JP2016186178A - Automatic faucet device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an automatic faucet device capable of properly preventing a sensor from erroneously detecting sprayed-out water.SOLUTION: An automatic faucet device 1 discharges water automatically when detecting an object. The automatic faucet device 1 includes: a sensor 14 for detecting an object; and a discharge part 13 for discharging water to spray out. The sensor 14 and a discharge port 13a are disposed on the front end of the automatic faucet device 1. The sensor 14 is disposed so that a detection direction for detecting an object is oriented to a direction which separates away from a water discharge direction from the discharge part 13.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an automatic water faucet device, and more particularly to an automatic water faucet device that performs spray water discharge to discharge water in a mist form.

  Conventionally, various attempts have been made to realize water saving in a faucet device. Among them, spray water discharge that discharges water in a mist form at a low flow rate is effective for water saving. For example, Patent Document 1 discloses a technique in which a predetermined device is attached to a faucet and sprayed water is discharged from the water. Further, for example, Patent Document 2 discloses a faucet device that can manually switch a plurality of types of water discharge including spray water discharge (mist water discharge).

Noto 3007505 gazette Japanese Utility Model Publication No. 7-31969

  By the way, when it was going to be performed by the automatic faucet device which performs water discharge automatically when a sensor detects a thing to be detected, the above-mentioned spray water discharge was carried out because the water discharge range by spray water discharge is wide. There is a possibility that the sensor may detect water. In that case, the automatic water faucet device will accidentally discharge water, which is undesirable from the viewpoint of saving water.

  Therefore, an object of the present invention is to provide an automatic faucet device that can appropriately suppress erroneous water discharge caused by a sensor detecting water sprayed and discharged.

In order to achieve the above object, the present invention is an automatic water faucet device that automatically discharges water when a detected object is detected so that water spreads at a predetermined angle from the sensor that detects the detected object and the water outlet. A water discharge unit for discharging water, and a sensor and a water discharge port of the water discharge unit are provided at the tip of the automatic water faucet device, and the sensor has a detection direction away from the water discharge direction of the water discharge unit. It is arranged so as to face in a certain direction.
In the present invention configured as above, in the automatic water faucet device provided with the water discharge portion and the sensor at the tip portion, the sensor is disposed so that the detection direction of the sensor is away from the water discharge direction of the water discharge portion. In other words, because the sensor is arranged so that the line along the detection direction of the sensor does not intersect the line extending in the vertical direction from the approximate center of the water discharge port of the water discharge part on the front side, It is possible to appropriately suppress the automatic water faucet device from erroneously discharging water due to the sensor detecting the water discharged from the water discharge port of the water discharge unit at a predetermined angle.

In this invention, Preferably, the sensor is arrange | positioned ahead rather than the water outlet of the water discharging part.
In the present invention configured as described above, since the sensor is disposed on the front side of the water discharge port of the water discharge unit, compared with the case where the sensor is disposed on the rear side of the water discharge port of the water discharge unit, In order for the user to detect the hand by the sensor, it is not necessary to force the hand to extend backward. In other words, the configuration according to the present invention is such that the water discharge port of the water discharge unit is disposed behind the sensor. According to this, compared with the case where the water outlet of a water discharging part is arrange | positioned ahead of a sensor, the water discharged from the water discharging part of the water discharging part over a wide range becomes difficult to apply to a user.

In this invention, Preferably, the front-end | tip of a sensor is arrange | positioned in the back side rather than the front-end | tip of the water discharge port of the water discharge part, or the front-end | tip of the water discharge part.
In the present invention configured as described above, the front end of the sensor is disposed at the same side as the front end of the water discharger or behind the front end of the water discharger of the water discharger. In other words, the front end of the water discharge port of the water discharger is disposed at the same position as the front end of the sensor or ahead of the front end of the sensor. According to this, compared with the case where the front-end | tip of a sensor is arrange | positioned ahead rather than the front-end | tip of the water discharge part of a water discharge part, the water discharge in the part with which the detection range of a sensor and the water discharge range from the water discharge part of a water discharge part overlap. Density decreases. Therefore, compared to the case where the tip of the sensor is disposed on the front side of the tip of the water discharge port of the water discharge unit, erroneous water discharge caused by the sensor detecting water discharged from the water discharge port of the water discharge unit is more effective. Can be suppressed.

In this invention, Preferably, it further has an illumination part which irradiates the water discharging by a water discharge part with light, and an illumination part is provided in the front-end | tip part of an automatic water faucet apparatus, and the front-end | tip of an illumination part is back rather than the front-end | tip of a sensor. It is arranged on the side.
In the present invention configured as described above, the front end of the illumination unit is disposed behind the front end of the sensor. In other words, the tip of the sensor is disposed in front of the illumination unit. Therefore, as compared with the case where the front end of the illumination unit is disposed on the front side of the front end of the sensor, the distance to the portion that overlaps the detection range of the sensor and the irradiation range from the illumination unit becomes longer. Since the light irradiation intensity is attenuated according to the distance, the irradiation intensity in the portion where the detection range of the sensor 14 and the irradiation range from the LED 15 overlap is low. Therefore, the light emitted from the irradiating unit can be appropriately irradiated with the light from the illuminating unit, and the light emitted from the irradiating unit as compared with the case where the front end of the illuminating unit is disposed in front of the front end of the sensor. It is possible to effectively suppress erroneous water discharge due to the detection of the sensor.

In this invention, Preferably, the front-end | tip of an illumination part is arrange | positioned in the back side rather than the front-end | tip of the water outlet of a water discharging part.
In this invention comprised in this way, the front-end | tip of an illumination part is arrange | positioned rather than the front-end | tip of the water discharge port of a water discharge part. In other words, the tip of the water discharge port of the water discharge unit is disposed in front of the illumination unit. According to this, since the light irradiated from the irradiation unit has a larger influence on the sensor than the water discharge from the water discharge port of the water discharge unit, the front end of the illumination unit is placed in front of the water discharge port of the water discharge unit. Compared with the case where it arrange | positions, the erroneous water discharge resulting from a sensor detecting the light irradiated from the irradiation part can be suppressed more effectively.

  According to the automatic faucet device of the present invention, it is possible to appropriately suppress erroneous water discharge caused by the sensor detecting water sprayed and discharged.

It is the perspective view which looked at the hand-washing machine which applied the automatic faucet device by embodiment of this invention from diagonally upward. It is a figure for demonstrating the structure of the automatic faucet device by embodiment of this invention concretely, FIG. 2 (A) is the perspective view which looked at this automatic faucet device from diagonally downward, FIG. B) is a cross-sectional view of the automatic faucet device as seen along line IIB-IIB in FIG. It is a longitudinal cross-sectional view of this 2nd water discharging part for demonstrating the principle of the spray water discharging of the 2nd water discharging part by embodiment of this invention. It is sectional drawing of the automatic water faucet apparatus by embodiment of this invention for demonstrating the relationship between the water discharge range of the 2nd water discharge part by embodiment of this invention, and the irradiation range of LED. It is sectional drawing of the automatic water faucet device by embodiment of this invention for demonstrating the arrangement | positioning relationship of the 1st water discharging part by the embodiment of this invention, the 2nd water discharging part, a sensor, and an irradiation part. It is a block diagram showing roughly the functional composition of the automatic faucet device by the embodiment of the present invention. It is a time chart which shows the basic control by 1st Embodiment of this invention. It is a schematic diagram which shows the state of the water in the 2nd flow path in the period which performs the after water discharge by 1st Embodiment of this invention from left to right in time series. It is a time chart which shows the 1st control example by 1st Embodiment of this invention. It is a time chart which shows the 2nd control example by 1st Embodiment of this invention. It is a time chart which shows the 3rd control example by 1st Embodiment of this invention. It is a flowchart which shows the control flow which concerns on the water discharge for hand-washing by 1st Embodiment of this invention. It is a flowchart which shows the control flow which concerns on the after-water discharge by 1st Embodiment of this invention performed after the flowchart shown in FIG. It is a time chart which shows the basic control by 2nd Embodiment of this invention. It is a flowchart which shows the control flow which concerns on the water discharge for hand-washing by 2nd Embodiment of this invention. It is a block diagram showing roughly the functional composition of the automatic faucet device by the modification in the embodiment of the present invention. It is a figure for demonstrating the structure of the automatic faucet apparatus by 3rd Embodiment of this invention concretely, FIG. 17 (A) is the perspective view which looked at this automatic faucet apparatus from diagonally downward, 17 (B) is a cross-sectional view of the automatic faucet device in FIG. 17 (A). It is sectional drawing of the automatic water faucet device by 3rd Embodiment of this invention for demonstrating the arrangement | positioning relationship of the 2nd water discharging part by 3rd Embodiment of this invention, a sensor, and an irradiation part. It is a block diagram showing roughly the functional composition of the automatic faucet device by a 3rd embodiment of the present invention. It is a time chart which shows the control by 3rd Embodiment of this invention.

  Next, an automatic faucet device according to an embodiment of the present invention will be described with reference to the accompanying drawings.

<Overall configuration>
First, FIG. 1 is a perspective view of a hand wash basin to which an automatic faucet device according to an embodiment of the present invention is applied, viewed obliquely from above. As shown in FIG. 1, the hand-washing machine 5 mainly includes an automatic water faucet device 1 that automatically stops water discharge and water discharge according to the detection state of an object to be detected such as a human body, and the automatic water faucet device 1. A bowl 3 that receives water discharged from the water and drains water from a drain port (not shown).

<Configuration of automatic faucet device>
Next, with reference to FIG. 2 thru | or FIG. 6, the detail of the automatic water tap apparatus by embodiment of this invention is demonstrated.

  FIG. 2 is a diagram for specifically explaining the configuration of the automatic water faucet device according to the embodiment of the present invention. FIG. 2 (A) is a perspective view of the automatic faucet device according to the embodiment of the present invention as seen obliquely from below, and FIG. 2 (B) shows the automatic faucet device in FIG. 2 (A) IIB- It is sectional drawing seen along the IIB line. Here, the configuration near the water discharge portion of the automatic faucet device 1 according to the present embodiment will be mainly described.

  As shown in FIG. 2A, the automatic faucet device 1 has a water discharge pipe 11 which is a curved tubular member. As shown in FIG. 2 (A) and FIG. 2 (B), at the tip of the water discharge pipe 11, a first water discharge unit 12 configured to perform foam water discharge from the first water discharge port 12a, A nozzle-like second water discharger 13 configured to perform spray water discharge (in other words, mist water discharge) from the second water discharge port 13a, a sensor 14 that detects infrared rays, and the like, detects an object to be detected; An LED (Light Emitting Diode) 15 for irradiating light is disposed. Specifically, the sensor 14, the first water outlet 12a, the LED 15, and the second water outlet 13a are arranged in this order from the top to the bottom of the water discharge pipe 11. Further, the water discharge pipe 11 is connected to the first water discharge unit 12, and is connected to the first flow path 17 for supplying water to the first water discharge unit 12 and the second water discharge unit 13. A second flow path 18 that is connected and supplies water (including electrolyzed water described later) to the second water discharger 13 is disposed. In addition, the 2nd water discharging part 13 is corresponded to the "water discharging part" in this invention.

