JP2020042465A - Touch operation detecting device and water supply device using the same - Google Patents

Abstract

To provide a touch operation detecting device capable of preventing erroneous detection of a touch operation on a faucet device in consideration of the influence of installation environment of the faucet device, and a water supply device using the same.SOLUTION: A touch operation detecting device according to the present invention comprises: a threshold setting unit that stores an electrostatic detecting area for detecting change in capacitance, and the capacitance in an installed state including the electrostatic detecting area, and sets a predetermined threshold based on the capacitance; an electrostatic detecting unit for outputting a detecting signal reflecting the change in the capacitance; and an operation determining unit for determining whether or not a user has performed a touch operation. The operation determining unit comprises: a contact determining unit for determining the user's contact by determining whether the detecting signal is equal to or greater than the predetermined threshold for a predetermined duration or more; and a separation determining unit for determining whether the user has separated based on whether the detecting signal is equal to or less than the predetermined threshold. The operation determining unit determines whether time from the contact determination to the separation determination is equal to or less than predetermined time, and if the time is equal to or less than the predetermined time, determines that the touch operation is performed.SELECTED DRAWING: Figure 5a

Description

  The present invention relates to a touch operation detection device and a water supply device using the same.

  2. Description of the Related Art Conventionally, a water supply device using a water faucet device that automatically performs water discharge and water stoppage by detecting a human operation by a sensor has been widely used.

  As a sensor used in such a faucet device, for example, a capacitance type sensor is used. This capacitance type sensor has a detection electrode installed on the faucet device, and a circuit for detecting the capacitance between the electrode and the ground, when the user touches or approaches the detection electrode with a finger. The touch operation of the fingertip is determined by detecting the change in the capacitance between the ground and the time. For example, in such a faucet device, control is performed such that water is discharged when the detection electrode of the faucet device is touched, and water is stopped when the detection electrode is touched again.

  When a capacitance type sensor is used in the faucet device for switching between water discharge and water stoppage, if a water drop other than a human body, for example, water drops adheres to the detection electrode, the sensor may malfunction.

  Therefore, in order to prevent such a malfunction of the capacitance type sensor, for example, a capacitance type operation switch as described in Patent Document 1 has been proposed. In the capacitance-type operation switch described in Patent Literature 1, the facing area between the rotating electrode and the detection electrode changes according to the rotation of the rotating operation unit, and a shield potential is applied to the shield electrode. At this time, it is possible to detect the user's contact with the rotating operation part, and when the ground potential is applied to the shield electrode, by detecting the rotation of the rotating operation part, the rotating electrode can be detected. This is a faucet device that can detect a rotation operation and a touch operation of the operation unit by a change in the area of opposition between the operation unit and the detection electrode.

  In addition, a touch switch detection device and a touch switch detection device disclosed in Patent Document 2 are provided as a device that can determine whether a malfunction has occurred in a capacitance sensor, that is, whether a touch operation on a detection electrode is performed by a person or water. There has been proposed a water supply device using a water supply. The touch switch detection device described in Patent Document 2 includes a touch detection electrode that detects a change in capacitance due to a user's contact, a detection unit that outputs a detection output reflecting the change in capacitance, and a detection output. An operation determining unit that determines whether or not the user has performed an operation based on the operation determination unit. A contact determination unit, and a separation determination unit that determines whether the user has separated based on whether the rate of change of the detection output is equal to or greater than a predetermined separation value, and the operation determination unit is configured to operate according to the length of the duration. A touch switch detection device that sets an operation determination value in accordance with an operation determination value and determines whether the user has performed an operation based on whether a change rate of a detection output is equal to or greater than the operation determination value.

JP 2009-218785 A Patent No. 5158492

  However, in the capacitance-type operation switch described in Patent Literature 1, a space for providing the rotating electrode is required, so that the mechanism of the faucet device itself is complicated, and the capacitance-type operation switch is provided. There is a problem that the faucet device itself becomes large.

Further, in the touch switch detection device described in Patent Document 2, an output value detected by a touch detection electrode that detects a change in capacitance due to a user's contact is determined by a stainless steel sink or an artificial sink in which a faucet device is installed. Due to the influence of the installation environment such as a marble sink, it differs in each installation environment. Therefore, if the threshold value is fixed, the determination may be different when the installation environment changes.
Furthermore, since the capacitance varies depending on the user, the determination may be different for each user if the threshold is fixed.

  Therefore, a main object of the present invention is to consider the influence of the installation environment of the faucet device, and to control the operation of the faucet device based on the detection of the capacitance, based on the user's operation or other operations. It is an object of the present invention to provide a touch operation detecting device capable of accurately judging whether the contact is caused by a touch and a water supply device using the same.

A touch operation detection device according to the present invention is formed of a conductive material, and includes a static detection region for detecting a change in capacitance due to a user's contact and a static region including a static detection region in an installed state. A threshold setting unit that stores the capacitance and sets a predetermined threshold based on the stored capacitance; an electrostatic detection unit that outputs a detection signal reflecting a change in the capacitance; and An operation determining unit that determines the presence or absence of a user's touch operation. The operation determining unit determines the user's contact based on whether the detection signal continues for a predetermined duration or more and is equal to or more than a predetermined threshold. A contact determination unit and a separation determination unit that determines whether or not the user has separated by determining whether the detection signal is equal to or less than a predetermined threshold after the contact determination unit determines that the contact determination has been performed. Predetermined time from contact judgment to separation judgment Determines whether or less between, determines that the touch operation in the case of less than or equal to a predetermined time, and judging with the other operation is greater than the predetermined time, a touch operation detection device.
Further, the touch operation detection device according to the present invention is formed of a conductive material, and is an electrostatic detection region for detecting a change in capacitance due to a user's contact, wherein the electrostatic detection region is an insulating region. A plurality of sub-detection areas, and an electrostatic detection area, which is capacitively coupled by an adjacent sub-detection area via an insulating part among the plurality of sub-detection areas, The capacitance including the capacitance capacitively coupled by the sub-detection regions is stored as the entire capacitance, and each of the capacitances changed when the user touches each of the plurality of sub-detection regions. The capacitance is stored as the capacitance of each electrostatic detection region, and a predetermined threshold value of each electrostatic detection region is determined based on the stored total capacitance and the capacitance of each electrostatic detection region. The set A threshold setting unit, an electrostatic detection unit that outputs a detection signal reflecting a change in capacitance, and an operation determination unit that determines whether or not a user has performed a touch operation based on the output detection signal. A contact determination unit that determines whether or not the user has touched the operation determination unit based on whether the detection signal continues for a predetermined duration or more and is equal to or greater than a predetermined threshold value of each electrostatic detection region. And a separation determining unit that determines whether the user has separated based on whether the detection signal is equal to or less than a predetermined threshold value of the respective electrostatic detection regions. A touch operation detecting device for determining whether or not the time until the determination is equal to or shorter than a predetermined time, determining that the touch operation is performed when the time is equal to or shorter than the predetermined time, and determining other operation when the time is longer than the predetermined time; It is.
In the touch operation detection device according to the present invention, the threshold setting unit stores, as the initial setting, the capacitance including the electrostatic detection region in the installation state as the first capacitance, and the user sets the first capacitance. It is preferable that the changed capacitance at the time of contact with the detection area is stored as a second capacitance, and a predetermined threshold is set within a range between the first capacitance and the second capacitance. .
Further, the touch operation detection device according to the present invention preferably includes a threshold setting unit, wherein the predetermined threshold is set to a plurality of thresholds, and a switching unit for switching between the plurality of thresholds is provided.
The water supply device according to the present invention is a touch operation detection device according to the present invention, a solenoid valve that opens and closes a water discharge channel, and a water tap device that has a water discharge port that discharges water supplied through the water discharge channel, A control unit that controls the operation of the solenoid valve based on a determination by the operation determination unit, wherein the electrostatic detection region is disposed on an outer surface of the faucet device.

