TW201034598A - Hair care device - Google Patents

Abstract

A hair care device comprising a casing, a fine metal particle-forming part for forming fine metal particles which is provided in a section within the casing, and a mist-forming part for forming a mist which is provided in the aforesaid section within the casing. The fine metal particle-forming part is located outside a mist-passing area through which the mist formed in the mist-forming part passes. According to this hair care device, the arrival of the mist formed in the mist-forming part to the fine metal particle-forming part can be inhibited using a simplified constitution. As a result, a lowering in the ability of the fine metal particle-forming part to release the fine metal particles caused by the mist can be prevented.

Description

201034598 VI. [Technical Field] The present invention relates to a hair care device.  [Prior Art] As a conventional hair care hair dryer (hair care device), There is a metal microparticle generating unit and a mist generating unit (Japanese Patent Laid-Open No. 2008_23063 No. 0: Patent Document 1).  [Technical Problem to be Solved by the Invention] When the mist generated by the mist generating portion of the hair care device is moved to the metal fine particle generating portion, The metal microparticle generating portion is corroded.  also, When the mist generating portion is formed as a static mist Q-forming mechanism that is atomized by discharge, When the mist moves to the metal particle generating portion, By the charge of the mist, The release property of the metal fine particles in the metal fine particle generating portion is lowered.  In the hair dryer of the above-mentioned Patent Document 1, the metal microparticle generating portion and the mist generating portion are housed in separate housings. Therefore, The mist does not easily move to the metal microparticle generating portion.  but, Since the number of parts is increased due to the additional arrangement of the housing, the weight is increased or the manufacturing cost is increased.  here, The purpose of the present invention, It is to provide a composition that can be simplified by -5-201034598, It is possible to suppress the movement of the mist generated by the mist generating portion to the hair care device of the metal microparticle generating portion.  [Technical means for solving the problem] Features of the present invention, In order to provide a housing having And a dividing zone disposed in the housing, And generating a metal microparticle generating portion of the metal microparticles, And the above-mentioned divided area disposed in the above casing, And generating a mist generating portion of the mist; The metal fine particle generating portion, For configuration in: The mist passing through the mist generated by the mist generating portion passes through the hair care device outside the region.  According to the above hair care device, Compared with the case where the metal fine particle generating portion and the mist generating portion are housed in another casing, In order to make it simpler, The mist is prevented from moving to the metal fine particle generating portion.  here, The metal fine particle generating portion is disposed in a direction substantially perpendicular to a direction in which the mist passes through the mist passing region, from the mist generating portion. More ideal.  As a result, The mist which is discharged from the mist generating portion and flows through the mist passing region can be prevented from moving to the metal fine particle generating portion.  here, a metal fine particle discharge port for discharging the metal fine particles and a mist discharge port for discharging the mist. To form the outer casing of the hair care device described above, The metal fine particle generating portion is disposed to face the metal fine particle discharge port. The mist generating unit is disposed to face the mist discharge port, More ideal.  As a result, The mist that will be released from the mist generating part is faster. -6- 201034598 The ground is discharged from the mist discharge port. It is also possible to suppress the mist from moving to the metal fine particle generating portion. also, Since the metal fine particle generating portion is disposed opposite to the metal fine particle discharging port, Therefore, the metal particles are more quickly discharged from the metal particle discharge port.  also, here, a distance between the metal fine particle generating portion and the mist generating portion, Therefore, the distance between the mist generating portion and the cover is longer than More ideal.  As a result, The mist that will be released from the mist generating portion is quickly discharged from the mist discharge port. It is also possible to suppress the mist from moving to the metal particle generating portion.  a cover having a lower electrical conductivity than the above-mentioned housing and the above-mentioned housing being a separate component, Mounted in the above casing as the outer casing, More ideal.  As a result, The housing is electrically charged because the outer casing is a separate component of low electrical conductivity. the result, The metal fine particle emission performance of the metal fine particle generating portion can be suppressed from being lowered due to charging.  Further, the shielding wall that moves to the metal fine particle generating portion by suppressing the mist is further provided. More ideal.  