JPWO2005097350A1 - Spraying apparatus and spraying method - Google Patents

Abstract

Provided is a spraying apparatus that is capable of spraying a spray object on any part of a human body and that is capable of spraying the spray object over a wide range at once and is excellent in convenience. A container (8) provided in the housing (6) and containing a predetermined electrolyte solution, and inert electrodes facing each other without a diaphragm, and the polarity of electric power supplied to these inert electrodes A plurality of times at predetermined time intervals to electrolyze the supplied electrolyte solution to produce a mixed electrolyte solution of the cathode side electrolyte solution and the anode side electrolyte solution, and a container A supply mechanism for supplying the electrolyte solution in the diaphragm to the diaphragm electrolyzer, and a spray section (4 for spraying the mixed electrolyte generated in the diaphragm electrolyzer to the outside of the housing while being vibrated by ultrasonic vibration ), And three or more inert electrodes of the diaphragm electrolyzer are provided, and at least one of the electrodes electrolyzes the electrolyte solution using both surfaces thereof.

Description

  The present invention relates to a spraying apparatus and a spraying method for spraying a fluid (liquid) such as a medicine used for cosmetics and hygiene.

  Conventionally, various types of spraying apparatuses for spraying liquids such as cosmetic liquids and disinfecting liquids are known. In such a spraying apparatus, a spraying object such as a medicine is stored in a container or the like in a state where it is preliminarily blended by a predetermined method. Sprayed.

For example, a spray device disclosed in Patent Document 1 includes a tank that stores a predetermined medicine, a pump that pumps the medicine in the tank, and a spray unit that sprays the medicine pumped by the pump to the outside. I have. The spray unit includes a perforated plate having a large number of through holes and a vibrator that vibrates the perforated plate. Therefore, the medicine pumped by the pump is passed through the through-hole of the vibrating perforated plate, and is diffused and sprayed as a fine liquid drop.
JP 2002-52069 A

  However, the conventional spraying apparatus as described above sprays electrolyzed water having an effect on the skin, and does not target other parts of the human body. In addition, there is a single pressure feed path from the pump to the spraying section, and there is also a single spout for ejecting the drug to the perforated plate, so there is a limit to the sprayable range. That is, it was difficult to spray on parts other than the skin or to spray over a wide range.

  The present invention has been made by paying attention to the above circumstances, and the object of the present invention is to spray an object to be sprayed not only on the skin but also on any part of the human body, and a wide range of objects to be sprayed at a time. Another object of the present invention is to provide a spraying apparatus and a spraying method excellent in convenience that can be sprayed over a wide range.

  In order to solve the above-described problems, a spray device according to the present invention includes a housing, a container provided in the housing, in which a predetermined spray target is stored, and the housing while vibrating the spray target by ultrasonic vibration. A spraying section for spraying to the outside of the container, and a supply means for supplying the spraying object in the container to the spraying section, wherein the supplying means stores the spraying object in the container It is characterized by comprising a delivery means for delivering to the outside, and a supply conduit for guiding the spray object to be delivered from the container by this delivery means to the spray section.

  Moreover, in this invention, the spraying method which has the said characteristic is also provided.

  ADVANTAGE OF THE INVENTION According to this invention, the spraying apparatus and spraying method excellent in the convenience which can spray the spraying object over a wide range at once can be provided.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a spray device 1 according to an embodiment of the present invention. As illustrated, the spray device 1 includes a device main body 2 and a spray unit 4 that is detachably attached to the device main body 2.

  The apparatus main body 2 has a substantially rectangular parallelepiped housing 6. In the housing 6, one liquid supply tank (container) 8 in which a predetermined liquid (a spray target such as a medicine) as a spray target is stored is detachably stored, for example, and the liquid is electrolyzed. A non-diaphragm electrolytic cell 29 is housed. In addition, a pump 10 serving as a pressure feeding unit is provided below the liquid supply tank 8, and the pump 10 supplies a liquid contained in the liquid supply tank 8 to a first pipe (supply pipe). The liquid is sucked through 12 or received by the action of gravity, and the liquid is pumped to the electrolytic cell 28 through the second pipe (supply pipe) 14. In addition, from the electrolytic cell 29, two first and second discharge pipes (flow channels) 15a and 15b (three or more discharge pipes) for discharging the electrolyzed water generated in the electrolytic cell 29 to the spray unit 4 are provided. It may be present) extends for a predetermined length. As can be seen from the above, in the present embodiment, the pump 10 and the pipes 12, 14, 15 a and 15 b are used for supplying the electrolytic aqueous solution in the liquid supply tank 8 to the electrolytic cell 29 and the spray unit 4. It constitutes a supply means.