According to the touch operation detection device according to the present invention, the threshold value setting unit that stores the capacitance including the electrostatic detection region in the installed state and sets the predetermined threshold based on the stored capacitance is provided. In setting the threshold, erroneous detection due to the influence of the installation environment can be suppressed.
Further, according to the touch operation detection device according to the present invention, the operation determination unit, a contact determination unit that determines the user's contact by whether the detection signal is equal to or greater than a predetermined threshold continuously for a predetermined duration or more, A separation determination unit that determines the separation of the user based on whether the detection signal is equal to or less than a predetermined threshold value after the contact determination unit determines that the contact determination is performed, and wherein the operation determination unit determines the separation from the contact determination. It is determined whether the time up to the predetermined time is equal to or less than a predetermined time. If the time is equal to or less than the predetermined time, it is determined that the touch operation has been performed.
Further, according to the touch operation detection device of the present invention, as the initial setting, the capacitance including the electrostatic detection area in the installation state is stored as the first capacitance, and the user performs the electrostatic detection. Having a function of storing the changed capacitance when contacting the region as a second capacitance and setting a predetermined threshold within a range between the first capacitance and the second capacitance, According to the user, the setting of the predetermined threshold value can be set more accurately.
Further, according to the touch operation detection device according to the present invention, in the threshold setting unit, the predetermined threshold is set to a plurality of thresholds, and a switching unit for switching between the plurality of thresholds is provided. And can be set with higher accuracy.
According to the water supply device according to the present invention, a touch operation detection device of the present invention, a solenoid valve that opens and closes a water discharge channel, and a water tap device that has a water discharge port that discharges water supplied through the water discharge channel. A control unit that controls the operation of the solenoid valve based on the determination of the operation determination unit.Since the electrostatic detection region is disposed on the outer surface of the faucet device, An operation that can avoid a malfunction can be performed.

  According to the present invention, in consideration of the influence of the installation environment of the faucet device, regarding the operation of the faucet device based on the detection of the capacitance, whether the contact is based on the operation of the user or the contact by another operation is determined. It is possible to provide a touch operation detection device capable of accurately determining and a water supply device using the same.

  The above objects, other objects, features and advantages of the present invention will become more apparent from the following description of embodiments for carrying out the invention with reference to the drawings.

It is an appearance perspective view showing an example of an installation state of a faucet device used for a water supply device concerning a 1st embodiment of this invention. (A) is a front view of a water tap device used in the water supply device according to the first embodiment of the present invention, and (b) is a water tap used in the water supply device according to the first embodiment of the present invention. Figure 3 shows a side view of the plug device. 1 is a cross-sectional view of a water tap device used in a water supply device according to a first embodiment of the present invention. It is a block diagram showing an example of composition of a water supply device concerning a 1st embodiment of this invention. It is a block diagram showing an example of composition of a control board of a water supply device using a touch operation detection device concerning a 1st embodiment of this invention. FIG. 5B is a block diagram illustrating an example of a configuration of the operation determination unit illustrated in FIG. 5A. FIG. 4 is a flowchart illustrating an example of an operation of a threshold setting unit according to the first embodiment of the present invention. It is a flowchart figure which shows an example of operation | movement of the operation determination part concerning 1st Embodiment of this invention. It is a flowchart figure which shows an example of operation | movement of the contact determination part concerning 1st Embodiment of this invention. It is a flowchart figure which shows an example of operation | movement of the separation determination part concerning 1st Embodiment of this invention. It is a mimetic diagram showing the composition of the faucet device used for the water supply device concerning a 2nd embodiment of this invention. It is a block diagram showing an example of composition of a control board of a water supply device using a touch operation detection device concerning a 2nd embodiment of this invention. It is a schematic diagram which shows the structure of the faucet apparatus used for the water supply apparatus concerning 3rd Embodiment of this invention. It is a block diagram showing an example of composition of a control board of a water supply device using a touch operation detecting device concerning a 3rd embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. The embodiment described below is an example embodying the present invention, and does not limit the technical scope of the present invention.

1. First Embodiment FIG. 1 is an external perspective view showing an example of an installation state of a faucet device used for a water supply device according to a first embodiment of the present invention. FIG. 2A is a front view of a water tap device used in the water supply device according to the first embodiment of the present invention, and FIG. 2B is a water supply device according to the first embodiment of the present invention. The side view of the faucet device used for FIG. FIG. 3 is a sectional view of a faucet device used in the water supply device according to the first embodiment of the present invention. FIG. 4 is a block diagram showing an example of a configuration of the water supply device according to the first embodiment of the present invention. The water tap device 200A used in the water supply device 100 according to the present invention is installed, for example, on the upper surface side of a kitchen sink or on a counter.

  In the following, as shown in FIG. 1, the direction in which the spout portion 226 extends from the mounting plate S to which the faucet device 200A used in the water supply device 100 is mounted is defined as a front direction, and the opposite direction is defined as a rear direction. I do. The direction in which water is discharged is defined as a downward direction, and the opposite direction is defined as an upward direction. When the user views the faucet device 200A from the front, the right side is defined as the right direction, and the left side is defined as the left direction.

  The faucet device 200A includes a water discharge unit 210 and a water faucet main body 220 for detachably disposing the water discharge unit 210.

  For example, the water discharging unit 210 faces the sink (not shown) at a distance, and has a function of discharging water toward the sink. The water discharging section 210 is detachably supported by the spout section 226. The base material 211 of the water discharging section 210 is formed to be thin and made of, for example, a synthetic resin. The outer shape of the water discharging section 210 is formed in an L shape in a side view. A water discharge port 212 is provided at the tip of the water discharge section 210. For example, the base material 211 of the water discharging section 210 is subjected to a plating process using a conductive material on the entire outer surface and inner surface thereof, thereby forming a conductive plating layer. Note that the conductive plating layer formed on the water discharging section 210 does not have a function of detecting static electricity, which will be described later.

  The faucet main body 220 has a tubular portion 224 having a built-in valve unit 330 for adjusting hot water and temperature, and an operation for operating the valve unit 330 on one end side of the tubular portion 224 to adjust the flow rate and temperature of hot water. A part 222, a spout part 226 extending outward and upward from a side surface of the cylindrical part 224, and a pedestal part 228 arranged on the other end side of the cylindrical part 224 and rotatably supporting the cylindrical part 224 are provided.

  A pipe screw 202 protrudes from a lower portion of the pedestal portion 228. The pipe screw 202 is inserted into a mounting hole provided in the mounting plate S to which the faucet device 200A is mounted, and a nut 204 is screwed thereto. Thereby, the faucet device 200A is fixed on the mounting plate S.

The operation unit 222 is provided for adjusting the temperature of the water discharged from the water outlet 212 and further adjusting the flow rate discharged from the water outlet 212. By operating the operation unit 222, the mixing ratio of water and hot water can be manually adjusted by the valve unit 330 described later. For example, the discharge operation portion 222 is adjusted so that hot water having a high temperature in accordance with clockwise rotation T _1, the water that has been adjusted so that the cold water temperature becomes low according rotates counterclockwise T ₂ The temperature can be adjusted as follows. Further, by turning the operation part 222 upward, the switching operation from the still water to the water discharge can be performed. Then, the flow rate can be increased by rotating the operation unit 222 upward, and the flow rate of the hot water can be set larger as the operation unit 222 is set at the position rotated upward. On the other hand, when the operation unit 222 is rotated to the lowest position, the hot and cold water discharged from the water discharge port 212 of the water discharge unit 210 can be set to the water stopped state.

  The cylindrical portion 224 is formed in a cylindrical shape, and its base material is formed of resin. Further, the entire surface of the cylindrical portion 224 is plated with a conductive material on the entire outer surface and inner surface, and a conductive plating layer is formed. Inside the cylindrical portion 224, a valve unit 330 is disposed on an upper side thereof, and a water supply pipe 310 and a hot water supply pipe 320 connected to the valve unit 330 are disposed. A water pipe 342 for discharging the water is disposed.

  The spout portion 226 extends outward and upward from the side surface of the cylindrical portion 224, and is integrally formed so as to rotate together with the cylindrical portion 224. Further, the spout portion 226 has a configuration in which the water discharging portion 210 is detachably supported, and the hose 344 can be pulled out and inserted as the water discharging portion 210 moves. The spout portion 226 has a base material 227 formed of, for example, a synthetic resin to have a small thickness. The entire outer surface of the base material 227 of the spout portion 226 is plated with, for example, a conductive material, so that an electrostatic detection region (conductive plating layer) 230 is arranged. A conductive plating layer 231 is also formed on the entire inner surface of the base material 227 of the spout portion 226 by, for example, a plating process using a conductive material, and is electrically connected to the electrostatic detection region 230 formed on the outer surface. It is formed so that it may be connected.

