JP2013081646A - Ion generation device and hair care device with ion generation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ion generation device that can more reliably remove electricity of a cover, and a hair care device with the ion generation device.SOLUTION: The ion generation device 100 includes: a first electrode 51 for discharging; a second electrode 52 provided separately from the first electrode 51, and further includes: an ion generation part 50 for generating ions; and a cover 20 in which an ion blowout port 20c for blowing out the ions generated by the ion generation part 50 is formed. The cover 20 includes a projection part 21 in contact with the second electrode 52. The second electrode 52 makes contact with the projection part 21 on surfaces 52h, 21b facing in a direction crossing with an assembly direction of the cover 20 and the ion generation part 50.

Description

  The present invention relates to an ion generation device and a hair care device including the ion generation device.

  2. Description of the Related Art Conventionally, as a hair care device, a hair dryer including an ion generation unit having a first electrode that discharges and a second electrode provided separately from the first electrode is known (see, for example, Patent Document 1).

  In Patent Document 1, ions are generated by applying a high voltage between the first electrode and the second electrode to perform discharge, and the generated ions are blown out from an ion outlet formed in the cover. ing. And the hair care effect is heightened by hitting the ion blown out from the ion blower outlet to the hair.

  Furthermore, in this patent document 1, by providing a protrusion on the cover and bringing the protrusion into contact with the second electrode, the cover charged by the ions generated by the ion generation unit is neutralized, and ions blown out from the ion outlet The amount is suppressed from decreasing.

JP 2008-29813 A

  However, in the above-described conventional technique, the protrusion provided on the cover is brought into contact with the surface of the second electrode facing the cover assembly direction, thereby bringing the protrusion into contact with the second electrode. Therefore, there is a possibility that the protrusion and the second electrode do not come into contact with each other due to an assembly error of the cover, and there is a possibility that the charge cannot be reliably removed from the cover.

  Therefore, an object of the present invention is to obtain an ion generating device that can more reliably perform static elimination of a cover and a hair care device including the ion generating device.

  The first feature of the present invention includes a first electrode that discharges and a second electrode that is provided separately from the first electrode. The ion generator generates ions and the ion generator generates the ions. A cover on which an ion blow-out port for blowing out the generated ions is formed, wherein the cover is provided with a protrusion that contacts the second electrode, and the second electrode and the The gist is that the protrusion is in contact with a surface facing in the direction intersecting with the assembly direction of the cover and the ion generator.

  According to a second aspect of the present invention, the second electrode has a front surface facing the assembly direction of the cover and the ion generation unit, and a direction intersecting the assembly direction of the cover and the ion generation unit. The projecting portion is in contact with the side surface of the second electrode.

  The third feature of the present invention is summarized in that the protrusion is in contact with a side surface and a front surface of the second electrode.

  The gist of the fourth feature of the present invention is that the second electrode has a rear surface, and the protrusion is in contact with a side surface, a front surface and a rear surface of the second electrode.

  A fifth feature of the present invention is summarized as that the second electrode is in contact with the protrusion while being press-fitted.

  According to a sixth aspect of the present invention, the ion generation unit includes a plurality of fixing ribs that regulate the positions of the first electrode and the second electrode, and the protrusions are formed between the fixing ribs and the fixing ribs. And the second electrode are in contact with each other.

  The gist of a seventh feature of the present invention is a hair care device comprising the ion generating device.

  According to the present invention, the second electrode and the projecting portion are brought into contact with each other on a surface facing each other in a direction crossing the assembly direction of the cover and the ion generating portion. Therefore, even if the cover is displaced in the assembling direction between the cover and the ion generator, the contact state between the second electrode and the protrusion can be maintained. As a result, it is possible to obtain an ion generating device that can more reliably perform static elimination of the cover.

  Moreover, the hair care apparatus which can improve a hair care effect more can be obtained by using the ion production | generation apparatus which can discharge a cover more reliably.