  Here, the pumping means for pumping the liquid in the liquid supply tank 8 to the electrolytic cell 29 does not need to be the pump 10 and may be a device using a pumping medium such as gas spray. Of course, as long as the liquid in the liquid supply tank 8 can be supplied to the electrolytic cell 29, the supply form is not limited to pressure feeding. Although not shown, the housing 6 is provided with waterproof means (for example, a packing made of an elastic body such as rubber) for preventing the liquid to be injected from entering the apparatus main body 2. Further, the number of liquid supply tanks 8 is not necessarily one. For example, when spraying a plurality of types of liquids, a plurality of liquid supply tanks are stored in the housing 6, and each liquid supply tank is connected to a corresponding pipe line. You may make it supply a liquid to the electrolytic vessel 29 and the spray part 4 (it mentions later).

  The spray unit 4 includes a spray unit main body 34 in which the spray element 28 is housed, and an open / close cover 36 attached to the upper part of the spray unit main body 34. The spray element 28 includes a porous plate 28a and a piezoelectric vibrator 28b. The discharge ends of the first discharge pipe 15a and the second discharge pipe 15b are opposed to the back surface of the porous plate 28a. The perforated plate 28a has a large number of through holes having a hole diameter of 18 to 24 μm, and the end thereof is fixed to the piezo vibrator 28b. Therefore, the porous plate 28a fixed to the piezoelectric vibrator 28b can be vibrated by applying an alternating current or pulse voltage to the piezoelectric vibrator 28b to vibrate the piezoelectric vibrator 28b. Thereby, the liquid discharged (supplied) from the first discharge pipe 15a and the second discharge pipe 15b is diffused and sprayed as fine droplets to the outside through a large number of through holes formed in the perforated plate 28a. .

  The porous plate 28a is preferably formed by coating a nickel plate with diamond-like carbon (DLC). As described above, when a nickel plate is used, a porous plate can be manufactured at a lower cost than when a platinum plate is used, and by coating the nickel plate with DLC, the acid solution or the like is not brought into direct contact with nickel. Just do it. Further, since DLC is carbon, for example, it is possible to avoid a situation in which the human body to be injected causes metal allergy, and it is also possible to prevent corrosion due to acid (improves durability).

  The opening / closing cover 36 exposes or hides the porous plate 28a of the spray element 28, and is attached to the spray portion main body 34 so as to be slidable up and down. The apparatus body 2 side of the open / close cover 36 closes the discharge ends of the first discharge pipe 15a and the second discharge pipe 15b when the open / close cover 36 is closed so as to hide the porous plate 28a. It is formed as a discharge port opening / closing part 38 for preventing liquid from leaking out.

  Note that the spray unit 4 is detachably attached to the housing 6 of the apparatus body 2 using, for example, ordinary fitting means using a slide guide, a locking projection, or the like. Of course, you may fix the spraying part 4 with respect to the housing 6 so that removal is not possible.

  A magnet 40 as a switch operating means is attached to the upper part of the opening / closing cover 36. The magnet 40 can detect the position of the open / close cover 36 in cooperation with a corresponding reed switch 42 attached to the apparatus main body 2 side.

  In the housing 6, a control unit 18 incorporating a microprocessor is provided. The control unit 18 controls the pump 10, the electrolytic cell 29, and the like, and receives a detection signal from the reed switch 42. In the figure, reference numeral 20 denotes a drive power source that supplies power to the control unit 18, the pump 10, the electrolytic cell 29, the vibrator 28b, and the like. As this drive power supply 20, a primary battery, a secondary battery, etc. can be used. In the figure, reference numeral 22 is a wiring for applying a controlled voltage from the control unit 18 to the piezo vibrator 28b, and reference numeral 27 is a controlled electric power suitable for electrolysis to the electrolytic cell 29. Wiring, reference numeral 24 is a wiring for supplying power of the drive power supply 20 to the control unit 18, and reference numeral 26 is a signal line connecting the reed switch 42 and the control unit 18. Reference numeral 29 is a wiring for supplying the electric power controlled by the control unit 18 to the pump 10, and by controlling the electric power supplied to the pump 10 by the control unit 18, the amount of liquid discharged through the pump 10 is desired. The amount can be adjusted.

  Further, in the present embodiment, the first discharge pipe line 15a and the second discharge pipe line 15b are configured such that the tip side including the discharge end portion can be rotated up and down around a predetermined rotation fulcrum. Yes. Specifically, when a predetermined drive signal is input from the control unit 18 via the wiring 30 to the rotation units (discharge angle variable means) 31 and 32, the first discharge is performed via the rotation units 31 and 32. The distal end sides of the pipe line 15a and the second discharge pipe line 15b are rotated up and down so that the liquid discharge angle changes.

