JP7524111B2 - Drain valve control system - Google Patents

Description

The present invention relates to a drain plug control system. More specifically, the present invention relates to a drain plug control system that controls the opening and closing of a drain plug.

Patent Document 1 discloses a drain plug control system that can open and close the drain plug of a washbasin by operating a switch. Specifically, the drain plug control system is configured to open and close the drain plug by driving an actuator using a solenoid each time a user operates a switch.

Publication No. 7-52208

From a hygienic standpoint, it is preferable that the switch be constructed in such a way that direct contact with the operating part can be avoided. Therefore, the present invention provides a drain plug control system that can open and close the drain plug hygienically and with good operability.

In order to solve the above problems, the drain plug control system of the present invention takes the following measures. That is, the drain plug control system is a drain plug control system that controls the opening and closing of the drain plug, and has a solenoid actuator, a control device, and a remote controller. The solenoid actuator is connected to the drain plug and switches the drain plug between open and closed. The control device operates and controls the solenoid actuator. The remote controller has a proximity sensor that detects the approach of a detection target in a non-contact manner at a position away from the drain plug, and transmits a control signal based on the detection result of the proximity sensor to the control device via wireless communication. The control device switches the drain plug between open and closed in response to the received control signal.

According to the above configuration, the remote controller equipped with a proximity sensor located away from the drain plug allows the user to switch between opening and closing the drain plug without directly touching the remote controller or the drain plug. This makes it possible to open and close the drain plug in a hygienic and easy-to-operate manner.

The drain plug control system of the present invention may be further configured as follows: The remote controller is a stationary device that is battery-powered to drive the proximity sensor and the wireless communication, and whose installation position can be freely changed.

The above configuration allows the remote controller to be freely positioned so that it is easy for the user to use. In particular, because the remote controller is of a wireless communication type, the remote controller can be more easily and freely repositioned.

The drain plug control system of the present invention may further be configured as follows: The drain plug control system further includes another remote controller equipped with a tactile switch that detects a push operation by a user at a position away from the drain plug. The other remote controller transmits a control signal based on the detection result of the tactile switch to the control device via wireless communication. The control device switches between opening and closing the drain plug not only in response to the control signal transmitted from the remote controller but also in response to a control signal transmitted from the other remote controller.

According to the above configuration, the user can select between a non-contact opening/closing switching operation using a remote controller and a contact opening/closing switching operation using another remote controller. Therefore, for example, by setting another remote controller as a foot switch, it becomes possible to selectively use the operation such as switching the drain valve open/close without contact when the hands are dry, and switching the drain valve open/close with the foot switch when the hands are wet.

1 is a perspective view showing a schematic configuration of a drain plug control system according to a first embodiment. FIG. 2 is a schematic diagram showing a structure for opening and closing a drain plug using a solenoid actuator. 1 is a block diagram showing the overall configuration of a drain plug control system. 10 is a flowchart showing a control flow of an exhaust control device. FIG. 11 is a perspective view showing a schematic configuration of a drain plug control system according to a second embodiment. 1 is a block diagram showing the overall configuration of a drain plug control system. 4 is a flowchart showing a control flow of the control device.

Below, the form for implementing the present invention is explained with reference to the drawings.

First Embodiment
(General configuration of drain plug control system 10)
First, the configuration of a drain plug control system 10 according to a first embodiment of the present invention will be described with reference to Figures 1 to 4. In the following description, directions such as front, back, top, bottom, left, and right refer to the directions shown in each figure. The directions shown in each figure are based on the position of a user standing in front of a washbasin 2 to which the drain plug control system 10 according to this embodiment is applied. In the following description, when no specific reference figure is shown or when no reference figure has a corresponding symbol, any of Figures 1 to 4 will be referred to as appropriate.

As shown in FIG. 1, the drain plug control system 10 according to this embodiment is configured as a system that controls the opening and closing of the drain plug 3 of a washbasin 2 provided in a bathroom vanity S. Specifically, the drain plug control system 10 is configured to enable switching between opening and closing of the drain plug 3 by remote control via a non-contact remote controller (hereinafter, non-contact remote control) 13.

