JP2021091456A - Liquid feeding device and nozzle for liquid feeding device - Google Patents

Abstract

To provide a liquid feeding device that can supply power to a nozzle light source without the use of an electrical connector and that allows the nozzle to be easily replaced.SOLUTION: A drink server 10 includes a nozzle 17 incorporating an LED 39 that generates ultraviolet light for sterilization, a main body device 29 to which the nozzle 17 is detachably attached, and a wireless power feeding part 80. The wireless power feeding part 80 includes a power receiving coil 58 deployed in the nozzle 17 and connected to the LED 39, and a power transmission coil 70 deployed in the main body device 29 to input AC.SELECTED DRAWING: Figure 6

Description

The present invention relates to a liquid feeder and a nozzle for the liquid dispenser installed as a drink server or the like in a drink bar or the like.

In the drink server, a small amount of drink may remain in the nozzle after the discharge of the drink from the nozzle is completed. The residual liquid is mixed with the next drink and discharged from the nozzle the next time the drink is discharged. However, if the time interval until the release of the next drink is long, bacteria will propagate in the residual liquid, and the quality of the next drink will tend to deteriorate.

Patent Document 1 discloses a sterilizer in which a light source of ultraviolet light is attached to a tip end portion of a nozzle and radiates ultraviolet light into the nozzle from the light source to perform sterilization. In the sterilizer, the power supply of the light source is performed by extending the wiring from the nozzle to the outside and from the external power source via the wiring.

JP-A-2018-61618

As in Patent Document 1, the problems when power is supplied to the light source at the tip of the nozzle via the external wiring are as follows.

(A) Since the external wiring is integrally connected to the nozzle, it is necessary to remove the wiring from the nozzle when replacing the nozzle. However, the work of removing the wiring from the nozzle is extremely complicated, and it is practically impossible to replace the nozzle.
(B) When the nozzle and the external wiring are electrically connected by a separable connector, the connector is exposed to the outside, and the electric connector needs to be waterproofed to prevent electric leakage. This leads to increased costs.
(C) Since the wiring is exposed to the outside, it looks bad.

The present invention has been made in view of the above problems, and provides a liquid feeder and a nozzle for a liquid donor which can supply power to the light source of the nozzle without using an electric connector and can easily replace the nozzle. The purpose is to provide.

The liquid feeder of the present invention
A main body device having a liquid feeding passage and a nozzle mounting portion provided at an outlet portion of the liquid feeding passage.
It has a passage forming member having a liquid receiving passage formed inside and having transparency, and a light source that radiates ultraviolet light from the outside of the passage forming member to the liquid receiving passage, and the liquid receiving passage is the said main body device. A nozzle detachably attached to the main body device so as to be connected to the liquid feeding passage, a power transmission coil arranged in the main body device, and a power transmission coil arranged in the nozzle and connected to the light source. Wireless power supply unit with a power receiving coil,
To be equipped.

According to the present invention, power is supplied from the main unit to the light source of the nozzle via a wireless power supply unit provided between the main unit and the nozzle. As a result, power can be supplied to the light source of the nozzle without using an electric connector, and the nozzle can be easily replaced.

Preferably, in the present invention
The nozzle has a cylindrical shape and has a flange portion that projects radially at the end portion on the main body device side.
The power receiving coil is arranged on the flange portion so as to orbit around the central axis of the nozzle.
The power transmission coil is arranged at a contact portion on the main body device side that comes into contact with the flange portion so as to be co-axis with the power receiving coil when the nozzle is attached to the main body device.

According to this configuration, when the nozzle is attached to the main body device, the power transmission coil and the power reception coil are co-axised, so that it is possible to secure a dimension that is not too small. As a result, wireless power supply can be realized with a sufficient amount of electric power between the main body device and the nozzle.

Preferably, in the present invention
The main body device has a control device that controls power supply to the power transmission coil.

According to this configuration, it is possible to appropriately control the emission timing of ultraviolet light from the light source.

