JP2001223111A - Water supply control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water supply control device which can be effectively reduced in power consumption even if a solenoid valve is a few in frequency of control because water supply is low in frequency. SOLUTION: A latching type solenoid valve 9 turns a valve which controls water supply to an open state from a closed state and vice versa corresponding to drive signals 13 fed to its solenoid, or keeps the valve in an open or in closed state even when the drive signals 13 are stopped, where the lowest drive voltage VL required for turning the solenoid valve 9 into a required state, either an open state or a closed state, is applied to feed the drive signals 13 continuously to the solenoid for a minimum drive time tMIN.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water supply control device, and more particularly to a water supply control device that performs water supply control using a latching type solenoid valve as water supply means.

[0002]

2. Description of the Related Art In a sanitary washing apparatus for washing a local part of a human body by discharging washing water, water supply control is performed using a solenoid valve. For example, the solenoid valve is controlled to an open state in accordance with an operation for instructing the start of a posterior or bidet wash, the cleaning water is supplied to the water discharge nozzle, and the solenoid valve is closed in accordance with an operation for instructing a cleaning end. The supply of the washing water to the water discharge nozzle is stopped by controlling.

[0003] In a water supply control device such as a sanitary washing device for controlling water supply, a latching type solenoid valve may be used for the purpose of reducing power consumption. In a general solenoid valve, it is necessary to continuously supply a drive signal when the valve is maintained in an open state. However, in a latching type solenoid valve, a drive signal is supplied only when the valve is shifted to an open state or a closed state. Power supply can be reduced simply by supplying power.

Conventionally, in such a water supply control device using such a latching type solenoid valve, for the purpose of further reducing power consumption, the rated voltage range is limited to the amount of charge necessary to drive the latching type solenoid valve. It has been proposed to supply it within (for example,
See, for example, Japanese Patent Application Laid-Open No. 10-163025). Further, when a latching type solenoid valve operates as a load, for example, power required by the solenoid valve is directly supplied from a power source such as a battery.

[0005]

However, in such a conventional water supply control device, when the frequency of water supply is high and the number of times of control of the solenoid valve is large, the power saving effect can be obtained, but the frequency of water supply is low and the solenoid valve of the solenoid valve is low. When the number of times of control is small, power consumption by a circuit for supplying a required amount of charge and a circuit for detecting the completion of the operation of the solenoid valve becomes relatively large. When a battery is used as a power source, a voltage higher than the minimum required voltage is applied to the solenoid valve when the load is operated while the battery is relatively fresh and not consumed, and a current larger than necessary is supplied to the solenoid valve. Will flow to Therefore, such a conventional water supply control device has a problem that power consumption cannot be reduced effectively. An object of the present invention is to solve such a problem, and an object of the present invention is to provide a water supply control device capable of effectively reducing power consumption even when the frequency of water supply is low and the number of times the solenoid valve is controlled is small.

[0006]

In order to achieve the above object, a water supply control device according to the present invention is a system in which the drive time of each load is controlled to be constant, and a battery as a power supply is provided. A water supply control device comprising: a water supply means driven by a battery; and a control means for instructing power supply to the water supply means, wherein the control means includes a control circuit and a first power supply for supplying power to the control circuit. And a second constant voltage means for supplying electric power to the water supply means. Further, the first constant voltage means and the second
Are connected in parallel to the batteries. The first constant voltage means and the second constant voltage means have different stabilizing voltages. Each of the stabilizing voltages is a minimum guaranteed voltage of the control circuit and the water supply means.

The second constant voltage means includes a normal mode for applying a predetermined voltage to the water supply means, and a standby operation mode for reducing power consumption in the own circuit without applying a predetermined voltage to the water supply means. And the control circuit includes a transition unit that transitions the second constant voltage unit to the normal mode or the standby operation mode as needed. Also,
Detecting means for detecting use of the device may be provided, and the shift means may be controlled by an output of the detecting means.
Further, a detecting means for detecting non-use of the apparatus may be provided, and the shift means may be controlled by an output of the detecting means. Further, the detecting means may be constituted by a human body detecting means for detecting a user who uses the apparatus, and the water supply means may be constituted by a latching solenoid valve.

