JP6825904B2 - Water sampling dispenser, adapter and pure water production equipment - Google Patents

Description

The present invention includes a water sampling dispenser that is connected to a pure water producing apparatus or the like and discharges pure water according to demand, an adapter that can be attached to the water sampling dispenser or the like, and a pure water containing such a water sampling dispenser or adapter. Regarding manufacturing equipment.

When pure water is used in research institutes, pure water is often produced using a relatively small pure water production device. At the point of use, a water sampling dispenser connected to a pure water production apparatus is widely used to sample pure water into, for example, a beaker, a flask, a test tube, or the like. The water sampling dispenser includes a nozzle for discharging pure water and an on-off valve provided in the path of pure water to the nozzle to supply pure water to the nozzle and shut off the supply. The water sampling dispenser is usually provided at a place away from the main body of the pure water production apparatus, and is connected to the pure water outlet of the main body of the pure water production apparatus by a pipe. When the user operates the on-off valve, pure water is discharged from the nozzle, whereby the user can collect pure water in an amount as required. As the on-off valve, a manual valve can be used, but a solenoid valve can also be used. The manual on-off valve is not limited to a valve operated by hand, and includes, for example, a valve operated by a foot pedal or the like. When a solenoid valve is used, the solenoid valve is controlled by a push button switch that can be operated with a finger or a foot switch that can be operated by a foot, and pure water is discharged from a nozzle. Furthermore, by combining the flow rate sensor and the solenoid valve, the solenoid valve is opened until the flow rate measured by the flow rate sensor reaches the specified value when there is one switch operation, so that the specified amount of pure water can be obtained. Water can also be sampled. Patent Document 1 discloses a water sampling dispenser capable of exchanging nozzles according to a water sampling amount, and a nozzle configuration for each water sampling amount.

In fields such as bioscience, if the number of viable bacteria in pure water is large, the results of experiments and analysis will be affected, so it is necessary to reduce the number of viable bacteria in pure water. Therefore, conventionally, an ultraviolet sterilizer has been provided inside the pure water production apparatus. For example, in Patent Document 2, the water to be treated is sterilized by irradiating the water to be treated with ultraviolet rays generated by an ultraviolet LED (light emitting diode) in a pure water production apparatus that treats the water to be treated to produce pure water. It discloses that it incorporates a UV sterilizer to perform. Further, as a device for sterilizing water used in a laboratory or the like, Patent Document 3 discloses a device in which an ultraviolet light source composed of an ultraviolet LED is provided at the end of a tube and water is passed through the tube for sterilization. Therefore, Patent Document 4 discloses a configuration in which an ultraviolet light source composed of an ultraviolet LED is provided on a lid portion of a container to sterilize the water to be treated in the container.

Patent Document 5 describes in a sampling valve for collecting pure water from a pure water pipe for water quality control of pure water used in the pharmaceutical field, sterilizing or sterilizing the microorganisms remaining in the valve after sampling the pure water. It is disclosed that the pipeline is branched from the pipe and a light source for irradiating the inside of the pipeline with ultraviolet rays is provided so as to be able to do so.

Japanese Unexamined Patent Publication No. 2013-180285 JP-A-2016-123930 Special Table 2016-523594 Special Table 2016-525906 Gazette International Publication No. 2016/002475

In research institutes and the like, the amount of pure water used per day is relatively small, and therefore, in many cases, the pure water production device is operated to collect water only when pure water is required. However, when the pure water production apparatus is operated discontinuously in this way, even if the pure water production apparatus is equipped with an ultraviolet sterilizer, water will be discharged into the apparatus or piping when the apparatus is stopped. Since it stays, there is a risk that live bacteria will grow in pure water.

An object of the present invention is a water sampling dispenser capable of constantly supplying pure water in which the number of viable bacteria contained is reduced, and an adapter that can be used to construct a device such as such a water sampling dispenser. It is an object of the present invention to provide a pure water production apparatus capable of constantly supplying pure water with a reduced number of viable bacteria contained therein.

The water sampling dispenser of the present invention is a water sampling dispenser used for sampling pure water, and is an on-off valve connected to a pure water source, a nozzle for discharging pure water, and a flow for connecting the nozzle to the outlet of the on-off valve. It has a road and an ultraviolet LED arranged so as to irradiate the pure water flowing through the flow path with ultraviolet rays.

The adapter of the present invention is an adapter suitable for a device having a nozzle that is detachably connected to an on-off valve and an on-off valve outlet to discharge a liquid from the on-off valve, and is provided with a flow path and is an on-off valve outlet. It has a housing that can be detachably connected to and the nozzle is detachably connected to, and an ultraviolet LED that is arranged to irradiate the liquid flowing through the flow path with ultraviolet rays, and the flow path has the outlet of the on-off valve and the nozzle. And communicate with.