  FIG. 2 schematically shows a diaphragm electrolytic cell 29 and its surrounding components, with a diaphragm electrolytic cell added to this embodiment. As described above, the liquid L as the spray target is stored in the liquid supply tank 8.

  The non-membrane electrolytic cell 29 has three or more (three in the present embodiment) electrodes 29a, 29b. 29c inside. Specifically, as clearly shown in FIG. 3, the electrolytic cell 29 has three electrodes 29a, 29b, and 29c arranged in parallel to face each other. Both sides can be used for electrolysis (of course, if 4 or more electrodes are used, both sides of 2 or more electrodes can be used for electrolysis). The liquid can be electrolyzed by flowing the liquid between these electrodes through the second conduit 14.

  In this case, the distance between the electrodes 29a, 29b, and 29c varies depending on the type of spray object, but in the case of a relatively low viscosity, it is set to 2 mm or less, preferably 1.5 to 0.05 mm, preferably 1.0 to 0.1 mm is more preferable. In the case of a substance having a relatively high viscosity, electrolysis can be performed by appropriately adjusting the distance between the electrodes and the applied voltage.

  Each electrode 29a, 29b, 29c is formed of an electrochemically inactive metal material. As the electrode material, platinum, a platinum alloy or the like is preferable. Further, titanium may be used as an electrode material and platinum coating may be applied. Furthermore, instead of platinum coating, diamond like carbon (DLC) coating may be applied. In this case, the electrode can be formed at a lower cost than platinum coating, and the base material of the electrode may be nickel or nickel, and variations in selection of the base material at the time of electrode formation are widened.

  Each electrode 29a, 29b, 29c is connected to a plus terminal or a minus terminal of an electrolytic power source 18a provided in the control unit 18, for example, via wirings 27a, 27b, 27c. The polarities of the power applied to each electrode 29a, 29b, 29c are switched with each other at a predetermined time interval. By switching the polarity of the applied power every predetermined time, the cathode side electrolyte solution and the anode side electrolyte solution are alternately generated in one electrode, so the anode side electrolyte solution and the cathode side electrolyte solution are efficiently mixed. Is done. The polarity switching time interval is preferably 2 to 1200 times / minute, more preferably 120 to 600 times / minute. Further, by switching the polarity, it is possible to effectively prevent the scale from adhering to the electrode.

The liquid L sent to the diaphragm electrolyzer 29 through the first conduit 12 is electrolyzed here. Electrolytic current density is preferably from ^{0.003~0.03A / cm 2, 0.01~0.02A / cm} 2 is particularly preferred.

  By performing electrolysis as described above, the anode-side electrolyte solution and the cathode-side electrolyte solution generated during electrolysis in the electrolyte layer 29 are naturally mixed, and the mixed electrolyte solution obtained by mixing both the electrolytes is discharged into the discharge pipe 15a. , 15b and continuously discharged to the spraying section 4.

  In the non-diaphragm electrolytic cell 29, the middle electrode 29b may be omitted. Also in this case, the distance between the pair of electrodes 29a and 29c varies depending on the type of spray object, but in the case of a relatively low viscosity, it is set to 2 mm or less, preferably 1.5 to 0.05 mm. 0 to 0.1 mm is more preferable. In the case of a substance having a relatively high viscosity, electrolysis can be performed by appropriately adjusting the distance between the electrodes and the applied voltage. In this case, the polarities of the power applied to the electrodes 29a and 29c are also switched with each other at a predetermined time interval as described above. In addition, when a diaphragm exists in both electrodes 29a and 29c, mixing of the anode side electrolyte solution produced | generated by electrolysis and a cathode side electrolyte solution becomes inadequate, and is unpreferable.

  Next, the case where a liquid is sprayed using the spraying apparatus 1 having the above configuration will be described.

  When spraying the liquid, first, the open / close cover 36 is pulled upward from the closed state shown by the one-dot chain line in FIG. 1 to the open state shown by the solid line in FIG. As a result, the discharge port opening / closing part 38 also moves upward, and the discharge ports of the first discharge pipe line 15a and the second discharge pipe line 15b change from the closed state to the open state.