Further, the water supply control device according to the present invention is a method in which the drive time of each load is controlled to be constant and time-controlled, and a valve for performing water supply control in accordance with a drive signal supplied to a solenoid is opened or closed. A latching type solenoid valve that keeps the valve open or closed even when the drive signal is stopped, and a control circuit, and the control circuit causes the solenoid valve to open or close. A minimum drive voltage required to shift to a desired state is applied, and a drive current is continuously supplied to the solenoid for a minimum drive time.

The power supply circuit includes a first power supply circuit that supplies a predetermined operating voltage to a control circuit using a battery as a power supply, and a second power supply circuit that supplies a minimum drive voltage used for a drive signal using the battery as a power supply. They may be provided separately. Also, the second
A power supply circuit having a normal operation mode for supplying the lowest drive voltage and a standby operation mode for stopping supply of the lowest drive voltage to reduce power consumption in the own circuit,
If necessary, the second power supply circuit may be shifted to a normal operation mode or a standby operation mode. further,
Detecting means for detecting proximity of a human body whose water supply operation is predicted may be provided, and the second power supply circuit may be shifted to the normal operation mode or the standby operation mode according to the detection result of the detecting means.

[0010]

Next, the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of a water supply control device according to an embodiment of the present invention. Here, a sanitary washing device that controls supply of wash water to a human body part using a battery as an operation power supply will be described as an example. In FIG. 1, a control circuit 1 includes a CPU (arithmetic processing unit) and controls each part of the sanitary washing device. The cleaning start switch 2 and the cleaning end switch 3 are switches for the user to input instructions for starting and ending the cleaning of the posterior cleaning and bidet cleaning.

The seating detection circuit (detection circuit) 4 detects whether the user is seated / not seated on the toilet seat due to the proximity of the human body.
The detection result is input to the control circuit 1. The control power supply circuit (first power supply circuit) 6 supplies the control power supply V _CC to the control circuit 1 and its peripheral circuits using the battery 5 as a power supply.
In a power supply circuit for solenoid (second power supply circuit) 7, a minimum drive voltage (minimum guaranteed voltage) _VL required to drive a solenoid valve 9 for water supply control such as a water discharge valve and a drain valve using the battery 5 as a power supply is set. Supplying. The solenoid power circuit 7 has a standby mode to reduce power consumption in the self circuit by stopping the supply of the normal operation mode and the lowest drive voltage V _L supplies a minimum driving voltage V _L, the control Circuit 1
It operates in one of the operation modes instructed by the power supply control signal 11 from.

The solenoid valve 9 shifts a valve for performing water supply control to an open state or a closed state in accordance with a drive signal 13 supplied to the solenoid.
Is a latching type solenoid valve that keeps the valve open or closed even when the valve is stopped. From the control circuit 1, an open drive control signal 12A or a close drive control signal 12B having a minimum drive time t _MIN required to drive the solenoid valve 9 is output. In the solenoid drive circuit 8, a predetermined drive signal 13 is supplied to the solenoid valve 9 based on the drive control signals 12A and 12B and the minimum drive voltage _VL . The drive signal 13 has the lowest drive voltage _VL of the solenoid valve 9 and the solenoid valve 9
_Is continuously output for the minimum drive time t _{MIN of}

Next, the operation of the present invention will be described with reference to FIG. FIG. 2 is a timing chart showing the operation of the present invention. In the period before time T ₁ , the user is not seated, and the control circuit 1 detects non-seating from the output from the seating detection circuit 4. As a result, the control circuit 1 sets the power supply control signal 11 to L level (ground potential GND) and controls the solenoid power supply circuit 7 to the standby operation mode. Therefore, the minimum drive voltage _VL is not supplied from the solenoid power supply circuit 7, and the power consumption of the solenoid power supply circuit 7 itself is reduced. The control circuit 1 sets the respective drive control signals 12A and 12B to L level, and the drive signal 13 is not output from the solenoid drive circuit 8.