  Here, the 1st water discharge part 12 mixes air with a filter as foam water discharge, and performs the foam-like water discharge which included the bubble in the water flow to discharge. On the other hand, the second water discharger 13 is wider than the cross-sectional area (diameter) of the second water discharge port 13a in which water spreads at a predetermined angle as the spray water discharge from the second water discharge port 13a. Use a mist-like water discharge that spreads water over the area. Further, the second water discharger 13 sprays water at a flow rate lower than that of the first water discharger 12 and sprays water at a flow rate faster than that of the first water discharger 12. In one example, the first water discharger 12 foams and discharges water at 2 liters per minute, and the second water discharger 13 sprays and discharges water at 0.3 liters per minute.

  Next, with reference to FIG. 3, the principle of the spray water discharge of the 2nd water discharge part 13 by this embodiment is demonstrated. FIG. 3 is a longitudinal sectional view of the second water discharger 13 as viewed along the direction of water flow.

  As shown in FIG. 3, in the second water discharger 13, the water flowing in from the inlet 13 b provided at the upper end part causes a straight flow (see arrow A <b> 11) in the internal flow path 13 d and the internal flow. A swirling flow (see arrow A12) is generated in the internal flow path 13d by the water flowing in from the slit portion 13c formed on the outer peripheral surface of the upper end portion of the path 13d. Due to the synergistic effect of the straight flow and the swirl flow, the spray water discharge is performed in a full cone shape from one second water discharge port 13a at the lower end of the internal flow path 13d. Specifically, the water is discharged over a range larger than the cross-sectional area (diameter) of the second water discharge port 13a. In this case, water spreads and is discharged from the second water discharge port 13a at the discharge angle θ. In the foam water discharge by the first water discharge unit 12 described above, since water is discharged in a range almost the same as the cross-sectional area (diameter) of the first water discharge port 12a, the second water discharge port of the second water discharge unit 13 is discharged. The discharge angle θ from 13a is larger than the discharge angle from the first water outlet 12a of the first water discharger 12.

  Next, with reference to FIG. 4, the relationship between the water discharge range of the 2nd water discharge part 13 by this embodiment and the irradiation range of LED15 is demonstrated. FIG. 4 is a cross-sectional view of the automatic faucet device 1 according to the present embodiment, similar to FIG.

  As shown in FIG. 4, in this embodiment, in order to notify the user of the water discharge range R11 of the water sprayed and discharged by the second water discharge unit 13 by the light from the LED 15, the light irradiation range R12 by the LED 15 is: The installation angle of the LED 15 and the irradiation range of the LED 15 are set so as to substantially coincide with the water discharge range R11 by the second water discharge unit 13. For example, the LED 15 is disposed so that the central axis of the LED 15 is substantially parallel to the central axis of the second water discharger 13.

  Next, with reference to FIG. 5, the arrangement | positioning relationship of the 1st water discharging part 12, the 2nd water discharging part 13, the sensor 14, and LED15 by this embodiment is demonstrated. FIG. 5 is a cross-sectional view of the automatic faucet device 1 according to the present embodiment, similar to FIG.

  As shown in FIG. 5, in the present embodiment, the sensor 14 and the second water discharger that make it difficult for the sensor 14 to detect water sprayed and discharged from the second water discharge port 13 a of the second water discharger 13. The orientation relationship with 13 is adopted. Specifically, since the detection accuracy of the sensor 14 decreases as the distance from the sensor 14 increases, a directivity range R13 (a range including the detection range of the sensor 14) corresponding to the detection direction A23 related to detection of the detection object by the sensor 14 is detected. The sensor 14 and the second water discharger 13 intersect the water discharge range R11 of the second water discharger 13 at a position distant from the front side. The orientation relationship is adopted. Specifically, the sensor 14 is disposed so that the detection direction A23 of the sensor 14 is directed away from the water discharge direction A22 of the second water discharger 13. In other words, a line L13 (typically corresponding to the central axis of the sensor 14) along the detection direction A23 of the sensor 14 extends in the vertical direction from the center of the second water discharge port 13a of the second water discharge unit 13. The sensor 14 is disposed so as not to cross the line L12 (typically corresponding to the central axis of the second water discharger 13) on the front side.

  Further, in the present embodiment, the sensor 14 is connected to the second water discharge port 13a of the second water discharge unit 13 so that the hand is appropriately detected by the sensor 14 even if the person does not reach the back so much. Is also arranged on the front side. In other words, the second water discharge port 13 a is disposed behind the sensor 14. By doing so, the water sprayed and discharged from the second water outlet 13a is less likely to be applied to a portion of the user's arm or body that is not desired to be wetted.

  Further, in the present embodiment, the tip C3 of the LED 15 is further rearward than the tip C1 of the sensor 14 with respect to the detection direction A23 of the sensor 14 so that it is difficult for the sensor 14 to detect the light emitted from the LED 15. It is arranged. In other words, the tip C1 of the sensor 14 is disposed in front of the tip C3 of the LED 15.

  Further, in the present embodiment, the tip C3 of the LED 15 is arranged in the second direction of the second water discharger 13 with respect to the detection direction A23 of the sensor 14 so that the light emitted from the LED 15 is more difficult to detect. It is arrange | positioned in the back side rather than the front-end | tip C2 of the water discharge port 13a. In other words, the tip C3 of the second water discharge port 13a of the second water discharger 13 is disposed in front of the tip C3 of the LED 15.

  Furthermore, in this embodiment, the 2nd water discharge port 13a of the 2nd water discharge part 13 is arrange | positioned rather than the 1st water discharge port 12a of the 1st water discharge part 12, and the 1st water discharge port 12a. Water dripping from the second water outlet 13a. In this case, the second water discharge port 13a of the second water discharge unit 13 may prevent the water sprayed from the second water discharge port 13a from being applied to the first water discharge port 12a of the first water discharge unit 12. It is arranged. In addition, the second water discharge port 13a of the second water discharge unit 13 is disposed so as to spray water toward the vicinity of the drain port of the bowl 3 (not shown in FIG. 5).

  Further, in the present embodiment, the first water discharge unit 12 and the second water discharge unit 13 are configured such that the water sprayed from the second water discharge port 13a of the second water discharge unit 13 is not easily applied to the user. The orientation relationship is adopted. Specifically, the first water discharge unit 12 and the second water discharge unit so that the water discharge direction A21 of the first water discharge unit 12 and the water discharge direction A22 of the second water discharge unit 13 are directed away from each other. Each of 13 is arranged. In other words, the line L11 (typically corresponding to the central axis of the first water discharger 12) extending from the center of the first water discharger 12a of the first water discharger 12 and the second water discharger. The first water discharge portion so that a line L12 (typically corresponding to the central axis of the second water discharge portion 13) extending in the vertical direction from the center of the 13 second water discharge ports 13a does not intersect on the front side. 12 and the 2nd water discharging part 13 are each arrange | positioned.

  Next, the functional configuration of the automatic faucet device according to the embodiment of the present invention will be described with reference to FIG. FIG. 6 is a block diagram schematically showing a functional configuration of the automatic water faucet device according to the embodiment of the present invention.

  As shown in FIG. 6, the automatic faucet device 1 according to the present embodiment has a common channel 21 on the upstream side of both the first channel 17 and the second channel 18 (see FIG. 2 and the like). It is connected. The common flow path 21 is supplied with normal water such as general tap water (city water) (in this specification, this water is referred to as “normal water” as appropriate in order to distinguish this water from electrolyzed water). Is done. On the common flow path 21, in order from the upstream side, a stop cock 22 for blocking the flow of normal water in the common flow path 21, a filter 23 for removing foreign matters mixed in normal water, a flow rate on the secondary side Is provided at a constant flow rate, and branches into a first flow path 17 and a second flow path 18 at the downstream end of the common flow path 21.

  The first flow path 17 is provided with a first electromagnetic valve 25 that opens and closes to switch between normal water flow and blocking in the first flow path 17. When the first electromagnetic valve 25 is open, normal water flows through the first flow path 17 and from the first water discharger 12 connected to the downstream end of the first flow path 17. Usually, water is discharged as foam.

  On the other hand, in the second flow path 18, a second electromagnetic valve 28, a pressure regulating valve 29, a safety valve 30, a check valve 35, and an electrolytic cell 37 are provided in order from the upstream side. The second solenoid valve 28 switches between the flow and the block of normal water in the second flow path 18 by opening and closing. When the second electromagnetic valve 28 is open, the normal water flows into the second flow path 18, and from the second water discharger 13 connected to the downstream end of the second flow path 18. Spray water is discharged. The pressure regulating valve 29 is a valve that adjusts the water pressure to a desired pressure (a pressure suitable for performing spray water discharge). The safety valve 30 is opened when the pressure in the second flow path 18 becomes equal to or higher than a predetermined pressure (for example, when the second water discharge port 13a is blocked and the pressure in the second flow path 18 suddenly increases). In this case, the water in the second flow path 18 flows through the first flow path 17 via the bypass flow path 31 to reduce the pressure in the second flow path 18. The check valve 35 is a valve that prevents back flow of water. When the electrolyzer 37 is energized, it normally electrolyzes water to generate electrolyzed water. A filter may be further provided on the downstream side of the electrolytic cell 37.

  The automatic faucet device 1 further includes a controller 40 that controls components in the automatic faucet device 1 (this controller 40 corresponds to a “control unit” in the present invention). The controller 40 is operated by the power from the AC power source 39 and supplies the power of the AC power source 39 to each of the sensor 14, the LED 15, the first electromagnetic valve 25, the second electromagnetic valve 28, and the electrolytic cell 37. Take control. Specifically, the controller 40 acquires a sensor signal indicating the detection state of the object to be detected by the sensor 14, and performs control for switching on / off of the LED 15 based on this sensor signal, and opening / closing of the first electromagnetic valve 25. The control which switches the opening / closing of the 2nd solenoid valve 28, and the control which switches execution / stop of the production | generation of the electrolyzed water by the electrolyzer 37 are performed.

  Here, the electrolyzed water produced | generated by the electrolytic vessel 37 is demonstrated.

  As electrolyzed water used by this embodiment, what is necessary is just water which has the disinfection function obtained by electrolysis. A representative example of electrolyzed water is electrolyzed water containing hypochlorous acid. In general, since clean water or intermediate water contains chlorine ions, free chlorine is produced by electrolysis. Free chlorine exists as hypochlorous acid (HClO) when acidic, and in this form is about 10 times stronger in bactericidal power than hypochlorite ion (ClO-), which is an alkaline existence form. Moreover, even if it is neutral, a strong bactericidal power about the middle of it can be obtained. Therefore, the water electrolyzed in the continuous electrolysis tank is sterilized water having a strong sterilizing power.

  As described above, generally used clean water or intermediate water contains chlorine ions, but when used in areas where the chloride ion concentration is low or when a strong bactericidal action is required, salt water Chlorine ions can be supplemented by adding chloride such as.

  As an electrode used for chlorine generation, a conductive base material carrying a chlorine generation catalyst or a conductive material made of a chlorine generation catalyst is used. Depending on the type of catalyst for generating chlorine, for example, iron-based electrodes such as ferrite, palladium-based electrodes, ruthenium-based electrodes, iridium-based electrodes, platinum-based electrodes, ruthenium-tin-based electrodes, palladium-platinum-based electrodes, iridium-platinum-based electrodes , Ruthenium-platinum electrodes, iridium-platinum-tantalum electrodes, and the like. In the case where a catalyst for generating chlorine is carried on a conductive base material, the base material part that bears the structure can be made of inexpensive materials such as titanium and stainless steel, which is advantageous in terms of manufacturing cost.

  In addition to chlorine, hypohalous acid obtained by electrolyzing water containing halogen ions may be used.