  On the other hand, the magnet 40 attached to the opening / closing cover 36 is also moved upward and separated from the reed switch 42. In addition, the control unit 18 that has detected this state supplies power from the drive power supply 20 to the pump 10, the vibrator 28 b, and the electrolytic cell 29. As a result, the pump 10 operates and the liquid in the liquid supply tank 8 is supplied to the electrolytic cell 29 through the first pipe 12, the pump 10, and the second pipe 14. In the electrolytic cell 29, the polarity of the power applied to the electrodes 29a, 29b, and 29c is switched every predetermined time, whereby the cathode side electrolyte solution and the anode side electrolyte solution are alternately generated in one electrode, and the anode side The electrolytic solution and the cathode side electrolytic solution are mixed efficiently. Then, the mixed electrolyte of the anode side electrolyte and the cathode side electrolyte generated during electrolysis in the electrolytic layer 29 is divided into the discharge pipes 15a and 15b, and is discharged from the discharge ports of the discharge pipes 15a and 15b. The droplets 58 are supplied to the vibrating perforated plate 28a and further diffused and sprayed to the front of the perforated plate 28a through the fine through holes formed in the perforated plate 28a. In this case, if necessary, the rotary units 31 and 32 are operated by a switch or the like (not shown), and the distal ends of the first discharge pipe 15a and the second discharge pipe 15b are turned up and down. The liquid discharge angle may be changed.

  When the spraying of the liquid is finished and the spraying is stopped, the open / close cover 36 is pushed downward. As a result, the magnet 40 approaches the reed switch 42, and a signal is sent to the control unit 18 through the signal line 26. Thereby, the electric power supplied to the vibrator 28b, the electrolytic cell 28, and the pump 10 is cut off, and the spraying of the liquid is stopped.

  In the above configuration, the reed switch 42 plays the role of a liquid spray operation switch. However, the present invention is not limited to this, and a power switch is provided separately, and after opening the open / close cover 36, the liquid switch is turned on. You may comprise so that spraying may start. In this case, by spraying the liquid under the AND condition of the reed switch 42 and the power switch, the liquid is not sprayed even if the power switch is turned on when the open / close cover 36 is not lifted up, resulting in an erroneous operation. Misspraying can be reliably prevented.

  In addition, when the spray device 1 is used for a long period of time, a liquid spray failure may occur. Such poor spraying occurs due to a cause such as drying with the liquid adhering to the spray element and clogging of the through hole of the porous plate 28a due to a predetermined deposit. When a spray failure occurs, the spray unit 4 is removed from the apparatus main body 2 as indicated by an arrow in FIG. 1 and replaced with a spray unit 4 that sprays normally. Since the spraying section 4 can be easily removed and replaced by a sliding guide, a locking projection or the like, it can be operated according to each mounting structure, and no special knowledge is required.

  In addition, the spraying part 4 removed can be returned to the original performance, for example, by appropriately washing using a cleaning liquid containing a surfactant or the like. In this case, since the spray unit 4 is separated from the apparatus main body 2, the spray unit 4 is easy to handle.

  As described above, according to the spraying device 1 of the present embodiment, the polarity of the power supplied to the inactive electrodes 29a, 29b, 29c facing each other without using a diaphragm is switched a plurality of times at predetermined time intervals. Is provided in the non-membrane electrolytic cell 29 because the non-membrane electrolytic cell 29 is provided that electrolyzes the supplied liquid to produce a mixed electrolyte of the cathode-side electrolyte and the anode-side electrolyte. All electrolytes can be used as spray solutions. Therefore, there is no electrolyte discharged from the electrolytic bath 29 as waste liquid, and it is not necessary to provide a waste liquid tank in the housing 6 for receiving the waste liquid. Therefore, when it is the same size as a conventional spraying device having a waste liquid tank, an extra installation space for the liquid supply tank 8 can be secured by the amount that the waste liquid tank is excluded. That is, it is possible to ensure a larger volume of the liquid supply tank 8 than in the past. Further, when the liquid supply tank 8 having the same volume as the conventional one is used, the apparatus 1 can be reduced in size by the amount of eliminating the waste liquid tank.

  Further, according to the spray device 1 of the present embodiment, three or more inactive electrodes 29a, 29b, 29c are provided in the electrolytic cell 29, and both surfaces of the inactive electrode can be used for electrolysis. Therefore, a large electrode area can be secured (the amount of expensive electrodes used can be reduced). Further, such a laminated structure of the electrodes 29a, 29b, and 29c can be easily realized because it is a non-diaphragm form in which no diaphragm is interposed between the electrodes.

  Moreover, according to the spraying apparatus 1 of this embodiment, since liquid is electrolyzed and sprayed, the permeability to a human body etc. improves by electrolysis and ultrasonic vibration. In particular, since the mixed electrolyte solution (solution) itself is vibrated by ultrasonic vibration, the components of the mixed electrolyte solution are dispersed to increase the surface area, and the amount of the mixed electrolyte solution is smaller than when spraying without using ultrasonic vibration. Equivalent effects can be obtained with the amount of use. Moreover, electrophoresis by electrolysis also contributes to such an effect. Further, since the temperature of the electrolytic solution rises due to electrolysis and ultrasonic vibration, the viscosity of the electrolytic solution is reduced and the sprayability is improved (easier to spray). Furthermore, since the emulsification effect is greatly improved by electrolysis and ultrasonic vibration, the distribution amount of the surfactant in the electrolytic solution is reduced.