It is a side view of the hair dryer as a hair care apparatus concerning one Embodiment of this invention. It is a perspective view of a hair dryer as a hair care device concerning one embodiment of the present invention. It is the front view which looked at the hair dryer as a hair care apparatus concerning one Embodiment of this invention from the blower outlet side. It is sectional drawing of the hair dryer as a hair care apparatus concerning one Embodiment of this invention. It is a top view which shows the part by which a metal microparticle production | generation part and a mist production | generation part are provided in the main-body part of the hair dryer as a hair care apparatus concerning one Embodiment of this invention. It is the front view which looked at the part in which the metal microparticle production | generation part and the mist production | generation part are provided in the main-body part of the hair dryer as a hair care apparatus concerning one Embodiment of this invention from the blower outlet side. It is a front view which expands and shows the part in which the metal microparticle production | generation part and mist production | generation part of FIG. 6 are provided. It is sectional drawing which expands and shows the part in which the mist production | generation part of FIG. 4 is provided. It is sectional drawing which shows the modification of an ion generator typically.

  Preferred embodiments of the present invention will be described below with reference to the drawings.

  A hair dryer 1 as a hair care device according to the present embodiment includes a gripping portion 1a as a portion gripped by a user's hand, and a main body portion 1b coupled in a direction intersecting the gripping portion 1a. The grip portion 1a and the main body portion 1b are configured to have a substantially T-shaped or L-shaped appearance (substantially T-shaped in the present embodiment). The power cord 2 is pulled out from the protruding end of the grip 1a. In addition, the grip portion 1a is divided into a base portion 1c and a tip portion 1d on the main body portion 1b side, and the root portion 1c and the tip portion 1d are rotatably connected via a connecting portion 1e. Yes. The front end 1d can be folded to a position along the main body 1b.

  The case 3 forming the outer wall of the hair dryer 1 is configured by joining together a plurality of divided bodies. A cavity is formed inside the case 3, and various electrical components are accommodated in the cavity.

  A wind tunnel 4 extending from the inlet opening 4a on one side (right side) in the longitudinal direction (left-right direction in FIG. 4) to the outlet opening 4b is formed in the main body 1b, and is accommodated in the wind tunnel 4. By rotating the fan 5, an air flow W1 is formed. That is, the air flow W1 flows into the wind tunnel 4 from the outside through the inlet opening 4a, and is discharged to the outside through the wind tunnel 4 from the outlet opening 4b.

  Further, in the main body 1 b, a substantially cylindrical inner cylinder 6 is provided inside the outer cylinder 3 a of the case 3, and the air flow W <b> 1 flows inside the inner cylinder 6. Inside the inner cylinder 6, the fan 5 is arranged on the most upstream side, a motor 7 for driving the fan 5 is arranged on the downstream side, and a heater 8 as a heating mechanism is arranged on the further downstream side of the motor 7. . When the heater 8 is operated, warm air is blown out from the outlet opening 4b. In the present embodiment, the heater 8 is configured as a belt-like and corrugated electric resistor wound around the inner periphery of the inner cylinder 6, but is not limited to this configuration.

  In the main body 1b, two (plural) metal fine particle generation units (ion generation units) 30, 40 and a mist generation unit (ion) are formed in the cavity 9 formed between the case 3 and the inner cylinder 6. Generating section) 50, a voltage applying circuit 12 for applying a voltage to the mist generating section 50, and the like are accommodated. In addition, a voltage application circuit (not shown) for applying a voltage to the metal fine particle generation units 30 and 40 is accommodated in a part of the cavity 9 different from the part in which the voltage application circuit 12 is accommodated.

  A voltage application circuit (not shown) for applying a voltage to the voltage application circuit 12 and the metal fine particle generation units 30 and 40 is disposed in the gripping portion 1a or a region on the extension line of the gripping portion 1a in the main body portion 1b. Is preferred. When the user holds the grip portion 1a, the rotational moment due to the mass of the voltage application circuit 12 and the voltage application circuit (not shown) is reduced to reduce the load acting on the user's hand. is there.