A so-called pedestal-type automatic faucet 1 is installed on the countertop at the rear of the washbasin 2 of the washstand S. When a user places their hand over the water outlet 1A at the tip of the automatic faucet 1, a photoelectric sensor (not shown) installed near the water outlet 1A detects the hand and causes water to be discharged from the water outlet 1A. The automatic faucet 1 is also configured to stop water from being discharged from the water outlet 1A when the user moves their hand away from the water outlet 1A.

As shown in FIG. 2, the drain plug 3 is incorporated into a round hole-shaped drain outlet 2A formed in the bottom surface of the washbasin 2. A circular drain pipe 4 equipped with an S-trap 4A is connected to the bottom of the drain outlet 2A, and the water that flows in is discharged from the drain pipe 4 to the outside by gravity.

The drain plug control system 10 is equipped with a non-contact remote control 13 that can be attached to any location away from the drain plug 3. The drain plug control system 10 is configured to switch the drain plug 3 between open and closed in sequence each time a user performs a non-contact operation by placing their hand over the non-contact remote control 13. In this embodiment, the non-contact remote control 13 is installed on the top plate at the back of the washbasin 2, next to the right of the automatic faucet 1.

By installing the non-contact remote control 13 on the top plate at the back of the washbasin 2, the non-contact remote control 13 can be installed without narrowing the work space on the top plate on both sides of the washbasin 2. The non-contact remote control 13 may be installed on the top plate on either side of the washbasin 2 according to the user's physique.

The non-contact remote control 13 can be freely and removably attached to an appropriate location, such as around the periphery or front side of the washbasin 2, or on the floor F where the user stands, using an adhesive tape (not shown) attached to the backside of the remote control 13. The drain plug control system 10 eliminates the need for the user to directly touch the drain plug 3 or the device that opens and closes the drain plug 3 in order to switch the drain plug 3 on and off, allowing the drain plug 3 to be opened and closed hygienically and easily.

(About the composition of each part)
The specific configuration of each part of the drain plug control system 10 will be described in detail below. As shown in Fig. 2, the drain plug 3 is inserted from above into the drain outlet 2A and set in the drain pipe 4. The drain plug 3 has a plug body 3A that extends in a round bar shape in the vertical direction, which is the axial direction of the drain pipe 4, and a head 3B that spreads out like a disk and is formed at the upper end of the plug body 3A.

The plug body 3A is in the shape of a round bar with a diameter smaller than the diameter of the drain outlet 2A. The head 3B is in the shape of a disk with a diameter matching the diameter of the drain outlet 2A. The drain outlet 2A has an inner circumferential surface that slopes like an inverted truncated cone so that its opening tapers downward. Correspondingly, the head 3B also has an inner circumferential surface that slopes like an inverted truncated cone so that its peripheral side surface tapers downward.

The plug body 3A is configured with ribs 3C formed on four circumferential positions on its outer circumferential surface, which protrude in stripes in the axial direction of the pipe. When the plug body 3A is inserted into the drain pipe 4, each rib 3C is set in a guided state so that it can slide in the axial direction (up and down) along the inner circumferential surface of the drain pipe 4.

The drain plug 3 has a plug body 3A inserted into the drain pipe 4, which is supported in a lifted position from below by an operating rod 3D that extends laterally into the drain pipe 4, so that the head 3B is held floating above the drain outlet 2A, i.e., the drain outlet 2A is kept open.

The operating rod 3D is inserted through a connecting pipe 4B that is connected laterally to the middle of the drain pipe 4. The operating rod 3D is made of a straight rod-shaped member, and a sphere 3E connected to its middle part is fitted and set inside the connecting pipe 4B so that it can rotate.

As a result, the control rod 3D is set in a state in which it can seesaw up and down around the sphere 3E relative to the connecting tube 4B. The control rod 3D is normally held in a state in which it extends horizontally, which is the axial direction of the connecting tube 4B, due to the biasing force of the spring 3F hung between the control rod 3D and the connecting tube 4B.

As a result, the operating rod 3D normally lifts the plug body 3A from below with its end (the left end in the figure) that protrudes into the drain pipe 4, and keeps the head 3B of the drain plug 3 floating above the drain outlet 2A in an open state. The operating rod 3D is configured such that a solenoid actuator 11 is connected to its end (the right end in the figure) that extends away from the connecting pipe 4B in the pipe axial direction.

