized.

Further, the water level sensor 33 may be initialized in response to a change in the reference voltage (Vref).
FIG. 7 shows an example of a circuit in the case where the water level sensor 33 is initialized in response to a change in the reference voltage.

In the circuit shown in FIG. 7, the reference voltage Vref is applied to IN (plus) of the comparator 80, and the voltage divided from the power supply circuit unit 60 is inputted to IN (minus) of the comparator 80.
The output terminal 81 of the comparator 80 is connected to the standby terminal 52 of the water level sensor 33 as in the previous embodiment.

In the present embodiment, the sensor initialization program for “initializing the water level sensor” is slightly different from the previous case.
That is, in the sensor initialization program in the present embodiment, the reference voltage Vref is temporarily greatly reduced.
As a result, the voltage applied to the IN (plus) side of the comparator 80 decreases, and the output of the comparator 80 disappears. Therefore, the terminal voltage of the standby terminal 52 disappears, and the water level sensor 33 is turned off.

  When the reference voltage Vref is immediately recovered, the voltage applied to the IN (plus) side of the comparator 80 increases, the output of the comparator 80 is restored, and the water level sensor 33 is restarted. With the restart, the water level sensor 33 is initialized.

The voltage change of each part when the water level sensor 33 is initialized is as shown in FIG. That is, when the reference voltage Vref decreases, the voltage applied to the IN (plus) side of the comparator 80 decreases. When the reference voltage Vref falls below the threshold of the comparator 80, the terminal voltage at the standby terminal 52 disappears, and the water level sensor 33 is turned off. Enter the state.
In the sensor initialization program, the reference voltage Vref immediately recovers, so that the standby voltage is restored and the water level sensor 33 is restarted. And the water level sensor 33 is initialized with a restart.

  In this embodiment, the terminal voltage of the standby terminal 52 disappears and the water level sensor 33 is turned off when the reference voltage Vref is significantly reduced. Conversely, the reference voltage Vref is significantly increased, As a trigger, the water level sensor 33 may be turned off. In short, in the normal use state, the reference voltage Vref that is not output is output, and the water level sensor 33 is turned off as a trigger.

In the embodiment described above, when the bath automatic operation is started, the sensor diagnosis process and the subsequent sensor initialization are executed. However, the timing for performing the sensor diagnosis process and the like is not limited to this, and may be performed immediately before measuring the water level or before a certain time.
Moreover, you may perform regularly.
However, if the sensor diagnostic process or the like is performed at the time when the water level is measured, it will be confusing.
For example, in the case of automatic bath operation, when water level detection is performed at intervals of a certain time B, it is conceivable to perform a sensor diagnosis process or the like after a shorter A time has elapsed.

For example, as shown in the flowchart of FIG. 9, when the automatic bath operation is started, the process proceeds to step 22 to start the timer, and when time A elapses, the process proceeds to step 24 to diagnose the water level sensor 33, I do. That is, the steps after step 2 are executed.
Further, when the time elapses and the time B elapses, the water level is detected.

It is desirable that the first water level sensor 33 is activated after the voltage supplied to the water level sensor 33 is stabilized when the bath apparatus 1 is turned on.
For example, it is conceivable that a timer is started immediately after the bath apparatus 1 is turned on, and the water level sensor 33 is activated after a certain period of time has been confirmed by the timer. Even if it is not based on a timer or the like, it is sufficient if the water level sensor is activated substantially after the power is turned on.

  For example, immediately after turning on the power to the bath apparatus 1, the initial operation such as checking the origin of the hot water supply / hot water flow rate adjustment valve 17 and the like by energizing the hot water supply / hot water flow rate adjustment valve 17 and the like is performed. In some cases, the water level sensor 33 may be activated after the initial operation is completed.

  The flowchart shown in FIG. 10 shows an example in which the water level sensor 33 is activated after the initial operation is performed.

  When starting up the CPU of the control device, various confirmation operations are executed on the program. It is also conceivable to activate the water level sensor 33 after this series of steps.

  The flowchart shown in FIG. 11 shows an example in which the water level sensor 33 is activated after the CPU of the control device is initialized.