The pure water production apparatus of the present invention is characterized by comprising the water sampling dispenser of the present invention or the adapter of the present invention.

According to the present invention, it is possible to constantly supply pure water with a reduced number of viable bacteria contained in the structure so that the pure water can be irradiated with ultraviolet rays at a position immediately before the nozzle for discharging the pure water. Become.

It is a figure which shows an example of the structure of a pure water production apparatus. It is a figure which shows the water sampling dispenser of 1st Embodiment of this invention, (a) is a plan view, (b) is a front view. It is a figure which shows the circuit structure of the water sampling dispenser of 1st Embodiment. It is a figure which shows the circuit structure of the water sampling dispenser of 2nd Embodiment. It is a figure which shows the water sampling dispenser of 3rd Embodiment. It is a figure which shows the arrangement in an Example.

Next, a preferred embodiment of the present invention will be described with reference to the drawings. Before the water sampling dispenser based on the present invention is specifically described, first, a pure water production apparatus to which the water sampling dispenser is connected will be described. FIG. 1 shows an example of the configuration of a pure water production apparatus to which a water sampling dispenser based on the present invention can be connected.

The pure water production apparatus shown in FIG. 1 is provided with a subsystem (secondary pure water system) for circulating purification, and is connected to a storage tank 10 to which primary pure water is supplied and a storage tank 10 connected to an outlet of the storage tank 10. A non-mixed bed in which a pump 11 for supplying pure water in 10 and an ultraviolet oxidizing device (UV) 12 connected to the outlet of the pump 11 and a strongly acidic cation exchange resin and a strongly basic anion exchange resin are filled. It includes a regenerative ion exchange device (CP: also referred to as a cartridge polisher) 13 and an ultrafiltration device (UF) 14 connected to the outlet of the non-regenerative ion exchange device 13. A circulation pipe 15 from the outlet of the ultrafiltration device 14 to the storage tank 10 is provided, and the storage tank 10 passes through the ultraviolet oxidizing device 12, the non-regenerative ion exchange device 13, and the ultrafiltration device 14 from the storage tank 10 via the pump 11. A circulation purification system is constructed. As the primary pure water, for example, water obtained by passing city water through a filter, an activated carbon treatment device and an ion exchange device is used.

In this pure water production apparatus, pure water is further purified by operating the pump 11 to circulate the pure water in the circulation purification system. A pipe 16 heading to the use point branches from the circulation pipe 15, and a water sampling dispenser 20 based on the present invention is provided at the end of the pipe 16. The details of the configuration of the water sampling dispenser 20 will be described later, but the water sampling dispenser 20 is provided with a solenoid valve 21 as an on-off valve connected to a pure water source. Other types of on-off valves may be used instead of the solenoid valve 21. The connection position of the water sampling dispenser 20 to the circulation purification system is not limited to the circulation pipe 15, and for example, the water sampling dispenser 20 is connected to the pipe between the outlet of the pump 11 and the inlet of the ultraviolet oxidizing device 12. You may do so. The ultraviolet oxidizing device 12 is for decomposing total organic carbon (TOC) in pure water and also has a sterilizing action. However, an ultraviolet sterilizing lamp may be provided in the storage tank 10 separately from the ultraviolet oxidizing device 12. ..

Even if the circulation purification system is provided with a mechanism for sterilizing with ultraviolet rays, the pure water in the pipe 16 and the water sampling dispenser 20 does not circulate, so that there is a risk that viable bacteria will propagate at this position. The water sampling dispenser 20 based on the present invention can sterilize the viable bacteria that have propagated inside the pipe 16 and the water sampling dispenser 20 to reduce the number of viable bacteria contained in the pure water. It makes it possible to supply at all times.

FIG. 2 shows the water sampling dispenser 20 of the first embodiment of the present invention. The water sampling dispenser 20 is used for collecting pure water using the circulation purification system shown in FIG. 1 as a pure water source. For example, the water sampling dispenser 20 of the present embodiment is held and moved by the user so that pure water can be poured one after another into a large number of test tubes arranged side by side on a laboratory table. It is provided with a head portion 20a capable of capable. In the water sampling dispenser 20, the tip of the pipe 16 is connected to the head portion 20a. The head portion 20a is provided with a solenoid valve 21 in which pure water is supplied from the pipe 16 to interrupt the flow of pure water, and a switch 23 for operating the solenoid valve 21. A button 24 is attached to the switch 23, and a push button switch is configured. The solenoid valve 21 is of a type in which the valve opens when a drive signal is applied to the solenoid, that is, the valve is in an open state while the solenoid is energized, and the valve is in a closed state when the solenoid is not energized. Is used. Further, the head portion 20a is provided with a handle 25 so that the user can easily grip the head portion 20a.