  Further, it is preferable that the voltage application circuit 12 and the voltage application circuit (not shown) are arranged at positions opposite to each other across the inner cylinder 6. By so doing, it is possible to suppress problems such as voltage drop and instability due to mutual interference between the voltage application circuit 12 and the voltage application circuit (not shown).

  Furthermore, in the present embodiment, a switch unit (not shown) that performs switching between hot air and cold air, an operation mode, and the like on a side surface portion of the cavity 9 (a part different from the part where the voltage application circuit 12 of the cavity 9 is accommodated). Is housed.

  Further, another switch portion 16 for switching the power ON and OFF and the like is accommodated in the cavity in the distal end portion 1d of the grip portion 1a. These electrical components are connected to each other by a lead wire 17 in which a core wire made of a metal conductor or the like is covered with an insulating resin or the like. Note that the lead wire 17 connected to the metal fine particle generation unit 30, the lead wire 17 connected to the metal fine particle generation unit 40, and the lead wire 17 connected to the mist generation unit 50 are routed as far as possible without crossing each other. Is preferred. This is to prevent the metal fine particle generation units 30 and 40 or the mist generation unit 50 from obtaining a desired voltage or causing the voltage to become unstable due to mutual interference of currents flowing through the lead wires 17. .

  In addition, a switch unit (not shown) for switching between hot air and cold air, an operation mode, and the like operates the operation element 19 formed integrally by cutting the surface of the case 3 to change the open / close state of the internal contacts. It can be switched. A display unit 14 for displaying the currently selected mode is formed above the operation element 19.

  Further, the switch unit 16 is configured to be able to switch the open / close state of the internal contact by operating the operation element 18 exposed on the surface of the case 3.

  The inner cylinder 6 includes a cylindrical portion 6a, a plurality of support ribs 6b (only one place is shown in FIG. 4) that extends radially outward from the cylindrical portion 6a and is distributed in the circumferential direction. A flange portion 6c connected to the tubular portion 6a via the rib 6b and projecting in a direction substantially orthogonal to the axial direction of the tubular portion 6a. A gap g1 is formed between the tubular portion 6a and the flange portion 6c, and a part of the air flow W1 is branched into the cavity 9 via the gap g1 to form a branch flow W2. ing. The gap g1 that serves as an inlet for the branch flow W2 into the cavity 9 is provided at a position downstream of the fan 5 and upstream of the heater 8. Therefore, the branch flow W2 becomes a relatively cool air flow before being heated by the heater 8.

  A part of the branch flow W2 is further branched into a branch flow W3. This branch flow W3 does not pass through the metal fine particle outlets (ion outlets) 20a and 20b and the mist outlet (ion outlet) 20c, which will be described later, and passes between the inner cylinder 6 and the case 3 to become an outlet opening 4b. It is a relatively cool air flow that blows out from the outer peripheral portion.

  The case 3 is formed with an elliptical through hole 3b at a position on the outlet opening 4b side of the cavity 9, and the through hole 3b is closed with a cover 20 made of an insulating synthetic resin material. In the cover 20, metal fine particle outlets (ion outlets) 20 a and 20 b and a mist outlet (ion outlet) 20 c are formed independently. The cover 20 preferably has lower conductivity than the case 3 in order to suppress charging due to metal fine particles or mist. This is because when the cover 20 is charged, charged metal particles, negative ions, and mist are hardly released from the metal particle generation units 30 and 40 and the mist generation unit 50 due to the charge. In order to suppress charging of the cover 20, it is preferable to form the cover 20 using a material that does not easily charge, for example, PC (polycarbonate) resin, and to make the material of the cover 20 a material that does not easily cause charging. In this part, the cover 20 forms the outer wall of the hair dryer 1.