The solenoid actuator 11 has its main body 11A fixed integrally to the drain pipe 4. The solenoid actuator 11 has a movable iron core 11B that is drawn into the main body 11A when electricity is applied, and is connected to the end of the operating rod 3D (the right end shown in the figure).

With the above configuration, in the initial state before the solenoid actuator 11 is energized, the movable iron core 11B does not retract the operating rod 3D, and keeps the operating rod 3D in a free state. However, when the solenoid actuator 11 is energized by the control device 12 of the drain plug control system 10 (described later), the movable iron core 11B is retracted into the main body 11A.

As a result, the end of the control rod 3D connected to the solenoid actuator 11 (the right end in the figure) is pulled upward in the figure, and the end of the control rod 3D that protrudes into the drain pipe 4 (the left end in the figure) is pushed downward. As a result, the drain plug 3 falls due to gravity, and the head 3B switches to a state in which the drain outlet 2A is closed.

When the solenoid actuator 11 is de-energized, the operating rod 3D returns to its horizontally extended state due to the biasing force of the spring 3F. This causes the operating rod 3D to lift the drain plug 3 and switch to an open state.

As shown in Figures 1 and 3, the drain plug control system 10 includes a solenoid actuator 11, a control device 12, and a non-contact remote control 13. The solenoid actuator 11 is electrically connected to the control device 12, and is configured to operate by controlling the flow of current by the control device 12 to draw a movable iron core (not shown) into a magnetic field and release the draw.

As described above in FIG. 2, the solenoid actuator 11 has a movable iron core 11B extending from its main body 11A, which is connected to the control rod 3D. As a result, the solenoid actuator 11 operates to pull up the right end of the control rod 3D as shown in the figure when the control device 12 applies electricity to an internal coil (not shown) and the movable iron core 11B is drawn into the main body 11A (into the magnetic field).

In addition, when the power supply is released, the solenoid actuator 11 releases the retracted state of the control rod 3D. As a result, the solenoid actuator 11 enters a state in which the control rod 3D is allowed to move back to the horizontally extended state by the biasing force of the spring 3F described above.

3, the control device 12 has a CPU 12A which is an arithmetic processing unit, a RAM 12B which is a readable and writable memory unit that temporarily stores data, a ROM 12C which is a read-only memory unit that stores a control program executed by the CPU 12A, and a timer 12D. The control device 12 also has a receiver 12E which receives control signals from a transmitter 13F of a non-contact remote control 13 which will be described later, and a power adapter 12F which is connected to an AC power source AC provided in a storage space below the washstand S and supplies power to each functional unit of the control device 12.

The control device 12 loads the control program stored in the ROM 12C by the CPU 12A onto the RAM 12B, and executes various processes based on the control program in cooperation with the RAM 12B. As a result, the control device 12 controls the energization of the solenoid actuator 11 electrically connected to its output side. Specifically, the control device 12 repeatedly executes the process shown in the flowchart of FIG. 4 at predetermined time intervals (e.g., 0.015 seconds). The specific processing procedure will be described in detail later.

3, the non-contact remote control 13 has a CPU 13A which is an arithmetic processing unit, a RAM 13B which is a readable and writable memory unit that temporarily stores data, a ROM 13C which is a read-only memory unit that stores a control program executed by the CPU 13A, and a timer 13D. The non-contact remote control 13 also has a photoelectric sensor 13E which is a non-contact sensor, a transmitter 13F which transmits a control signal based on the detection result of the photoelectric sensor 13E to the control device 12 via wireless communication, and a battery 13G which is composed of a dry cell, a button cell, or the like, which supplies power to each functional unit of the non-contact remote control 13.

The photoelectric sensor 13E includes a light-projecting unit that projects infrared light, and a light-receiving unit that receives the projected light that hits a detection target, such as a user's hand, and is reflected. When a detection target, such as a user's hand, is brought closer to the non-contact remote control 13, the amount of reflected light received by the light-receiving unit of the photoelectric sensor 13E increases. Note that the photoelectric sensor 13E may be configured to project and receive visible light instead of infrared light. Here, the photoelectric sensor 13E corresponds to the "proximity sensor" of the present invention.