  Moreover, in the spraying apparatus 1 of the present embodiment, the mixed electrolyte generated in the non-diaphragm electrolytic cell 29 is supplied to the spray unit 4 through the plurality of discharge pipes 15a and 15b, and each discharge pipe 15a, It is made to discharge with respect to the spray part 4 from the discharge outlet of 15b. Therefore, the mixed electrolyte can be sprayed over a wide range at a time, which is very convenient.

  Moreover, in the spraying apparatus 1 of this embodiment, since the discharge angle of the mixed electrolyte solution through the discharge pipes 15a and 15b can be changed, the discharge angle can be increased and sprayed over a wider range. It is also possible to spray locally concentrated.

  Moreover, in the spraying apparatus 1 of this embodiment, the discharge amount of mixed electrolyte solution can be adjusted now. Therefore, the spray amount can be adjusted according to the application, and an optimal spray effect can be obtained.

  Moreover, according to the spraying apparatus 1 of this embodiment, while the liquid which is a spraying object is supplied to the spraying part 4 by several flow path (1st and 2nd discharge pipe lines) 15a, 15b, It discharges with respect to the spray part 4 from the discharge outlet of each flow path 15a, 15b. Therefore, the spray object can be sprayed over a wide range at a time, which is very convenient and can sufficiently draw out the fine diffusion spray ability by ultrasonic vibration.

  Moreover, according to the spraying apparatus 1 of the present embodiment, since the spray target is sprayed while being ultrasonically vibrated, atomization spray can be achieved, and the sprayed portion can be applied to the human body or the like. Improves permeability. Moreover, since the spray target object (solution) itself is vibrated by ultrasonic vibration, the components of the spray target object are dispersed and the surface area per spray target component amount (volume) is enlarged, so that ultrasonic vibration is not used. Compared to the case of spraying, the same effect can be obtained with a small amount of sprayed object used. In addition, since the temperature of the spray object increases due to the ultrasonic energy, the viscosity of the spray object decreases, and the sprayability becomes good (easier to spray). Furthermore, since the emulsifying action is improved by the ultrasonic wave, the distribution amount of the surfactant in the spray object is reduced.

  Moreover, in the spraying apparatus 1 of this embodiment, since the spraying part 4 is detachable with respect to the housing 6, in the case where the spraying state of the spraying part 4 is not satisfactory, it is sufficient to replace only the spraying part 4, In addition to being able to respond quickly to failures and the like, it is more economical than replacing the entire device.

  Moreover, in the spraying apparatus 1 of this embodiment, since the nickel plate is used as the raw material of the porous plate 28a, the porous plate can be manufactured at a lower cost than when a platinum plate is used. Further, since the nickel plate is coated with DLC, it is not necessary to directly contact the acid solution or the like with nickel. Further, since DLC is carbon, for example, it is possible to avoid a situation in which the human body to be injected causes metal allergy, and it is also possible to prevent corrosion due to acid (improves durability). In addition, when the porous plate 28a is used for the spraying portion 4 in this way and when a high-viscosity mixed electrolyte is sprayed, it is desirable to widen the pore diameter of the porous plate according to the viscosity.

  Moreover, in the said structure, the shape of the spray part 4 can be changed arbitrarily according to a use. For example, as shown in FIG. 4, the spray unit 4 may have a comb shape. Specifically, the spray unit 4 includes a spray unit main body 34 having the same configuration as described above, and a comb-shaped unit 92 having a large number of comb teeth 90 extending from the spray unit main body 34 with a predetermined length. In this case, a discharge port for discharging the mixed electrolyte is formed between the comb teeth 90. In the drawing, the spray unit main body 34 protrudes laterally from the apparatus main body 2 having the same configuration as described above, but the spray unit main body 34 may be accommodated in the apparatus main body 2.

  FIG. 5 shows a further improved spray device 1A. This spraying device 1A includes a device main body 2A that forms a gripping portion that can be gripped by hand, a liquid supply tank 8 that is detachably attached to the proximal end side of the device main body 2A, and a handle portion on the distal end side of the device main body 2A. And spraying section 4 connected through 93. The apparatus main body 2A has a configuration in which the liquid supply tank 8 is exposed to the outside from the apparatus main body 2 described above. The spray unit 4 includes a spray unit main body 34 having the same configuration as described above, and a comb-shaped unit 92 having a large number of comb teeth 90 extending from the spray unit main body 34 with a predetermined length. In this case, a discharge port 95 for discharging the mixed electrolyte is formed between the comb teeth 90. Further, as clearly shown in FIG. 5B, the comb-shaped portion 92 is composed of a pair of comb-shaped bodies 92A and 92B that can be opened and closed, and the open / close angle can be arbitrarily adjusted.