At time T ₁ , when the user's seat is detected by the seat detection circuit 4 and the water supply operation is predicted,
The control circuit 1 sets the power control signal 11 to H level (V _CC ). Thereby, the solenoid power supply circuit 7 is controlled to the normal operation mode, and the minimum drive voltage _VL is supplied to the solenoid drive circuit 8. When the cleaning start switch 2 is operated at the subsequent time T ₂ , the control circuit 1 continues the open drive control for a fixed minimum drive time t _MIN = t _A required to open the solenoid valve 9. Set signal 12A to H
Level. Here, the minimum drive time is always constant according to the load.

In response to this, in the solenoid drive circuit 8,
The drive signal 13 having the minimum drive voltage V _L required to open the solenoid valve 9 is continuously output for the minimum drive time t _A required to open the solenoid valve 9. As a result, the latching type solenoid valve 9 drives the drive signal 1 with a small amount of electric power necessary to open the valve.
At 3, the state surely shifts to the open state.

When the cleaning end switch 3 is depressed at time T ₃ , the control circuit 1
, The closing drive control signal 12B is kept at the H level continuously for the minimum drive time t _MIN = t _B required to bring the switch to the closed state. In response to this, the solenoid drive circuit 8 generates the reverse drive signal 13 having the minimum drive voltage _VL required to close the solenoid valve 9 to the minimum drive time t required to close the solenoid valve 9. Output only _B continuously. Thereby, the latching type solenoid valve 9 is driven by the drive signal 13 of a small amount of electric power necessary for closing the valve,
Shift to the closed state without fail.

At a subsequent time T ₄ , if the user is not seated by the seat detection circuit 4 and the water supply operation is not predicted, the control circuit 1 sets the power supply control signal 11 to L level. In response, the solenoid power supply circuit 7 shifts to the standby operation mode, stops outputting the minimum drive voltage _VL , and reduces power consumption in its own circuit.

As described above, the driving signal (driving current) is applied by applying the minimum driving voltage _VL necessary to shift the solenoid valve 9 to a desired state of either the open state or the closed state.
13 is continuously supplied to the solenoid for the minimum drive time t _MIN , so that there is no need to provide a complicated circuit as in the prior art, and it is possible to reduce wasteful power consumed by these and reduce the frequency of water supply. Even when the number of times the solenoid valve is controlled is small, the power required to drive the solenoid valve 9 can be reduced. Further, since the solenoid power supply circuit 7 is provided separately from the control power supply circuit 6 for supplying the control power supply V _CC , the minimum drive voltage _VL unique to the solenoid valve to be used can be easily supplied, and at the same time, the internal Even when the battery 5 having a high resistance is used, it can be supplied accurately without being affected by the fluctuation of the control power supply V _CC .

Further, the voltage applied to the solenoid valve 9 is the minimum drive voltage _VL by the solenoid power supply circuit 7 irrespective of the voltage of the battery as a power supply. Therefore, as shown in FIG. T ₀ ) Even if a battery having a high open voltage (V _H ) is used, only the minimum drive voltage _VL is applied to the solenoid valve 9. Therefore, assuming that the resistance value of the solenoid valve 9 is R, the current (I ₁ ) consumed when the solenoid valve is driven is I ₁ = V _L / R. On the other hand, when the conventional solenoid drive circuit 7 as shown in FIG. 4 is not provided, the current (I ₂ ) consumed by the solenoid valve is I ₂ = V _H / R. As a result, V _L <V
_{From H} , I ₁ <I ₂ and the power consumption of the solenoid valve 9 can be reduced.