  As other electrolyzed water, silver ion water obtained by utilizing silver as an electrode can be mentioned. Silver ions are said to adsorb to the enzyme in the bacterial cell membrane and inhibit the action of the enzyme, which makes it impossible for the bacteria to sustain their lives. There is also an action of coating the surface of the base material that comes into contact, and it becomes difficult for bacteria to propagate on the surface of the base material. Since silver ions can coat the substrate surface to prevent the adhesion of bacteria and have bactericidal power, the growth of bacteria on the substrate surface can be effectively suppressed. At that time, by combining with a cleaning method for increasing the replacement rate of the drain trap, it becomes possible to suppress the slime and smell of the drain for a long period of time.

  In addition, various types of electrolyzed water, such as ozone water that generates high-concentration ozone along with the generation of oxygen on the anode side, can be suitably used, especially by using lead dioxide (β-type) as an electrode for electrolysis. It is.

  Furthermore, examples of the sterilizing water other than the electrolyzed water include aqueous solutions in which various sterilizing components are dissolved. As the disinfecting component to be dissolved, any of solid, liquid, and gas may be used. In the case of using a liquid sterilizing component, for example, alcohols such as ethanol and isopropanol, hydrogen peroxide, etc. may be applied. Moreover, when using a gas disinfection component, ozone water should just be produced by dissolving ozone in water as a fine bubble, for example. Moreover, what is necessary is just to apply sodium hypochlorite etc., for example, when using a solid sanitization component.

Here, in the present specification, the term “sanitization” not only means to reduce bacteria (in this case, it includes not only the meaning to remove and reduce bacteria but also the meaning to kill and reduce bacteria), It is used as a broad concept that also includes the meaning of inhibiting the growth of bacteria even if it is not reduced. The “functional water” in the present invention means water obtained by adding a sterilization function in this sense to normal water by a predetermined treatment.
In this embodiment, an example in which electrolyzed water is used as the functional water in the present invention will be described. However, in place of electrolyzed water, sterilized water as described above other than electrolyzed water may be used. Needless to say.

<Control by controller>
Next, the control executed by the controller 40 in the embodiment of the present invention will be specifically described.

(First embodiment)
First, the control performed by the controller 40 in the first embodiment of the present invention will be described.

FIG. 7 is a time chart showing the basic control according to the first embodiment of the present invention. FIG. 7 shows, from the top, the sensor signal supplied from the sensor 14 to the controller 40, the drive signal supplied from the controller 40 to the second electromagnetic valve 28, and the drive supplied from the controller 40 to the first electromagnetic valve 25. The signal, the drive signal supplied to the electrolytic cell 37 from the controller 40, and the drive signal supplied to the LED 15 from the controller 40 are shown.
The sensor signal is turned on when the sensor 14 detects the detected object, and turned off when the sensor 14 does not detect the detected object (hereinafter, the sensor signal is turned on, the sensor 14 is turned on). The state in which the detected object is detected is referred to as “detected state”, and the state in which the sensor signal is off and the sensor 14 does not detect the detected object is referred to as “non-detected state”). The drive signal for the second solenoid valve 28 corresponds to the open / close state of the second solenoid valve 28, and the drive signal for the first solenoid valve 25 corresponds to the open / close state of the first solenoid valve 25. The driving signal for the electrolytic cell 37 corresponds to on / off of the electrolytic cell 37 (in other words, the operating / non-operating state of the electrolytic cell 37), and the driving signal for the LED 15 corresponds to the on / off state of the LED 15. To do.

  First, at time t11, the sensor signal is switched from OFF to ON, that is, the sensor 14 is switched from the non-detection state to the detection state. At this time, the controller 40 energizes the first electromagnetic valve 25 to open the first electromagnetic valve 25, and causes normal water to be spouted from the first water discharger 12. This foam water discharge is water discharge for washing a user's hand. Hereinafter, the water discharged for such a purpose is referred to as “hand-washing water discharge” as appropriate (in addition to the purpose of washing hands, the water discharge is not only used for washing the face, storing in the bowl 3, washing the toothbrush, etc.) It is used for various purposes such as, but for the purpose of distinguishing it from after-water discharge described later, the term “hand-wash water discharge” is used to represent hand-washing). At time t12, the sensor signal is switched from on to off, that is, the sensor 14 is switched from the detection state to the non-detection state. At this time, the controller 40 stops energization to the first electromagnetic valve 25 and closes the first electromagnetic valve 25 to end the foam water discharge from the first water discharger 12, that is, water for hand washing. Exit.

  Thereafter, when the non-detection state of the sensor 14 continues for a predetermined time T1 from time t12 when the foam water discharge as the hand-wash water discharge is completed, the controller 40 causes the second water discharge unit 13 to perform spray water discharge. This spray water discharge is performed to prevent the dirt that has flowed out by hand washing using the hand wash water discharge described above from becoming difficult to remove by drying and adhering to the bowl 3 or the like of the hand washing machine 5. (Hereinafter, water discharge performed for such a purpose is appropriately referred to as “after water discharge” as water discharged after hand-washing water discharge). That is, after a lapse of a predetermined time T1 from the end of the hand-washing water discharge, spray water discharge is performed as after-water discharge, and the dirt is washed away before the dirt from the hand-washing water discharge is dried and fixed. From such a point of view, the predetermined time T1 is set based on the time until the dirt due to the water for hand washing is dried and fixed. For example, the predetermined time T1 is set to 3 seconds.

  Specifically, the controller 40 first turns on the LED 15 at time t13 and irradiates the water discharge range R11 of the spray water discharged by the second water discharge unit 13 with the light of the LED 15 (see FIG. 4). The user is notified that water discharge is performed. Then, the controller 40 energizes the second electromagnetic valve 28 at the time t14 immediately after the time t13 (corresponding to the time after the elapse of the predetermined time T1 from the time t12 when the hand-washing water discharge is finished), and the second electromagnetic The valve 28 is opened, and at time t15 immediately after time t14, the electrolytic cell 37 is energized to generate electrolyzed water in the electrolytic cell 37, whereby the electrolyzed water is sprayed and discharged from the second water discharger 13. In other words, after water discharge. As described above, the energization of the electrolytic cell 37 is started after the energization of the second electromagnetic valve 28 without starting the energization of the second electromagnetic valve 28 and the electrolysis cell 37 at the same time. Electric power is consumed greatly at the timing of switching the electromagnetic valve 28 from the closed state to the open state, so that the electrolytic cell 37 is not energized at the timing of this switching, and an attempt is made to energize the electrolytic cell 37 while the power is stable. Is.

  Thereafter, at time t16 when a predetermined time T3 (for example, 1.9 seconds) has elapsed from time t14 when the second electromagnetic valve 28 is opened, the controller 40 stops energization of the electrolytic cell 37, and the electrolytic cell The generation of electrolyzed water at 37 is terminated. At this time, since the second electromagnetic valve 28 is still open, the spray water discharge from the second water discharge unit 13 is continuously performed. At time t17 after time t16, specifically, at time t17 when a predetermined time T2 (for example, 3.5 seconds) elapses from time t14 when the second electromagnetic valve 28 is opened, the controller 40 detects the LED 15 Is turned off and the irradiation of light from the LED 15 is terminated, and the energization of the second electromagnetic valve 28 is stopped and the second electromagnetic valve 28 is closed, whereby the spray from the second water discharger 13 is sprayed. End water discharge, that is, end after water discharge.

  Here, it is good to extend the life (endurance years) of the electrolytic cell 37 and to perform the control related to the above-mentioned after water discharge.

  In one example, the controller 40 performs after-water discharge every time the hand-wash water discharge is performed a predetermined number of times without performing after-water discharge every time hand-wash water discharge is performed. Specifically, the controller 40 counts the number of times that the hand-washing water discharge has been performed, and does not perform after-water discharge while the counted number of times does not reach the predetermined number of times, and when the counted number reaches the predetermined number of times. After water discharge is performed, the number of times counted at this time is reset, and the number of times water is discharged for hand washing is counted again. In this case, the controller 40 shall apply electrolyzed water when performing after-water discharge.

  In another example, the controller 40 performs after-water discharge every time hand-washing water is discharged, and performs after-water discharge to which electrolytic water is applied and after-water discharge to which electrolytic water is not applied (that is, after-water discharge to which normal water is applied). Switch appropriately. In this case, the controller 40 applies the electrolyzed water every time after-after water discharge is performed a predetermined number of times. Specifically, the controller 40 counts the number of times after-water discharge has been performed, and does not energize the electrolytic cell 37 while the number of times counted has not reached a predetermined number of times, thereby performing after-water discharge using normal water. When the number of times counted reaches a predetermined number, the electrolysis tank 37 is energized to perform after-water discharge using electrolyzed water, and the number of times counted after this is reset and the number of after-water discharge Count again.

  In yet another example, the controller 40 performs after-water discharge every time hand-washing water is discharged, but changes the energization time of the electrolytic cell 37 to perform after-water discharge. That is, the controller 40 changes the concentration of the electrolyzed water to be applied when performing after water discharge. Specifically, the controller 40 learns the usage frequency of the automatic faucet device 1 and adjusts the energization time of the electrolytic cell 37 based on this usage frequency. Specifically, the controller 40 shortens the energization time of the electrolytic cell 37 as the learned usage frequency increases, in other words, increases the energization time of the electrolytic cell 37 as the learned usage frequency decreases.

  In addition, although the control regarding the after-water discharge performed considering the lifetime (endurance years) of the electrolytic cell 37 was described above, it is not limited to performing such control and the bowl 3 of the hand-washer 5 is cleaned. You may perform control regarding after water discharge giving priority to keeping. In this case, the bowl 3 of the hand-washing machine 5 is soiled after the user has washed his / her hand. Therefore, the controller 40 should perform after-water discharge using electrolyzed water every time hand-washing water is discharged.

  Next, referring to FIG. 8, the electrolyzed water is generated only in the initial period (period T3 in FIG. 7) in the period for performing after-water discharge (period T2 in FIG. 7). The reason for flowing normal water without generating electrolyzed water in the later period will be described. FIG. 8 schematically shows the second flow path 18 and the second water discharger 13 on the upstream side of the electrolytic cell 37, and the state of the water in the second flow path 18 during the period of performing after-water discharge. Are shown in chronological order from left to right. In FIG. 8, the normal water and the electrolyzed water in the second flow path 18 are shown in different modes.

  First, at the start of after-water discharge, the controller 40 switches the second electromagnetic valve 28 from closed to open and starts energization to the electrolytic cell 37. Since it is filled with water, normal water is discharged from the second water discharger 13 (see FIG. 8A). Thereafter, the electrolyzed water generated in the electrolyzer 37 flows downstream through the second flow path 18 (see FIG. 8B), and when the electrolyzed water reaches the downstream end of the second flow path 18. That is, when the second water discharger 13 is reached (at this time, the inside of the second flow path 18 is filled with electrolyzed water), the electrolyzed water starts to be discharged from the second water discharger 13 (FIG. 8). (See (C)). Thereafter, the controller 40 stops energization of the electrolytic cell 37 in a state where the second electromagnetic valve 28 is kept open, and stops generation of electrolyzed water in the electrolytic cell 37. Then, normal water is supplied to the second flow path 18 and the electrolyzed water in the second flow path 18 is pushed out, so that the electrolyzed water is discharged from the second water discharger 13, and the second flow The electrolyzed water in the passage 18 is gradually replaced with normal water (see FIG. 8D). Finally, the electrolyzed water in the second flow path 18 is almost eliminated, and the second flow path 18 is filled with normal water (see FIG. 8E). At this time, the controller 40 switches the second electromagnetic valve 28 from open to closed to end the spray water discharge from the second water discharge unit 13, that is, end the after water discharge.