  Moreover, in this embodiment, the hole diameter of metal fine particle outlet 20a, 20b is made smaller than the hole diameter of mist outlet 20c. In other words, maintenance of the mist generating unit 50 through the mist outlet 20c, confirmation of the state, etc. can be performed more easily, and erroneous entry of fingers, tools, etc. through the metal particulate outlets 20a, 20b can be suppressed. It is.

  Further, a rib (projection) 21 is provided on the inner side of the cover 20, and the rib (projection) 21 is brought into contact with a discharge counter electrode (second electrode) 52 of a mist generation unit 50 described later. The cover 20 is neutralized.

  As described above, in this embodiment, the cover 20 and the mist generation unit (ion generation unit) 50, and the cover 20 and the metal fine particle generation units (ion generation units) 30 and 40 form three ion generation apparatuses 100. Yes.

  Furthermore, in the present embodiment, metal fine particle outlets (ion outlets) 20a and 20b are formed in the peripheral portion 20d of the mist outlet 20c.

  Specifically, the metal fine particle outlet 20a and the metal fine particle outlet 20b are arranged side by side so that the mist outlet 20c is at the center.

  In other words, the cover 20 has metal fine-particle outlets 20a, 20b and a mist outlet 20c in the width direction of the hair dryer 1 (left-right direction in FIG. 3). They are formed so as to be arranged in the order of 20b.

  With such an arrangement, a negatively charged mistake is caused by negative ions blown out from the metal fine particle outlets (ion outlets) 20a and 20b formed in the peripheral portion 20d of the mist outlet 20c. It is possible to suppress the diffusion (discrete) to the outside.

  As a result, the straightness of the mist is improved so that the mist can easily reach the hair, and the hair care effect can be further enhanced.

  Furthermore, a wall portion 20e is provided downstream and below the mist outlet 20c so as to extend in the mist blowing direction. By providing the wall portion 20e, the mist blown from the mist blower outlet 20c can be prevented from diffusing downward (discrete).

  Further, the metal fine particle generation units 30 and 40 and the mist generation unit 50 are arranged in the cavity 9 in the width direction of the hair dryer 1 (left and right direction in FIG. 7), the metal fine particle generation unit 30, the mist generation unit 50, and the metal fine particle generation unit 40. Are arranged in parallel.

  A shielding plate (partition unit) 6 d is provided between the mist generation unit 50 and the metal fine particle generation units (negative ion generation units) 30 and 40 adjacent to the mist generation unit 50. Then, as shown in FIGS. 5 and 7, the shielding plate 6d is arranged so as to extend in the vertical direction of the hair dryer 1 and the blowing direction of the mist (the horizontal direction in FIG. 7), so that the metal fine particles and the mist are formed. Mixing before being blown out from the metal fine particle outlets 20a and 20b and the mist outlet 20c is suppressed.

  The metal fine particle generation units 30 and 40 have discharge electrodes (first electrodes) 32 and 42 and discharge counter electrodes (second electrodes) 33 and 43 formed of a conductive metal material. Then, a high voltage (-1 kV to -3 kV in this embodiment) is applied between the discharge electrodes 32 and 42 and the discharge counter electrodes 33 and 43 by a voltage application circuit (not shown) to discharge (corona discharge). Etc.) and the discharge action causes metal fine particles (metal molecules, negative ions, etc.) to be emitted from the discharge electrodes 32, 42, the discharge counter electrodes 33, 43, and the like.

  In this embodiment, the metal fine particle generation units 30 and 40 are formed in substantially the same shape, but the metal fine particle generation units 30 and 40 may have different shapes.

  The discharge electrodes 32 and 42 are configured as extremely fine wires, and have a width (diameter) of 10 to 400 [μm] (preferably 30 to 300 [μm], and more preferably 50 to 200 [μm]). It is set to. As the cross-sectional shape, various shapes such as a circular shape, an elliptical shape, and a polygonal shape can be adopted.