As a result, By shielding the wall, It is also possible to suppress the mist from moving to the metal microparticle generating portion.  Further, the shielding wall that moves to the metal fine particle generating portion by suppressing the mist is further provided, and the cover is electrically insulated from the shielding wall. More ideal.  As a result, The charging of the shielding wall caused by the movement of the metal particles or the mist from the cover toward the shielding wall can be suppressed. therefore, It can suppress the decrease in the metal fine particle emission performance of the metal micro-201034598 particle generating portion due to charging.  here, By forming a gap between the cover and the shielding wall, The cover is electrically insulated from the shielding wall, More ideal.  In this way, the electrical insulation between the cover and the shielding wall can be achieved by a very simplified configuration.  The above shielding wall, The assembly is integrated with a mounting member that mounts the metal fine particle generating portion or the mist generating portion in the casing. More ideal.  As a result, The mounting member and the shielding wall can be shared. Compared with the case where these are separately set, The composition can be simplified.  To have a light source, And guiding the light from the light source and performing the light guiding member functioning as the shielding wall. More ideal.  As a result, When setting the light guiding member, Effectively utilizing the light guiding member as a shielding wall, It can suppress the movement of the mist to the metal fine particle generating portion.  here, In addition to the above light guiding members, Further, the other shielding wall integrated with the mounting member that mounts the metal fine particle generating portion or the mist generating portion in the casing is provided. And the light guiding member is arranged in parallel with the other shielding walls. More ideal.  As a result, The double wall structure can be formed by the shielding wall (light guiding member) and other shielding walls, Further, it is possible to suppress the mist from moving to the metal fine particle generating portion.  [Embodiment] -8 * 201034598 Below, The embodiment of the present invention will be described with reference to the drawings. also, The following constituent elements and modifications include the same constituent elements. therefore, The same components are denoted by the same reference numerals, and the description thereof will not be repeated.  (First embodiment) In Figs. 1 to 3, A hair dryer (hair care device) 1 according to the first embodiment is shown.  护 Hair care hair dryer 1, There is a grip la that the user holds with his hand, And a body lb that is combined with the grip la in a direction intersecting the grip la.  Hair care hair dryer 1, At the time of use, the grip 1 a and the main body 1 b have an appearance of a T-shape or an L-shape (substantially T-shaped in the present embodiment).  From the end of the grip la, The power cord 2 is exported. also, Grip la, The base 1 c and the grip 1 d on the side of the body 1 b are divided. Base 1 c and grip 1 d,  The interposing portions 1 e are rotatably coupled together. Grip 1 d,  Q is foldable to a position parallel to the body lb.  a casing 3 constituting a casing of the hair care hair dryer 1, It is constructed by joining a plurality of dividing bodies. A cavity is formed inside the casing 3, In the hole,  Contains a variety of electrical parts.  Inside the body lb, A wind tunnel 4 is formed. Wind tunnel 4, The inlet opening 4a (suction port) from the one side (right side) is formed in the longitudinal direction of the main body 1b (the horizontal direction in Fig. 2) to the outlet opening 4b (discharge port). By the rotation of the fan 5 housed in the wind tunnel 4, A free air flow W is formed. that is, Air flow W, The inlet opening 4a is inserted from the outside into the wind tunnel 4, It is discharged to the outside through the outlet opening 4b through the inside of the wind tunnel 4.  Inside the outer cylinder 3a of the casing 3, A cylindrical inner cylinder 6 is provided. The air flow W flows inside the inner cylinder 6. On the inner side of the inner cylinder 6,  Fan 5, And a motor that drives the fan 5, And a heater 8 as a heating mechanism, It is arranged from the upstream side in this order. When the heater 8 is activated, The warm air will be blown out from the exit opening 4b. also, In this embodiment,  Heater 8, A strip-shaped and corrugated electric resistance body is wound around the inner circumference of the inner cylinder 6. but, The composition of the heater 8, It is not limited to the above configuration.  a cavity 9 between the casing 3 and the inner cylinder 6 formed in the body lb In order to accommodate the metal microparticle generating portion 10, The mist generating unit 11, And a second voltage applying circuit 12 or the like for applying a voltage to the mist generating portion 11. also,  a cavity 13 in the base portion lc of the grip la, A first voltage applying circuit 14 that applies a voltage to the metal particle generating portion 1 容纳 is housed, And a switch 15 for switching the operation mode or the like. Furthermore, The void in the handle Id of the grip, The other switch 16 that performs switching of the power supply ΟΝ/OFF or the operation mode is accommodated. Such electrical parts, The guide wires 17 formed by covering the core wires of the metal conductor or the like with an insulating resin or the like are connected to each other. also, Switch 1 5, 1 6, a switch button 18 that is exposed on the surface of the casing 3, 1 9 operation, To switch the open and close state of the internal contacts.  