  Thus, in the present embodiment, the second flow path 18 is filled with normal water at the end of after water discharge using electrolyzed water. By doing so, corrosion (deterioration) of the second flow path 18 and the like due to the electrolyzed water staying in the second flow path 18 is suppressed. In this case, after stopping energization of the electrolytic cell 37, the controller 40 has the same amount of normal water or the same volume as the volume of the second flow path 18 (the volume including the second water discharger 13 may be used). By supplying the normal water to the second flow path 18 by keeping the second electromagnetic valve 28 open for the time required for a larger amount of normal water to flow through the second flow path 18, At the end of the after water discharge, a state in which the second flow path 18 is filled with normal water is created.

  In one example, when the volume of the second flow path 18 is 8 cc and the flow rate in the second flow path 18 is 5 cc per second, the second flow path 18 is filled with normal water. Since it takes 1.6 seconds, the controller 40 keeps the second electromagnetic valve 28 open for 1.6 seconds after stopping energization of the electrolytic cell 37, and supplies normal water to the second flow path 18. Supply. In this example, when the after-water discharge is performed for 3.5 seconds (corresponding to the predetermined time T2 shown in FIG. 7), the controller 40 performs the first 1.9 seconds (the predetermined time shown in FIG. 7). (Corresponding to T3), the electrolysis tank 37 is energized with the second electromagnetic valve 28 opened, and the second electromagnetic valve 28 is energized with the electrolysis tank 37 stopped for 1.6 seconds thereafter. Keep open. In such a case, normal water is discharged for the first 1.6 seconds, and electrolyzed water is discharged for the subsequent 1.9 seconds.

  In the example described above, 1.6 seconds is the minimum time required to fill the second flow path 18 with normal water after the energization of the electrolytic cell 37 is stopped. It is not limited to supplying the normal water to the second flow path 18 by keeping the second electromagnetic valve 28 open for 2 seconds, and the second electromagnetic valve 28 is opened for a time longer than 1.6 seconds. The normal water may be supplied to the second flow path 18 while maintaining the above. This is equivalent to supplying normal water in an amount larger than the volume of the second flow path 18 to the second flow path 18. In such a case, after the electrolyzed water is discharged, the normal water is discharged for a while, and the electrolyzed water discharged to the bowl 3 of the hand-washer 5 can be flushed with the normal water, and the bowl 3 or the eye plate is discharged. It becomes possible to suppress the influence of electrolyzed water.

In the above-described example, in the after water discharge, after the electrolyzed water is discharged from the second water discharge unit 13, the energization to the electrolytic cell 37 is stopped and the electrolyzed water is supplied to the second flow path 18. In the other example, after the electrolyzed water is discharged from the second water discharger 13, the energization of the electrolytic cell 37 is not stopped. It is also possible to reduce the energization power (meaning current or voltage) of the electrolytic cell 37 and supply the second flow path 18 with electrolyzed water having a low concentration instead of normal water.
In this case, the controller 40 first applies the first energizing power to the electrolytic cell 37 to generate the first concentration of electrolyzed water in the electrolyzer 37, and this electrolyzed water of the first concentration is generated. In the electrolytic cell 37, water is discharged from the second water discharger 13 through the second flow path 18, and then, a second conductive power lower than the first conductive power is applied to the electrolytic cell 37. Electrolyzed water having a second concentration lower than the first concentration is generated, and the electrolyzed water having the second concentration is supplied to the second flow path 18. For example, as the first concentration of electrolyzed water, electrolyzed water having a sufficient sterilization function is applied, and as the second concentration of electrolyzed water, the influence on the second flow path 18 and the like is considerably small. Electrolyzed water having a concentration (preferably electrolyzed water having a concentration capable of sufficiently diluting the electrolyzed water having the first concentration filled in the second flow path 18) is applied. Note that when the second energizing power applied to the electrolytic cell 37 is set to 0, the energization to the electrolytic cell 37 is stopped, the second concentration becomes 0, and the normal water is the second as in the example described above. Will be supplied to the flow path 18.
According to such another example, after the electrolysis water having a relatively high first concentration is discharged, the electrolysis water having a relatively low second concentration is supplied to the second flow path 18. The electrolyzed water can reduce the concentration of the electrolyzed water in the second flow path 18 and suppress corrosion (deterioration) of the second flow path 18 and the like caused by the electrolyzed water.

Next, with reference to FIG. 9 to FIG. 11, another control example performed based on the above-described basic control (see FIG. 7) in the first embodiment of the present invention will be described.

FIG. 9 is a time chart showing a first control example according to the first embodiment of the present invention. FIG. 9 shows the sensor signal supplied from the sensor 14 to the controller 40, the drive signal supplied from the controller 40 to the second electromagnetic valve 28, and the drive supplied from the controller 40 to the first electromagnetic valve 25 in order from the top. The signal is shown.
Here, the description of the same control as the basic control described above will be omitted as appropriate. Specifically, since the control from time t21 to time t22 and the control after time t24 are the same as the basic control, description thereof will be omitted, and only control from time t22 to time t24 will be described.

  The basic control described above executes after water discharge when a predetermined time T1 has elapsed since the handwash water discharge, but the first control example performs a predetermined time T1 after executing the handwash water discharge. This is related to the control performed when the sensor 14 is switched from the non-detection state to the detection state. Specifically, in the first control example, the controller 14 is switched from the non-detection state to the detection state at the time t23 before the predetermined time T1 elapses after the time t22 when the hand-washing water discharge ends. 40 energizes the first electromagnetic valve 25 to open the first electromagnetic valve 25, and causes the first water discharger 12 to discharge the foam. In this case, the controller 40 maintains the first electromagnetic valve 25 in the open state from time t23 when the detection state of the sensor 14 continues to time t24, and performs foam water discharge by the first water discharge unit 12. That is, water is discharged for hand washing.

  As described above, in the first control example, when the sensor 14 is in a detection state within the period until the after-water discharge after the hand-wash water discharge, the spray water discharge by the second water discharge unit 13 is not performed. The foam water discharge by the 1st water discharge part 12 is performed. In this way, when the sensor 14 is switched from the temporarily non-detection state to the detection state after the hand-wash water discharge is performed (for example, the user temporarily moves the hand outside the detection range of the sensor 14 during the hand-washing). In such a case, water discharge for hand washing is resumed without starting after water discharge. That is, the user can resume hand washing without waiting for the end of after-water discharge.

Next, FIG. 10 is a time chart showing a second control example according to the first embodiment of the present invention. FIG. 10 shows, in order from the top, the sensor signal supplied from the sensor 14 to the controller 40, the drive signal supplied from the controller 40 to the second electromagnetic valve 28, and the drive supplied from the controller 40 to the first electromagnetic valve 25. The signal is shown.
Here, the description of the same control as the basic control described above will be omitted as appropriate. Specifically, since the control from time t31 to time t33 and the control after time t35 are the same as the basic control, description thereof will be omitted, and only control from time t34 to time t35 will be described.

  The second control example relates to control performed when the sensor 14 is switched from the non-detection state to the detection state during the execution of after-water discharge. Specifically, in the second control example, when the sensor 14 is switched from the non-detection state to the detection state at time t34 during execution of the after water discharge, the controller 40 energizes the second electromagnetic valve 28. Stop and close the second electromagnetic valve 28 (when the electrolysis tank 37 is energized, the electrolysis tank 37 is also de-energized), stop spraying water discharge from the second water discharge section 13, and The first electromagnetic valve 25 is energized to open the first electromagnetic valve 25, and foam water is discharged from the first water discharge unit 12. That is, the controller 40 ends the after water discharge and starts the hand wash water discharge. In this case, the controller 40 maintains the first electromagnetic valve 25 in the open state from time t34 when the detection state of the sensor 14 continues to time t35, and performs foam water discharge by the first water discharge unit 12. . Then, the controller 40 energizes the second solenoid valve 28 at the time t36 when the non-detection state of the sensor 14 continues for a predetermined time T1 after the time t35 when the hand-washing water discharge is finished. 28 is opened, spray water discharge is performed by the second water discharge unit 13, that is, after-water discharge is resumed.

  As described above, in the second control example, when the sensor 14 is in a detection state during the after-water discharge, the spray water discharge by the second water discharge unit 13 is stopped and the foam water discharge by the first water discharge unit 12 is stopped. Do it, that is, stop after-water discharge and hand-wash water. By doing so, the user can perform hand washing without waiting for the end of the after water discharge. In addition, when electrolyzed water is applied to the user's hands, it may cause rough skin depending on the concentration of the electrolyzed water, or it may leave a smell peculiar to electrolyzed water (such as a chlorine odor). When the sensor 14 is in a detection state during the execution of the above, the after water discharge is stopped to prevent a problem that may occur due to such electrolyzed water being applied to the user's hand.

  Next, FIG. 11 is a time chart showing a third control example according to the first embodiment of the present invention. FIG. 11 shows the drive signal supplied to the second electromagnetic valve 28 from the controller 40 on the upper side, and shows the drive signal supplied to the electrolytic cell 37 from the controller 40 on the lower side. Here, the description of the same control as the basic control described above will be omitted as appropriate.

  In the basic control described above, it has been described that the energization of the electrolysis tank 37 is started after the energization of the second electromagnetic valve 28 is started without simultaneously energizing the second electromagnetic valve 28 and the electrolysis tank 37. In the third control example, in addition to this control, the controller 40 does not stop the energization of the second electromagnetic valve 28 and the energization of the electrolytic cell 37 at the same time. The energization of the second solenoid valve 28 is stopped. Specifically, the controller 40 energizes the second electromagnetic valve 28 at time t41, energizes the electrolytic cell 37 at time t42 immediately thereafter, stops energization of the electrolytic cell 37 at time t43, and immediately thereafter. At time t44, the energization of the second solenoid valve 28 is stopped. For example, the controller 40 stops energization of the electrolytic cell 37 and the second electromagnetic valve 28 in such a procedure when the sensor 14 is in a detection state during execution of after-water discharge that generates electrolytic water. .

  As described above, the energization of the second solenoid valve 28 is stopped after the energization of the electrolytic cell 37 is stopped without simultaneously stopping the energization of the second electromagnetic valve 28 and the energization of the electrolytic cell 37. Since a large amount of power is consumed at the timing of switching the second solenoid valve 28 from open to closed, the energization of the electrolytic cell 37 is already stopped at the timing of this switching, and the power is stabilized while the power is stable. The second solenoid valve 28 is to be operated. Note that, during the period in which both the second electromagnetic valve 28 and the electrolytic cell 37 are energized (period from time t42 to time t43), a large amount of electric power is consumed, so that the second electromagnetic valve 28 is supplied. The electric power to be used may be thinned out as appropriate. Specifically, the energization of the second electromagnetic valve 28 may be temporarily stopped. After the second solenoid valve 28 is once opened, the second solenoid valve 28 is hardly closed even if the energization to the second solenoid valve 28 is temporarily stopped. This is because the substantial valve open state of 28 can be maintained.

  Next, a control flow performed by the controller 40 in the first embodiment of the present invention will be described with reference to FIGS. FIG. 12 is a flowchart showing a control flow related to hand-washing water discharge according to the first embodiment of the present invention, and FIG. 13 shows after-water discharge according to the first embodiment of the present invention performed after the flowchart shown in FIG. It is a flowchart which shows the control flow which concerns. The control flow shown in FIGS. 12 and 13 is obtained by applying the first to third control examples (see FIGS. 9 to 11) to the basic control (see FIG. 7).