  In addition, the discharge electrodes 32 and 42 are, for example, a transition metal (for example, gold, silver, copper, platinum, zinc, titanium, rhodium, palladium, iridium, ruthenium, osmium, etc.), an alloy, or a transition metal plated It can comprise as a member etc. which did. When the metal fine particles generated and released by the metal fine particle generation units 30 and 40 contain gold, silver, copper, or the like, the antibacterial action can be caused by the metal fine particles. In addition, when the metal fine particles contain platinum, zinc, titanium, or the like, the metal fine particles can cause an antioxidant effect. Platinum fine particles have been found to have an extremely high antioxidant effect. In addition, the metal fine particle generation units 30 and 40 generate ions (for example, negative ions such as NO 2− and NO 3−) by the discharge action, and the ions are discharged to the discharge electrodes 32 and 42 and the discharge counter electrodes 33 and 43, Metal fine particles may be generated by colliding with other metal materials or members containing metal components. That is, the discharge counter electrodes 33 and 43 and the other members may be made of a material containing the transition metal, and the metal fine particles may be emitted therefrom.

  As shown in FIG. 7, the discharge counter electrodes 33 and 43 have substantially rectangular base portions 33a and 43a and terminal portions 33b and 43b protruding from the base portions 33a and 43a.

  Circular openings 33c and 43c serving as metal particle discharge ports are formed at substantially central positions of the base portions 33a and 43a. As shown in FIG. 7, when viewed from the front, the discharge electrodes 32 and 42 are disposed substantially at the centers of the openings 33c and 43c. On the other hand, the terminal portions 33b and 43b are provided with through holes 33d and 43d through which the lead wires 17 are inserted and connected.

  As a result of intensive studies by the inventors on the metal fine particle generation part having the above structure, platinum fine particles are supplied to the hair and the like to impart an antioxidant effect to the hair and recover the damage to the hair. In addition, it has been found that when zinc fine particles are supplied to hair or the like, damage to hair or the like can be recovered more effectively.

  Therefore, in the present embodiment, the metal contained in the discharge electrode 32 of the metal fine particle generation unit 30 is platinum, and the metal contained in the discharge electrode 42 of the metal fine particle generation unit 40 is zinc. Note that platinum may be included in the discharge electrode 42 and zinc may be included in the discharge electrode 32.

  The mist generating unit 50 includes a discharge electrode (first electrode) 51 and a discharge counter electrode (second electrode) 52 formed of a conductive metal material. A high voltage (-3 kV to -5 kV in the present embodiment) is applied between the discharge electrode 51 and the discharge counter electrode 52 by the voltage application circuit 12 to generate a discharge (corona discharge or the like). is there.

  In the present embodiment, the discharge electrode 51 is formed in a needle shape, and the discharge counter electrode 52 is formed as an annular and plate-like member spaced apart from the distal end side of the discharge electrode 51.

  As shown in FIG. 7, the discharge counter electrode 52 has a substantially annular base portion 52a and a terminal portion 52b protruding from the base portion 52a.

  A circular opening 52c serving as a metal fine particle outlet is formed at a substantially central position of the base 52a. As shown in FIG. 7, when viewed from the front, the discharge electrode 51 is disposed substantially at the center of the opening 52c. On the other hand, the terminal portion 52b is provided with a through hole 52d through which the lead wire 17 is inserted and connected.

  In addition, as the mist generating unit 50, an electrostatic fog provided with a cooling device 53 for cooling the discharge electrode 51, and a radiation fin 54 for radiating heat generated when the discharge device 51 is cooled by the cooling device 53 The device is used.

  Specifically, the mist generating unit 50 includes a Peltier element 53a as the cooling device 53 and a cooling plate 53b made of a member having thermal conductivity (for example, a metal member), and is cooled by the Peltier element 53a. Moisture in the air is condensed on the surface of the cooling plate 53b to generate condensed water. Further, on the upstream side of the mist generating unit 50, a heat dissipating fin 54 that dissipates heat generated when the cooling plate 53b is cooled is provided. In such a configuration, the supplied water, that is, condensed water is atomized by the discharge action, and a very fine mist (a negatively charged mist including negative ions) is generated.