Preferably, in the present invention
The control device is
A delivery detection unit that detects a delivery period and a non-delivery period of the liquid from the main body device to the nozzle.
A power supply switching unit that switches between a power supply period for supplying power to the power transmission coil and a non-power supply period for stopping power supply.
The transmission period includes the non-power supply period for the entire period, and the non-delivery period includes a switching control unit that controls the power supply switching unit so that the power supply period and the non-power supply period are alternately repeated.
To be equipped.

According to this configuration, the emission of ultraviolet light from the light source can be performed discretely during the non-delivery period of the liquid from the main body device to the nozzle. As a result, power consumption can be saved.

Preferably, in the present invention
The control device further
A storage unit is provided in which the time interval of generational change of bacteria that propagates in the residual liquid of the liquid receiving passage of the nozzle is written.
The switching control unit controls the power supply switching unit so that the length of each non-power supply period during the non-delivery period is shorter than the time interval read from the storage unit.

According to this configuration, this makes it possible to sterilize the previous generation and efficiently suppress the growth of the fungus before the generation of the fungus is replaced.

The nozzle for the liquid supply device of the present invention
A passage-forming member that is formed so that the liquid passes through the inside and has transparency to ultraviolet light.
A light source that is arranged outside the passage forming member and emits ultraviolet light inside the passage forming member.
It includes a power receiving coil that is electrically connected to the light source and is arranged on one end side of the passage forming member.

According to the present invention, when the nozzle for the liquid supply device is mounted on the liquid supply device together with the main body device, the power of the light source can be supplied from the main body device by wireless power supply. As a result, power can be supplied to the light source of the nozzle without using an electric connector, and the nozzle can be easily replaced.

It is a front view of a drink server. It is a block diagram of the server control device equipped with a drink server. It is a vertical sectional view of a nozzle. It is a structural drawing of the main body side which the nozzle of FIG. 3 is detachably attached. It is a schematic diagram when a nozzle is attached to a main body part. It is a block diagram of a server control device. It is an electric circuit diagram of a server control device. It is a flowchart of the main routine of the liquid control method in a drink server. It is a flowchart of a liquid supply processing routine. It is a flowchart of a sterilization process routine.

Hereinafter, preferred embodiments of the present invention will be described in detail. In addition, a code having the same number but different only in the alphabet of the subscript indicates that it is an element of a pair or the same group. In addition, when these elements are collectively referred to, the subscripts are omitted and only numbers are used.

(Drink server)
FIG. 1 is a front view of the drink server 10. The drink server 10 is installed in a restaurant, an employee cafeteria, or other eating and drinking facility, and provides a drink 18 to customers and related parties.

The drink server 10 includes a housing 11. The housing 11 has a main body portion 12, a container set portion 13, and a base portion 14 in this order from the top. The container set portion 13 is open to the outside in order to secure the taking in and out of the cup 15.

When the user intends to receive the drink 18 such as coffee or juice from the drink server 10, the cup 15 is inserted into the container set portion 13 and placed on the base 14 at a position directly below the nozzle 17. Then, press the liquid supply switch 16. After that, the drink 18 is discharged from the nozzle 17 into the cup 15, and when the discharge amount reaches a predetermined amount, the discharge is automatically stopped.

(Server control device)
FIG. 2 is a configuration diagram of a server control device 28 included in the drink server 10. The server control device 28 includes a nozzle 17 and a main body device 29. The main body device 29 is housed in the main body portion 12 (FIG. 1) of the housing 11.

The beverage tank 30 stores the beverage 18. The beverage tank 30 is a package type or a replenishment type, and stores the beverage 18 inside. In the case of the package type, when the beverage tank 30 becomes empty, the beverage tank 30 as a package is replaced with a new beverage tank 30. In the case of the fixed type, when the beverage tank 30 is empty, the cap is opened to replenish the beverage tank 30 with the beverage 18.