  First, the control flow relating to the water for hand washing according to the first embodiment of the present invention shown in FIG. 12 will be described.

  First, in step S11, the controller 40 determines whether or not the sensor signal from the sensor 14 has been switched from off to on, that is, whether or not the sensor 14 has been switched from the non-detection state to the detection state. As a result, when the sensor signal is not switched from OFF to ON (step S11: No), the determination in step S11 is performed again. That is, the controller 40 repeatedly performs the determination in step S11 until the sensor signal is switched from off to on.

  On the other hand, when the sensor signal is switched from OFF to ON (step S11: Yes), the process proceeds to step S12, where the controller 40 energizes the first electromagnetic valve 25 to open the first electromagnetic valve 25, The normal water is discharged from the first water discharge unit 12 in the form of foam water, that is, hand-wash water is discharged.

  Next, in step S13, the controller 40 determines whether the sensor signal from the sensor 14 has been switched from on to off, that is, whether the sensor 14 has been switched from the detection state to the non-detection state. As a result, when the sensor signal is not switched from on to off (step S13: No), the determination in step S13 is performed again. That is, the controller 40 repeatedly performs the determination in step S13 until the sensor signal is switched from on to off. In this case, the controller 40 continues the energization to the first electromagnetic valve 25 and keeps the first electromagnetic valve 25 open, thereby continuously discharging the water for hand washing.

  On the other hand, when the sensor signal is switched from on to off (step S13: Yes), the process proceeds to step S14, where the controller 40 stops energizing the first electromagnetic valve 25 and closes the first electromagnetic valve 25. And ends the foam water discharge from the first water discharge unit 12, that is, the hand wash water discharge ends. Thereafter, the process proceeds to step S20 shown in FIG.

  Next, a control flow relating to after-water discharge according to the first embodiment of the present invention shown in FIG. 13 will be described.

  First, in step S20, the controller 40 determines whether or not the sensor signal from the sensor 14 is OFF, that is, determines whether or not the sensor 14 is in a non-detection state. As a result, when the sensor signal is not off (step S20: No), that is, when the sensor signal is switched from off to on, the process returns to step S12 shown in FIG. In this case, as described above, the controller 40 energizes the first electromagnetic valve 25 to open the first electromagnetic valve 25 and causes normal water to be spouted from the first water discharger 12 for hand washing. Perform water discharge again.

  On the other hand, when the sensor signal is OFF (step S20: Yes), the process proceeds to step S21, and the controller 40 has passed 3 seconds (corresponding to the predetermined time T1 shown in FIG. 7) after finishing the hand-washing water discharge. Determine whether or not. As a result, when 3 seconds have not elapsed since the end of hand-washing water discharge (step S21: No), the process returns to step S20, and the determinations of steps S20 and S21 are performed again. In this case, the controller 40 waits for 3 seconds to pass while determining whether the sensor signal is off.

On the other hand, when 3 seconds have elapsed since the end of the hand-washing water discharge (step S21: Yes), the process proceeds to step S22, and the controller 40 turns on the LED 15. Immediately thereafter, in step S23, the controller 40 energizes the second electromagnetic valve 28 to open the second electromagnetic valve 28. Immediately thereafter, in step S24, the controller 40 energizes the electrolytic cell 37. Then, electrolyzed water is generated in the electrolytic cell 37. By carrying out like this, the controller 40 sprays electrolyzed water from the 2nd water discharging part 13, ie, performs after water discharging.
Strictly speaking, the controller 40 passes 3 seconds after ending handwash water discharge so that the second electromagnetic valve 28 opens when 3 seconds have passed since handwash water discharge was finished. The LED 15 is turned on at the previous time point, that is, when a predetermined time of less than 3 seconds has elapsed since the end of hand-washing water discharge.

  Next, in step S25, the controller 40 determines whether or not the sensor signal from the sensor 14 is off, that is, determines whether or not the sensor 14 is in a non-detection state. As a result, when the sensor signal is not off (step S25: No), that is, when the sensor signal is switched from off to on, the process proceeds to step S26. In this case, in step S <b> 26, the controller 40 stops energization to the electrolytic cell 37 and ends the generation of the electrolyzed water in the electrolytic cell 37. Immediately thereafter, in step S27, the controller 40 turns off the LED 15, stops the energization of the second electromagnetic valve 28, and closes the second electromagnetic valve 28. By carrying out like this, the controller 40 complete | finishes the spray water discharge from the 2nd water discharge part 13, ie, ends an after water discharge. Thereafter, the process returns to step S12 shown in FIG. 12, and the controller 40 energizes the first electromagnetic valve 25 to open the first electromagnetic valve 25 as described above. Usually, the water is discharged as foam and the water for hand washing is discharged again.

  On the other hand, when the sensor signal is off (step S25: Yes), the process proceeds to step S28, and the controller 40 starts 1.9 seconds after the start of after-water discharge (corresponding to the predetermined time T3 shown in FIG. 7). It is determined whether or not it has elapsed. As a result, when 1.9 seconds have not elapsed since the start of after-water discharge (step S28: No), the process returns to step S25, and the determinations of steps S25 and S28 are performed again. In this case, the controller 40 waits for 1.9 seconds to elapse while determining whether or not the sensor signal is off.

  On the other hand, when 1.9 seconds have elapsed since the start of after-water discharge (step S28: Yes), the process proceeds to step S29, where the controller 40 stops energization of the electrolytic cell 37 and performs electrolysis in the electrolytic cell 37. Finish the water production.

Next, in step S30, the controller 40 determines whether or not the sensor signal from the sensor 14 is OFF, that is, determines whether or not the sensor 14 is in a non-detection state. As a result, if the sensor signal is not off (step S30: No), that is, if the sensor signal is switched from off to on, the process proceeds to step S27. In this case, in step S27, the controller 40 turns off the LED 15, stops energization of the second electromagnetic valve 28, and closes the second electromagnetic valve 28. By carrying out like this, the controller 40 complete | finishes the spray water discharge from the 2nd water discharge part 13, ie, ends an after water discharge. Thereafter, the process returns to step S12 shown in FIG. 12, and the controller 40 energizes the first electromagnetic valve 25 to open the first electromagnetic valve 25 as described above. Usually, the water is discharged as foam and the water for hand washing is discharged again.

  On the other hand, when the sensor signal is OFF (step S30: Yes), the process proceeds to step S31, and the controller 40 starts 3.5 seconds after the start of after-water discharge (corresponding to the predetermined time T2 shown in FIG. 7). It is determined whether or not it has elapsed. As a result, when 3.5 seconds have not elapsed since the start of after-water discharge (step S31: No), the process returns to step S30, and the determinations of steps S30 and S31 are performed again. In this case, the controller 40 waits for 3.5 seconds while determining whether or not the sensor signal is off.

  On the other hand, when 3.5 seconds have elapsed since the start of after-water discharge (step S31: Yes), the process proceeds to step S32, and the controller 40 turns off the LED 15 and energizes the second electromagnetic valve 28. The operation is stopped and the second electromagnetic valve 28 is closed. By carrying out like this, the controller 40 complete | finishes the spray water discharge from the 2nd water discharge part 13, ie, ends an after water discharge.

(Operational effects of the first embodiment)
Next, the effect of the automatic water faucet device according to the first embodiment of the present invention will be described.

  According to the first embodiment, when the sensor 14 is in the detection state, water is discharged for hand washing, and when the sensor 14 is in the non-detection state, the water discharge for hand washing is terminated, and after that, water is discharged after (FIG. 7). See), after-water discharge can be performed properly when there is a possibility that the dirt flowing out by hand-washing using hand-washing water will adhere and adhere to the bowl 3 of the hand-washing machine 5, etc. While suppressing water discharge, it is possible to prevent such dirt from being dried and fixed in a state of being attached to the bowl 3 of the hand-washing device 5 or the like. Therefore, the bowl 3 etc. of the hand-washing machine 5 can be kept clean. In particular, according to the first embodiment, after water discharge is performed using electrolyzed water, the bowl 3 and the like of the handwasher 5 can be effectively kept clean.

  Moreover, although the water (sewage) which flowed out by the handwash using the handwash water discharge tends to fall in a wider range than the water discharge range of the handwash water discharge, according to the first embodiment, the foam water discharge used in the handwash water discharge After spraying using spray spray with a wider discharge angle of water from the water outlet, it is possible to discharge water over a wide range with a small flow rate, while effectively suppressing unnecessary water discharge. The bowl 3 and the like can be effectively kept clean. In this case, although it is difficult for the user to predict the water discharge range R11 of the spray water discharge, according to the first embodiment, the LED 15 irradiates the range R12 substantially the same as the water discharge range R11 of the spray water discharge (FIG. 4). Reference), the water discharge range R11 of the spray water discharge can be appropriately notified to the user, and it is possible to prevent the user from landing on a place not desired by the user. In particular, according to the first embodiment, the spray water discharge range R11 is notified to the user in advance by the light from the LED 15 before the spray water discharge is started (see FIG. 7). It is possible to effectively suppress water landing.

  In addition, according to the first embodiment, after the hand-washing water discharge is finished, after-water discharge is performed when the non-detected state of the sensor 14 continues for a predetermined time (see FIG. 7), the hand-washing water discharge ends and thereafter The user can be notified of the start of after-water discharge. If electrolyzed water from after-water discharge is applied to the user's hand, rough skin may occur depending on the concentration of the electrolyzed water, or odors peculiar to electrolyzed water (such as chlorine smell) may remain. In this way, by notifying the user of the start of after-water discharge, it is possible to appropriately prevent problems that may occur when the electrolytic water is applied to the user's hand.

  Moreover, according to 1st Embodiment, when the sensor 14 will be in a detection state before performing after-water discharge after hand-wash water discharge, since foam water discharge is performed without performing spray water discharge (refer FIG. 9). When the sensor is switched from a temporarily non-detection state to a detection state after handwash water discharge (for example, when the user temporarily moves his / her hand outside the detection range of the sensor 14 during handwashing), Without starting water discharge, water for hand washing can be restarted appropriately. That is, the user can resume hand washing without waiting for the end of after-water discharge.

  Moreover, according to 1st Embodiment, when the sensor 14 will be in a detection state during after water discharge, since spray water discharge is stopped and foam water discharge is performed, that is, after water discharge is stopped and hand water discharge is performed. (Refer to FIG. 10) The user can perform hand washing without waiting for the end of after-water discharge, and can prevent the problems that can occur when electrolytic water is applied to the user's hand as described above. .

  In addition, according to the first embodiment, when the after water discharge is started, the energization of the electrolytic cell 37 is started after the energization of the second electromagnetic valve 28 is started, and the electrolysis cell 37 is in a state where the power is stable. When the energization is started and the after water discharge is finished, the energization of the second electromagnetic valve 28 is stopped after the energization of the electrolytic cell 37 is stopped, and the second electromagnetic valve 28 is operated in a state where the power is stable. Since the operation is performed from opening to closing (see FIG. 11), it is possible to appropriately cope with a power source having a small capacity, and to reduce the size of the apparatus.

  In addition, according to the first embodiment, after every time handwashing water is discharged, after every time handwashing water discharge is performed a predetermined number of times, or after using the automatic faucet device 1 is learned. Thus, by adjusting the energization time of the electrolytic cell 37 based on the frequency of use, the load applied to the electrolytic cell 37 can be reduced, and the life (durable years) of the electrolytic cell 37 can be extended.