The non-contact remote control 13 loads the control program stored in the ROM 13C by the CPU 13A onto the RAM 13B, and executes various processes based on the control program in cooperation with the RAM 13B. Specifically, when a detection target such as a user's hand is brought close to the photoelectric sensor 13E and a received light amount equal to or greater than a predetermined value is detected, the non-contact remote control 13 transmits a control signal from the transmitter 13F to the receiver 12E of the control device 12.

The transmitter 13F performs wireless communication to the receiver 12E of the control device 12 using low-power, weak radio that is compatible with a communication standard of a transmission frequency of 315 MHz, a transmission strength of 500 μV/m, and a communication speed of 500 bps. The transmitter 13F may be configured to perform wireless communication to the receiver 12E using a communication standard such as specific low-power radio, Bluetooth (registered trademark), ZigBee (registered trademark), or wireless LAN (e.g., Wi-Fi (registered trademark)), or infrared.

(Regarding power supply control processing)
Next, the current supply control process for the solenoid actuator 11 executed by the control device 12 will be described with reference to the flowchart of Fig. 4. In the initial state after power is turned on, the control device 12 is in a state where no current is supplied to the solenoid actuator 11. Therefore, in this initial state, the drain plug 3 shown in Fig. 2 is in an open state.

When the process is started, the control device 12 first determines in step S101 whether or not a control signal has been received from the non-contact remote control 13. If the control device 12 has not received a control signal (step S101: NO), the control device 12 ends the process. Note that if the control device 12 has not received a control signal in step S101 (step S101: NO), the control device 12 may return the process to step S101.

On the other hand, if the control device 12 receives a control signal from the non-contact remote control 13 (step S101: YES), the process proceeds to step S102, where the control device 12 determines whether the solenoid actuator 11 is energized. If the solenoid actuator 11 is not energized (step S102: NO), the control device 12 proceeds to step S104, where the control device 12 energizes the solenoid actuator 11.

This switches the drain plug 3 to the closed state. The control device 12 maintains the power supply state for the solenoid actuator 11 even after processing of step S104.

On the other hand, if the solenoid actuator 11 is energized in step S102 (step S102: YES), the control device 12 proceeds to step S103 and removes power from the solenoid actuator 11. This switches the drain plug 3 to an open state. Therefore, by repeating the above series of processes, the drain plug 3 can be switched between closed and open in sequence each time the user holds their hand over the photoelectric sensor 13E of the non-contact remote control 13.

(summary)
In summary, the drain plug control system 10 according to the first embodiment has the following configuration. Note that the reference characters in parentheses below are reference characters corresponding to the respective components shown in the above embodiment.

That is, the drain plug control system (10) controls the opening and closing of the drain plug (3), and includes a solenoid actuator (11), a control device (12), and a remote controller (13). The solenoid actuator (11) is connected to the drain plug (3) and switches the drain plug (3) between open and closed states.

The control device (12) controls the operation of the solenoid actuator (11). The remote controller (13) is equipped with a proximity sensor (13E) that detects the approach of a detection object in a non-contact manner at a position away from the drain plug (3), and transmits a control signal based on the detection result of the proximity sensor (13E) to the control device (12) via wireless communication. The control device (12) switches the drain plug (3) between open and closed in response to the received control signal.

According to the above configuration, the remote controller (13) equipped with a proximity sensor (13E) located away from the drain plug (3) allows the user to switch between opening and closing the drain plug (3) without directly touching the remote controller (13) or the drain plug (3). Therefore, the drain plug (3) can be opened and closed in a hygienic and easy-to-operate manner.

The remote controller (13) is a stationary device that is battery-powered to drive the proximity sensor (13E) and the wireless communication, and can be freely positioned. With the above configuration, the remote controller (13) can be freely positioned so that it is easy for the user to use. In particular, because the remote controller (13) is of the wireless communication type, the remote controller (13) can be more easily and freely positioned.

Second Embodiment
Next, the configuration of a drain plug control system 10 according to a second embodiment of the present invention will be described with reference to Figures 5 to 7. As shown in Figures 5 to 6, the drain plug control system 10 according to this embodiment is further configured to include a contact-type remote controller (hereinafter, contact-type remote controller) 14 that can remotely switch between opening and closing the drain plug 3, in addition to the non-contact-type remote controller 13 shown in the first embodiment. Here, the contact-type remote controller 14 corresponds to the "another remote controller" of the present invention.