In FIG. 2, the case where the power control signal 11 is controlled based on the detection output of the seat detection circuit 4 has been described. As shown in FIG. 5, however, the detection output of the seat detection circuit 4 and the cleaning start switch 2 are controlled. Alternatively, the power supply control signal 11 may be controlled by a logical sum with the output of the cleaning end switch 3. Seating is detected at time T ₁ of the FIG. 5, when the depression of the cleaning start switch 2 in a subsequent time T _2, is detected, the control circuit 1, immediately the power control signal 11 to the H level.
As a result, the solenoid power supply circuit 7 is controlled to the normal operation mode, and the minimum drive voltage _VL is reduced to the solenoid drive circuit 8.
Supplied to

[0021] Then, at time T ₂₁ the minimum driving voltage V _L from the time T _2, has passed only a small fraction of the time to rise to a specified value (e.g. 1 ms), the control circuit 1 is the minimum drive time t _MIN =
Only continue t _A to the open drive control signals 12A to the H level. In response, the solenoid drive circuit 8 sets a minimum drive voltage V _L required to open the solenoid valve 9.
Is continuously output for the minimum drive time t _A necessary to open the same state. Thereafter, the control circuit 1 sets the power supply control signal 11 to the L level together with the opening drive control signal 12A, and controls the solenoid power supply circuit 7 to the standby operation mode. As a result, the latching type solenoid valve 9 reliably shifts to the open state with the drive signal 13 of a small amount of electric power required to open the valve.

Also, when the user presses down the washing end switch 3 at time T ₃ in a state where the seating is detected,
The control circuit 1 immediately sets the power control signal 11 to the H level. Thereby, the solenoid power supply circuit 7 is controlled to the normal operation mode, and the minimum drive voltage _VL is supplied to the solenoid drive circuit 8. Then, little time to rise from the time T _2, the minimum driving voltage V _L is up to the specified value (e.g., 1m
At time T ₃₁ that has elapsed s), the control circuit 1 in the closed drive control signal 12B to the H level continues for minimum drive time t _MIN = t _B.

In response, the solenoid drive circuit 8
The drive signal 13 having the minimum drive voltage V _L required to close the solenoid valve 9 is continuously output for the minimum drive time t _B required to close the solenoid valve 9. After that, the control circuit 1 sets the power supply control signal 11 to the L level together with the open drive control signal 12B, and controls the solenoid power supply circuit 7 to the standby operation mode. As a result, the latching type solenoid valve 9 reliably shifts to the closed state with the drive signal 13 of a small amount of electric power required to close the valve.

In the above, the case where the minimum drive voltage _VL is output from the solenoid power supply circuit 7 has been described. However, when a voltage drop occurs in the solenoid drive circuit 8, a voltage in consideration of the voltage drop is applied to the solenoid. What is necessary is just to output from the power supply circuit 7. The same applies to the minimum drive time. If a time length shift occurs in the solenoid drive circuit 8, the drive control signals 12A, 1 taking into account the shift are considered.
2B may be output. Further, if a boost voltage circuit is used as the solenoid drive power supply circuit, the battery can be operated even when the battery voltage is equal to or lower than the minimum drive voltage of the solenoid, so that the life of the battery can be further extended.

[0025]

As described above, the present invention relates to a water supply control device including a battery as a power supply, water supply means driven by the battery, and control means for instructing power supply to the water supply means. The control means comprises a control circuit, a first constant voltage means for supplying power to the control circuit, and a second constant voltage means for supplying power to the water supply means. As described above, there is no need to provide a complicated circuit, and it is possible to reduce wasted power constantly consumed by these,
Even when the frequency of water supply is low and the number of times the solenoid valve is controlled is small, and even when the battery is relatively new, the power required to drive the solenoid valve can be effectively reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram of a water supply control device according to an embodiment of the present invention.

FIG. 2 is a timing chart showing the operation of the present invention.

FIG. 3 is a characteristic diagram showing an example of a change in battery voltage.

FIG. 4 is a block diagram showing a conventional water supply control device.

FIG. 5 is a timing chart showing another operation of the present invention.