  As described above, when the spray part 4 has a comb shape as shown in FIGS. 4 and 5, the mixed electrolyte solution can be applied or ejected while the hair is scooped up by the comb part 92. The mixed electrolyte can be spread evenly throughout the hair. In this case, the comb-shaped part itself may be configured as an electrode, and the mixed electrolytic solution may penetrate into the hair while performing electrolysis.

  6 to 8 show a specific example of a structure for attaching / detaching the liquid supply tank 8 to / from the housing 6. FIG. 6 shows the back side portion of the apparatus main body 2 on the side opposite to the spray unit 4. As shown in this figure, the upper opening of the liquid supply tank 8 is opened and closed at the upper end of the housing 2. A lid 50 is attached for rotation. A locking projection 52 is integrally formed on the free end of the lid 50. Further, the liquid supply tank 8 is formed with a locking groove 54 on the outer surface of which the locking projection 52 can be locked. The liquid supply tank 8 can be attached to and detached from the housing 2 in a cartridge type with the lid 50 opened.

  Specifically, as shown in FIG. 7, the liquid supply tank 8 is inclined with respect to the wall surface 76 of the housing 2, and the lower part of the liquid supply tank 8 (the O-ring 70 and the holding member 71) is placed in the housing. 2 is inserted into the recess 65 of the bottom 63. In the state of FIG. 7, the position of the engagement beam 77 of the housing 2 is lower than the position of the engagement groove 80 of the liquid supply tank 8. Even if the liquid supply tank 8 is pushed in the horizontal direction, the housing 2 The engagement groove 80 of the liquid supply tank 8 does not engage with the engagement beam 77.

  However, when the liquid supply tank 8 is pushed downward from the state of FIG. 7 in which the lower part of the liquid supply tank 8 is inserted into the recess 65 of the bottom part 63 of the housing 2, the O-ring 70 is pressed against the tapered wall surface 75 of the bottom part 63 and deformed. The O-ring 70 is accommodated in the recess 65. As a result, the height of the engaging groove 80 of the liquid supply tank 8 moves to the same height as the engaging beam 77 of the housing 2. Thereafter, when the upper portion of the liquid supply tank 8 is pushed horizontally, the engagement groove 80 of the liquid supply tank 8 engages with the engagement beam 77 of the housing 2 (state shown in FIG. 8).

  In a state where the O-ring 70 is accommodated in the recess 65, the outer peripheral surface of the O-ring 70 is compressed by the tapered wall surface 75, or the upper and lower surfaces of the O-ring 70 are the bottom surface of the recess 65 and the body 8 a of the liquid supply tank 8. And compressed between. As a result of the compression of the O-ring 70, a repulsive force that returns to the original acts on the O-ring 70, and a force that moves it upwards acts on the liquid supply tank 8 by the repulsive force. Due to the upward force acting on the liquid supply tank 8, a pressing force is applied to the contact portion between the engagement groove 80 of the liquid supply tank 8 and the engagement beam 77 of the housing 2, and the liquid supply tank 8 can be easily removed from the housing 2. It will not come off.

  Next, when removing the liquid supply tank 8 from the housing 2, the liquid supply tank 2 is once pushed downward. As a result, the pressing force applied to the contact portion between the engagement groove 80 of the liquid supply tank 8 and the engagement beam 77 of the housing 2 by the O-ring 70 is removed, and then the upper portion of the liquid supply tank 8 is pulled horizontally forward. Thus, the liquid supply tank 8 can be removed from the housing 2.

  In this way, if the liquid supply tank 8 is detachable from the housing 2, only the liquid supply tank 8 can be easily cleaned, and the liquid supply tank 8 containing various electrolyte solutions can be selectively used. Convenience is good.

  FIG. 10 shows another improved spray device 1B. In the following description, the same components as those of the above-described embodiment are denoted by the same reference numerals and description thereof is omitted.

  As shown in the figure, a plurality of (two in this embodiment) liquid supply tanks (containers) 8A and 8B in which a predetermined liquid as an object to be sprayed is stored are detachably stored in the housing 6, for example. Yes. The pump 10 sucks the liquid stored in the liquid supply tank 8A through the first pipe (supply pipe) 12a or receives it by the action of gravity, and receives the liquid in the second pipe (supply). (Pipe line) 14 and pumped to the electrolytic cell 28. Further, the conduit 12 b extending from the liquid supply tank 8 </ b> B is connected to the second conduit 14 at the junction 19. As a preferred modification, the conduit 12b extending from the tank 8B may be directly connected to the discharge conduit 15a (or 15b) or the electrolytic cell 29 without being connected to the second conduit 14. Alternatively, in addition to the configuration of FIG. 1, a third liquid supply tank may be provided separately, and this liquid supply tank may directly communicate with the discharge pipe 15 a (or 15 b) or the electrolytic cell 29. In addition, a constriction may be provided at the junction 19.