  Further, the metal fine particle generation units 30 and 40 and the mist generation unit 50 are placed on a fixing rib (fixing member) 6g projecting from the upper wall 6f of the inner cylinder 6 so that the metal fine particle generation units 30 and 40 and A mist generating unit 50 is fixed above the inner cylinder 6.

  In addition, by setting the shape and the protruding position of the fixing rib 6g in various ways, it is possible to set the wind direction and the amount of wind flowing through the cavity (branch channel) 9 to a desired amount. That is, the fixed rib 6g can be used as a control means for controlling the wind direction and the amount of wind flowing through the cavity (branch channel) 9.

  Here, in this embodiment, the discharge counter electrode (second electrode) 52 and the rib (projection) 21 are opposed to each other in a direction crossing the front-rear direction (the assembly direction of the cover 20 and the mist generating unit 50). The surface is in contact.

  Specifically, the discharge counter electrode (second electrode) 52 includes a front surface 52g facing forward in the front-rear direction (the assembly direction of the cover 20 and the mist generating unit 50), and the width direction of the hair dryer 1 (cover 20 and ions). A direction intersecting the assembly direction with the generation unit 50) and a side surface 52h facing outward. The rib (projection) 21 is brought into surface contact with the side surface 52 h of the discharge counter electrode (second electrode) 52.

  Further, in the present embodiment, the rib (projection) 21 is also in surface contact with the front surface 52 g of the discharge counter electrode (second electrode) 52.

  In the present embodiment, when the cover 20 is assembled, the discharge counter electrode (second electrode) 52 is press-fitted into the rib (projection) 21 so that the front surface 52 g and the side surface of the discharge counter electrode (second electrode) 52 are pressed. The rib (projection) 21 is brought into surface contact with 52h.

  Specifically, the ribs 21 are in contact with the front surface 52g and the side surface 52h of the discharge counter electrode (second electrode) 52 at four locations on the outer periphery of the base portion 52a of the discharge counter electrode (second electrode) 52. Projected at four locations on the back surface of the cover 20.

  The four ribs 21 are formed with guide inclined surfaces 21a for guiding the insertion of the discharge counter electrode (second electrode) 52 on the front end side, and the lateral contact surfaces 21b are provided continuously with the guide inclined surfaces 21a. Is formed. And the front side contact surface 21c is formed so that it may continue with the horizontal side contact surface 21b.

  Further, the four ribs 21 are provided at positions shifted by 90 degrees so that the two ribs 21 face each other. At this time, the four ribs 21 are provided such that the guide inclined surfaces 21a of the ribs 21 facing each other and the side contact surfaces 21b face each other. The guide slopes 21a facing each other are formed to have a taper that becomes wider toward the tip (rear).

  Further, the width of the lateral contact surfaces 21 b facing each other is made slightly narrower than the diameter of the base portion 52 a of the discharge counter electrode (second electrode) 52, so that the discharge counter electrode (second electrode) ) 52 is held between the ribs 21 facing each other.

  With this configuration, the discharge counter electrode (second electrode) 52 is inserted while being guided by the guide inclined surface 21a, and the side surface 52h of the discharge counter electrode (second electrode) 52 faces the lateral contact surface 21b. Press-fitted to contact. Further, by inserting the discharge counter electrode (second electrode) 52 to the back, the side surface 52h is in surface contact with the lateral contact surface 21b and the front surface 52g is in front contact with the rib 21 being press-fitted. It will be in surface contact with the surface 21c.

  Further, in the present embodiment, the mist generation unit (ion generation unit) 50 includes a plurality of fixing ribs 55 that regulate the positions of the discharge electrode (first electrode) 51 and the discharge counter electrode (second electrode) 52. Yes.

  Specifically, the four fixing ribs 55 are provided at positions shifted by 90 degrees so that the two fixing ribs 55 face each other.