a first voltage applying circuit 14 and a second voltage applying circuit 12, As shown in Figure 1, The area inside the grip 1 a or the body 1 b disposed on the extension line of the grip 1 a is suitable. If so implemented, It is possible to reduce the rotational moment (the moment arm) generated by the gravity acting on the first voltage applying circuit 14 and the second voltage applying circuit 12 when the user -10- 201034598 is holding the grip la,  It can reduce the load on the user's hand.  also, As shown in Figure 1, In this embodiment, The first voltage applying circuit 14 and the second voltage applying circuit 12, The inner cylinders 6 are placed at positions opposite to each other. that is, An inner cylinder 6 is interposed between the first voltage applying circuit 14 and the second voltage applying circuit 12. As a result, It is possible to suppress the deterioration of the voltage caused by the mutual interference between the first voltage applying circuit 14 and the second voltage applying circuit 12 or the instability or the like.  Inner cylinder 6, In order to have a cylinder 6a, And the supporting rib 6b (in the first picture, only one picture is not shown), And a flange 6c. Support rib 6b, To extend outward from the cylindrical body 6a in the radial direction, And arranged at predetermined intervals in the direction of the circumference. Flange 6c, The intervening support rib 6b is connected to the barrel 6a, And projecting outward in a direction orthogonal to the axial direction of the cylindrical body 6a. A gap gi is formed between the cylindrical body 6a and the flange 6c. Part of the air flow W, Will divide Q and flow into the cavity 9 via the gap g 1 The split flow Wp is formed. also, The gap gl of the introduction port into which the branching flow Wp is directed into the cavity 9 is formed. Located downstream of the fan 5, It is the upstream position of the heater 8. therefore, Divide W p, It is a relatively cold air stream before being heated by the heater 8.  also, As shown in Figure 3, Connected to the guide wire 17a of the metal fine particle generating portion 1〇, And a guide line 17b connected to the mist generating portion 1 1 It is preferable to use wiring that does not cross each other and is extremely separated. in this way, It can suppress the flow to the guide line 17a, The current of 1 7b does not obtain the voltage expected by the metal fine particle generating portion 10 or the mist generating portion 11 due to mutual interference. Or the voltage change -11 - 201034598 is not stable. In the present embodiment, the metal fine particle generating portion 10 and the mist generating portion 11, It is disposed apart along the circumferential direction of the inner cylinder 6. And ' lead wire 1 7a, For the void 9, Along the direction of the circumference above, The wiring is in a region on one side of the metal fine particle generating portion 1 (upper side in Fig. 3).  on the other hand, The guide line 17b' is in the cavity 9 along the circumferential direction described above, Wiring the area on the other side (the lower side of Figure 3).  As shown in Figure 2, in the housing 3, The elliptical through hole 3b' is formed on the outlet opening 4b side of the cavity 9. Through hole 3b, It is covered by a cover 20 made of an insulating synthetic resin material. In the cover 20, A metal fine particle discharge port 20a and a mist discharge port 20b are formed. In order to suppress the charging of the cover 20 due to metal particles or mist, Cover 20, It is preferable to have a low electrical conductivity lower than that of the casing 3. If the cover 20 is energized, Due to the charge, The charged metal fine particles or the mist are less likely to be released from the metal fine particle generating portion 1 or the mist generating portion 11. also, In this part, The cover 20 is an outer casing constituting the hair care hair dryer 1.  Metal particle generation unit 1 〇, The discharge electrode 10a and the ground electrode 10b formed of a conductive metal material are provided. When a high voltage is applied between the discharge electrode 10 a and the ground electrode 1 〇b by the first voltage application circuit 14 to discharge (corona discharge, etc.), By the discharge action, Metal fine particles (metal ions, metal ions, etc.) are emitted from the discharge electrode 10a, the ground electrode 10b, and the like.  Metal particle generating portion 10, A box-shaped casing 10c is provided. Discharge electrode 1 〇a, On a base (printed circuit board, etc.) that is fixed to the casing 1 〇c, The illustration is omitted) It is fixed by soldering or riveting.  -12- 201034598 Discharge electrode 1 〇a, It is a very thin wire. The width (diameter) of the wire, 10~400[//m] (preferably 30~300[" m], More preferably 5〇~200[#m]). It can be rounded, Oval, Various wires of a cross-sectional shape such as a polygon. also, Discharge electrode 1 〇a, It may also be formed to have a pointed needle shape.  Ground electrode 1 〇b, For the front end side of the discharge electrode 10a, It is placed away from the discharge electrode 10a. Ground electrode 1 Ob, It is an annular plate which is orthogonal to the extending direction of the discharge electrode 0a.  