An irradiation unit 30 is attached to the outlet of the solenoid valve 21. The irradiation unit 30 includes a housing 31, a substrate 34, and an ultraviolet LED 35 attached to the substrate 34. The substrate 34 is fixed to the housing 31 by, for example, screwing.

The housing 31 has a substantially rectangular parallelepiped shape, and a flow path 32 extending in the longitudinal direction is formed inside the housing 31. One end (upper end side in the drawing) of the flow path 32 extends into a protrusion protruding from the upper surface in the drawing of the housing 31, and a screw groove is formed on the outer surface of the protrusion. This screw groove is screwed with a screw groove formed on the inner surface of the outlet opening of the solenoid valve 21, whereby the irradiation unit 30 is applied to the outlet of the solenoid valve 21, that is, the head portion 20a of the water sampling dispenser 20. Can be detachably attached. Further, the other end (lower end side in the drawing) of the flow path 32 receives the root portion of the nozzle 22, whereby the nozzle 22 is attached to the irradiation unit 30, and the pure water that has passed through the flow path 32 is discharged to the nozzle 22. It will be discharged from the tip of. Actually, a screw groove is formed on the inner surface of the other end of the flow path 32, and the screw groove formed on the outer surface of the root portion of the nozzle 22 is screwed into the screw groove. There is. At this time, it is preferable that the above-mentioned protrusion of the housing 31 has the same shape as the root of the nozzle 22, including the shape of the screw groove. In this way, the irradiation unit 30 is added later to the conventional water sampling dispenser in which the nozzle 22 is originally attached to the outlet opening of the solenoid valve 21 by screwing, and water sampling based on the present invention is performed. It can be a dispenser 20. In other words, the irradiation unit 30 is also an adapter to the existing water sampling dispenser. As the nozzle 22, various nozzles having different tip shapes can be used, and an example thereof is disclosed in Patent Document 1.

In the housing 31, a hollow portion 33 is formed from the central portion of the flow path 32 toward one side surface of the housing 31, and quartz serving as an ultraviolet ray introducing window is formed in the innermost portion of the hollow portion 33 when viewed from the flow path 32 side. A glass plate 36 is provided. The outer surface of the quartz glass plate 36 faces the emission surface of the ultraviolet LED 35 attached to the substrate 34. As a result, the ultraviolet LED 35 is arranged so as to irradiate the pure water flowing through the flow path 32 with ultraviolet rays. The ultraviolet rays generated by the ultraviolet LED 35 reach the flow path 32 from the quartz glass plate 36 via the hollow portion 33. As a result, the pure water in the flow path 32 is subjected to ultraviolet sterilization treatment. The material constituting the housing 31 must have a small amount of components eluted in pure water and must be durable against ultraviolet rays, and can irradiate the pure water in the flow path 32 with ultraviolet rays all over. Therefore, it is preferable that the material constituting the housing 31 excluding the portion of the quartz glass plate 36 is one that largely diffusely reflects (diffusely reflects) ultraviolet rays. Therefore, the housing 31 is preferably made of a fluororesin typified by, for example, polytetrafluoroethylene (PTFE) or polyvinylidene fluoride (PVDF), except for the portion of the quartz glass plate 36, and in particular, polytetrafluoroethylene. It is preferably composed of. The ultraviolet diffuse reflectance of polytetrafluoroethylene varies depending on the wavelength of ultraviolet rays, the particle size of the resin used for molding, the resin manufacturer, and the thickness of the molded product, but within the range investigated by the inventors, in many cases, It is about 90% to 98%.

Next, the ultraviolet LED 35 will be described. In the present embodiment, since the viable bacteria in pure water are reduced by the ultraviolet rays generated by the ultraviolet LED 35, the ultraviolet rays generated by the ultraviolet LED 35 need to have a wavelength having a high bactericidal effect. From this point of view, it is preferable to use the ultraviolet LED 35 whose emission peak wavelength is in the range of 260 nm or more and 285 nm or less. Since the ultraviolet LED 35 having such a wavelength generates a large amount of heat during operation, it is preferable to use a material having high thermal conductivity, for example, aluminum, as the substrate 34 on which the ultraviolet LED 35 is mounted.