As shown in FIG. 5, in this embodiment, the contact remote control 14 is configured as a foot switch that is installed on the floor F at a position where the user stands in front of the washbasin 2 and is operated by the user by stepping on it with his/her foot. As shown in FIG. 6, the contact remote control 14 has a CPU 14A which is an arithmetic processing unit, a RAM 14B which is a readable/writable memory unit that temporarily stores data, a ROM 14C which is a read-only memory unit that stores a control program executed by the CPU 14A, and a timer 14D.

The contact remote control 14 also has a tactile switch 14E, which is a contact sensor, a transmitter 14F that transmits a control signal based on the detection result of the operation of the tactile switch 14E to the control device 12 via wireless communication, and a battery 14G consisting of a dry cell, a button cell, or the like, that supplies power to each functional part of the contact remote control 14. The tactile switch 14E has a known contact switch structure that energizes an internal electrical circuit when the user pushes it with their foot.

The contact remote control 14 loads the control program stored in the ROM 14C by the CPU 14A onto the RAM 14B, and executes various processes based on the control program in cooperation with the RAM 14B. Specifically, when the tactile switch 14E is operated by the user, the contact remote control 14 transmits a control signal from the transmitter 14F to the receiver 12E of the control device 12.

The transmitter 14F performs wireless communication with the receiver 12E of the control device 12 using low-power, weak radio that is compatible with communication standards of a transmission frequency of 315 MHz, a transmission strength of 500 μV/m, and a communication speed of 500 bps. The transmitter 14F may be configured to perform wireless communication with the receiver 12E using wireless communication compatible with communication standards such as specific low-power radio, Bluetooth (registered trademark), ZigBee (registered trademark), or wireless LAN (e.g., Wi-Fi (registered trademark)), or infrared.

(Regarding power supply control processing)
Next, the energization control process for the solenoid actuator 11 executed by the control device 12 will be described with reference to the flowchart in Fig. 7. The control device 12 repeatedly executes the process shown in the flowchart in Fig. 7 at a predetermined time interval (e.g., 0.015 seconds). As with the configuration shown in the first embodiment, in the initial state after power is turned on, the control device 12 is in a state in which no current is being applied to the solenoid actuator 11. Therefore, in this initial state, the drain plug 3 (see Fig. 5) is in an open state.

When the process is started, the control device 12 first determines in step S201 whether or not it has received a control signal from either the non-contact remote control 13 or the contact remote control 14. If the control device 12 has not received a control signal (step S201: NO), it ends the process. Note that the control device 12 may be configured to return the process to step S201 if it has not received a control signal in step S201 (step S201: NO).

On the other hand, if the control device 12 receives a control signal from either the non-contact remote control 13 or the contact remote control 14 (step S201: YES), the control device 12 proceeds to step S202 and determines whether the solenoid actuator 11 is energized. If the solenoid actuator 11 is not energized (step S202: NO), the control device 12 proceeds to step S204 and energizes the solenoid actuator 11.

This switches the drain plug 3 to the closed state. The control device 12 maintains the power supply state for the solenoid actuator 11 even after processing of step S204.

On the other hand, if the solenoid actuator 11 is energized in step S202 (step S202: YES), the control device 12 proceeds to step S203 and removes power from the solenoid actuator 11. This switches the drain plug 3 to an open state. Therefore, by repeating the above series of processes, the drain plug 3 can be switched between closed and open in sequence each time the user either holds their hand over the photoelectric sensor 13E of the non-contact remote control 13 or operates the contact remote control 14.

In this way, according to the drain plug control system 10 of this embodiment, the user can perform the same operations as those performed with the non-contact remote control 13 by stepping on the contact remote control 14 with his/her foot. Therefore, the user can select between a non-contact switching operation for opening/closing the valve using the non-contact remote control 13 and a contact switching operation for opening/closing the valve using the contact remote control 14.