As shown in FIGS. 1 and 2, an insulating portion 240 is formed on the spout portion 226 of the faucet device 200A. The insulating portion 240 is formed with a predetermined width in the ejection direction on one end (tip) side of the spout portion 226. The size of this width is only such that no capacitive coupling occurs due to the conductive plating layer formed on the outer surface thereof and the electrostatic detection region 230 arranged on the spout portion 226, which are plated in the water discharging section 210 and formed on the outer surface thereof. Is secured. That is, the insulating portion 240 is provided so that capacitive coupling does not occur between the plated surface of the water discharging portion 210 and the electrostatic detection region 230 arranged in the spout portion 226.
Therefore, in a state where the water discharging section 210 is fitted and held in the spout section 226, as shown in FIG. 3, the plated surface of the water discharging section 210 and the electrostatic detection disposed in the spout section 226. The region 230 is not electrically connected, and the surface of the water discharge unit 210 on which the plating process is performed and the electrostatic detection region 230 are separated by the insulating unit 240 and are not capacitively coupled.

The pedestal portion 228 is disposed on the other end side of the cylindrical portion 224, and has a function of fixing the faucet device 200A to the mounting plate S and enabling the cylindrical portion 224 to rotate. An LED display unit 228a is arranged at the front of the outer surface of the pedestal unit 228. The LED display unit 228a is displayed such that the color changes in accordance with the temperature of the hot and cold water discharged from the faucet device 200A. On the other hand, it is displayed so that the color changes in the order of blue → cyan → green → green → yellow → red.
The LED display unit 228a blinks when water is discharged (when the solenoid valve 350 is opened), turns off when water is stopped (when the solenoid valve 350 is closed), or when water is discharged during a touch operation. The display method and the color to be displayed can be changed such as blinking differently or turning off the light during standby. In addition, by monitoring the state of the power supply (battery) supplied to the control board 600A, the monitoring result can be displayed on the LED display unit 228a. In addition, the cylindrical portion 224 and the mounting plate S, which are plated and serve as an electrostatic detection region, are not electrically connected to each other by the gap of the pedestal portion 228 formed of an insulating material, and may not be capacitively coupled. Good.

The piping section 300 forms a piping network of the water supply device 100 as shown in FIG.
The pipe section 300 includes a water supply pipe 310 for supplying cold water and a hot water supply pipe 320 for supplying hot water, and adjusts a mixing ratio of cold water supplied from the water supply pipe 310 and hot water supplied from the hot water supply pipe 320. , A valve unit 330 for adjusting the flow rate. Part of the valve unit 330 is formed of a conductive material. The piping section 300 has a water discharge channel 340 for supplying water whose temperature is appropriately adjusted from the valve unit 330 to the faucet apparatus 200A. An electromagnetic valve 350 having a function of opening and closing the water discharge channel 340 is provided at an intermediate portion of the water discharge channel 340. The water discharge passage 340 includes a water supply pipe 342 for discharging water from the valve unit 330 to the electromagnetic valve 350 and a hose 344 for discharging water from the electromagnetic valve 350 to the water discharge part 210 of the faucet device 200A. The water pipe 342 is preferably formed of a material having conductivity.

  The hose 344 is formed, for example, by fixing a resin member to the inner surface of a tubular body formed of a mesh-like resin having an insulating property. Therefore, the hose 344 has flexibility. One end of the hose 344 is attached to the water discharge port 212 of the water discharge part 210 so as to allow water to flow therethrough, is inserted into the spout part 226, and is inserted so as to be able to be pulled out. The hose 344 corresponds to a part of the water discharge channel 340.

Water supply apparatus 100, as shown in FIG. 4 includes a signal transmitting unit 400 for transmitting the detection signal S _d 10 detected in the electrostatic detection region 230 provided on the spout portion 226 to the control board 600A. The signal transmission section 400 includes a spout section 226, a tubular section 224, a valve unit 330, and a water pipe 342. Specifically, the detection signal S _d 10 detected in the electrostatic detection region 230 provided on the spout portion 226 is transmitted to the control board 600A as follows. That is, when the user touches the electrostatic detection region 230 provided on the outer surface of the spout portion 226, the detection signal S _d 10 is transmitted to the conductive plating layer 231 on the inner surface of the spout portion 226 and the cylindrical portion 224 to the conductive plating layer on the inner surface, further to the portion of the valve unit 330 formed of a conductive material, and then to the water pipe 342, and subsequently from the water pipe 342 via a lead wire. This is transmitted to the electrostatic detection circuit 510 provided in the control board 600A described later.

  Subsequently, an electrical configuration of the water supply device 100 according to the first embodiment will be described. FIG. 5A is a block diagram illustrating an example of a configuration of a control board of the water supply device using the touch operation detection device according to the first embodiment of the present invention. FIG. 5B is a block diagram illustrating an example of a configuration of the operation determining unit illustrated in FIG. 5A.

  The electrical configuration of the water supply device 100 includes the touch operation detection device 500 and the control board 600A.

First, the touch operation detection device 500 will be described.
The touch operation detection device 500 has a function of determining whether the time from the contact determination to the separation determination is equal to or shorter than a predetermined time, and determining whether the operation is a touch operation or a rotation operation. Touch operation detection device 500 sets an electrostatic detection region 230 provided on the surface of spout portion 226, an electrostatic detection circuit 510 for receiving detection signal S _d 10 from electrostatic detection region 230, and a threshold value. And an operation determination unit 530 for determining whether the user has performed a touch operation.

The electrostatic detection circuit 510 serving as an electrostatic detection unit detects the capacitance including the electrostatic detection region 230 in the installed state and the change in the capacitance caused by a part of the human body touching the electrostatic detection region 230. It has a function to Further, it has a function of outputting an output signal S _o10 to the control microcomputer 610 according to the detected capacitance. The output signal S _{o10 corresponding} to the magnitude of the capacitance detected by the electrostatic detection circuit 510 is output to the threshold setting unit 520 to set a threshold. Further, an output signal S _{o10 corresponding} to the magnitude of the capacitance detected by the electrostatic detection circuit 510 is output to the operation determination unit 530 to determine whether the user has performed a touch operation.

  Here, the capacitance including the electrostatic detection area 230 in the installation state refers to, for example, not only the electrostatic detection area 230 arranged on the spout part 226 but also the mounting plate S on which the faucet device 200A is installed. The total capacitance includes the capacitance of the kitchen sink and the capacitance of the counter. That is, this depends on whether the environment in which the faucet device 200A is installed is located in a region formed of a conductive material or a region formed of an insulative material. Means that the magnitude of the capacitance including the electrostatic detection region 230 changes.

The threshold setting unit 520 has a function of storing the capacitance including the electrostatic detection region 230 in the installed state, and setting a predetermined threshold based on the stored capacitance.
As a method of setting the predetermined threshold, the threshold setting unit 520 first stores, as an initial setting, the capacitance including the electrostatic detection region 230 in the installation state as a first capacitance, and A function of storing a changed capacitance when the battery contacts the electric detection region 230 as a second capacitance and setting a predetermined threshold value within a range between the first capacitance and the second capacitance. It is preferred to have.

  In addition to the above-described method of setting the predetermined threshold, the method of setting the predetermined threshold can be, for example, the following method.

  1) The capacitance in the installed state is stored after the power is turned on, and a predetermined threshold value used for determination is set as a ratio setting. For example, a predetermined threshold value can be set so that contact is determined when the capacity has decreased to 70% from the state after installation.

  2) It is preferable to have a switching unit (not shown) that allows the user to switch between a plurality of predetermined thresholds (medium, low, high, etc.). In the threshold setting unit 520, a plurality of predetermined thresholds may be set in advance and assigned to each switching unit.

  3) The user can set the detection of the change in capacitance by bringing his / her hand close to the electrostatic detection region 230 arranged on the spout portion 226 without contact, and wears rubber gloves (insulator). A predetermined threshold value may be set so that detection can be performed even by touching with a hand. Alternatively, it can be made to respond to a change in response such as gender, age, and body type.

The operation determination unit 530 has a function of determining whether or not a user has performed a touch operation based on the output detection signal S _d10 . As shown in FIG. 5B, the operation determination unit 530 includes a contact determination unit 532 and a separation determination unit 534.
The contact determination unit 532 has a function of determining a user's contact based on whether or not the detection signal S _d10 continues for a predetermined duration or more and is equal to or more than a predetermined threshold. In addition, the separation determination unit 534 has a function of determining whether the user has separated based on whether or not the detection signal is equal to or less than a predetermined threshold after the contact determination unit 532 determines that the contact has been determined. The operation determination unit 530 determines whether the time from the contact determination by the contact determination unit 532 to the separation determination by the separation determination unit 534 is equal to or less than a predetermined time, and determines that the touch operation is performed when the time is equal to or less than the predetermined time. If it is longer than the predetermined time, it is determined to be another operation.