In the past, mercury lamps were often used as a light source for ultraviolet rays for sterilization, but mercury lamps were large and could not be incorporated into water sampling dispensers. In addition, mercury lamps take a long time to start up, and if they are turned on and off frequently, their lifespan will be significantly shortened, so they are not suitable for use when there is a demand for pure water at the point of use. Met. On the other hand, in the present embodiment, by using an ultraviolet LED which is small in size, has a quick rise time, and has little deterioration even if it is repeatedly turned on and off, it is incorporated in a water sampling dispenser and is on the outlet side of the solenoid valve 21. The sterilization process is enabled at the position immediately before the nozzle 22, which is the position closest to the water sampling position, which is the actual use point. For example, the size of the ultraviolet LED is about several mm square to 2 cm square, and the rising time of the ultraviolet LED is on the order of milliseconds, which is equal to or faster than the operating time of the solenoid valve 21. By using the ultraviolet LED, even if the ultraviolet irradiation is performed only when there is a demand for pure water, the sterilization treatment can be surely performed without causing the problem of the life of the element.

FIG. 3 shows the circuit configuration of the water sampling dispenser 20 shown in FIG. The switch 23 includes a pair of terminals, and is configured to be in a conductive state between both terminals only when pressed by the button 24 (FIG. 2) as a push button switch. One terminal of the switch 23 is connected to the power line, and the other terminal is connected to one end of the solenoid of the solenoid valve 21. The other end of the solenoid is grounded. Further, the cathode of the ultraviolet LED 35 is grounded, and the anode is connected to the other terminal of the switch 23 via a current limiting resistor 36.

In this configuration, when the switch 23 is pressed and becomes conductive, a drive signal is supplied from the switch 23 to the solenoid valve 21, the solenoid of the solenoid valve 21 is energized, the solenoid valve 21 is opened, and pure water is irradiated to the irradiation unit. It is discharged from the nozzle 22 via the flow path 32 in the 30. At the same time as energizing the solenoid of the solenoid valve 21, the ultraviolet LED 35 is also energized, and the ultraviolet LED 35 generates ultraviolet rays. That is, the ultraviolet LED 35 is driven in synchronization with the drive signal of the solenoid valve 21. The pure water flowing through the flow path 32 in the irradiation unit 30 is irradiated with this ultraviolet ray and undergoes sterilization treatment. When the pressure on the switch 23 is released, no current flows through the solenoid of the solenoid valve 21 or the ultraviolet LED 35, the solenoid valve 21 closes, the discharge of pure water from the nozzle 22 stops, and the ultraviolet LED 35 is extinguished at the same time. The sterilization process is also stopped. After all, pure water is discharged from the nozzle 22 only during the period when the switch 23 as the push button switch is operated, and the pure water is sterilized by ultraviolet rays at the position immediately before the nozzle 22. ..

Next, the water sampling dispenser of the second embodiment of the present invention will be described. In the water sampling dispenser 20 of the first embodiment of the circuit configuration shown in FIG. 3, the nozzle 22 flows out only during the period when the switch 23 is pressed, but in the water sampling dispenser based on the present invention, once with respect to the switch 23. It is also possible to discharge a certain amount of pure water from the nozzle 22 by operation. The water sampling dispenser of the second embodiment is such that a fixed amount of pure water is discharged by one switch operation, and its appearance and shape are the same as those shown in FIG. 2, and the first The only difference from the water sampling dispenser of the embodiment is the circuit configuration. Therefore, the circuit configuration of the second water sampling dispenser will be described with reference to FIG.

In the water sampling dispenser of the second embodiment, the arrangement of the solenoid valve 21, the nozzle 22, the irradiation unit 30, and the ultraviolet LED 35 in the irradiation unit 30 is the same as those shown in FIGS. 2 and 3. A flow rate sensor 37 that measures the flow rate of pure water and outputs a flow rate detection value is provided in the pipe connected to the inlet of the solenoid valve 21. A control circuit 38 for driving the solenoid of the solenoid valve 21 and the ultraviolet LED 35 is provided, and the switch 23 is connected to the control circuit 38. The switch 23 here is provided to output a start signal to the control circuit 38. The flow rate detection value from the flow rate sensor 37 is also input to the control circuit 38. One end of the solenoid of the solenoid valve 21 is connected to the drive output terminal of the control circuit 38. The other end of the solenoid is grounded. The anode of the ultraviolet LED 35 is also connected to the drive output terminal of the control circuit 38 via a current limiting resistor 36. The cathode of the ultraviolet LED 35 is grounded. Further, a relay 39 as a failure detection mechanism is connected in parallel with the ultraviolet LED 35, and the contact output of the relay 39 is input to the control circuit 38 as a failure detection.