The liquid feeding passage 31 connects the beverage tank 30 and the nozzle mounting portion 32, and guides the beverage 18 of the beverage tank 30 to the nozzle mounting portion 32. The pump 33 is arranged in the liquid feeding passage 31, sucks the drink 18 from the beverage tank 30, and pumps the drink 18 to the nozzle mounting portion 32.

The nozzle 17 is detachably mounted on the nozzle mounting portion 32 of the main body device 29. The nozzle 17 includes a liquid receiving passage 38 through which the drink 18 passes, and an LED 39 that emits ultraviolet light. As the nozzle 17 is mounted on the nozzle mounting portion 32, the liquid receiving passage 38 is connected to the liquid feeding passage 31, and the drink 18 can be supplied from the liquid feeding passage 31 to the liquid receiving passage 38. ..

The control device 40 controls the pump 33 and the LED 39 based on an input signal or the like from the liquid supply switch 16.

(nozzle)
FIG. 3 is a vertical cross-sectional view of the nozzle 17. The nozzle 17 includes a cylindrical nozzle body 45 inside in the radial direction and a cover 46 that covers the outer peripheral portion of the nozzle body 45. The liquid receiving passage 38 extends into the nozzle body 45 along the central axis of the nozzle body 45 as a straight passage.

The nozzle body 45 is made of a material (eg, quartz) that transmits ultraviolet light at least at the tip (lower end in FIG. 3). The pair of protrusions 49 are formed on the outer peripheral portion of the base end portion (upper end portion in FIG. 3) of the nozzle body 45 at a distance of 180 ° from each other in the circumferential direction.

The cover 46 has a tubular portion 54 with a flange portion 53. The flange portion 53 is formed at the base end portion of the tubular portion 54 (the end portion on the tubular portion 54 side) and projects outward in the radial direction. The annular groove 57 is formed at a predetermined depth on the upper surface of the flange portion 53. The power receiving coil 58 is fitted and inserted into the annular groove 57 in a state of being wound so as to orbit around the central axis of the cylindrical nozzle body 45. The power receiving coil 58 may be in a state where the annular groove 57 is covered with a resin or the like. It prevents liquid from adhering and makes it easier to prevent problems such as short circuits.

A pair of recesses 59 are formed at the tip of the nozzle 17 between the outer peripheral portion of the nozzle body 45 and the inner peripheral portion of the cover 46. The pair of recesses 59 are located 180 ° apart from each other in the circumferential direction, and each recess 59 accommodates an LED 39 that emits ultraviolet light.

The LED 39 is operated by the electric power supplied from the power receiving coil 58. The ultraviolet light generated by the LED 39 radiates the liquid receiving passage 38 through the transmitting portion at the tip of the nozzle body 45. As will be described later, the residual liquid of the drink 18 and water droplets generated by dew condensation may adhere to the liquid receiving passage 38. Bacteria to be sterilized by irradiation with ultraviolet light propagate in residual liquid or the like.

(Power transmission side structure)
FIG. 4 is a structural diagram of the main body portion 12 side (nozzle mounting portion 32) to which the nozzle 17 of FIG. 3 is detachably mounted. The circular insertion hole 66 is formed in the lower wall 65 of the main body 12 at a position where the upper end of the nozzle 17 is inserted, and penetrates the lower wall 65.

When the nozzle 17 is mounted on the nozzle mounting portion 32 (FIG. 2), the portion of the lower wall 65 of the peripheral portion of the insertion hole 66 becomes the contact portion on the main body device 29 side with which the flange portion 53 contacts. The contact between the flange portion 53 and the contact portion is a surface contact.

The annular groove 69 is formed by opening on the upper surface of the lower wall 65 so as to be coaxial with the insertion hole 66. The power transmission coil 70 is wound around the central axis of the insertion hole 66 with the same circumference radius as that of the power reception coil 58, and is fitted in the annular groove 69.