  Furthermore, according to the first embodiment, in the after discharge, after the electrolyzed water is discharged from the second water discharge unit 13, the energization of the electrolyzer 37 is stopped and the electrolyzed water to the second flow path 18 is stopped. Since the supply is stopped and normal water is supplied to the second flow path 18 (see FIGS. 7 and 8), the electrolyzed water in the second flow path 18 is discharged by the supplied normal water and the normal water is used. By replacing, the concentration of the electrolyzed water in the second flow path 18 can be reduced (when a sufficient amount of normal water is supplied, almost all of the electrolyzed water in the second flow path 18 is discharged. The inside of the second channel 18 can be filled with normal water). Thereby, corrosion (deterioration) of the second channel 18 and the like due to the electrolyzed water staying in the second channel 18 can be suppressed. Here, a method of adjusting the concentration of the electrolyzed water in order to suppress the corrosion of the second flow path 18 and the like can be considered, but in that case, it is necessary to adjust the electrolyzed water to such a concentration that the corrosion is suppressed. However, according to the first embodiment, normal water is supplied to the second flow path 18 as described above, so that electrolyzed water of various concentrations can be supplied without considering the corrosion of the second flow path 18 and the like. Can be applied.

  On the other hand, according to the first embodiment, since the sensor 14 is disposed so that the detection direction A23 of the sensor 14 is away from the water discharge direction A22 of the second water discharger 13, in other words, The sensor 14 is arranged so that the line L13 along the detection direction A23 of the sensor 14 does not intersect the line L12 extending in the vertical direction from the center of the second water discharge port 13a of the second water discharge unit 13 on the front side. (Refer to FIG. 5), the crossing with the water discharge range R11 of the second water discharge unit 13 at a portion where the detection accuracy in the directivity range R13 of the sensor 14 is considerably low (that is, a portion far from the sensor 14 in the directivity range R13). Therefore, it is possible to appropriately suppress erroneous water discharge due to the sensor 14 detecting water sprayed and discharged from the second water discharge port 13a.

  Moreover, according to 1st Embodiment, since the sensor 14 is arrange | positioned ahead of the 2nd water discharge port 13a of the 2nd water discharge part 13 (refer FIG.2 (B)), 2nd water discharge Compared to the case where the sensor 14 is disposed on the rear side of the second spout 13a of the unit 13, the user does not have to extend his hand to the rear side in order to cause the sensor 14 to detect his hand. . In addition, since the second water discharge port 13a is disposed on the rear side of the sensor 14 (see FIG. 2B), the second water discharge unit 13 of the second water discharge unit 13 is on the front side of the sensor 14. Compared with the case where the water outlet 13a is provided, the water sprayed and discharged from the second water outlet 13a of the second water discharger 13 is less likely to be applied to a portion of the user's arm or body that the user does not want to get wet.

  Further, according to the first embodiment, the tip C3 of the LED 15 is disposed on the rear side of the tip C1 of the sensor 14. In other words, the tip C1 of the sensor 14 is disposed in front of the tip C3 of the LED 15. Therefore, as compared with the case where the tip C3 of the LED 15 is disposed in front of the tip C1 of the sensor 14, the distance to the portion where the detection range of the sensor 14 and the irradiation range from the LED 15 overlap is longer. Since the light irradiation intensity is attenuated according to the distance, the irradiation intensity in the portion where the detection range of the sensor 14 and the irradiation range from the LED 15 overlap is low. Therefore, the water discharged from the water discharge port 13a of the second water discharger 13 can be appropriately irradiated with the light from the LED 15, and the tip C3 of the LED 15 is disposed on the front side of the tip C1 of the sensor 14. In comparison, erroneous water discharge caused by the sensor detecting light emitted from the LED 15 can be effectively suppressed.

  Moreover, according to 1st Embodiment, the front-end | tip C3 of LED15 is arrange | positioned in the back side rather than the front-end | tip C2 of the water outlet 13a of the 2nd water discharging part 13. As shown in FIG. In other words, the tip C2 of the water discharge port 13a of the second water discharger 13 is disposed in front of the tip C3 of the LED 15. According to this, since the light irradiated from the LED 15 has a larger influence on the sensor 14 than the water discharged from the water outlet 13a of the second water discharger 13, the tip of the water outlet 13a of the second water discharger 13 Compared to the case where the tip C3 of the LED 15 is disposed in front of the C2, the erroneous water discharge due to the sensor 14 detecting the light emitted from the LED 15 can be more effectively suppressed.

  Moreover, according to 1st Embodiment, the 1st water discharging part 12a of the 1st water discharging part 12, the 2nd water discharging opening 13a of the 2nd water discharging part 13, and the sensor 14 were provided in the front-end | tip part. In the faucet device 1, since the first water outlet 12a is disposed between the sensor 14 and the second water outlet 13a (see FIG. 2B), the sensor 14 and the second water outlet 13a. Can be separated from each other, and erroneous water discharge caused by the sensor 14 detecting water sprayed and discharged from the second water outlet 13a can be suppressed. In particular, according to the first embodiment, since the LED 15 is further disposed between the first water outlet 12a and the second water outlet 13a (see FIG. 2B), the sensor 14 and the second The water discharge port 13a can be further separated from the water discharge port 13a, and the erroneous water discharge as described above can be effectively suppressed. In addition, since the LED 15 is disposed in the vicinity of the second water discharge port 13a, the water discharge range R11 of the second water discharge unit 13 can be appropriately irradiated by the light from the LED 15.

  Moreover, according to 1st Embodiment, the 1st water discharging part 12 and the water discharging direction A21 of the 1st water discharging part 12, and the water discharging direction A22 of the 2nd water discharging part 13 face in the direction which leaves | separates mutually. Since each of the second water discharge portions 13 is disposed, in other words, a line L11 extending in the vertical direction from the center of the first water discharge port 12a and a line extending in the vertical direction from the center of the second water discharge port 13a. Since each of the 1st water discharging part 12 and the 2nd water discharging part 13 is arrange | positioned so that L12 may not cross on the front side (refer FIG. 5), it faces toward the downward direction from the 2nd water discharging part 13 Thus, it is possible to cause the water sprayed and discharged from the second water discharger 13 to be appropriately prevented from being applied to the user.

  Moreover, according to 1st Embodiment, since the 2nd water discharge port 13a is arrange | positioned in the back side rather than the 1st water discharge port 12a (refer FIG.2 (B)), from the 1st water discharge port 12a. It is possible to appropriately prevent the dripping of water from being applied to the second water discharge port 13a. In this case, according to the first embodiment, the water sprayed and discharged from the second water discharge port 13a by applying the direction of the second water discharge unit 13 in consideration of the position of the first water discharge port 12a. Can be appropriately prevented from being applied to the first water outlet 12a.

(Second Embodiment)
Next, control performed by the controller 40 in the second embodiment of the present invention will be described. In the first embodiment described above, only the foam water discharge from the first water discharge unit 12 is performed in the hand wash water discharge. In the second embodiment, the foam from the first water discharge unit 12 is used in the hand wash water discharge. In addition to water discharge, spray water discharge from the second water discharge unit 13 is also performed. Specifically, in the second embodiment, in the hand-washing water discharge, the controller 40 first performs spray water discharge from the second water discharge unit 13 for a predetermined time, and then performs foam water discharge from the first water discharge unit 12. Do.

  In the following description, the control similar to that in the first embodiment described above is omitted as appropriate, and only control different from that in the first embodiment is described. That is, control not specifically described here is the same as in the first embodiment.

FIG. 14 is a time chart showing the basic control according to the second embodiment of the present invention. FIG. 14 shows, in order from the top, a sensor signal supplied from the sensor 14 to the controller 40, a drive signal supplied from the controller 40 to the second electromagnetic valve 28, and a drive supplied from the controller 40 to the first electromagnetic valve 25. The signal, the drive signal supplied to the electrolytic cell 37 from the controller 40, and the drive signal supplied to the LED 15 from the controller 40 are shown.
Here, since the control after time t54 is the same as the basic control according to the first embodiment, the description thereof is omitted, and only the control from time t51 to time t54 will be described.

  First, at time t51, the sensor signal is switched from OFF to ON, that is, the sensor 14 is switched from the non-detection state to the detection state. At this time, the controller 40 energizes the second electromagnetic valve 28 to open the second electromagnetic valve 28 and to spray water from the second water discharger 13. In this case, the controller 40 sprays normal water from the second water discharger 13 without turning on the LED 15 or energizing the electrolytic cell 37, that is, without generating electrolytic water in the electrolytic cell 37. Let The controller 40 applies such spray water discharge as water discharge performed initially in water for hand washing. Then, the controller 40 stops energization of the second electromagnetic valve 28 at a time t52 when a predetermined time T5 (for example, 3 seconds) has elapsed from the time t51 when the spray water discharge from the second water discharger 13 is started. By closing the second electromagnetic valve 28, the spray water discharge from the second water discharge unit 13 is terminated.

  Then, at a time t53 when a certain amount of time (for example, 0.5 seconds) has elapsed from the time t52 when the spray water discharge from the second water discharger 13 is finished, the controller 40 energizes the first electromagnetic valve 25 to The first electromagnetic valve 25 is opened, and normal water is discharged from the first water discharge unit 12 in the form of foam. The controller 40 applies such foam water discharge as water discharge performed after spray water discharge in hand-washing water discharge. Thereafter, at time t54, the sensor signal is switched from on to off, that is, the sensor 14 is switched from the detection state to the non-detection state. At this time, the controller 40 stops energization of the first electromagnetic valve 25 and closes the first electromagnetic valve 25, and ends the foam water discharge from the first water discharge unit 12. By doing so, the water for hand washing is terminated. Thereafter, the controller 40 performs after-water discharge in the same procedure as in the first embodiment.

  In addition, it is good to be able to adjust predetermined time T5 which performs spray water discharge in the water discharge for hand-washing. Specifically, an adjustment unit such as a switch is provided in the automatic faucet device 1, and the usage environment of the automatic faucet device 1 (characteristics of the user of the automatic faucet device 1, installation location of the automatic faucet device 1, etc.) Accordingly, it is preferable that an administrator or the like can adjust the predetermined time T5 using the adjustment unit.

Next, a control flow performed by the controller 40 in the second embodiment of the present invention will be described with reference to FIG. FIG. 15 is a flowchart showing a control flow relating to water discharge for hand washing according to the second embodiment of the present invention.
Note that the control flow related to the after-water discharge shown in FIG. 13 described above is executed in the same manner even after the control flow related to the hand-washing water discharge according to the second embodiment ends.

  First, in step S41, the controller 40 determines whether or not the sensor signal from the sensor 14 has been switched from off to on, that is, whether or not the sensor 14 has been switched from the non-detection state to the detection state. As a result, when the sensor signal is not switched from OFF to ON (step S41: No), the determination in step S41 is performed again. That is, the controller 40 repeatedly performs the determination in step S41 until the sensor signal is switched from off to on.

  On the other hand, when the sensor signal is switched from OFF to ON (step S41: Yes), the process proceeds to step S42, and the controller 40 energizes the second electromagnetic valve 28 to open the second electromagnetic valve 28, Spraying water is discharged from the second water discharge unit 13. By doing so, water discharge for hand washing is started.