Therefore, for example, when the user's hands are dry, the non-contact remote control 13 can be used to switch between opening and closing the drain plug 3 in a non-contact manner, and when the user's hands are wet or blocked, the drain plug 3 can be opened and closed by stepping on the contact remote control 14, which is a foot switch. Note that, like the non-contact remote control 13, the contact remote control 14 may be installed on the side or top plate at the back of the washbasin 2 and operated by the user by pushing it with his or her hand. Like the non-contact remote control 13, the contact remote control 14 can be freely and detachably attached to any suitable position by means of an adhesive tape (not shown) attached to the back surface of the contact remote control 14.

(summary)
In summary, the drain plug control system 10 according to the second embodiment has the following configuration. Note that the reference characters in parentheses below are reference characters corresponding to the respective components shown in the above embodiment.

That is, the drain plug control system (10) further includes another remote controller (14) equipped with a tactile switch (14E) that detects a push operation by a user at a position away from the drain plug (3). The other remote controller (14) transmits a control signal based on the detection result of the tactile switch (14E) to the control device (12) via wireless communication. The control device (12) switches the drain plug (3) between open and closed not only in response to the control signal transmitted from the remote controller (14) but also in response to the control signal transmitted from the other remote controller (14).

According to the above configuration, the user can select between a non-contact opening/closing switching operation using the remote controller (14) and a contact opening/closing switching operation using another remote controller (14). Therefore, for example, by setting the other remote controller (14) as a foot switch, it becomes possible to selectively use the operation such as switching the drain plug (3) without contact when the hands are dry and switching the drain plug (3) with the foot switch when the hands are wet.

Other embodiments
Although the present invention has been described above using two embodiments, the present invention can be embodied in various forms as described below in addition to the above embodiments.

1. The drain plug control system of the present invention can be used to control the opening and closing of a washbasin drain plug, as well as the opening and closing of a bathtub drain plug.

2. The proximity sensor may be any sensor capable of detecting the approach of an object without contact, and may be a photoelectric sensor, a capacitance sensor, or an ultrasonic sensor.

REFERENCE SIGNS LIST 1 Automatic faucet 1A Spout 2 Washbasin 2A Drain 3 Drain plug 3A Plug body 3B Head 3C Rib 3D Control rod 3E Sphere 3F Spring 4 Drain pipe 4A S-trap 4B Connecting pipe 10 Drain plug control system 11 Solenoid actuator 11A Body 11B Movable iron core 12 Control device 12A CPU
12B RAM
12C ROM
12D Timer 12E Receiver 12F Power adapter 13 Remote controller 13A CPU
13B RAM
13C ROM
13D Timer 13E Photoelectric sensor (proximity sensor)
13F Transmitter 13G Battery 14 Remote controller (another remote controller)
14A CPU
14B RAM
14C ROM
14D Timer 14E Tactile switch 14F Transmitter 14G Battery S Vanity unit AC AC power supply F Floor

Claims (2)

A drain plug control system that controls the opening and closing of a drain plug,
A solenoid actuator connected to the drain valve for switching between opening and closing the drain valve;
A control device that controls the operation of the solenoid actuator;
a remote controller that includes a proximity sensor that detects the approach of a detection object in a non-contact manner at a position away from the drain plug, and transmits a control signal based on the detection result of the proximity sensor to the control device via wireless communication;
The control device switches between opening and closing the drain valve in response to the received control signal ,
The drain plug control system is a stationary device in which the remote controller is battery-powered to drive the proximity sensor and the wireless communication, and whose installation position can be freely changed. A drain plug control system that controls the opening and closing of a drain plug,
A solenoid actuator connected to the drain valve for switching between opening and closing the drain valve;
A control device that controls the operation of the solenoid actuator;
a remote controller that includes a proximity sensor that detects the approach of a detection target in a non-contact manner at a position away from the drain plug, and transmits a control signal based on the detection result of the proximity sensor to the control device via wireless communication;
and another remote controller including a tactile switch that detects a push operation by a user at a position away from the drain plug, the other remote controller transmitting a control signal based on a detection result of the tactile switch to the control device via wireless communication,
A drain plug control system in which the control device switches between opening and closing the drain plug in response to the control signal transmitted from the remote controller, and also switches between opening and closing the drain plug in response to the control signal transmitted from the other remote controller .

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