(Detachment of nozzle)
FIG. 5 is a schematic view when the nozzle 17 is attached to the main body 12. Notches (not shown) are formed at two locations 180 ° apart in the circumferential direction on the peripheral edge of the insertion hole 66. The operator aligns the positions of the protrusions 49 at the upper end of the nozzle 17 with the positions of the notch holes in the lower wall 65 in the circumferential direction, and then pushes the nozzle 17 upward. As a result, the protrusion 49 passes through the notch hole and enters the inner peripheral side of the nozzle mounting portion 32 (FIG. 2) of the main body portion 12.

Next, the operator rotates the nozzle 17 in the circumferential direction by a predetermined amount. As a result, the protrusion 49 advances along the circumferential guide groove (not shown) on the inner surface of the nozzle mounting portion 32, is locked to the inner surface of the nozzle mounting portion 32, and the nozzle 17 to the nozzle mounting portion 32. Installation is completed. The nozzle 17 is detached from the nozzle mounting portion 32 in the reverse procedure of mounting.

(Server control device)
FIG. 6 is a block diagram of the server control device 28. The control device 40 includes a pump drive unit 75, a control unit 76, a power supply switching unit 77, and a storage unit 78.

The pump drive unit 75 controls the supply of the drive current to the pump 33 in response to the on operation of the liquid supply switch 16, and switches the execution and stop of the drive of the pump 33.

The period during which the pump drive unit 75 supplies the drive current to the pump 33 is the period during which the drink 18 is delivered to the nozzle 17. The period during which the pump drive unit 75 stops supplying the drive current to the pump 33 is a non-delivery period of the drink 18 to the nozzle 17. As a result, the pump drive unit 75 has a function of a transmission detection unit that detects a transmission period and a non-delivery period of the liquid supply switch 16 from the main body device 29 to the nozzle 17.

The power supply switching unit 77 switches between a power supply period for supplying power to the power transmission coil 70 of the wireless power supply unit 80 and a non-power supply period for stopping power supply. The control unit 76 controls the power supply switching unit 77 so that the entire transmission period is a non-power supply period and the non-delivery period alternately repeats the power supply period and the non-power supply period.

In the storage unit 78, data relating to the time interval of the alternation of generations of the bacteria that propagate in the residual liquid of the liquid receiving passage 38 of the nozzle 17 is written. The control unit 76 controls the on / off of the power supply switching unit 77 so that the length of each non-power supply period during the non-delivery period is shorter than the time interval of the generation change read from the storage unit 78.

In the nozzle 17, the power receiving coil 58 is connected to the LED 39. The power receiving coil 58 and the power transmission coil 70 form a wireless power feeding unit 80.

FIG. 7 is an electric circuit diagram of the server control device 28. The server control device 28 receives, for example, 24V AC from an external AC power supply 83.

The control device 40 includes an AC distributor 84, an AC-DC converter 85, an AC switch 86, a DC switch 87, an ON-OFF controller 88, and an electric connector 89. The AC distributor 84 distributes the AC from the AC power supply 83 to the AC-DC converter 85 and the AC switch 86.

The AC-DC converter 85 converts the alternating current from the AC distributor 84 into direct current. The AC switch 86 is interposed between the AC distributor 84 and the electric connector 89. The DC switch 87 is interposed between the AC-DC converter 85 and the electric connector 89. The ON-OFF controller 88 controls the AC switch 86 and the DC switch 87 based on the signal from the liquid supply switch 16.

The electrical connectors 89 and 90 are separably connected. The electric connector 90 is connected to the power transmission coil 70. The electrical connector 90 is also connected to the pump 33 via a terminal connection 92.

The AC-DC converter 95 and the constant current circuit 96 are built in the nozzle 17 together with the LED 39. The AC-DC converter 95 and the constant current circuit 96 are interposed between the LED 39 and the power receiving coil 58.

(Wireless power supply)
When the AC switch 86 is on, the power transmission coil 70 receives alternating current from the AC distributor 84 via the electrical connectors 89 and 90 to change the magnetic flux. This change in magnetic flux is transmitted wirelessly to the power receiving coil 58 of the nozzle 17, and the power receiving coil 58 generates alternating current.