  Next, the process proceeds to step S43, and the controller 40 determines whether or not 3 seconds (corresponding to the predetermined time T5 shown in FIG. 14) has elapsed since the start of spray water discharge as hand-wash water discharge. As a result, if 3 seconds have not elapsed since the start of spray water discharge (step S43: Yes), the process proceeds to step S44, and the controller 40 determines whether or not the sensor signal from the sensor 14 has been switched from on to off. That is, it is determined whether or not the sensor 14 is switched from the detection state to the non-detection state. As a result, when the sensor signal is switched from on to off (step S44: Yes), the process proceeds to step S45, where the controller 40 stops energizing the second electromagnetic valve 28 and closes the second electromagnetic valve 28. The spray water discharge from the 2nd water discharge part 13 is complete | finished. Thereby, the water discharge for hand-washing will be complete | finished. Thereafter, the process proceeds to step S20 shown in FIG.

  On the other hand, when the sensor signal is not switched from on to off (step S44: No), the process returns to step S43, and the determinations of steps S43 and S44 are performed again. That is, the controller 40 waits for 3 seconds while determining whether or not the sensor signal has been switched from on to off. In this case, the controller 40 continues energizing the second electromagnetic valve 28 and maintains the open state of the second electromagnetic valve 28, thereby continuing the spray water discharge from the second water discharge unit 13. Do.

  On the other hand, when 3 seconds have elapsed since the start of spray water discharge (step S43: No), the process proceeds to step S46, where the controller 40 stops energization of the second electromagnetic valve 28 and the second electromagnetic valve 28. Is closed, and the spray water discharge from the second water discharge unit 13 is terminated.

  Subsequently, it progresses to step S47 and the controller 40 supplies with electricity to the 1st solenoid valve 25, opens the 1st solenoid valve 25, and starts the foam water discharge from the 1st water discharge part 12. FIG. In this case, the controller 40 starts such foam spouting after a predetermined time (for example, 0.5 seconds) has elapsed since the spray spouting was terminated.

Next, the process proceeds to step S48, where the controller 40 determines whether or not the sensor signal from the sensor 14 has been switched from on to off, that is, whether or not the sensor 14 has been switched from the detection state to the non-detection state. As a result, when the sensor signal is not switched from on to off (step S48: No), the determination in step S48 is performed again. That is, the controller 40 repeatedly performs the determination in step S48 until the sensor signal is switched from on to off. In this case, the controller 40 continues energization to the first electromagnetic valve 25 and maintains the open state of the first electromagnetic valve 25, thereby continuing the foam water discharge from the first water discharge unit 12. Do.

  On the other hand, when the sensor signal is switched from on to off (step S48: Yes), the process proceeds to step S49, where the controller 40 stops energizing the first electromagnetic valve 25 and closes the first electromagnetic valve 25. The foam water discharge from the first water discharge unit 12 is terminated. Thereby, the water discharge for hand-washing will be complete | finished. Thereafter, the process proceeds to step S20 shown in FIG.

  When the control flow according to the second embodiment is executed, when the determination in step S20 shown in FIG. 13 is “No” and after the control in step S27 is performed, step S47 shown in FIG. Return to. Specifically, also in the second embodiment, when the sensor 14 is in a detection state within a period until after-water discharge is performed after executing hand-wash water discharge, spray water discharge by the second water discharge unit 13 is performed. Without performing the foam water discharge by the first water discharge unit 12 and when the sensor 14 is in a detection state during the execution of the after water discharge, the spray water discharge by the second water discharge unit 13 is stopped, and the first water discharge Foam water discharge by the part 12 is performed.

(Operational effect of the second embodiment)
Next, the effect of the automatic water faucet device according to the second embodiment of the present invention will be described. Here, only the effects different from the above-described first embodiment will be described.

  According to the second embodiment, while the sensor 14 is detecting an object to be detected, spray water is discharged from the second water discharge unit 13 first, and the spray water discharge is started for a predetermined time T5 (for example, 3 seconds). ), The spray water spouting is stopped and the foam water spouting is performed from the first water spouting unit 12, and at first, hand spraying can be efficiently performed using the spray water spouting with a small flow rate but a high flow rate. Thereafter, not only hand washing but also face washing, water storage, etc. can be performed efficiently by using foam spout with a large flow rate. Therefore, it is possible to appropriately save water while ensuring user convenience. In particular, according to the second embodiment, the spray water discharge is automatically switched to the foam water discharge, so when performing an operation other than hand washing (face washing, water storage, etc.) or a relatively long time such as hand washing with soap. Even when the user performs an operation or the like, the user is automatically switched to the foam water spouting without performing a special operation or being aware of it, so that high convenience is ensured.

  Moreover, according to 2nd Embodiment, after stopping the spray water discharge from the 2nd water discharge part 13, a certain amount of time (for example, 0.5 second later), the foam water discharge from the 1st water discharge part 12 In other words, since the water is temporarily stopped between the spray water discharge and the foam water discharge, it is possible to notify the user of the end of the spray water discharge. As a result, the user can be given a kick to stop hand washing and the like, and water can be effectively saved.

  Moreover, according to 2nd Embodiment, since it comprised so that the predetermined time T5 which performs spray water discharge in the water discharge for hand-washing could be changed, according to the use environment of the automatic water faucet device 1, a user's convenience and water saving Depending on which is prioritized, the predetermined time T5 during which the spray water is discharged can be appropriately adjusted. For example, in an environment in which dirt that is difficult to remove adheres to the hand and a relatively long hand wash is required, the predetermined time T5 for spraying water discharge is shortened, giving priority to user convenience over water saving. it can.

  Further, according to the second embodiment, the sensor 14 stops detecting the detected object, and after the water discharge for washing the hand is stopped, the sensor 14 detects the detected object until a predetermined time T1 (for example, 3 seconds) elapses. When the water is detected, the spray water discharge from the second water discharge unit 13 is not performed again, but the foam water discharge from the first water discharge unit 12 is performed, so that the convenience of the user can be appropriately ensured. . For example, when the user temporarily moves his / her hand out of the detection range of the sensor 14 during hand washing and then tries to draw water with his hand or wash his hand with soap, he / she does not use water spray. Since water is discharged, convenience for the user can be ensured.

(Third embodiment)
Next, a third embodiment of the present invention will be described. In the first embodiment and the second embodiment described above, two water discharge sections (the first water discharge section 12 and the second water discharge section 12) are formed using two flow paths (the first flow path 17 and the second flow path 18). However, in the third embodiment, only one flow path and one water discharge part are used, and hand wash water discharge and water discharge (foam water discharge and spray water discharge) are performed in two forms. Perform both after-water discharge. Specifically, in the third embodiment, both hand-washing water discharge and after-water discharge are performed by this spray water discharge using only a water discharge unit capable of performing spray water discharge.

With reference to FIG. 17, the structure of the automatic water faucet apparatus which performs both the hand-washing water discharge and after-water discharge only by spray water discharge is demonstrated. FIG. 17A is a perspective view of an automatic faucet device according to a third embodiment of the present invention as viewed obliquely from below, and FIG. 17B is a cross-sectional view of the automatic faucet device of FIG. It is.
In addition, below, the same code | symbol is attached | subjected about the component same as the component (refer FIG. 2) of the automatic faucet device 1 by above-described embodiment, and those description shall be abbreviate | omitted suitably. That is, the components not specifically described here are the same as those of the automatic water faucet device 1.

As shown to FIG. 17 (A) and (B), the automatic water faucet device 1b by 3rd Embodiment does not comprise the 1st water discharging part 12 and the 1st flow path 17 for performing foam water discharging. The configuration differs from the automatic faucet device 1 according to the above-described embodiment in that only the second water discharger 13 and the second flow path 18 for performing spray water discharge are provided. The other configuration is almost the same as the automatic faucet device 1 according to the embodiment. Specifically, the automatic faucet device 1b according to the modified example 5 also includes the sensor 14 that detects an object to be detected and the LED 15 that emits light, like the automatic faucet device 1 according to the embodiment.
In the automatic faucet device 1b according to the modified example 5, the words “second” are attached to the “second water discharge portion 13” and the “second flow path 18”. It is not based on the presence of the water discharge part and the flow path, but because it has the same configuration as the second water discharge part 13 and the second flow path 18 of the automatic faucet device 1 according to the above-described embodiment. .

  Next, with reference to FIG. 18, the arrangement | positioning relationship of the 2nd water discharging part 13, the sensor 14, and LED15 by 3rd Embodiment is demonstrated. FIG. 18 is a cross-sectional view of the automatic faucet device 1b according to the third embodiment, similar to FIG.

  As shown in FIG. 18, in the third embodiment, similarly to the first embodiment and the second embodiment, the sensor 14 detects water sprayed and discharged from the second water discharge port 13 a of the second water discharge unit 13. The relationship of the direction of the sensor 14 and the 2nd water discharging part 13 which becomes difficult to do is employ | adopted. Specifically, since the detection accuracy of the sensor 14 decreases as the distance from the sensor 14 increases, a directivity range R13 (a range including the detection range of the sensor 14) corresponding to the detection direction A23 related to detection of the detection object by the sensor 14 is detected. The sensor 14 and the second water discharger 13 intersect the water discharge range R11 of the second water discharger 13 at a position distant from the front side. The orientation relationship is adopted. Specifically, the sensor 14 is disposed so that the detection direction A23 of the sensor 14 is directed away from the water discharge direction A22 of the second water discharger 13. In other words, a line L13 (typically corresponding to the central axis of the sensor 14) along the detection direction A23 of the sensor 14 extends in the vertical direction from the center of the second water discharge port 13a of the second water discharge unit 13. The sensor 14 is disposed so as not to cross the line L12 (typically corresponding to the central axis of the second water discharger 13) on the front side.

  Further, in the third embodiment, as in the first embodiment and the second embodiment, the sensor 14 is configured so that the hand can be appropriately detected by the sensor 14 even if the person does not reach the back so far. The second water discharger 13 is disposed on the front side of the second water discharge port 13a. In other words, the second water discharge port 13 a is disposed behind the sensor 14. By doing so, the water sprayed and discharged from the second water outlet 13a is less likely to be applied to a portion of the user's arm or body that is not desired to be wetted.

  Further, in the third embodiment, similarly to the first embodiment and the second embodiment, the sensor 14 is more difficult to detect water sprayed and discharged from the second water discharge port 13a of the second water discharge unit 13. In addition, the tip C5 of the sensor 14 is disposed on the rear side of the tip C4 of the water discharge port 13a of the second water discharger 13 with respect to the detection direction A23 of the sensor 14. In other words, the tip C4 of the water discharge port 13a of the second water discharger 13 is disposed in front of the tip C5 of the sensor 14. According to this, compared with the case where the tip C5 of the sensor 14 is disposed in front of the tip C4 of the water outlet 13a of the second water discharger 13 with respect to the detection direction A23 of the sensor 14, the second It is possible to more effectively suppress erroneous water discharge caused by the sensor detecting water discharged from the water discharge port 13a of the water discharge unit 13.

  In the third embodiment, similarly to the first embodiment and the second embodiment, the tip C6 of the LED 15 is in the detection direction A23 of the sensor 14 so that the sensor 14 is difficult to detect the light emitted from the LED 15. On the other hand, the sensor 14 is disposed on the rear side of the tip C5. In other words, the tip C5 of the sensor 14 is disposed in front of the tip C6 of the LED 15.

  Furthermore, in 3rd Embodiment, the front-end | tip C6 of LED15 is the 1st of the 2nd water discharging part 13 with respect to the detection direction A23 of the sensor 14, so that the sensor 14 becomes difficult to detect the light irradiated from LED15. It arrange | positions in the back side rather than the front-end | tip C4 of the 2 spout 13a. In other words, with respect to the detection direction A23 of the sensor 14, the tip C4 of the second water discharge port 13a of the second water discharger 13 is disposed in front of the tip C6 of the LED 15.