Next, the control board 600A will be described.
The control board 600A is configured to include a part of the touch operation detection device 500. That is, the control board 600A includes the electrostatic detection circuit 510 included in the touch operation detection device 500, the threshold setting unit 520, and the operation determination unit 530. Further, the control board 600A includes a control microcomputer 610 for controlling on the basis of the output signal S _o 10 from the electrostatic detection circuit 510. Based on the signal output from the touch operation detection device 500, the presence or absence of a user operation is determined, and the solenoid valve 350 is operated.

The control microcomputer 610, which is a control unit, has a function for performing control based on the output signal S _o10 output from the electrostatic detection circuit 510. Then, it has a function of outputting a control signal S _c 10 to the solenoid valve control circuit 620 in order to control the output signal S _o 10 based on a predetermined control condition. The predetermined control condition is stored in the control microcomputer 610. The predetermined control conditions will be described later together with the operation of the touch operation detection device 500.

The solenoid valve control circuit 620 receives the control signal S _c 10 output from the control microcomputer 610 and controls the solenoid valve 350 based on the input control signal S _c 10 to control the opening and closing of the valve of the solenoid valve 350. _It has a function of outputting c20 to the solenoid valve 350.

  Next, an operation of initial setting of the water supply device according to the first embodiment will be described. The initial setting is performed in the threshold setting unit 520 of the touch operation detection device 500. FIG. 6 is a flowchart illustrating an example of the operation of the threshold setting unit according to the first embodiment of the present invention.

  First, when the power of the water supply device 100 is turned on (S100), the threshold setting unit 520 firstly sets the whole of the installation state of the water supply device 100, that is, the faucet device 200A and the mounting plate S to be installed. The capacitance is detected, and the detected capacitance is stored as a first capacitance (S102). Subsequently, the capacitance that has changed after the user has touched the electrostatic detection region 230 of the spout portion 226 of the faucet device 200A is detected, and the detected capacitance is stored as a second capacitance. Is performed (S104). Then, based on the first capacitance stored in S102 and the second capacitance stored in S104, a predetermined threshold used in operation determination unit 530 in touch operation detection device 500 is set. (S106).

Subsequently, an operation of the touch operation detection device 500 according to the first embodiment will be described. FIG. 7 is a flowchart illustrating an example of an operation of the operation determining unit according to the first embodiment of the present invention.
The touch operation detection device 500 according to the first embodiment can switch between water discharge and water stoppage by an operation in which a part of a human body touches the electrostatic detection region 230 (a so-called toggle type). The details will be described below.
The operation determining unit 530 determines, by the operation of the contact determining unit 532, whether or not a part of the human body has touched the electrostatic detection region 230 for operating the faucet device 200A (S200). When it is determined that a part of the human body has touched the electrostatic detection region 230 for operation of the faucet device 200A by the operation of the contact determination unit 532 described later with reference to FIG. 8 (S202), subsequently, the separation determination unit 534 By the operation described above, it is determined whether or not a part of the human body has separated from the electrostatic detection area 230 (S204). When the time T which has been touched part of the human body electrostatic detection region 230 is a predetermined time T ₁ following times (S206), the electrostatic detection for the operation for water discharge by water faucet device 200A The touch operation for touching the area 230 is determined. On the other hand, if the electrostatic detection region 230 time part of a human body had touched T is a predetermined time T ₁ is greater than the time (S206), it is determined that the operation other than the operation for water discharge by water faucet device 200A (S210). The operations other than the operation for discharging water include, for example, an operation of gripping the spout portion 226 and rotating the spout portion 226, an operation of adjusting the temperature and the flow rate by the operation portion 222, and an operation of pulling out the water discharge portion 210. And so on.

FIG. 8 is a flowchart illustrating an example of an operation of the contact determination unit according to the first embodiment of this invention.
The contact determination unit 532 reads the detection signal S _d10 detected by the electrostatic detection circuit 510 (S300). Subsequently, it is determined whether the read detection signal S _d10 is equal to or more than a predetermined threshold (S302). If it is determined that the value is equal to or less than the predetermined threshold value, the detection signal S _d10 is continuously read (S300). On the other hand, when it is determined that the value is larger than the predetermined threshold (S302), the timer T starts counting (S304). If the count of the timer T has become longer than the predetermined duration T ₀ , it is determined that a part of the human body has been in contact with the electrostatic detection area 230 (contact determination) (S308). . On the other hand, if the time of the timer T is equal to or less than the predetermined duration T _0, it is determined that the human body part is not in contact (contactless determination) (S310). Then, the operation of the contact determination unit 532 ends.

FIG. 9 is a flowchart illustrating an example of the operation of the separation determination unit according to the first embodiment of the present invention.
The separation determination unit 534 reads the detection signal S _d10 detected by the electrostatic detection circuit 510 (S400). Subsequently, it is determined whether the read detection signal S _d10 is equal to or greater than a predetermined threshold (S402). If it is determined that it is larger than the predetermined threshold, the detection signal S _d10 is continuously read (S400). On the other hand, when it is determined that the difference is equal to or smaller than the predetermined threshold (S402), the counting of the timer T is terminated (S404). Then, the operation of the separation determination unit 534 ends.

Next, the operation and control conditions of the water supply device 100 according to the first embodiment will be described.
The water supply device 100 according to the first embodiment can switch between water discharge and water stoppage by an operation of touching a part of a human body to the electrostatic detection region 230 arranged on the spout portion 226 (a so-called toggle type). The details will be described below.

First, in a state where the water discharging section 210 is fitted and held in the spout section 226, the electrostatic detection circuit 510 can detect.
That is, touching a portion of the human body electrostatic detection region 230 of the spout 226, it is determined that the touch operation, the detection signal S _d 10 are input to the electrostatic detection circuit 510. As a result, an electrostatic detection circuit 510 to detect a change in capacitance through a signal transfer unit 400, an electrostatic detection circuit 510 outputs an output signal S _o 10 to the control microcomputer 610. Then, the control microcomputer 610 based on the output signal S _o 10, and outputs a control signal S _c 10 to the electromagnetic valve control circuit 620, a control signal S _c 10 to the solenoid valve control circuit 620 are input. Subsequently, the solenoid valve control circuit 620 outputs a control signal S _c 20 to the solenoid valve 350 so as to open the valve, so that the solenoid valve 350 opens the valve and passes through the water discharge passage 340 (hose 344). Water is spouted.

Further, in the water discharge state, when the water discharge unit 210 is fitted and held in the spout unit 226, the control microcomputer 610 stops the water discharge by touching a part of the human body to the electrostatic detection region 230 of the spout unit 226. Control to be able to.
That is, when a part of the human body touches the electrostatic detection region 230 of the spout unit 226, the electrostatic detection circuit 510 detects a change in the capacitance via the signal transmission unit 400, and the electrostatic detection circuit 510 , and outputs an output signal S _o 10 to the control microcomputer 610. Then, control microcomputer 610 outputs control signal S _c 10 to solenoid valve control circuit 620, and control signal S _c 10 is input to solenoid valve control circuit 620. Subsequently, the solenoid valve control circuit 620, to solenoid valve 350, by outputting a control signal S _c 20 to close the valve, the solenoid valve 350 closes the valve, is water cutoff.

  On the other hand, in a case where the water is stopped in a state where the water spouting section 210 is pulled out from the spout section 226, the water can be spouted when a part of the human body touches the electrostatic detection region 230 of the spout section 226.

  Further, when the water is discharged from the water discharging unit 210 in a state where the water discharging unit 210 is pulled out from the spout unit 226, the water can be stopped by a part of the human body touching the electrostatic detection region 230 of the spout unit 226. .

If the control microcomputer 610 determines that the water is being discharged for a specified time (for example, one minute), the control microcomputer 610 outputs a control signal S _c10 to the solenoid valve control circuit 620 and outputs the control signal S c10. Outputs the control signal S _c 20 to the electric valve 350 so as to close the valve, so that the solenoid valve 350 closes the valve and the water is stopped.