The alternating current generated by the power receiving coil 58 is converted to direct current in the AC-DC converter 95. The constant current circuit 96 generates a constant current from the direct current output by the AC-DC converter 95 and outputs the constant current to the LED 39. The LED 39 generates ultraviolet light by the constant current supplied from the constant current circuit 96. The LED 39 may have a configuration in which a plurality of LEDs are connected in antiparallel so as to receive an alternating current generated by the power receiving coil 58 and emit light.

(Liquid control method)
FIG. 8 is a flowchart of the main routine of the liquid control method in the drink server 10.

In step S101, the control unit 76 determines whether or not the power of the drink server 10 has been turned on. If the result of the determination is positive (YES), the control unit 76 advances the process to step S102, and if the result of the determination is negative (NO), the control unit 76 repeats step S101 until the result of the determination becomes positive.

Next, the control unit 76 sequentially executes the liquid supply processing routine in step S102 and the sterilization processing routine in step S103.

In step S104, the control unit 76 determines whether or not the power of the drink server 10 has been turned off. If the result of the determination is positive, the control unit 76 ends the main routine, and if the result of the determination is negative, returns the process to step S102.

FIG. 9 is a flowchart of the liquid supply processing routine.

In step S110, the control unit 76 determines whether or not the liquid supply switch 16 has been switched from off to on. If the determination is positive, the control unit 76 advances the process to step S111, and if the determination is negative, the control unit 76 ends the routine (returns to the main routine).

In step S111, the control unit 76 forcibly terminates the wireless power supply. Specifically, the control unit 76 turns off the power supply switching unit 77 (AC switch 86) to forcibly terminate the wireless power supply. This is a step for terminating the wireless power supply when the liquid supply switch 16 is switched on.

In step S112, the pump drive unit 75 starts driving the pump 33. Specifically, the pump drive unit 75 starts driving the pump 33 by turning on the DC switch 87 and starting to supply the drive current to the pump 33.

In step S113, the pump drive unit 75 determines whether or not the drive time To of the pump 33 exceeds the predetermined value Cp. To = Cp means that the amount of the drink 18 released from the nozzle 17 in FIG. 1 has reached a predetermined value, and the specified amount of the drink 18 has been supplied into the cup 15.

The pump drive unit 75 repeats the determination in step S113 until the determination in step S113 becomes affirmative. Then, as soon as the determination becomes positive, the process proceeds to step S114.

In step S114, the pump drive unit 75 stops driving the pump 33 in step S114. As a result, the discharge of the drink 18 from the nozzle 17 to the cup 15 is stopped.

Although the discharge of the drink 18 from the nozzle 17 is interrupted, a part of the drink 18 remains attached to the liquid receiving passage 38 of the nozzle 17 without being discharged from the nozzle 17. The drink 18 remaining in this way is mixed with the drink 18 to be discharged next when the next liquid supply switch 16 is turned on, and is discharged from the nozzle 17.

However, if the time interval until the next operation of turning on the liquid supply switch 16 becomes long, bacteria may propagate in the residual liquid, leading to deterioration of the quality of the drink 18. Further, even if there is no residual liquid in the liquid receiving passage 38 on the inner surface of the nozzle 17, water vapor in the atmosphere may adhere to the liquid receiving passage 38 due to dew condensation and bacteria may propagate. Since the bacteria are mixed with the next drink 18 when the next drink 18 is released, this also leads to a deterioration in the quality of the drink 18.

Therefore, it is desirable to sterilize the residual liquid by periodically irradiating the residual liquid with ultraviolet light during the non-emission period of the drink 18 from the nozzle 17. The sterilization process will be described in the sterilization process routine of FIG. 10 below.

The control unit 76 resets the measurement time Tc of the power supply timer in step S116, and further starts the measurement of the power supply timer in the next step S117. The power supply timer is used to detect the length of the non-power supply period of the wireless power supply unit 80 in the sterilization processing routine of FIG. 10 below.