In the water sampling dispenser shown in FIG. 4, when the switch 23 is pressed and the pair of terminals becomes conductive, the control circuit 38 detects that the switch 23 is conductive, determines that the start signal has been input, and drives the output. A drive signal of a predetermined voltage is output to the terminal. As a result, as in the case of the circuit configuration shown in FIG. 3, the solenoid of the solenoid valve 21 and the ultraviolet LED 35 are driven, pure water is discharged from the nozzle 22, and the ultraviolet LED 35 is sterilized by ultraviolet rays. Become. The control circuit 38 monitors the flow rate detection value, and the switch 23 is in a non-conducting state on the way until the integrated flow rate of pure water reaches the set capacity value from the time when the switch 23 becomes conductive. Even if it does, the output of the drive signal to the drive output terminal is continued. Further, when the integrated flow rate of pure water reaches the set capacitance value, the control circuit 38 stops the output of the drive signal to the drive output terminal even if the switch 23 is still in the conductive state at that time. When the output of the drive signal is stopped, the solenoid valve 21 is closed, the discharge of pure water from the nozzle 22 is stopped, the light emission of the ultraviolet LED 35 is also stopped, and the sterilization process is completed.

As described above, in the water sampling dispenser of the present embodiment, only by pressing the switch 23, which is a push button switch, once, it is not necessary to continuously press the switch 23, and pure water having a set capacity value is discharged from the nozzle 22. It is possible to realize a fixed quantity discharge. It is preferable that the set capacity value for fixed-quantity discharge can be changed by the user via a setting switch (not shown) or the like. Further, by setting the control circuit 38, it is possible to switch between continuing to discharge pure water while the switch 23 is pressed as in the first embodiment, or switching between fixed-quantity discharge in the present embodiment. preferable. In any case, when the solenoid valve 21 is opened and pure water is discharged from the nozzle 22, the discharged pure water is sterilized by the ultraviolet LED 35 at a position immediately before the nozzle 22.

By the way, when a failure such as disconnection occurs in the ultraviolet LED 35, since the solenoid of the solenoid valve 21 and the ultraviolet LED 35 are provided in series, the electromagnetic valve 21 opens even though the ultraviolet LED 35 is not operating. , Pure water will be discharged from the nozzle 22. Since this pure water has not been sterilized by ultraviolet rays from the ultraviolet LED 35, it may contain a large amount of viable bacteria. Therefore, in the present embodiment, the relay 39 detects the disconnection of the ultraviolet LED 35 and the like. When the normal ultraviolet LED 35 is energized, the voltage between the anode and the cathode of the ultraviolet LED 35 is a forward voltage determined by the characteristics of the ultraviolet LED. On the other hand, when the ultraviolet LED 35 is disconnected, the voltage between the anode and the cathode becomes the voltage itself of the drive signal output from the control circuit 38. Therefore, a relay 39 is provided that does not operate with the forward voltage of the ultraviolet LED 35 but operates with the voltage of the drive signal from the control circuit 38, and the contact output of the relay 39 is input to the control circuit 38 as a failure detection to control the control circuit. 38 can detect an obstacle such as a disconnection in the ultraviolet LED 35. When such a failure is detected, the control circuit 38 can perform processing such as stopping the output of the drive signal or displaying a failure on a display device (not shown).

Next, the third water sampling dispenser of the present invention will be described with reference to FIG.

In the water sampling dispenser 20 of the first embodiment, the irradiation unit 30 is attached to the head portion 20a so that the pure water flowing through the flow path 32 in the irradiation unit 30 is irradiated with ultraviolet rays. Considering the operability as a water dispenser, there is a limit to lengthening the flow path 32. Therefore, when the flow rate of pure water collected increases and the flow velocity increases, it becomes difficult to secure a sufficient irradiation amount of ultraviolet rays for pure water. Therefore, in the water sampling dispenser 50 of the third embodiment shown in FIG. 5, the ultraviolet source is provided in the head portion 50a, and the ultraviolet rays are obliquely incident in the conduit from the head portion 50a to the pure water source to cause the ultraviolet source. The ultraviolet rays are directed toward the pure water source while being multiple-reflected inside. As a result, in the water sampling dispenser 50, the section in which the pure water is irradiated by the ultraviolet rays is substantially lengthened so that a sufficient amount of ultraviolet rays can be irradiated to the pure water even when the flow rate of the pure water is large. ing. Hereinafter, the water sampling dispenser 50 of the third embodiment will be described in more detail.