According to the touch operation detection device 500 used for the faucet device 200A included in the water supply device 100 according to the first embodiment, it is determined whether the time from the contact determination to the separation determination is equal to or less than a predetermined time, The touch operation detection device 500 has a function of determining whether the touch operation or the rotation operation is performed. Further, the touch operation detection device 500 includes an electrostatic detection region 230 provided on the surface of the spout portion 226 and a detection signal S _d from the electrostatic detection region 230. 10 includes an electrostatic detection circuit 510 for receiving the signal 10, a threshold setting unit 520 for setting a threshold, and an operation determination unit 530 for determining whether the user has performed a touch operation. In the case where the operation is sometimes determined, it is possible to prevent an erroneous operation in which an operation other than the touch operation, such as a rotation operation, is determined to be a contact determination.

  Further, according to the touch operation detection device 500 used for the faucet device 200A included in the water supply device 100 according to the first embodiment, the capacitance including the electrostatic detection region 230 in the installed state is stored and stored. Since the threshold setting unit 520 having the function of setting the predetermined threshold based on the obtained capacitance is provided, erroneous detection due to the influence of the installation environment can be suppressed when setting the predetermined threshold.

  Furthermore, according to the touch operation detection device 500 used for the faucet device 200A included in the water supply device 100 according to the first embodiment, as an initial setting, the capacitance including the electrostatic detection region 230 in the installation state is set. The first capacitance is stored, and the changed capacitance when the user contacts the electrostatic detection region 230 is stored as the second capacitance, and the first capacitance and the second capacitance are stored. With the function of setting the predetermined threshold value within the range of the electrostatic capacitance, the setting of the predetermined threshold value can be set more accurately according to the user.

  Further, according to the touch operation detection device 500 used for the faucet device 200A included in the water supply device 100 according to the first embodiment, a switching unit (not shown) that allows a user to switch a plurality of predetermined thresholds. If the threshold setting unit 520 sets a plurality of predetermined thresholds in advance and assigns them to each switch, the thresholds can be set more accurately according to the installation environment.

  Furthermore, according to the touch operation detection device 500 used for the faucet device 200A included in the water supply device 100 according to the first embodiment, the signal transmission unit 400 allows conduction from the electrostatic detection region 230 to the control board 600A. It is formed, and the water pipe fitting itself by the cylindrical part 224, the spout part 226, the valve unit 330, and the water pipe 342 which comprises the water supply apparatus 100 substitutes wiring as the signal transmission part 400, Does not require complicated wiring.

  Further, according to the faucet device 200A included in the water supply device 100 according to the first embodiment, the conventional plating process is performed by using a material having conductivity on the entire outer surface of the spout portion 226, so that the static electricity is reduced. Since the detection region 230 is arranged, it is not necessary to separately provide a process for forming the electrostatic detection region 230 or a space for providing electrodes for the faucet device. The degree of freedom of the design of the water faucet device and the location of the faucet device can be increased.

Further, according to the faucet device 200A of the water supply device 100 according to the first embodiment, the conventional plating process is performed on the entire outer surface of the spout portion 226 using a conductive material, so that the electrostatic detection can be performed. Since the region 230 is arranged, even if water droplets or the like adhere to the spout portion 226, the capacitance hardly changes due to the water droplet and the like, so that the region 230 is hardly affected by an erroneous reaction.
In addition, according to the faucet device 200A of the water supply device 100 according to the first embodiment, since the spout portion 226 has a structure extending upward and outward with respect to the cylindrical portion 224, if water droplets are temporarily Even if it adheres to the electrostatic detection area 230 disposed on the outer surface of the spout part 226, it flows down, and is less susceptible to erroneous reactions due to water droplets.

2. Second Embodiment Next, a water supply device 100 according to a second embodiment will be described. FIG. 10 is a schematic diagram illustrating a configuration of a faucet device used for a water supply device according to a second embodiment of the present invention. FIG. 11 is a block diagram illustrating an example of a configuration of a control board of a water supply device using the touch operation detection device according to the second embodiment of the present invention.

  In the faucet device 200B used in the water supply device 100 according to the second embodiment, an insulating portion 242 is formed between the water discharge portion 210 and the spout portion 226. Has a configuration similar to that of the faucet device 200A shown in FIG. 4 except that a static detection area 232 is provided in the water supply device 200, and a first electromagnetic valve 350a and a second electromagnetic valve 350b are further provided. Therefore, the same portions as those of the faucet device 200A shown in FIGS. 1 to 3 and the touch operation detecting device 500 and the control board 600A shown in FIG. 5A are denoted by the same reference numerals, and description thereof will be omitted.

As shown in FIG. 10, the entire outer surface of the base material 211 of the water discharging section 210 is plated with, for example, a conductive material, so that an electrostatic detection region (conductive plating layer) 232 is arranged. I have. The conductive plating layer 233 is also provided on the entire inner surface of the base material 211 of the water discharging section 210 by, for example, plating with a conductive material by plating.
In addition, an insulating portion 242 is formed on the other end side of the spout portion 226 of the faucet device 200B so as to have a predetermined width from the spout portion 226 side toward the water discharge portion 210 side. With respect to the size of this width, a width where capacitive coupling can be ensured by the electrostatic detection region 232 arranged in the water discharge unit 210 and the electrostatic detection region 230 arranged in the spout unit 226. That is, the insulating unit 242 is provided such that capacitive coupling can occur between the electrostatic detection region 232 arranged in the water discharge unit 210 and the electrostatic detection region 230 arranged in the spout unit 226.
Therefore, in a state where the water discharging unit 210 is fitted and held in the spout unit 226, the electrostatic detection region 232 arranged in the water discharging unit 210 and the electrostatic detection region 230 arranged in the spout unit 226 are different. Are not electrically connected, and the electrostatic detection region 232 and the electrostatic detection region 230 are capacitively coupled by the insulating portion 242.

Further, as shown in FIG. 11, the control board 600B is different from the control board 600A, and is provided with a first solenoid valve control circuit 620a and a second solenoid valve control circuit 620b.
Note that the electrostatic detection circuit 510 is electrically connected only to the electrostatic detection area 230 arranged in the spout section 226 via the signal transmission section 400.
The first solenoid valve 350a is a small flow rate solenoid valve. The second solenoid valve 350b is a large flow solenoid valve having a larger flow rate than the first solenoid valve 350a.

  Further, in the faucet device 200B, since the electrostatic detection area 230 and the electrostatic detection area 232 are capacitively coupled, a part of the human body touches the electrostatic detection area 230 arranged in the spout 226. There is a difference in the change of the capacitance between the case and the case where a part of the human body touches the electrostatic detection region 232 arranged in the water discharge unit 210. Therefore, the threshold setting unit 520 sets two types of predetermined thresholds: a predetermined threshold when the spout unit 226 is touched, and a predetermined threshold when the spout unit 226 is touched.

Next, the operation and control conditions of the water supply device 100 according to the second embodiment will be described.
The determination as to whether or not a touch has been performed by the touch operation detection device 500 used for the faucet device 200B of the water supply device 100 for discharging water is common to the operation of the touch operation detection device 500 according to the first embodiment. The description is omitted.

  The water supply apparatus 100 according to the second embodiment performs an operation of touching a part of a human body to the electrostatic detection area 230 arranged in the spout part 226 or a human body in the electrostatic detection area 232 arranged in the water discharge part 210. By touching a part, it is possible to switch between water discharge and water stoppage (so-called toggle type). The details will be described below.

In a state where the water discharging section 210 is fitted and held in the spout section 226, the electrostatic detection circuit 510 can detect.
That is, when a part of the human body touches the electrostatic detection region 232 arranged in the water discharging unit 210 and it is determined that the touch operation is performed, the detection signal S _d 10 ′ is input to the electrostatic detection circuit 510. Accordingly, the electrostatic detection circuit 510 detects a change in the capacitance by using a predetermined threshold value when the electrostatic detection circuit 510 touches the water discharging unit 210 via the signal transmission unit 400. And outputs an output signal S _o 10 ′. Then, the control microcomputer 610 based on the output signal S _o 10 ', and outputs a control signal S _c 10 to the first solenoid valve control circuit 620a, the first solenoid valve control circuit 620a control signal S _c 10 is input. Subsequently, the first solenoid valve control circuit 620a is relative to the first solenoid valve 350a, by outputting a control signal S _c 20 to open the valve, the first solenoid valve 350a opens the valve, ejection Water is discharged through the water flow path 340 (hose 344).