  Next, with reference to FIG. 19, the functional configuration of the automatic faucet device 1b according to the third embodiment of the present invention will be described. FIG. 19 is a block diagram schematically showing a functional configuration of an automatic faucet device 1b according to the third embodiment of the present invention.

  As shown in FIG. 19, the automatic faucet device 1 b according to the third embodiment is based on the above-described embodiment in that it does not include the first water discharge portion 12, the first flow path 17, and the first electromagnetic valve 25. The configuration is different from the automatic faucet device 1. In the automatic faucet device 1b according to the third embodiment, the controller 40 controls the opening and closing of the second electromagnetic valve 28 (the reason why the word “second” is attached is as described above). Then, the spray water discharge from the second water discharge unit 13 through the second flow path 18 is switched on / off.

  Next, control according to the third embodiment of the present invention will be described with reference to FIG. FIG. 19 is a time chart showing the control according to the third embodiment of the present invention. FIG. 20 shows, in order from the top, the sensor signal supplied from the sensor 14 to the controller 40, the drive signal supplied from the controller 40 to the second electromagnetic valve 28, the drive signal supplied from the controller 40 to the electrolytic cell 37, and the controller. The drive signal supplied to LED15 from 40 is shown.

  First, at time t61, the sensor signal is switched from OFF to ON, that is, the sensor 14 is switched from the non-detection state to the detection state. At this time, the controller 40 energizes the second electromagnetic valve 28 to open the second electromagnetic valve 28, and sprays normal water from the second water discharge unit 13. At time t62, the sensor signal is switched from on to off, that is, the sensor 14 is switched from the detection state to the non-detection state. At this time, the controller 40 stops energization of the second electromagnetic valve 28, closes the second electromagnetic valve 28, and ends the foam water discharge from the second water discharge unit 13, that is, the water for hand washing. Exit.

  Thereafter, when the non-detection state of the sensor 14 continues for a predetermined time T1 from time t62 when the spray water discharge as the hand-wash water discharge is completed, the controller 40 causes the second water discharge unit 13 to perform the spray water discharge again. Specifically, the controller 40 first turns on the LED 15 at a time t63, and at a time t64 immediately after the time t63 (corresponding to a time after a predetermined time T1 has elapsed from the time t62 when the hand-washing water discharge was terminated). Then, the second electromagnetic valve 28 is energized to open the second electromagnetic valve 28. And the controller 40 energizes the electrolysis tank 37 at the time t65 immediately after this time t64 to generate electrolyzed water in the electrolysis tank 37, thereby spraying the electrolyzed water from the second water discharger 13. That is, after-water discharge is performed.

  Thereafter, at time t66 when a predetermined time T3 (eg, 1.9 seconds) has elapsed from time t64 when the second electromagnetic valve 28 is opened, the controller 40 stops energization of the electrolytic cell 37, and the electrolytic cell The generation of electrolyzed water at 37 is terminated. At this time, since the second electromagnetic valve 28 is still open, the spray water discharge from the second water discharge unit 13 is continuously performed. At time t67 after time t66, specifically, at time t67 when a predetermined time T2 (for example, 3.5 seconds) elapses from time t64 when the second electromagnetic valve 28 is opened, the controller 40 detects the LED 15 Is turned off and the irradiation of light from the LED 15 is terminated, and the energization of the second electromagnetic valve 28 is stopped and the second electromagnetic valve 28 is closed, whereby the spray from the second water discharger 13 is sprayed. End water discharge, that is, end after water discharge.

(Operational effect of the third embodiment)
Next, the effect of the automatic water faucet device according to the third embodiment of the present invention will be described. Here, only the effects different from the above-described first embodiment will be described.

  According to 3rd Embodiment, the front-end | tip C5 of the sensor 14 is arrange | positioned in the back side rather than the front-end | tip C4 of the water outlet 13a of the 2nd water discharging part 13. As shown in FIG. In other words, the tip C4 of the water discharge port 13a of the second water discharger 13 is disposed in front of the tip C5 of the sensor 14. Therefore, compared with the case where the tip C5 of the sensor 14 is disposed in front of the tip C4 of the water discharge port 13a of the second water discharge unit 13, the detection range of the sensor 14 and the water discharge port 13a of the second water discharge unit 13. The density of the water discharge in the part which overlaps with the water discharge range from becomes low. Therefore, compared with the case where the tip C5 of the sensor 14 is disposed in front of the tip C4 of the water discharge port 13a of the second water discharge unit 13, the water discharged from the water discharge port 13a of the second water discharge unit 13 is reduced. It is possible to more effectively suppress erroneous water discharge due to detection by the sensor 14.

  In addition, in 3rd Embodiment, although the front-end | tip C5 of the sensor 14 is arrange | positioned in the back side rather than the front-end | tip C4 of the spout 13a of the 2nd water discharging part 13, the front-end | tip C5 of the sensor 14 and 2nd The tip C4 of the water discharge port 13a of the water discharge unit 13 may be disposed at the same position. Even in this case, the detection range of the sensor 14 and the discharge of the second water discharger 13 are compared to the case where the tip C5 of the sensor 14 is disposed in front of the water discharge 13a tip C4 of the second water discharger 13. The density of the discharged water in the part which overlaps with the discharged water range from the water mouth 13a becomes low. Therefore, compared with the case where the tip C5 of the sensor 14 is disposed in front of the tip C4 of the water discharge port 13a of the second water discharge unit 13, the water discharged from the water discharge port 13a of the second water discharge unit 13 is reduced. It is possible to more effectively suppress erroneous water discharge due to detection by the sensor 14.

<Modification>
Next, a modification of the above embodiment will be described. Note that the modifications described below can be applied to the above-described embodiment in an appropriate combination.

(Modification 1)
In 1st Embodiment and 2nd Embodiment mentioned above, although the foam water spouting was performed from the 1st water discharging part 12, it is not limited to applying foam water spouting. As a form of water discharge from the first water discharge unit 12, shower water discharged from a large number of water outlets having a small diameter in a shower shape, or linearly from one or more water outlets having a relatively large diameter Apply various water discharge forms such as straight water discharge to discharge water (strictly speaking, the foam water discharge shown in the above embodiment is included in this straight water discharge) and a water discharge form combining foam water discharge and shower water discharge Is possible.

(Modification 2)
In the first embodiment and the second embodiment described above, the water discharge from the first water discharge unit 12 and the second electromagnetic valve are performed using the two electromagnetic valves of the first electromagnetic valve 25 and the second electromagnetic valve 28. Although the water discharge from the water discharge part 13 was switched, you may switch the water discharge from the 1st water discharge part 12 and the water discharge from the 2nd water discharge part 13 using only one solenoid valve.

  With reference to FIG. 16, the functional configuration of an automatic water faucet device according to Modification 3 in the embodiment of the present invention using only one electromagnetic valve will be described. FIG. 16 is a block diagram schematically showing a functional configuration of an automatic water faucet device according to Modification 3 of the embodiment of the present invention. Here, the same components as those of the automatic faucet device 1 shown in FIG. 6 are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIG. 16, the automatic faucet device 1 a according to the modified example 3 includes an electromagnetic valve 51 and a switching valve 52 instead of the first electromagnetic valve 25 and the second electromagnetic valve 28. The configuration is different from the automatic faucet device 1 shown. The electromagnetic valve 51 is provided on the common flow path 21 and is opened and closed by control from the controller 40 to switch between normal water flow and blocking in the common flow path 21. The switching valve 52 is provided at a connection point between the common flow path 21 and the first flow path 17 and the second flow path 18, in other words, at a branch point at the downstream end of the common flow path 21. The switching valve 52 operates under the control of the controller 40 to switch the flow path through which normal water flows to either the first flow path 17 or the second flow path 18.

  The switching valve 52 described above is configured as an electric valve controlled by the controller 40, but instead of such a switching valve 52, a mechanical valve driven by water pressure is applied as the switching valve. May be. When a switching valve as a mechanical valve is applied, the opening of the electromagnetic valve 51 provided on the common flow path 21 upstream of the switching valve is adjusted to adjust the water pressure applied to the switching valve. Thus, the flow path for flowing normal water may be switched between the first flow path 17 and the second flow path 18.

(Modification 3)
In the first embodiment, the second embodiment, and the third embodiment described above, after water discharge is performed using electrolyzed water, but after water discharge is performed using normal water without using electrolyzed water. May be. In that case, the electrolytic cell 37 may not be provided on the second flow path 18. Even with such after-water discharge using normal water, it is possible to prevent the dirt that has flowed out by hand washing from adhering to the bowl 3 or the like of the hand-washing machine 5 and drying.

(Modification 4)
In the first embodiment, the second embodiment, and the third embodiment described above, after a predetermined time has elapsed after the stoppage of hand-washing water discharge, after-water discharge is performed (see FIG. 7 and FIG. 14). In other examples, after stopping hand-washing water discharge, after-water discharge may be performed without leaving a gap, that is, after-water discharge may be performed continuously with hand-washing water discharge.
In yet another example, after-water discharge may be started during execution of hand-wash water discharge, and the after-water discharge may overlap the hand-wash water discharge. In that case, water is discharged for hand washing while the sensor 14 is in the detection state. When the sensor 14 is switched from the detection state to the non-detection state, after the water discharge for hand washing is continued, What is necessary is just to overlap the completion | finish time of water discharge and the start time of after-water discharge. However, it is assumed that the hand-washing water discharge is stopped before the after-water discharge, in other words, the after-water discharge is stopped after the hand-washing water discharge is stopped.

(Modification 5)
In the first embodiment, the second embodiment, and the third embodiment described above, the automatic water faucet device according to the present invention is applied to the hand washing machine 5, but the application of the present invention is not limited to this. The automatic faucet device according to the present invention may be applied to a kitchen or the like. In such a case, by performing after-water discharge, it is possible to prevent the dirt (dirt water) generated by using the kitchen from drying and adhering to the sink or the like.

DESCRIPTION OF SYMBOLS 1, 1b Automatic water faucet device 3 Bowl 5 Hand wash basin 11 Water discharge pipe 12 1st water discharge part 12a 1st water discharge port 13 2nd water discharge part 13a 2nd water discharge port 14 Sensor 15 LED
17 1st flow path 18 2nd flow path 21 Common flow path 25 1st solenoid valve 28 2nd solenoid valve 37 Electrolyzer 40 Controller

Claims (5)

An automatic faucet device that automatically discharges water when it detects a detected object,
A sensor for detecting the detected object;
A water discharge part for discharging water so that water spreads at a predetermined angle from the water discharge port,
The tip of the automatic faucet device is provided with the water outlet of the sensor and the water discharger,
The automatic water faucet device, wherein the sensor is disposed such that a detection direction for detecting an object to be detected is directed in a direction away from the water discharge direction of the water discharge unit.   The automatic water faucet device according to claim 1, wherein the sensor is disposed in front of the water discharge port of the water discharge unit.   The automatic water faucet device according to claim 1 or 2, wherein the tip of the sensor is disposed at the same position as the tip of the water outlet of the water discharger or on the rear side of the tip of the water outlet of the water discharger. . It further has an illumination unit that irradiates water discharged from the water discharging unit with light,
The illumination unit is provided at the tip of the automatic faucet device,
The automatic faucet device according to any one of claims 1 to 3, wherein a tip of the illumination unit is disposed on a rear side of a tip of the sensor.   The automatic faucet device according to claim 4, wherein a tip of the illumination unit is disposed rearward of a tip of a water discharge port of the water discharge unit.

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