Like the water sampling dispenser 20 of the first embodiment, the water sampling dispenser 50 of the third embodiment has a head portion 50a provided with a handle 25, and a nozzle 22 is attached to the head portion 50a. As the nozzle 22, the same nozzle as that used in the first embodiment is used. However, the head portion 50a of the water sampling dispenser 50 is not provided with the solenoid valve 21 as an on-off valve connected to the pure water source. The solenoid valve 21 is provided in the main body housing (not shown) of the water sampling dispenser 50, and a pipe 16 from a pure water source is connected to the inlet thereof. The outlet of the solenoid valve 21 and the head portion 50a are connected by a flexible connecting pipe 51. The connection pipe 51 is a pipe portion that forms a part of a flow path that connects the outlet of the on-off valve 21 and the nozzle 22.

Inside the head portion 50a, an incident unit 60 for injecting ultraviolet rays into the connecting pipe 51 in a direction oblique to the flow direction of pure water in the connecting pipe 51 is provided. The incident unit 60 includes a housing 61, a substrate 34 similar to that used in the first embodiment, an ultraviolet LED 35 attached to the substrate 34, and a radiator (heat sink) 54. The substrate 34 is fixed to the housing 61, and the radiator 54 is attached to the surface of the substrate 34 opposite to the surface fixed to the housing 61. The radiator 54 is for radiating heat generated when the ultraviolet LED 35 is driven. The surface of the housing 61 on which the substrate 34 is mounted is referred to as a mounting surface.

A flow path 62 is formed in the housing 61 so as to penetrate the housing 61. The flow path 62 has a shape that is parallel to the mounting surface on the outlet side and bent by about 135 ° on the way so as to form an angle of about 45 ° with respect to the mounting surface on the inlet side. The tip of the connecting pipe 51 is connected to the inlet of the flow path 62 of the housing 61 via the joint 51a so that the center line of the connecting pipe 51 and the center line of the flow path 62 on the inlet side of the flow path 62 coincide with each other. doing. In the housing 61, a hollow portion 63 is formed from a bent portion of the flow path 62 toward the mounting surface, and a quartz glass plate 36 serving as an ultraviolet ray introducing window is formed at the innermost portion of the hollow portion 63 when viewed from the flow path 62 side. Is provided. The outer surface of the quartz glass plate 36 faces the emission surface of the ultraviolet LED 35 attached to the substrate 34. When an ultraviolet LED 35 that emits ultraviolet rays from its emitting surface centering on the direction perpendicular to the emitting surface is used, the ultraviolet rays from the ultraviolet LED 35 are the joint 51a as shown by the dotted arrow marked UV in FIG. It is incident on the inside of the connecting pipe 51 including the ultraviolet rays in a direction oblique to the flow direction of pure water in the connecting pipe 51, and then propagates in the direction of the electromagnetic valve 21 while being multiple reflected on the inner wall of the connecting pipe 51. It will be. As a result, the pure water in the connecting pipe 51 can be sterilized by ultraviolet rays. In the illustrated one, ultraviolet rays are incident inside the connecting pipe 51 at an angle of about 45 ° with respect to the flow direction of pure water in the connecting pipe 51, but the incident angle of the ultraviolet rays is not limited to this. Any angle can be used as long as it causes multiple reflections on the inner wall of the connecting pipe 51 and the ultraviolet rays can propagate in the connecting pipe 51. In the present invention, the "direction oblique to the flow direction of pure water" means an angle of more than 0 ° and less than 90 ° with respect to the flow direction of pure water.

The water sampling dispenser 50 of this embodiment propagates ultraviolet rays in pure water to a long distance while performing multiple reflections to lengthen the section in which the ultraviolet rays are irradiated in the flow path, so that the ultraviolet rays are surely emitted even when the flow velocity is high. It enables sterilization treatment. Therefore, the inner wall of the housing 61 excluding the portion of the quartz glass plate 36 and the inner wall of the connecting pipe 51 including the joint 51a both have little elution to pure water, have durability against ultraviolet rays, and have a large amount of ultraviolet rays. It is preferably composed of diffuse reflection (diffuse reflection). The inner wall is a part that can come into contact with pure water. As such a material, as in the case of the first embodiment, for example, a fluororesin typified by polytetrafluoroethylene or polyvinylidene fluoride is preferably used, and in particular, a composition made of polytetrafluoroethylene is used. Is preferable. As the ultraviolet LED 35, the same one as shown in the first embodiment can be used.