  Therefore, in such a configuration, when the pump 10 is operated, the liquid in the liquid supply tank 8A is pumped through the first pipe 12, the pump 10, and the second pipe 14, and the junction 19 Then, it is mixed with the liquid from the liquid supply tank 8B and supplied to the electrolytic cell. In the electrolytic cell 29, the polarity of the power applied to the electrodes 29a, 29b, and 29c is switched every predetermined time, whereby the cathode side electrolyte solution and the anode side electrolyte solution are alternately generated in one electrode, and the anode side The electrolytic solution and the cathode side electrolytic solution are mixed efficiently. Then, the mixed electrolyte of the anode side electrolyte and the cathode side electrolyte generated during electrolysis in the electrolytic layer 29 is divided into the discharge pipes 15a and 15b, and is discharged from the discharge ports of the discharge pipes 15a and 15b. The droplets 58 are supplied to the vibrating perforated plate 28a and further diffused and sprayed to the front of the perforated plate 28a through the fine through holes formed in the perforated plate 28a.

  As described above, according to the spraying apparatus 1B, since a plurality of liquid supply tanks 8A and 8B for storing a liquid as a spray target are provided, a plurality of types of liquids are sprayed at the same time or blended in the apparatus. It becomes possible to do. Specifically, two kinds of liquids that react with each other at the time of mixing can be used simultaneously, or two kinds of liquids having different effects can be used simultaneously to obtain a synergistic effect thereof. Furthermore, it is possible to use in such a way that the disadvantage of one liquid is compensated by the other liquid. For example, it is possible to obtain a viscosity suitable for spraying as a whole by using a liquid having a high viscosity while using a liquid having a low viscosity. Further, it is possible to use a mixture of an electrolyte container and a non-electrolyte solution. In FIG. 10, the volumes of the two liquid supply tanks 8A and 8B are different, but a plurality of tanks having the same volume may be arranged.

  Further, in the spray device 1B, the spray objects from the respective liquid supply tanks 8A and 8B are mixed in the merging unit 19 and supplied to the spray unit. For example, two types of liquids are reacted in advance in the device. Can be sprayed. Needless to say, the spray objects from the liquid supply tanks 8A and 8B may be individually supplied to the spray unit 4 without being mixed in the merge unit 19.

  Needless to say, the present invention is not limited to the above-described embodiments, and can be variously modified without departing from the scope of the invention. For example, in the above-described embodiment, there are two discharge pipelines extending from the electrolytic cell 28, but there may be one or three or more. FIG. 9 shows an embodiment having one discharge pipe. In this case, the spray object can be sprayed over a wide range by rotating the discharge end of the discharge pipe up and down. Even when such rotation is not performed, by reducing the particle diameter of the emulsified emulsified particles by ultrasonic vibration, it is possible to spray uniformly on the spray target site and increase the penetration rate. It is also possible to obtain unique effects that are not possible in the past. In the above-described embodiment, the mixed electrolyte is generated by switching the polarity of the power supplied to the inert electrode a plurality of times at a predetermined time interval. The form is arbitrary (not limited to switching the polarity). Further, in the above-described embodiment, three or more inert electrodes of the diaphragm electrolyzer are provided, but even if only one pair of inert electrodes is provided, ultrasonic vibration and electrolysis By the synergistic effect, it is possible to obtain the above-mentioned specific effects such as improvement of permeability, reduction of viscosity due to temperature rise, improvement of emulsification action and the like. Further, in the above-described embodiment, both ultrasonic vibration and electrolysis configurations are included, but only one configuration may be used. That is, in the configuration of FIGS. 1 and 10, the diaphragm electrolyzer 28 may be omitted, or the spray element 28 may be omitted.

  The spray device of the present invention electrolyzes an electrolyte solution such as a cosmetic or hygiene agent and applies ultrasonic vibration to improve the permeability to the human body, etc., and the mixed electrolyte is applied to the skin of the human body (colon). , Sunscreen, disinfection, sterilization, burn prevention, cleaning after excretion in the toilet, etc.), hair (dyeing, perm, rehabilitation, shampoo, rinse, treatment), scalp (hair restorer, hair restorer, tonic), eyelashes (eyelash) Curls, etc.), eyeball (eyeball disinfection, cleaning, etc.), mouth (disinfection, oral margin countermeasures, etc.), teeth (toothpaste, dental nail polish, etc.), nails (nail art chemicals, abrasives, nail nutrients, etc.) It can also be applied to the case of applying or spraying.