Discharge electrode l〇a, Made of transition metals (gold, silver, copper, platinum,  Zinc, titanium, germanium, palladium, iridium, ruthenium, Hungry, etc.) Or such a combination, It is composed of a member plated with a transition metal or the like. The metal fine particles discharged from the metal fine particle generating portion 10, Containing gold, silver, copper, Zinc, etc. The antibacterial action produced by the metal microparticles can be obtained. also,  The metal microparticles ' contain platinum, Zinc, When titanium is used, The antioxidant action produced by the metal microparticles can be obtained. also, Platinum particles, It is known for its extremely high antioxidant activity. also, The portion where the metal fine particles are not emitted (the ground electrode 1 〇b, etc.) can be formed using stainless steel or tungsten.  Metal particle generating portion 10, It is also possible to cause ions generated by the discharge action (negative ions 'e.g., n〇2_, No3-etc.) and containing the discharge electrode 10a, Grounding electrode l〇b, Other metal materials, Or a member of the metal component collides with the phase to produce metal particles. that is, It is also possible to make the ground electrode 1 〇b or the above components, Constructed by a material containing the above transition metal, The material is then released from the metal particles.  Fog multiplier 1 generation unit 1 It is provided with a discharge electrode 11a and a ground electrode lib which are formed of a conductive metal material -13-201034598. A high voltage is applied between the discharge electrode 11a and the ground electrode 1 1 b by the second voltage application circuit 12 to discharge it (corona discharge, etc.). Specifically, The discharge electrode 11a is formed in a needle shape. also, Ground electrode 1 1 b, For the front end side of the discharge electrode 1 1 a, It is provided separately from the discharge electrode 11a. Grounding electrode lib, It is a ring-shaped plate. Mist generation unit 1 1, It has a cooling plate 1 1 C. Cooling plate 1 1 C, As a cooling mechanism, it functions. It consists of a Peltier element (not shown) and a thermally conductive member (metal member, etc.). On the surface of the cooling plate 11c which is cooled by the Peltier element, Produces dew condensation water from the moisture in the air. Water being supplied (ie, Dew condensation water is micronized by discharge, A very fine mist of negative nanometer size (a negatively charged mist containing negative ions) is produced. In this embodiment, It is equivalent to a water supply unit having a cooling plate 1 1 e having a Peltier element.  In this embodiment, Metal fine particle generating portion 1 and mist generating portion 11, The same is equivalent to the ion generating portion. also, Mist generation department, It is also possible to carry a steam generating mechanism that heats water to generate steam. also, Metal microparticle production department, A metal solution atomization mechanism that atomizes a metal solution to generate metal fine particles can also be mounted.  also, In this embodiment, As shown in Figure 2, The aperture of the metal particle discharge port 20a, It is set to be smaller than the aperture of the mist discharge port 20b. That is, The maintenance or status of the mist generating unit 1 1 is confirmed, Easy to carry out from the mist discharge 2 Ob. also, Can suppress fingers, Props, Foreign matter or the like enters from the metal particle discharge port 20a.  Furthermore, Hair care hair dryer 1, The light emitting unit 21 is provided. Light Department -14 - 201034598 21, Have: a light source 21a such as an LED (Light Emitting Diode) disposed in the cavity 9, And the light guiding member 2 1 b formed of the light transmitting synthetic resin material such as acryl or the light guiding the light source 21a. As shown in Figure 2, Between the metal fine particle discharge port 20a and the mist discharge port 20b, A hole 20c having a longitudinally round shape is formed. The emission end 21c' opposite to the light source 21a of the light guiding member 21b is inserted into the hole 20c and exposed outside the cover 20.  therefore, Light source 2 1 a, Is guided by the light guiding member 2 1 b, The cover 20 is shot from the exit end 0 21c. When using hair care hair dryer 1, The injection end 2 1 c is the head facing the user.  Light emitting unit 2 1, A means of expression as an operation mode of the hair care hair dryer 1 can be utilized. E.g, The state of the warm air blown by the heater 8 is turned red, The state in which the cold air is blown without using the heater 8 becomes green, and the state in which the metal fine particles are released by the metal fine particle generating portion 10 becomes yellow. The state in which the mist is emitted by the mist generating portion 1 1 is changed to cyan or the like. The color of the light-emitting portion 21 can be changed in accordance with the operation state. At this time Q, a control circuit (not shown) that is mounted on the same substrate as the second voltage application circuit 1 2, The light emission of the light source 2 1 a can be controlled in accordance with the action state. also, Constructing a plurality of light sources 21a corresponding to the respective colors, The control circuit controls the illumination of the plurality of light sources 2 1 a. also, The light source 2 1 a can also be turned off by the control circuit. Or control the point interval, Or change the luminous intensity. Can also make such a luminous form, It is set corresponding to various operation modes.  