The head portion 50 is further provided with a joint 52 having one end connected to the outlet of the flow path 62 of the housing 61 and a backflow prevention mechanism 53, and the other end of the joint 52 is provided with a backflow prevention mechanism via the joint 52a. It is connected to the entrance of 53. The outlet of the backflow prevention mechanism 53 is open to the outer surface of the head portion 50a, and the nozzle 22 is attached to the outer surface thereof, for example, by screwing. In the water sampling dispenser 50 of the present embodiment, the flow path length from the on-off valve 21 to the nozzle 22 is long, and therefore, the influence when dust or contaminants invade the flow path from the nozzle 22 side becomes large. Therefore, a backflow prevention mechanism 53 is provided in order to prevent dust and contaminants from entering the flow path from the nozzle 22 side. As the backflow prevention mechanism 53, for example, a check valve, a solenoid valve, or the like can be used. When a solenoid valve is used as the backflow prevention mechanism 53, the solenoid valve is controlled to open and close in synchronization with the opening and closing of the above-mentioned solenoid valve 21 in the main body housing. In the water sampling dispenser 50, the discharge of pure water from the nozzle 22 is controlled by opening and closing the solenoid valve 21 inside the main body housing. In order to reduce the mass of the head portion 50 and improve the operability, it is preferable to use a check valve as the check valve mechanism 53. Also in the water sampling dispenser 20 of the first embodiment, a check valve or other check flow prevention mechanism can be provided between the irradiation unit 30 and the nozzle 22.

Although the wiring to the ultraviolet LED 35 and the wiring to the solenoid valve 21 are not shown in FIG. 5, the same wiring as that shown in FIG. 3 or 4 can be adopted in the water sampling dispenser 50. The switch 23 for opening and closing the on-off valve 21 may be provided on the head portion 50 as in the case of the first embodiment, may be provided on the main body housing, or may be provided on the main body housing, or a footstep connected to the main body housing. It may be a switch or the like. When the switch 23 is turned on, the solenoid valve 21 opens and the ultraviolet LED 35 emits light. As a result, the pure water from the pure water source enters the head portion 50a from the solenoid valve 21 via the connecting pipe 51, and is discharged from the nozzle 22 via the incident unit 60, the joint 52, and the backflow prevention mechanism 53. In this process, the pure water is sterilized by being irradiated with ultraviolet rays from the ultraviolet LED 35 in the connecting pipe 51 near the head portion 50a. Therefore, the sterilized pure water is discharged from the nozzle 22. When the switch 23 is turned off, the solenoid valve 21 closes and the discharge of pure water from the nozzle 22 stops, and at the same time, the ultraviolet LED 35 is extinguished and the sterilization process also stops. Also in this embodiment, pure water is discharged from the nozzle 22 only during the period when the switch 23 is operated, and the pure water is sterilized by ultraviolet rays at a position immediately before the nozzle 22.

Next, the present invention will be described in more detail by way of examples.

(Example 1)
The device shown in FIG. 6 was assembled. Pure water is stored in the storage tank 40 open to the atmosphere, and pure water is supplied to the irradiation unit 30 described in the first embodiment via the pump 41 and the valve 42. A nozzle 22 was attached to the outlet of the irradiation unit 30. Polytetrafluoroethylene was used as the material of the housing 31 of the irradiation unit 30. Then, the number of general bacteria per 1 mL of pure water in the storage tank 40 (described as "no UV") and the pure water that has passed through the valve 42 and is irradiated with ultraviolet rays by the ultraviolet LED 35 in the irradiation unit 30 and discharged from the nozzle 22. The number of general bacteria per 1 mL (described as "with UV") was determined. As the ultraviolet LED 35, a model VPC161 manufactured by Nikkiso Co., Ltd. was used, and the central wavelength of the generated ultraviolet rays was 277 nm. The ultraviolet LED 35 was driven with a constant current of 300 mA. At this time, the flow rate of pure water discharged from the nozzle 22 was switched between 0.5 L / min and 0.07 L / min by adjusting the opening degree of the valve 42. The results are shown in Table 1. In Table 1, the sterilization rate indicates how many bacteria were killed by the pure water discharged from the nozzle 22 as a ratio to the number of general bacteria per volume of pure water in the storage tank 40. is there.

(Example 2)
The same apparatus as in Example 1 was assembled except that polypropylene (PP) was used as the material of the housing 31 of the irradiation unit 30. The number of general bacteria per 1 mL of pure water in the storage tank 40 (described as "no UV") and 1 mL of pure water discharged from the nozzle 22 after being irradiated with ultraviolet rays by the ultraviolet LED 35 in the irradiation unit 30 after passing through the valve 42. The number of general bacteria per hit (described as "with UV") was measured, and the sterilization rate was calculated in the same manner as in Example 1. At this time, the flow rate of pure water discharged from the nozzle 22 was switched between 0.1 L / min and 0.05 L / min by adjusting the opening degree of the valve 42. The results are shown in Table 1.