  In addition, projecting portions 52 e that project in a semicircular shape are provided at four locations on the outer periphery of the base portion 52 a of the discharge counter electrode (second electrode) 52. The positions of the discharge electrode (first electrode) 51 and the discharge counter electrode (second electrode) 52 are respectively inserted by inserting the fixing ribs 55 into the through holes 52f formed at the positions where the protrusions 52e are provided. Is regulated.

  At this time, the rib (projection) 21 and the discharge counter electrode (second electrode) 52 are in contact with each other between the fixing rib 55 and the fixing rib 55. That is, the fixing rib 55 and the rib (projection) 21 do not come into contact with the cover 20 and the mist generation unit (ion generation unit) 50 assembled (the discharge counter electrode 52 is press-fitted into the rib 21). I am doing so.

  As described above, in the present embodiment, the discharge counter electrode (second electrode) 52 and the rib (projection) 21 intersect the assembly direction of the cover 20 and the mist generation unit (ion generation unit) 50. Surface contact (surface 52h and side contact surface 21b) facing each other. Therefore, even if the cover 20 is displaced in the assembly direction of the cover 20 and the mist generating part (ion generating part) 50, the contact state between the discharge counter electrode (second electrode) 52 and the rib (projecting part) 21 Can keep. As a result, it is possible to obtain the ion generating apparatus 100 that can more reliably remove the charge of the cover 20.

  Thus, when the cover 20 is displaced in the assembling direction of the cover 20 and the mist generating part (ion generating part) 50, the discharge counter electrode (second electrode) 52 and the rib (projecting part) 21 By allowing the contact state to be maintained, an allowable range of an assembly error between the cover 20 and the mist generating unit (ion generating unit) 50 is widened, and the manufacturing can be easily performed.

  In the present embodiment, the rib (projection) 21 is also in surface contact with the front surface 52 g of the discharge counter electrode (second electrode) 52. As a result, the contact area between the discharge counter electrode (second electrode) 52 and the rib (projection) 21 increases, and the charge removal of the cover 20 can be performed more sufficiently.

  In this embodiment, the discharge counter electrode (second electrode) 52 is press-fitted into the rib 21, and the side surface 52h is in surface contact with the lateral contact surface 21b and the front surface 52g is in front contact surface 21c. Is in surface contact. Thus, by press-fitting the discharge counter electrode (second electrode) 52 into the rib 21, the contact pressure between the discharge counter electrode (second electrode) 52 and the rib 21 can be increased, and the cover 20 can be stabilized more stably. It becomes possible to perform static elimination.

  Furthermore, in this embodiment, the rib (projection) 21 and the discharge counter electrode (second electrode) 52 are in contact between the fixing rib 55 and the fixing rib 55. That is, the fixing rib 55 and the rib (projection) 21 do not come into contact with the cover 20 and the mist generation unit (ion generation unit) 50 assembled (the discharge counter electrode 52 is press-fitted into the rib 21). I am doing so. Accordingly, it is possible to suppress the reduction of the charge removal effect due to the contact between the fixing rib 55 and the rib (projection) 21, and the charge removal of the cover 20 can be performed more reliably and more stably.

  Moreover, the hair dryer (hair care apparatus) which can improve a hair care effect more can be obtained by using the ion production | generation apparatus 100 which can discharge the cover 20 more reliably.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above embodiments, and various modifications can be made.

  For example, as shown in FIG. 9, the rib (projection) 21 may be in surface contact with the front surface 52g, the side surface 52h, and the rear surface 52i of the discharge counter electrode (second electrode) 52.

  Specifically, in FIG. 9, a rear contact surface 21d is formed between the guide slope 21a and the lateral contact surface 21b.

  The rear contact surface 21d is in surface contact with the rear surface 52i.