Also, by the light from the light-emitting portion 21, Give the body a specific effect. E.g, When the light source 21a is used as a highlight -15-201034598 degree LED having a wavelength of 41 5 [ηιη], The sterilizing effect produced by the cyan light emitted from the light source 2 1 a can be obtained, Or the prevention effect of acne caused by shrinkage of pores or decreased secretion of sebum. also, When a high-brightness LED having a wavelength of about 63 0 [nm] is used as the light source 21a, The blood generated by the red light emitted from the light source 21a can be obtained, Or the metabolically active effects of angiogenesis, Or promote the production of collagen or elastin. Furthermore, When the red light is irradiated repeatedly, Can improve fine lines, Liver spot, Dark spot, The effect of improving the photoaging skin such as large pores or improving the scar after acne. also, These effects, It varies from person to person.  Furthermore, Light emitting unit 2 1, An irradiation means for irradiating the metal fine particle generating portion 10 or the mist generating portion 1 1 can be used. As a result, The effect of recognizing the state of the metal fine particle generating portion 1 or the mist generating portion 1 1 can be recognized. Or the effect of improving work efficiency by improving the visibility during maintenance such as cleaning.  As above, Hair care hair dryer (hair care device) 1 of the present embodiment The metal fine particle generating portion 10 and the mist generating portion 11 are housed in a single cavity 9. When the mist generated by the mist generating portion 11 moves to the metal microparticle generating portion 10, The voltage or electric field changes due to charging of the metal microparticle generating portion 10, There will be instability in the production of metal particles. Or the metal microparticle generating portion 10 is corroded by moisture.  here, In this embodiment, As shown in Figure 3, Metal microparticle production section 1 〇, It is disposed outside the mist passage region Ami for passing the mist generated by the mist generating portion 11. Specifically, Metal particle generation section 10, for: The mist generating unit 11 is disposed in a direction orthogonal to the mist passage direction Dp in the mist passage region -16 - 201034598 region Ami. The mist flows from the mist generating portion 11 toward the direction Dp. Therefore, the mist moves to the gold particle generating portion 10 which is displaced in the direction Dn with respect to the mist generating portion 1 1. therefore, Metal particle generating portion 10, It is not easy to be affected by the mist generated by the mist generating portion 11.  also, In this embodiment, In the void 9, Metal particles produce 1 〇, It is opposed to the metal fine particle discharge port 20a and disposed at a position where the comparison 0 is closer to the metal fine particle discharge port 20a. also, Fog production 1 1, It is opposed to the mist discharge port 20b and disposed at a position relatively close to the discharge port 20b. Furthermore, The mist generating portion 1 1 and the cover 20 are separated from D1, It is shorter than the mist generating portion 11 and the metal fine particle generating portion 1 by D2. Furthermore, In the void 9, Flow Wp flowing from the gap gl, It is discharged to the outside from the metal fine particle discharge port 20a and the mist discharge port.  therefore, The metal Q produced by the metal fine particle generating portion 10, In comparison, it is smoothly discharged from the metal particle discharge port 20a. The mist generated by the mist generating portion 1 1 , In comparison, it is discharged from the mist discharge port 20b. that is, Metal particles produced by the production of metal particles, It is not easy to flow toward the mist generating unit 1 1 The mist generated by the mist generating portion 11, It is difficult to flow toward the metal generating portion 1 . also, Divide Wp, Although it contributes to the discharge of metal particulate gas, But even if there is no split flow Wp, Metal particles, mist can also be discharged from the discharge port 20 a, 2 0 b discharge.  Furthermore, in this embodiment, The shadow D η is set in the cavity 9.  It is not easy to be microscopically affected by the fog of the Ministry of Health.  The Ministry of Health is moving.  Particles and mist and walls,  -17- 201034598 It is more effective to prevent the mist from moving to the metal particle generation part. Light guiding member 2 1 b, And the mounting member 6d for generating the metal microparticles into the inner tube 6, Playing the light guiding member 2 1 b as a shielding wall, For the plate shape, The thickness direction is arranged along the circumferential direction. also, Light guiding member 21b, It is disposed between the generating portion 1 and the discharge end of the mist generating portion 11 (Fig. 3). Light guiding member 2 1 b, The gas passage region (the region of the left Ami of the mist generating portion 11 in Fig. 3) functions as a partition wall on the left side of the metal fine particle generating portion 10 in the metal fine particle passage.  