In both Examples 1 and 2, the bactericidal effect of the ultraviolet rays from the ultraviolet LED 35 was recognized. In particular, by using polytetrafluoroethylene as the material of the housing 31 of the irradiation unit 30, a remarkable bactericidal effect was observed in a low flow rate region.

(Example 3)
An apparatus in which the water sampling dispenser (see FIG. 5) of the third embodiment was connected to the valve 42 in the apparatus shown in the first embodiment was assembled. Specifically, the end of the connection pipe 51 (the end far from the head portion 50a) of the water sampling dispenser 50 shown in FIG. 5 is connected to the outlet of the valve 42, and the flow rate of pure water flowing out from the nozzle 22. The number of general bacteria in the outflowing pure water was determined in the same manner as in Example 1. The same ultraviolet LED 35 as in Example 1 was used and driven under the same driving conditions. The results are shown in Table 3.

Comparing Example 1 and Example 3 with respect to the case where the flow rate is 0.5 L / min with ultraviolet irradiation, the sterilization rate was 50% in Example 1 and 98 in Example 3. It exceeds 8.8%, and it was found that a large bactericidal effect can be obtained even at a large flow rate by propagating ultraviolet rays while multiple reflections in the connecting pipe.

20,50 Water sampling dispenser 20a, 50a Head part 21 Solenoid valve 22 Nozzle 23 Switch 30 Irradiation unit 31,61 Housing 34 Board 35 Ultraviolet LED
51 Connection pipe 53 Backflow prevention mechanism 60 Incident unit

Claims (11)

A water sampling dispenser used for sampling pure water.
A solenoid valve that connects to a pure water source and opens with a drive signal ,
A head part that has a handle and can be held and moved by the user,
A nozzle attached to the head and discharging pure water,
A flow path connecting the nozzle to the outlet of the solenoid valve,
A switch provided on the head portion and used for operating the solenoid valve,
An ultraviolet LED arranged so as to irradiate the pure water flowing through the flow path with ultraviolet rays,
Have a,
The ultraviolet LED is a water sampling dispenser that is driven in conjunction with the drive signal . The water sampling dispenser according to claim 1 , wherein the drive signal is supplied to the solenoid valve when the switch becomes conductive . A flow rate sensor that detects the amount of pure water flowing into the solenoid valve,
When the start signal is input from the switch, the output of the drive signal is started, and the drive signal is started until the integrated flow rate of pure water from the start of the drive signal reaches a preset capacitance value based on the detection result of the flow sensor. A control circuit that continues the output of the drive signal and stops the output of the drive signal when the integrated flow rate reaches the capacitance value.
Further comprising, water sampling dispenser according to claim 1. The water sampling dispenser according to any one of claims 1 to 3, further comprising an irradiation unit including the ultraviolet LED and a housing, and the flow path is formed in the housing. The water sampling dispenser according to claim 4, wherein the housing is made of a fluororesin except for a portion that serves as a window for introducing the ultraviolet rays. The flow path has a tube portion, and the ultraviolet LED is arranged so as to inject ultraviolet rays into the tube portion in a direction oblique to the flow direction of the pure water in the tube portion. Item 2. The water sampling dispenser according to any one of Items 1 to 3. The water sampling dispenser according to claim 6, wherein at least the inner wall of the pipe portion is made of fluororesin. The water sampling dispenser according to any one of claims 1 to 7, further comprising a backflow prevention mechanism at a connection position between the flow path and the nozzle. The water sampling dispenser according to any one of claims 1 to 8, further comprising a failure detection mechanism for detecting a failure of the ultraviolet LED. A head portion provided with a handle that can be held and moved by the user, a solenoid valve provided in the head portion and opened by a drive signal, and a switch provided in the head portion and used for operating the solenoid valve. When, a adapter adapted to a device having a nozzle for discharging liquid from the connected detachably to an outlet of the solenoid valve the solenoid valve,
A housing provided with a flow path that can be detachably connected to the outlet of the solenoid valve and the nozzle can be detachably connected.
An ultraviolet LED arranged so as to irradiate the liquid flowing through the flow path with ultraviolet rays,
Have,
The channel is communicating the outlet of the solenoid valve nozzle,
The ultraviolet LED is an adapter that is driven in conjunction with the drive signal . A pure water production apparatus comprising the water sampling dispenser according to any one of claims 1 to 9 or the adapter according to claim 10.

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