  That is, in FIG. 9, the discharge counter electrode (second electrode) 52 is press-fitted to the rib 21, and the front surface 52g, the side surface 52h, and the rear surface 52i are the front contact surface 21c and the lateral contact surface, respectively. The surface 21b and the rear contact surface 21d are in surface contact.

  By so doing, the contact area between the discharge counter electrode (second electrode) 52 and the rib (projection) 21 increases, and the charge removal of the cover 20 can be performed more sufficiently.

  Further, by press-fitting the discharge counter electrode (second electrode) 52 into the rib 21, the discharge counter electrode (second electrode) 52 is suppressed from coming off the rib 21, and more reliably and more stably. The charge of the cover 20 can be removed.

  Moreover, in the said embodiment, although the mist production | generation part was illustrated as an ion production | generation part which has the discharge counter electrode (2nd electrode) which a rib (projection) contacts, this invention can also be applied to a metal microparticle production | generation part. It is.

  Moreover, in the said embodiment, although the metal microparticle production | generation part which produces | generates a metal microparticle and a negative ion was illustrated as an ion production | generation part, you may use what does not produce | generate a metal microparticle but only produces | generates a negative ion.

  The present invention can also be applied to an ion generator that generates positive ions.

  Moreover, in the said embodiment, although what has the discharge counter electrode (2nd electrode) facing a discharge electrode (1st electrode) as a mist production | generation part and a negative ion production | generation part was illustrated, a 2nd electrode is a discharge electrode (1st electrode). One provided at a position not facing one electrode) may be used.

  Moreover, in the said embodiment, although what formed two metal microparticle outlets (ion outlet) was illustrated, it is also possible to form three or more metal microparticle outlets (ion outlet).

  Further, in the above embodiment, the metal fine particles and the mist are blown out by the branch flow, but even when there is no branch flow, the metal fine particles and the mist can be blown out from the corresponding outlet.

  Further, the present invention can be implemented even in other hair care devices such as a hair brush and a hair iron.

  Further, the specifications (shape, size, layout, etc.) of the cover, case, and other details can be changed as appropriate.

1 Hair dryer (hair care device)
20 Cover 20a, 20b Metal fine particle outlet (ion outlet)
20c Mist outlet (ion outlet)
21 ribs
30, 40 Metal fine particle generator (ion generator)
32, 42 discharge electrode (first electrode)
33, 43 Discharge counter electrode (second electrode)
50 Mist generator (ion generator)
51 Discharge electrode (first electrode)
52 Discharge counter electrode (second electrode)
52g Front surface 52h Side surface 52i Rear surface 55 Fixing rib 100 Ion generator

Claims (7)

An ion generation unit that has a first electrode that discharges and a second electrode that is provided separately from the first electrode, and an ion outlet that blows out ions generated by the ion generation unit An ion generating device comprising a formed cover,
The cover is provided with a protrusion that contacts the second electrode,
The ion generating apparatus according to claim 1, wherein the second electrode and the protrusion are in contact with each other in a surface facing in a direction intersecting an assembly direction of the cover and the ion generating unit. The second electrode includes a front surface facing the assembly direction of the cover and the ion generation unit, and a side surface facing a direction intersecting the assembly direction of the cover and the ion generation unit,
The ion generating apparatus according to claim 1, wherein the protrusion is in contact with a side surface of the second electrode.   The ion generation apparatus according to claim 2, wherein the protrusion is in contact with a side surface and a front surface of the second electrode. The second electrode has a rear surface;
The ion generating apparatus according to claim 3, wherein the protrusion is in contact with a side surface, a front surface, and a rear surface of the second electrode.   5. The ion generating apparatus according to claim 1, wherein the second electrode is in contact with the protruding portion while being press-fitted.   The ion generating portion includes a plurality of fixing ribs that regulate the positions of the first electrode and the second electrode, and the protrusion and the second electrode are in contact between the fixing rib and the fixing rib. The ion generator according to any one of claims 1 to 5, wherein:   A hair care device comprising the ion generation device according to claim 1.

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