Mounting member 6d, It is provided in the diameter direction from the cylindrical body 6a. Metal particle generating portion 10, It is refined by the inner cylinder 6 by installation. Mounting member 6d, In order to have the shielding plate 6e extending from the metal micro 10 toward the metal fine particle discharge port 20a, In order to be disposed on the mounting member 6d, Therefore, it is inevitably arranged close to the generating unit 10. therefore, It is possible to relatively effectively suppress the movement of the mist to the metal fine particle generating portion 1 〇 by comparison.  also, Provided between the shielding plate 6e and the cover 20;  By the gap g2, The charge remaining in the cover 20 can be suppressed from being conducted to the metal fine particle generating portion 10 via E. The electric charge of the cover 20 belongs to the microparticle generating portion 1 〇, It will prevent the metal particles from replacing the gap g2. It is also possible to connect the low-conductivity or insulating member 6d to the cover 20.  Light guiding member 21b and mounting member 6d, As shown in Figure 3. Installed in this implementation 10 can be installed.  The area around the left end of the metal microparticles of the inner cylinder 6 (Ame, The area with the fog side) is protruding toward the outer side. The cow 6d is mounted with the particle generating unit 6 e. Shielding plate Metal particles Small composition to S gap g2. The white shielding plate 6e is generated if it is conducted in gold. also,  The component is between the ampoules, For phase -18- 201034598, the direction of the fog passing through Dp is arranged in parallel and functions as a double shielding wall. therefore, It is more effective in suppressing the movement of the mist to the metal fine particle generating portion 1 〇.  As explained above, In the hair care hair dryer (hair care device) of the present embodiment, The metal fine particle generating portion 10 and the mist generating portion 1 1 are housed in a single divided region (cavity 9) in the casing 3. And the metal microparticle generating portion 10, It is disposed outside the mist passage region Ami through which the mist generated by the mist generating portion 1 1 passes. therefore, Compared with the case where the metal fine particle generating portion and the mist generating portion are housed in different casings, By simplifying the composition, The mist is prevented from moving to the metal fine particle generating portion 10.  also, Metal particle generating portion 10, The mist generating portion 11 is separated from the mist generating portion 11 so as to be disposed in the direction Dp orthogonal to the mist passing direction Ami. therefore, Further, it is possible to suppress the mist emitted from the mist generating portion 11 and flowing in the mist passing region Ami from moving to the metal fine particle generating portion 10 ° Q. The mist generating portion 11, It is disposed opposite to the mist discharge port 20b. therefore, The mist emitted from the mist generating portion 11, It can be discharged from the mist discharge port 20b more quickly. the result, Further, it is possible to suppress the mist from moving to the metal fine particle generating portion 10. also, Metal particle generating portion 10, It is disposed opposite to the metal fine particle discharge port 20a. therefore, Metal particles, It can be discharged from the metal fine particle discharge port 20a more quickly.  also, The distance D2 between the metal fine particle generating portion 10 and the mist generating portion 11 is It is set to be longer than the distance D1 between the mist generating portion 1 1 and the cover 20. therefore, The mist that is released from the mist generating unit 1 1 is faster. -19- 201034598 It is quickly discharged from the mist exhaust port 20b. As a result, it is possible to prevent the mist from moving to the metal fine particle generating portion 10.  Further, a cover 20 which is made of a lower electrical conductivity than the casing 3 and which is a separate member from the casing 3, It is mounted to the housing 3. therefore, The charging of the cover 20 caused by metal particles or mist can be suppressed. As a result, the release performance of the metal fine particles or the mist from the metal fine particle generating portion 10 or the mist generating portion 11 can be suppressed from being lowered by charging.  also, As a shielding wall for suppressing the movement of the mist generated by the mist generating portion 11 to the metal fine particle generating portion 10, A light guiding member 21b and a shielding plate 6e are provided. therefore, It is possible to suppress the movement of the mist to the metal microparticle generating portion 1 by the shielding wall.  also, Between the cover 20 and the shielding plate 6e, Electrical insulation. therefore,  The electric charge of the metal fine particles or the mist can be suppressed from moving from the cover 20 to the shielding plate 6e to charge the shielding plate 6e. therefore, The metal fine particle emission performance of the metal fine particle generating portion 1 〇 can be suppressed from being lowered by charging.  also, By forming a gap g2 between the cover 20 and the shielding plate 6e,  The cover 20 is electrically insulated from the shielding plate 6e. therefore, The potential of the cover 20 and the shield plate 6e can be insulated by an extremely simplified configuration.  also, Shading plate 6e, The mounting member 6d is attached to the mounting member 6d in which the metal fine particle generating portion 10 is mounted in the casing 3. therefore, The mounting member 6d and the shielding plate 6e can be shared, Compare these occasions with individual settings, It can be simplified.  