It is a schematic block diagram of the spraying apparatus which concerns on one Embodiment of this invention. It is the figure which showed typically the non-diaphragm electrolyzer and its surrounding components. It is a general | schematic expansion perspective view of a diaphragm electrolyzer. It is a schematic side view of the spraying apparatus which concerns on the modification in which the spraying part forms a comb shape. (A) is a schematic side view of the spraying apparatus which concerns on the other modification in which a spraying part forms a comb shape, (b) is a schematic perspective view which shows the state which the comb-shaped part opened at the predetermined angle. It is a perspective view which shows one structural example of the spraying device with which a liquid supply tank can be attached or detached with respect to a housing. It is sectional drawing which shows the attachment or detachment structure of the liquid supply tank in the structure of FIG. 6 (state before tank attachment). It is sectional drawing which shows the attachment or detachment structure of the liquid supply tank in the structure of FIG. 6 (state after tank attachment). It is a schematic block diagram which shows the modification of a spraying apparatus. It is a schematic block diagram which shows the other modification of a spraying apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Spraying device 2 Housing 4 Spraying part 8 Liquid supply tank (container)
10 Pump (supply means)
12 1st pipe line (supply means)
14 Second pipe (supply means)
15a, 15b Discharge pipe (flow path)
28b Piezoelectric vibrator 29 Non-membrane electrolytic cell 29a, 29b, 29c Inactive electrode

Claims (16)

A housing;
A container provided in the housing and containing a predetermined spray object;
A spray unit for spraying an object to be sprayed to the outside of the housing while vibrating by ultrasonic vibration;
Supply means for supplying the spray object in the container to the spray section;
With
The supply means includes a delivery means for delivering the spray object in the container to the outside of the container, and a supply conduit for guiding the spray object delivered from the container by the delivery means to the spray unit. A spraying device characterized by that. A non-diaphragm electrolytic cell that has inert electrodes opposed to each other without a diaphragm, and electrolyzes the supplied liquid to generate a mixed electrolyte of a cathode side electrolyte solution and an anode side electrolyte solution ,
The container contains a liquid as the spray object,
The supply line supplies the liquid from the container to the spray unit through the diaphragm electrolyzer,
The spray device according to claim 1, wherein the spray unit sprays the mixed electrolyte generated in the diaphragm electrolyzer to the outside of the housing.   The non-diaphragm electrolytic cell electrolyzes the supplied liquid by switching the polarity of the power supplied to the inert electrode a plurality of times at a predetermined time interval, so that the cathode-side electrolyte solution and the anode-side electrolyte solution The spray apparatus according to claim 2, wherein a mixed electrolyte is generated.   The spray apparatus according to claim 2 or 3, wherein the inert electrode is formed by coating a nickel-like carbon on a nickel plate.   5. The inert electrode of the diaphragm electrolyzer is provided with three or more inert electrodes, and at least one of the electrodes electrolyzes liquid using both surfaces thereof. The spraying device according to item.   The supply pipe supplies the spray object to the spray unit through a plurality of flow paths and discharges the spray target from the discharge port of each flow path to the spray unit. The spraying device according to claim 5.   The said supply pipe line has the discharge angle variable means which changes the discharge angle of the spraying target object through each of several flow paths, The any one of Claim 1 thru | or 6 characterized by the above-mentioned. Spraying equipment.   The spraying device according to any one of claims 1 to 7, wherein a plurality of the containers are provided.   The spraying device according to claim 8, wherein the supply unit mixes and supplies the spray target object from the containers to the spray unit.   The spraying device according to any one of claims 1 to 9, wherein the spraying portion has a comb shape.   The spraying device according to any one of claims 1 to 10, wherein a discharge amount of the spray object is adjustable.   The spray section includes a perforated plate having a plurality of through holes through which an object to be sprayed can penetrate, and a vibrator for vibrating the perforated plate. The perforated plate has a nickel plate coated with diamond-like carbon. The spray device according to any one of claims 1 to 11, wherein the spray device is configured as follows.   The spraying device according to any one of claims 1 to 12, wherein the spraying part is detachable from the housing.   The spray device according to any one of claims 1 to 13, wherein the container is detachable from the housing.   A spraying method characterized by applying ultrasonic vibration to an object to be sprayed and spraying the object to be sprayed ultrasonically toward an area to be sprayed.   The spraying method according to claim 15, wherein the spraying object is electrolyzed before applying ultrasonic vibration to the spraying object.

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