[Explanation of symbols]

 1. Control circuit, 2. Cleaning start switch, 3. Cleaning end switch
Switch, 4: Seating detection circuit, 5: Battery, 6: Control power supply
Road, 7 ... Power supply circuit for solenoid, 8 ... Solenoid drive circuit
Road, 9 ... solenoid valve, 11 ... power control signal, 12
A: Open drive control signal, 12B: Close drive control signal, 13:
Drive signal, V_L... Minimum drive voltage, t_A, T _B… At minimum drive
while.

Continued on the front page (72) Inventor Mamoru Watanabe 100, Maeda-cho, Totsuka-ku, Yokohama-shi, Kanagawa Prefecture Inside (72) Inventor Takuya Hatayama 100, Maeda-cho, Totsuka-ku, Yokohama-shi, Kanagawa Koito Industry Co., Ltd. F term (reference) 2D038 JB05 JF03 JH12 KA01

Claims (14)

[Claims] 1. A water supply control device comprising: a battery as a power supply; water supply means driven by the battery; and control means for instructing power supply to the water supply means, wherein the control means comprises a control circuit. And a first constant voltage means for supplying electric power to the control circuit, and a second constant voltage means for supplying electric power to the water supply means. 2. The water supply control device according to claim 1, wherein said first constant voltage means and said second constant voltage means are respectively connected in parallel to said battery. . 3. The water supply control device according to claim 1, wherein said first constant voltage means and said second constant voltage means are:
Water supply control device characterized by different stabilization voltages. 4. The water supply control device according to claim 3, wherein each of the stabilizing voltages is a minimum guaranteed voltage of the control circuit and the water supply means. 5. The water supply control device according to claim 3, wherein the second constant voltage means applies a predetermined voltage to the water supply means and a normal mode in which a predetermined voltage is applied to the water supply means. A standby operation mode for reducing power consumption in its own circuit, and the control circuit includes a transition unit that transitions the second constant voltage unit to the normal mode or the standby operation mode as necessary. Water supply control device characterized by the above-mentioned. 6. The water supply control device according to claim 5, further comprising detection means for detecting use of the apparatus, and controlling the transition means based on an output of the detection means. 7. The water supply control device according to claim 5, further comprising detection means for detecting non-use of the apparatus, and controlling the transition means based on an output of the detection means. 8. The water supply control device according to claim 6, wherein said detection means comprises a human body detection means for detecting a user who uses the device. 9. The water supply control device according to claim 6, wherein the detection unit outputs an output of a human body detection unit that detects a user who uses the device and an operation input unit that inputs an instruction to start or end the cleaning. A water supply control device, which outputs a logical sum of the output and the output of the water supply. 10. The water supply control device according to claim 1, wherein said water supply means comprises a latching solenoid valve. 11. A latching mechanism that shifts a valve for performing water supply control to an open state or a closed state according to a drive signal supplied to a solenoid, and maintains the valve in an open state or a closed state even when the drive signal is stopped. A solenoid valve of the type, and applying a minimum drive voltage required to shift the solenoid valve to a desired state, either an open state or a closed state, and supplying a drive current to the solenoid continuously for a minimum drive time A water supply control device, comprising: a control circuit. 12. The water supply control device according to claim 11, wherein a first power supply circuit that supplies a predetermined operating voltage to the control circuit using a battery as a power supply, and the lowest drive using the battery as a power supply for the drive signal. And a second power supply circuit for supplying a voltage. 13. The water supply control device according to claim 12, wherein the second power supply circuit has a normal operation mode in which the minimum drive voltage is supplied, and a power supply in the own circuit by stopping supply of the minimum drive voltage. A water supply control device having a standby operation mode for reducing consumption, wherein the control circuit shifts the second power supply circuit to the normal operation mode or the standby operation mode as needed. 14. The water supply control device according to claim 13, further comprising detection means for detecting the proximity of a human body whose water supply operation is predicted, wherein the control circuit controls the second water supply in accordance with a detection result of the detection means. A water supply control device for shifting a power supply circuit to the normal operation mode or the standby operation mode.