also, Light guiding member 2 1 b, It functions as a shielding wall. Therefore, When the light guiding member 21b is provided, By effectively using the light guiding member 21b as a cover -20-201034598, It can suppress the movement of the mist to the metal microparticle generating portion by 10°. The light guiding member 211 that functions as a shielding wall? With the shielding plate 6e, Set for side by side. therefore, The shielding wall becomes a double-wall structure, and it is possible to suppress the mist from moving to the metal fine particle generating portion 1 .  (Example of layout modification of the metal fine particle generating portion and the mist generating portion) 0 Fig. 4 to Fig. 9, A modification of the first embodiment described above is shown.  Various modifications, The metal fine particle generating portion 1 and the mist generating portion 1 1 are also housed in a single space (cavity 9) in the casing 3. also, Metal particle generation unit 1〇, The mist generated by the mist generating portion 11 passes outside the region Ami.  In the first modification shown in FIG. 4, The mist generating portion 11, For the fog passing through the area Ami, the direction of the fog (the direction in which the mist is emitted) Dp, It is disposed closer to the front end than the metal fine particle generating portion 10.  Q According to such a layout, Metal particle generating portion 10, It is located on the opposite side of the mist discharge direction (Dp) of the mist generating portion 11. therefore, Further, it is possible to suppress the mist generated by the mist generating portion 11 from moving to the metal fine particle generating portion 10. also, According to the cover 20A of the present modification, Both the metal fine particles and the mist are discharged from the common discharge port 20d.  In the second modification shown in FIG. 5, In contrast to Figure 4, Metallic particle generation unit 1 〇, In order to pass the direction Dp along the mist passing through the area Ami, It is disposed closer to the front end than the mist generating portion 11. also,  In the third modification shown in FIG. 6, In the way that the metal granules and the mist - 21 - 201034598 are common outlets for the center of 20 o', that is, The manner in which the metal particles pass through the center line of the area Ame and the mist passes through the center line of the area Ami, The metal fine particle generating portion 10 and the mist generating portion 11 are disposed. By this layout, As long as the metal fine particle generating portion 10 is disposed outside the mist passing region Ami, There will be no problems.  In the fourth to sixth modifications shown in FIGS. 7 to 9 , Metal microparticle generating unit 10, For the direction of Dp along the fog, It is disposed closer to the front end than the mist generating portion 11. but, In these variations, To shield the wall 22A, 22A1 22A2 prevents the mist from moving to the metal fine particle generating portion 10. Because the wall 22A is shielded by the mist, 22A1' 22A2 shade,  Therefore, the shielding wall 22A is opposite to the mist passing region Ami. 22A1 The back side area of the 22A2, Become a fog outside the area Ami. As shown in this variant, Shielding wall 22A, 22A1 22A2, Appropriate changes can be made to the layout. that is, Can also be as shown in Figure 7, Flat shielding wall 22A, It is formed on the side surface of the metal fine particle generating portion 1 . It can also be as shown in Figure 8. Refraction plate-shaped shielding wall 22A1, It is provided to cover the side surface and the rear portion of the metal fine particle generating portion 1 . Can also be as shown in Figure 9, U-shaped or V-shaped shielding wall 22 A2, It is disposed behind the metal fine particle generating portion 10.  (Second Embodiment) A cross-sectional view of the first drawing, In order to display the hair care hair dryer (hair care device) 1B of the second embodiment.  For hair care hair dryer 1 B, A gap -22 - 201034598 g3 is provided on the front end side of the inner cylinder 6B. The cavity 9B and the wind tunnel 4B are in communication with the intervening gap g3. A mist generating portion 11 is disposed in the cavity. on the other hand, The metal fine particles are generated 10' in the wind tunnel 4B. According to this composition, Divide Wp,  The tiller is the branch Wpl discharged from the mist discharge port 20b of the cover 20B. And the branching flow Wp2 flowing back into the wind tunnel 4B from the gap g3. Branch Wpl, WP2' is a stream of air containing mist.  A shielding wall 22B is disposed on the side of the gap g 3 of the metal fine particle generating portion 10 (on the side of Fig. 10). Metal particle generation unit 1 〇, The mist is moved to the metal fine particle generating portion 1 by being shielded by the shielding wall 22B and located outside the mist passing region (the branching flow Wp2).  therefore, The comparatively simplified formation of the shielding wall 22B suppresses the metal fine particle generating portion 10 from being adversely affected by the mist generated by the mist generating portion 1 1 .  (Third Embodiment) A front view of the first one, In order to display the hair care blower (hair care device) 1 C of the third embodiment.  