  In the embodiment described above, as a program for diagnosing the water level sensor, the reference voltage (Vref) applied to the water level sensor 33 is changed to the maximum value, and the output voltage (Vo) of the water level sensor 33 before and after the change is compared. Conversely, the change may be observed by lowering the reference voltage (Vref) than usual. Further, the water level sensor 33 may be diagnosed by other measures. For example, when the water level sensor 33 indicates a water level in a range that cannot be normal, the water level sensor 33 may be determined to be abnormal and the water level sensor 33 may be initialized.

In the embodiment described above, the reset IC 70 is provided as a component provided outside the water level sensor. However, a member corresponding to the reset IC 70 may be provided in the internal circuit of the water level sensor 33 itself. When this configuration is adopted, the standby terminal 52 as an external terminal is omitted, and the standby terminal virtually exists on the circuit board.
In short, the part that processes the standby signal is the standby signal input part, and the part that supplies the signal to the standby signal input part corresponds to the standby terminal.

  In the present embodiment, an example in which the combustion apparatus 2 of the single can two-water channel type is incorporated is described as an example, but a combustion apparatus having another structure may be adopted as a matter of course. For example, a two-can two-water channel combustion device may be used. Moreover, what uses kerosene as a fuel, and the thing provided with the hot water supply function of the type called a hot water storage type may be used.

  In the above-described embodiment, a circuit in which the emitter-collector of the switching transistor 67 is inserted into the power line 68 is employed, but this circuit is merely an example. For example, an output signal (Hi / Low) of the control device 61 is input to an input terminal of an operational amplifier (not shown) through a transistor, and this operational amplifier provides power to the power line 68 according to the output signal of the control device 61. Or the power supply may be stopped. A circuit using a relay instead of the transistor 67 may be used.

  In the above embodiment, the water level sensor 33 is restarted and initialized, but only the signal control unit 41 may be initialized.

DESCRIPTION OF SYMBOLS 1 Bath apparatus 2 Combustion apparatus 5 Bathtub 13 Hot-water mixing valve 15 Gas proportional valve 17 Hot-water supply hot water flow rate adjustment valve 20 Hot-water supply circuit 21 Reheating circuit (circulation piping)
33 Water Level Sensor 40 Detection Unit 41 Signal Control Unit 45 Reference Voltage Application Terminal 46 Reference Voltage Input Unit 50 Power Input Terminal 51 Power Input Unit 52 Standby Terminal 53 Standby Voltage Input Unit (Standby Signal Input Unit)
60 power supply circuit part 61 controller 62, 65, 66 temperature sensor 67 transistor 70 for switch reset IC
80 comparator

Claims (9)

  In a bath apparatus equipped with a water level sensor for detecting the water level of a bathtub, a sensor diagnostic function for diagnosing whether or not the water level sensor can normally detect the water level, and an initialization function for initializing the water level sensor And a water level sensor is automatically initialized by the initialization function when the water level cannot be normally detected as a result of the diagnosis by the sensor diagnostic function.   The water level sensor requires electric power for activation, and the initialization function temporarily stops power supply to the water level sensor and supplies power again. Bath equipment.   The water level sensor has a standby terminal and / or a standby signal input unit, and operates on condition that a predetermined voltage or signal is input to the standby terminal and / or standby signal input unit. The bath apparatus according to claim 1, wherein the function is to temporarily stop input to the standby terminal and / or the standby signal input unit and perform input again.   The water level sensor is capable of inputting a reference voltage or a reference signal, and the water level sensor is initialized when the reference voltage or the reference signal is changed to a predetermined condition. Item 4. A bath apparatus according to any one of Items 1 to 3.   5. The bath apparatus according to claim 1, wherein the diagnosis for the water level sensor is executed before performing the water level detection process by the water level sensor.   6. The bath apparatus according to claim 1, wherein diagnosis for the water level sensor and / or initialization of the water level sensor is periodically performed.   The water level of the bathtub is periodically detected by the water level sensor, and diagnosis of the water level sensor and / or initialization of the water level sensor are performed during a time period when the water level of the bathtub is not detected. The bath apparatus according to any one of 6.   The bath apparatus according to any one of claims 1 to 7, wherein the water level sensor is activated after a power-on of the bath apparatus itself.   The bath apparatus performs an initial operation for initializing and / or confirming the operation of some or all of the component devices after the power is turned on, and triggers the completion of the initial operation of some or all of the component devices. The bath apparatus according to any one of claims 1 to 8, wherein a water level sensor is activated.

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