On the other hand, when a part of the human body touches the electrostatic detection area 230 arranged on the spout part 226 and it is determined that the touch operation is performed, the detection signal S _d 10 ′ is input to the electrostatic detection circuit 510. Accordingly, the electrostatic detection circuit 510 detects a change in the capacitance based on a predetermined threshold value when the electrostatic detection circuit 510 touches the spout unit 226 via the signal transmission unit 400. And outputs an output signal S _o 10 ′. Then, the control microcomputer 610 based on the output signal S _o 10 ', and outputs a control signal S _c 12 to the second solenoid valve control circuit 620b, the second solenoid valve control circuit 620b control signal S _c 12 is input. Subsequently, the second solenoid valve control circuit 620b outputs a control signal S _c 22 to the second solenoid valve 350b so as to open the valve, so that the second solenoid valve 350b opens the valve and discharges. Water is discharged through the water flow path 340 (hose 344).

In the water discharge state, when the water discharge unit 210 is fitted and held in the spout unit 226, the control microcomputer 610 determines whether the electrostatic detection region 232 of the water discharge unit 210 or the electrostatic detection region 230 of the spout unit 226. The crab is controlled so that water can be stopped by touching a part of the human body.
That is, when a part of the human body touches the electrostatic detection region 230 of the spout unit 226, the electrostatic detection circuit 510 detects a change in the capacitance via the signal transmission unit 400, and the electrostatic detection circuit 510 , And outputs an output signal S _o 10 ′ to the control microcomputer 610. Then, the control microcomputer 610, a second output a solenoid valve control circuit control signal S _c 12 relative 620b, the second solenoid valve control circuit 620b control signal S _c 12 is input. Subsequently, the second solenoid valve control circuit 620b outputs a control signal S _c 22 to the second solenoid valve 350b so as to close the valve, whereby the second solenoid valve 350b closes and stops the valve. Be watered.
Alternatively, when a part of the human body touches the electrostatic detection region 232 of the water discharging unit 210, the electrostatic detection circuit 510 detects a change in capacitance via the signal transmission unit 400, and the electrostatic detection circuit 510 , And outputs an output signal S _o 10 ′ to the control microcomputer 610. Then, the control microcomputer 610 outputs a control signal S _c 10 to the first solenoid valve control circuit 620a, the first solenoid valve control circuit 620a is the control signal S _c 10 are input. Subsequently, the first solenoid valve control circuit 620a outputs a control signal S _c 20 to the first solenoid valve 350a so as to close the valve, whereby the first solenoid valve 350a closes and stops the valve. Be watered.

In a state in which the water discharge unit 210 is pulled out from the spout unit 226, the capacitive coupling between the electrostatic detection region 232 arranged in the water discharge unit 210 and the electrostatic detection region 230 arranged in the spout unit 226 is released. The capacitance of the electrostatic detection region 230 arranged on the spout part 226 detected by the electric detection circuit 510 changes. The electrostatic detection circuit 510 detects this change, and outputs the change to the control microcomputer 610 as an output signal S _o 10 ′, so that the control microcomputer 610 determines that the water discharge unit 210 has been pulled out.

  On the other hand, in a case where the water is stopped in a state where the water spouting section 210 is pulled out from the spout section 226, the water can be spouted when a part of the human body touches the electrostatic detection region 230 of the spout section 226.

  Further, when the water is discharged from the water discharging unit 210 in a state where the water discharging unit 210 is pulled out from the spout unit 226, the water can be stopped by a part of the human body touching the electrostatic detection region 230 of the spout unit 226. .

In addition, when the water discharging section 210 is fitted into the spout section 226 again, the electrostatic detection area 232 arranged on the water discharging section 210 and the electrostatic detection area 230 arranged on the spout section 226 are capacitively coupled. The capacitance of the electrostatic detection area 230 of the spout 226 detected by the power detection circuit 510 changes. The electrostatic detection circuit 510 detects this change and outputs the change to the control microcomputer 610 as an output signal S _d 10 ′, so that the water discharge unit 210 is fitted into the spout unit 226. Recognize that Then, the control microcomputer 610 performs control so that water can be stopped by a part of the human body touching either the electrostatic detection region 232 of the water discharge unit 210 or the electrostatic detection region 230 of the spout unit 226.

The control microcomputer 610, the specified time (e.g., 1 minute) during, if it is determined that the water discharge state and outputs a control signal S _c 10 to the first solenoid valve control circuit 620a, the first The electromagnetic valve control circuit 620a outputs a control signal S _c 20 to the first electromagnetic valve 350a so as to close the valve, so that the first electromagnetic valve 350a closes the valve and the water is stopped, Alternatively, outputs a control signal S _c 12 to the second solenoid valve control circuit 620b, the second solenoid valve control circuit 620b is for the second solenoid valve 350b, the control signal S _c to close the valve By outputting 22, the second solenoid valve 350b closes the valve and is stopped.

In the tap operation detection device 500 according to the second embodiment and the faucet device 200B provided in the water supply device 100 using the same, the touch operation detection device 500 according to the first embodiment and the water supply device 100 using the same are provided. In addition to the same effects as described above, the following effects are also obtained.
That is, unlike the water supply device 100 according to the first embodiment, in the water supply device 100 according to the present embodiment, the touch operation is performed on the electrostatic detection region 230 arranged on the spout portion 226 on the control board 600B. Since a predetermined threshold for detecting a change in the capacitance in the case and a predetermined threshold for detecting the capacitance of the electrostatic detection region 232 arranged in the water discharging section 210 are set, the spout section 226 is set. Even if the electrostatic detection area 230 arranged in the water discharge section 210 is touched even if the electrostatic detection area 230 arranged in the Can be.

3. Third Embodiment Next, a water supply device 100 according to a third embodiment will be described. FIG. 12 is a schematic diagram illustrating a configuration of a water tap device used in a water supply device according to a third embodiment of the present invention. FIG. 13 is a block diagram illustrating an example of a configuration of a control board of a water supply device using the touch operation detection device according to the third embodiment of the present invention.

The faucet device 200C used in the water supply device 100 according to the third embodiment is described below in comparison with the faucet device 200A used in the water supply device 100 according to the first embodiment. Have such differences.
That is, the spout unit 226 of the water tap device 200C used in the water supply device 100 according to the third embodiment has a spout unit 226 as compared with the water tap device 200A used in the water supply device 100 according to the first embodiment. , A first spout portion 226a and a second spout portion 226b are divided via an insulating portion 244, a sub-detection region 230a is disposed in the first spout portion 226a, and a sub-detection region is disposed in the second spout portion 226b. In addition to the arrangement of 230b, an electrostatic detection region 232 is provided on the outer surface of the water discharging section 210, and an insulating section 242 is provided between the water discharging section 210 and the second spout section 226b.
Further, the water tap device 200C used in the water supply device 100 according to the third embodiment includes an electric valve 352 instead of the electromagnetic valve 350.

  On the other hand, the faucet device 200C used for the water supply device 100 according to the third embodiment is different from the faucet device 200A used for the water supply device 100 according to the first embodiment, in that the operation unit 222, It does not include the cylindrical portion 224, the valve unit 330, and the water supply pipe 342.

  Therefore, except for the above-described difference in configuration, the faucet device 200C used in the water supply device 100 according to the third embodiment is different from the faucet device 200A shown in FIGS. 1 to 3 and the touch device shown in FIG. 5A. The same portions as those of the operation detection device 500 and the control board 600A are denoted by the same reference numerals, and description thereof will be omitted.

  As shown in FIG. 12, the spout portion 226 is arranged on the side connected to the first spout portion 226 a connected to the pedestal portion 228 via the insulating portion 244 and the side connected to the water discharge portion 210. And two spout portions 226b. One side of the first spout portion 226a is connected to the pedestal portion 228, and the other side is formed with an insulating portion 244 having a predetermined width toward the second spout portion 226b. As for the size of this width, a width in which capacitive coupling can be ensured by the sub-detection region 230a arranged in the first spout portion 226a and the sub-detection region 230b arranged in the second spout portion 226b. That is, the insulating section 244 is not electrically connected between the sub-detection area 230a disposed on the first spout section 226a and the sub-detection area 230b disposed on the second spout section 226b. The region 230a and the sub-detection region 230b are capacitively coupled by the insulating unit 244. Then, an insulating part 224 is arranged on one side of the second spout part 226b.