FIG. 10 is a flowchart of the sterilization processing routine.

In step S121, the control unit 76 determines whether or not the measurement time Tc exceeds the predetermined value C1. The predetermined value C1 is stored in advance in the storage unit 78 as the time for the alternation of generations of the bacteria.

If the length of the non-irradiation time of the ultraviolet light from the nozzle 17 exceeds the predetermined value C1, a large amount of bacteria in the residual liquid in the liquid receiving passage 38 of the nozzle 17 will proliferate, and the irradiation time of the ultraviolet light will be increased. It will be necessary to increase it significantly or increase the intensity of ultraviolet light significantly. Therefore, for efficient sterilization treatment, the residual liquid may be irradiated with ultraviolet light at intervals shorter than C1.

If the determination in step S121 is positive, the control unit 76 advances the process to step S122, and if it is negative, the control unit 76 ends the routine.

In step S122, the control unit 76 executes wireless power supply for a certain period of time. Specifically, the control unit 76 switches the power supply switching unit 77 (AC switch 86) on and supplies AC to the power transmission coil 70 to perform wireless power supply.

In step S123, the control unit 76 ends the wireless power supply. Specifically, the control unit 76 ends the wireless power supply by switching off the power supply switching unit 77 (AC switch 86) and stopping the supply of AC to the power transmission coil 70.

In step S124, the control unit 76 resets the measurement time Tc of the power supply timer, and starts the measurement of the power supply timer in the next step S125. The power supply timer is used to measure the length of non-irradiation time of ultraviolet light.

The control unit 76 ends the routine (returns to the main routine) after the process of step S124 is executed.

(Modification example)
The drink server 10 is an embodiment of the liquid providing device of the present invention. The liquid providing device of the present invention is not limited to the drink server 10, and is also applicable to a liquid providing device that provides a liquid other than a drink (eg, chemicals or washing water).

In the embodiment, the nozzle body 45 as a passage forming member in which the liquid receiving passage 38 is formed is made of quartz in which only the tubular portion on the tip side where the LED 39 is arranged on the outside has transparency to ultraviolet light. It is made. However, the entire nozzle body 45 can be made into a cylindrical member having transparency to ultraviolet light such as quartz.

In the embodiment, only the pump 33 is provided in the liquid feeding passage 31, but an on-off valve may be provided on the downstream side of the pump 33. Then, by switching the opening / closing of the on-off valve, it is possible to switch between delivery and non-delivery of the drink 18. In that case, an open valve is provided in parallel with the pump 33, and when the on-off valve is in the closed position and the discharge pressure of the pump 33 exceeds a predetermined value, the drink 18 circulates in the loop between the pump 33 and the open valve. Can be configured to do so.

In the embodiment, the pump 33 is provided in the liquid feeding passage 31, but the beverage tank 30 is arranged at a position higher than the nozzle 17, and the drink 18 is guided from the beverage tank 30 to the nozzle 17 by gravity to push the pump 33. It can be omitted. In that case, the delivery and non-delivery of the drink 18 are switched by the on-off valve.

In the embodiment, the LED 39 is adopted as a light source that emits ultraviolet light. The light source of the present invention is not limited to the LED 39, and a light source that emits ultraviolet light other than the LED 39 can also be used.

In the embodiment, the power receiving coil 58 and the power transmission coil 70 have an arrangement relationship along the direction of the central axis of the nozzle with the central axis of the nozzle as the co-axis when the nozzle 17 is attached to the nozzle mounting portion 32. Instead, for each orbital radius of the power receiving coil 58 and the power transmission coil 70, one of the power receiving coil 58 and the power transmission coil 70 is made larger than the other, and the nozzle to the nozzle mounting portion 32 is set. When the 17 is mounted, the mounting structure may be such that the central axis of the nozzle is a common axis and the nozzles are arranged radially outside and inside with respect to the center axis of the nozzle.

10 ... drink server, 16 ... liquid supply switch, 17 ... nozzle, 18 ... drink, 28 ... server control device, 29 ... main unit device, 31 ... liquid supply passage, 32 ... Nozzle mounting part, 33 ... Pump, 38 ... Liquid receiving passage, 39 ... LED (light source), 40 ... Control device, 45 ... Nozzle body, 46 ... Cover, 53 ... Flange part, 54 ... Cylinder part, 58 ... Power receiving coil, 65 ... Lower wall, 69 ... Circular groove, 70 ... Power transmission coil, 75 ... Pump drive unit, 76 ... control unit, 77 ... power supply switching unit, 78 ... storage unit, 80 ... wireless power supply unit, 83 ... AC power supply, 86 ... AC switch, 87.・ ・ DC switch, 88 ・ ・ ・ ON-OFF controller, 89, 90 ・ ・ ・ Electric connector.

Claims (8)

A main body device having a liquid feeding passage and a nozzle mounting portion provided at an outlet portion of the liquid feeding passage.
It has a passage forming member in which a liquid receiving passage is formed inside and has transparency, and a light source that radiates ultraviolet light from the outside of the passage forming member to the liquid receiving passage, and the liquid receiving passage is the said main body device. A nozzle that is detachably attached to the nozzle mounting portion of the main body device so as to be connected to the liquid feeding passage is provided.
Further, a power transmission coil is arranged in the nozzle mounting portion of the main body device.
A power receiving coil electrically connected to the light source is arranged on the nozzle mounting portion side of the nozzle.
A liquid supply device constituting a wireless power feeding unit in which electric power is supplied from the power transmitting coil to the power receiving coil. In the liquid providing device according to claim 1,
The nozzle has a cylindrical shape and has a flange portion that projects radially at the end portion on the main body device side.
The power receiving coil is arranged on the flange portion so as to orbit around the central axis of the nozzle.
The power transmission coil is characterized in that it is arranged at a contact portion on the main body device side that comes into contact with the flange portion so as to be co-axis with the power receiving coil when the nozzle is attached to the main body device. Liquid supply device. In the liquid providing apparatus according to claim 1 or 2.
The main body device is a liquid providing device including a control device for controlling power supply to the power transmission coil. In the liquid providing apparatus according to claim 3,
The control device is
A delivery detection unit that detects a delivery period and a non-delivery period of the liquid from the main body device to the nozzle.
A power supply switching unit that switches between a power supply period for supplying power to the power transmission coil and a non-power supply period for stopping power supply.
The transmission period includes the non-power supply period for the entire period, and the non-delivery period includes a switching control unit that controls the power supply switching unit so that the power supply period and the non-power supply period are alternately repeated.
A liquid donor device comprising. In the liquid providing apparatus according to claim 4,
The control device further
A storage unit is provided in which the time interval of generational change of bacteria that propagates in the residual liquid of the liquid receiving passage of the nozzle is written.
The liquid supply switching unit controls the power supply switching unit so that the length of each non-power supply period during the non-delivery period is shorter than the time interval read from the storage unit. apparatus. A passage-forming member that is formed so that the liquid passes through the inside and has transparency to ultraviolet light.
A light source that is arranged outside the passage forming member and emits ultraviolet light inside the passage forming member.
A nozzle for a liquid providing device, comprising: a power receiving coil electrically connected to the light source and arranged on one end side of the passage forming member. In the nozzle for the liquid supply device according to claim 6.
It has a flange portion that projects radially on the one end side of the passage forming member.
The liquid feeding device nozzle is characterized in that the power receiving coil is arranged on the flange portion so as to orbit around the central axis of the liquid feeding device nozzle. In the nozzle for the liquid feeder according to claim 6 or 7.
The light source is an LED, and a nozzle for a liquid providing device comprising a circuit for converting an alternating current into a direct current between the LED and the power receiving coil.

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