In addition, as shown in FIG. 12, the entire surface of the outer surface of the water discharge unit 210 is plated with, for example, a conductive material, so that the electrostatic detection region 232 is arranged. An insulating portion 242 is formed on the other end side of the second spout portion 226b of the faucet device 200C so as to have a predetermined width from the second spout portion 226b side toward the water discharge portion 210 side. As for the size of this width, a width in which capacitive coupling can be ensured by the electrostatic detection area 232 arranged in the water discharging section 210 and the sub detection area 230b arranged in the second spout section 226b is secured. That is, the insulating unit 242 is provided such that capacitive coupling can be caused by the electrostatic detection region 232 arranged in the water discharge unit 210 and the sub detection region 230b arranged in the second spout unit 226b.
Therefore, in a state where the water spouting section 210 is fitted into and held by the second spout section 226b, the electrostatic detection area 232 arranged in the water spouting section 210 and the sub-spouts arranged in the second spout section 226b. The detection region 230b is not electrically connected, and the electrostatic detection region 232 and the sub-detection region 230b are capacitively coupled by the insulating portion 242.

  The motor-operated valve 352 has a function of changing the mixing ratio of hot water and water to adjust the temperature and adjust the flow rate according to a control signal from the motor-operated valve control circuit 622.

Also, as shown in FIG. 13, the control board 600C is different from the control board 600A in that an electric valve control circuit 622 is provided instead of the solenoid valve control circuit 620.
Note that the electrostatic detection circuit 510 is electrically connected only to the sub-detection region 230a arranged in the first spout portion 226a.

  Further, in the faucet device 200C, the sub-detection region 230a and the sub-detection region 230b are capacitively coupled, and the sub-detection region 230b and the electrostatic detection region 232 are capacitively coupled. The case where a part of the human body touches the sub-detection area 230a arranged on the spout part 226a of the second case, the case where a part of the human body touches the sub-detection area 230b arranged on the second spout part 226b, There is a difference in the change in capacitance between the case where a part of the human body touches the electrostatic detection region 232 arranged in 210. Therefore, in threshold setting section 520, a predetermined threshold when touching water spouting section 210, a predetermined threshold when touching first spout section 226a, and a predetermined threshold when touching second spout section 226b Three types of predetermined thresholds are set.

  The water supply device 100 according to the third embodiment does not include the signal transmission unit 400, and the first spout unit 226a and the control board 600C are connected by a cable.

Next, the operation and control conditions of the water supply device 100 according to the third embodiment will be described.
The determination of whether or not a touch has been performed by the touch operation detection device 500 used for the faucet device 200C of the water supply device 100 for discharging water is common to the operation of the touch operation detection device 500 according to the first embodiment. The description is omitted.

In a state where the water spouting section 210 is fitted and held in the second spout section 226b, the electrostatic detection circuit 510 can detect.
That is, when a part of the human body touches the electrostatic detection region 232 arranged in the water discharge unit 210 and it is determined that the touch operation has been performed, the detection signal S _d 10 ″ is input to the electrostatic detection circuit 510. As a result, the electrostatic detection circuit 510 detects a change in capacitance based on a predetermined threshold value when the water discharge unit 210 is touched, and the electrostatic detection circuit 510 sends the output signal S _o 10 ′ to the control microcomputer 610. 'Is output.
Then, the control microcomputer 610 outputs a control signal S _c 10 ″ to the motor-operated valve control circuit 622 based on the output signal S _o 10 ″, and the control signal S _c 10 is input to the motor-operated valve control circuit 622. Is done. Subsequently, the motor-operated valve control circuit 622 outputs a control signal S _c 20 to the motor-operated valve 352 so as to open the valve, so that the motor-operated valve 352 opens the valve and passes through the water discharge passage 340 (hose 344). Water is spouted. At this time, the electric valve 352 is controlled based on the control signal S _c20 so that hot water adjusted to, for example, a temperature of 40 ° C. is discharged at a large flow rate.

When a part of the human body touches the sub-detection area 230a arranged on the first spout part 226a and the touch operation is determined, the detection signal S _d10 ″ is input to the electrostatic detection circuit 510. Accordingly, the electrostatic detection circuit 510 detects a change in capacitance based on a predetermined threshold value when the first spout portion 226a is touched, and the electrostatic detection circuit 510 sends an output signal S to the control microcomputer 610. _o Output 10 ''. Then, the control microcomputer 610 based on the output signal S _o 10 '', and outputs a control signal S _c 10 to the electric valve control circuit 622, a control signal S _c 10 is input to the electric valve control circuit 622 . Subsequently, the motor-operated valve control circuit 622 outputs a control signal S _c 20 to the motor-operated valve 352 so as to open the valve, so that the motor-operated valve 352 opens the valve and passes through the water discharge passage 340 (hose 344). Water is spouted. At this time, the electric valve 352 is controlled so that the temperature is lower and a small amount of water is discharged as compared with a case where a touch operation is performed on the electrostatic detection region 232 arranged on the discharge unit 210.

Further, when a part of the human body touches the sub-detection area 230b arranged on the second spout part 226b and it is determined that a touch operation has been performed, the detection signal S _d10 ″ is input to the electrostatic detection circuit 510. Accordingly, the electrostatic detection circuit 510 detects a change in capacitance based on a predetermined threshold value when the second spout portion 226b is touched, and the electrostatic detection circuit 510 sends an output signal S to the control microcomputer 610. _o Output 10 ''.
Then, the control microcomputer 610 based on the output signal S _o 10 '', and outputs a control signal S _c 10 to the electric valve control circuit 622, a control signal S _c 10 is input to the electric valve control circuit 622 . Subsequently, the motor-operated valve control circuit 622 outputs a control signal S _c 20 to the motor-operated valve 352 so as to open the valve, so that the motor-operated valve 352 opens the valve and passes through the water discharge passage 340 (hose 344). Water is spouted. The motor-operated valve 352 is controlled so as to discharge a small amount of water at the same temperature (for example, 40 ° C.) as when a touch operation is performed on the electrostatic detection region 232 arranged on the discharge unit 210.

Further, in the water discharging state, when the water discharging unit 210 is fitted and held in the second spout unit 226b, the control microcomputer 610 determines whether the sub-unit of the electrostatic detection region 232 of the water discharging unit 210 and the first spout unit 226a is When a part of the human body touches either the detection area 230a or the sub-detection area 230b of the second spout part 226b, control is performed so that water can be stopped.
That is, when a part of the human body touches the sub-detection area 230a of the first spout part 226a or the sub-detection area 230b of the second spout part 226b, the electrostatic detection circuit 510 detects a change in capacitance. The electrostatic detection circuit 510 outputs an output signal S _o ″ to the control microcomputer 610. Then, the control microcomputer 610 outputs a control signal S _c 10 to the electric valve control circuit 622, the electric valve control circuit 622 a control signal Sc10 is input. Subsequently, the motor-operated valve control circuit 622 outputs a control signal S _c 20 to the motor-operated valve 352 so as to close the valve, thereby closing the valve and stopping the water.

When the water discharge unit 210 is pulled out from the second spout unit 226b, the capacitive coupling between the electrostatic detection region 232 disposed on the water discharge unit 210 and the sub detection region 230b disposed on the second spout unit 226b is released. Therefore, the capacitance of the sub-detection area 230b arranged in the second spout portion 226b detected by the electrostatic detection circuit 510 changes. The electrostatic detection circuit 510 detects this change, and outputs the change to the control microcomputer 610 as an output signal S _o 10 ″, so that the control microcomputer 610 detects that the water discharging section 210 has been pulled out. judge.

  On the other hand, when the water is stopped in a state where the water spouting section 210 is pulled out from the second spout section 226b, the human body is placed in the sub-detection area 230a of the first spout section 226a or the sub-detection area 230b of the second spout section 226b. The water can be spouted by touching a part of it.

  When the water is discharged from the water spouting section 210 in a state where the water spouting section 210 is pulled out from the second spout section 226b, the sub-detection area 230a of the first spout section 226a or the sub-detection area of the second spout section 226b. When a part of the human body touches 230b, water can be stopped.

Further, when the water discharging section 210 is re-fitted into the second spout section 226b, the electrostatic detection area 232 arranged on the water discharging section 210 and the sub-detection area 230b arranged on the second spout section 226b are capacitively coupled. Therefore, the capacitance of the sub-detection area 230b of the second spout portion 226b detected by the electrostatic detection circuit 510 changes. The electrostatic detection circuit 510 detects this change, by outputting the control microcomputer 610 that is the change as an output signal S _o 10, the control microcomputer 610, the water discharge portion 210 is a second spout section 226b Recognize that it has been inserted. Then, control microcomputer 610 causes a part of the human body to touch any one of electrostatic detection region 232 of water discharging unit 210, sub-detection region 230a of first spout unit 226a, or sub-detection region 230b of second spout unit 226b. In this way, control is performed so that water can be stopped.

If the control microcomputer 610 determines that the water is being discharged for a specified time (for example, one minute), the control microcomputer 610 outputs a control signal S _c10 to the motor-operated valve control circuit 622, and the motor-operated valve control circuit 622 Outputs the control signal S _c 20 to the motor-operated valve 352 so as to close the valve, whereby the motor-operated valve 352 closes the valve and the water is stopped.

In the tap operation detecting device 500 according to the third embodiment and the faucet device 200C provided in the water supply device 100 using the same, the touch operation detecting device 500 according to the first embodiment and the water supply device 100 using the same are provided. In addition to the same effects as described above, the following effects are also obtained.
That is, unlike the water supply device 100 according to the first embodiment, the water supply device 100 according to the present embodiment performs a touch operation on the sub-detection area 230a arranged on the first spout portion 226a on the control board 600C. And a predetermined threshold for detecting a change in capacitance when a touch operation is performed on a sub-detection area 230b arranged in the second spout portion 226b. A threshold value and a predetermined threshold value for detecting the capacitance of the electrostatic detection region 232 arranged in the water discharging section 210 are set, and the motor-operated valve 352 is set in advance with respect to each predetermined threshold value by each detection signal. Water is discharged based on the adjusted flow rate and temperature, so that the water is discharged when the sub-detection region 230a arranged on the first spout portion 226a is touched. The state where the user touches the state and the water discharge state when touching the sub-detection area 230b arranged on the second spout section 226b and the water discharge state when touching the electrostatic detection area 232 arranged on the water discharge section 210 Respectively.

As described above, the embodiment of the present invention has been disclosed in the above description, but the present invention is not limited to this.
That is, various changes can be made to the embodiment described above with respect to the mechanism, shape, material, quantity, position or arrangement without departing from the scope of the technical idea and the purpose of the present invention. And they are included in the present invention.

  For example, in the faucet devices 200A, 200B, and 200C according to the present embodiment, the spout portion 226 is provided rotatably with respect to the pedestal portion 228, but the spout portion 226 is not limited to this. It may be fixed to the plate S or the like.

  In the faucet devices 200A, 200B, and 200C according to the present embodiment, the water discharging section 210 is provided so as to be able to be drawn out to the spout section 226, but the water discharging section 210 is formed integrally with the spout section 226. May be.

  Furthermore, in the faucet devices 200A, 200B, and 200C according to the present embodiment, the electrostatic detection region 230 disposed on the spout unit 226, the electrostatic detection region 232 disposed on the water discharge unit 210, and the first spout unit 226a The sub-detection region 230a disposed on the second spout portion 226b or the sub-detection region 230b disposed on the second spout portion 226b is formed by performing a plating process using a conductive material, but is not limited thereto.

  In the water supply apparatus 100 according to the present embodiment, the electrostatic detection area 230 and the control board 600A, or the sub-detection area 230a and the control board 600B are connected via the signal transmission unit 400. The present invention is not limited to this, and may be separately connected via a cable.

  The touch operation detecting device according to the present invention and the water supply device using the same are, for example, in a water supply device arranged in a kitchen sink or a counter, in consideration of the effects of different installation environments, the touch on the faucet device. Prevention of erroneous detection of the operation makes it possible to use the device suitably.

Reference Signs List 100 water supply device 200A, 200B, 200C faucet device 210 water discharge section 211 base material 220 faucet main body section 222 operation section 224 cylindrical section 226 spout section 226a first spout section 226b second spout section 227 base material 228 pedestal section 228a LED display section 230, 232 Static detection area 230a, 230b Sub-detection area 300 Piping section 310 Water supply pipe 320 Hot water supply pipe 330 Valve unit 340 Water discharge channel 342 Water supply pipe 344 Hose 350 Solenoid valve 350a First solenoid valve 350b Second Electromagnetic valve 352 Motorized valve 400 Signal transmission unit 500 Touch operation detection device 510 Electrostatic detection circuit 520 Threshold setting unit 530 Operation determination unit 532 Contact determination unit 534 Separation determination unit 600A, 600B, 600C Control board 610 Control microcomputer 620 Electromagnetic valve control Rotational direction S _d 10 of the circuit 620a first solenoid valve control circuit 620b second solenoid valve control circuit 622 electrically operated valve control circuit S mounting plate T _1, T ₂ operation _{lever, S d 10 ', S d} 10'' Detection signal _{S o 10, S o 10 '} , S o 10'' output signal _{S c 10, S c 12,} S c 20, S c 22 control signals

Claims (5)

An electrostatic detection region formed of a conductive material, for detecting a change in capacitance due to user contact,
A threshold setting unit that stores the capacitance including the electrostatic detection region in the installation state, and sets a predetermined threshold based on the stored capacitance.
An electrostatic detection unit that outputs a detection signal reflecting the change in the capacitance,
An operation determination unit that determines whether or not a user has performed a touch operation based on the output detection signal,
With
The operation determining unit includes:
A contact determination unit that determines the contact of the user by determining whether the detection signal is equal to or greater than the predetermined threshold for a predetermined duration or more;
After being determined as a contact determination in the contact determination unit, a separation determination unit that determines the separation of the user by whether the detection signal is equal to or less than the predetermined threshold,
Has,
The operation determination unit determines whether or not the time from the contact determination to the separation determination is equal to or less than a predetermined time, determines that the touch operation is performed when the time is equal to or less than the predetermined time, and determines that the touch operation is performed when the time is longer than the predetermined time. A touch operation detection device, characterized by making a determination. It is formed of a conductive material, and is an electrostatic detection area for detecting a change in capacitance due to a user's contact, wherein the electrostatic detection area is divided into a plurality of sub-detection areas by an insulating unit. Is configured, of the plurality of sub-detection regions, capacitively coupled by adjacent sub-detection regions via the insulating portion, an electrostatic detection region,
The capacitance including the capacitance capacitively coupled by the plurality of sub-detection regions in the installed state is stored as the entire capacitance, and the user has contacted each of the plurality of sub-detection regions. The respective changed capacitances are stored as the capacitances of the respective electrostatic detection regions, and based on the stored total capacitance and the capacitance of the respective electrostatic detection regions, A threshold setting unit for setting a predetermined threshold of the electrostatic detection region of
An electrostatic detection unit that outputs a detection signal reflecting the change in the capacitance,
An operation determination unit that determines whether or not a user has performed a touch operation based on the output detection signal,
With
The operation determining unit includes:
A contact determination unit that determines whether or not the user has touched by whether the detection signal is equal to or greater than a predetermined threshold of each of the electrostatic detection regions continuously for a predetermined duration or more,
After being determined as a contact determination in the contact determination unit, a separation determination unit that determines separation of the user by determining whether the detection signal is equal to or less than a predetermined threshold value of the respective electrostatic detection regions,
Has,
The operation determination unit determines whether or not the time from the contact determination to the separation determination is equal to or less than a predetermined time, determines that the touch operation is performed when the time is equal to or less than the predetermined time, and determines that the touch operation is performed when the time is longer than the predetermined time. A touch operation detection device, characterized by making a determination. The threshold setting unit,
As an initial setting, the capacitance including the electrostatic detection area in the installation state is stored as a first capacitance, and the changed capacitance when the user contacts the electrostatic detection area is stored. 3. The method according to claim 1, wherein the predetermined threshold value is stored as a second capacitance, and the predetermined threshold value is set within a range between the first capacitance and the second capacitance. 3. The touch operation detecting device according to claim 1.   4. The threshold setting unit according to claim 1, wherein the predetermined threshold is set to a plurality of thresholds, and the switching unit switches between the plurality of thresholds. Touch operation detection device. A touch operation detecting device according to any one of claims 1 to 4,
A solenoid valve for opening and closing the water discharge channel;
A faucet device having a water discharge port for discharging water supplied through the water discharge channel,
A control unit that controls the operation of the solenoid valve based on the determination of the operation determination unit,
With
The water supply device, wherein the electrostatic detection region is disposed on an outer surface of the faucet device.