For hair care hair dryer 1C, The metal fine particle generating portion 10 and the mist generating portion 11 are provided on both sides of the inner cylinder 6 (see Fig. 1). The metal neutron generating unit 10 and the mist generating unit 11, It is disposed inside the single cavity 9C in the outer portion 3a of the casing 3C. that is, Empty 9C, It is formed from the upper side to the both sides of the inner cylinder 6. Metal particle generation unit 10, In order to be placed in the rear of the cover 20C1 formed in the through hole 3b of the casing 3C, it is closer to the cover 20C 1 . The mist generating unit 1] The portion of the 9B portion that is covered by the flow is arranged in the back of the -23-201034598 to be placed in the back of the through hole 3c formed in the casing 3C, and is closer to the cover 20C2. position.  therefore, By arranging the inner cylinder 6 between the metal fine particles and generating the mist generating portion 1 1 in comparison with each other, the metal fine particle generating portion 1 is less likely to be affected by the mist generated by the mist generating portion 1 1 .  (Fourth Embodiment) A cross-sectional view of Fig. 12, In order to display the device (hair care device) 1D of the fourth embodiment.  Hair dryer 1 D, It has a shape with a relay bar.  Hand grip 1 f, The comb 2 3 provided at the front end portion 1 g is used for combing. On the comb 2 3, Providing a plurality of protruding comb teeth to form a housing 3D of the outer casing, A cavity is formed in the interior of the casing 3D for joining a plurality of divided bodies. In the hole, Electrical parts.  The portion of the grip 1 f that is close to the comb 23, A cover 20D constituting a shape is attached. In the cavity 9 D of the cover 20D and the casing 3D, The metal fine particle generating portion 10 is accommodated in the raw portion 1 1 . In the cover 20D, It is formed to open 2〇d toward the comb teeth 23a. The mist generated by the metal fine particle generating portion 11 generated by the metal fine particle generating portion 10, It is applied to the hair or skin from the 20d part of the discharge port. also, The mist generating portion 11 is generated in the metal fine particles, A voltage cover 20C2 portion 10 from the circuit unit 24 is applied, and Can produce the hair dryer user,  Finishing hair 23a.  And constitute.  There are a variety of shells formed by the expansion of the shell and the discharge of the mist and the mist and the outside of the 10 and -24- 201034598 In order to suppress the interference of the release of metal particles caused by the user's electrification, The charging portion 25 is exposed to the surface of the grip If. Charging section 25, In order to have polarity opposite to the polarity of the emitted metal particles and mist (for example, The metal particles and the negative ions of the mist are positively charged when they are discharged. user, By holding the charging portion 25', there is charging opposite to the above polarity. also, At least the outermost layer of the charging portion 25 is made of an insulating material.  0, in order to suppress the movement of the mist generated by the mist generating portion 11 to the metal microparticle generating portion 10, The same shielding wall 22D as that of the fifth modification shown in Fig. 8 is provided.  therefore, By having a relatively simplified configuration with a shielding wall 2 2D,  It is possible to suppress the bad influence of the metal fine particle generating portion 10 from the mist generated by the mist generating portion 1 1 .  (Fifth Embodiment) 0 Sectional view of Fig. 3, In order to display the hair styling device (hair care device) 1 E of the fifth embodiment.  Hair dryer 1E, Basically, the same configuration as that of the hair styling device 1 D of the fourth embodiment described above is provided.  But in the hair dryer 1D, A fan 5E for generating an air flow W and a motor 7E for rotating the fan 5E are provided in the cavity 9D. The metal fine particles generated by the metal fine particle generating portion 10 and the mist generated by the mist generating portion 11 are The branching flow Wp generated by the fan 5E is discharged. At this point, It is different from the above-described fourth embodiment.  -25- 201034598 As the air motor 7E and fan 5E, It is housed in a cavity formed in the casing 3E. Motor 7E, It is rotated by the driving circuit of the circuit unit 24. At the base end of the housing 3E (on the lower side of Fig. 13), An opening portion lh serving as an air introduction port is formed. When the fan 5E is rotated, the air will flow into the cavity 9D from the outside through the opening portion 1h. The air flow Wp which is passed through the cavity 9D and discharged from the discharge port 20d toward the comb 23 is formed. Simultaneously, An air flow W which is discharged from the blowing holes 2 3 b formed in the bottom of the comb teeth 23a of the comb portion 23 is also formed. also, The power is supplied to the electrical component for the clip dielectric line 2.  therefore, In the same manner as in the fourth embodiment described above, In order to have a simplified configuration with a shielding wall 22D, The metal fine particle generating portion 10 can be suppressed from being adversely affected by the mist generated by the mist generating portion 11.  (Sixth embodiment) A side view of Fig. 14, The hair straightener (hair care device) 1F of the sixth embodiment is shown. Figure 15, A cross-sectional view taken along the line χν_χν in Fig. 14.  As shown in Figure 14, Hair straightener 1F, In order to have the two arm portions 1 i which can be expanded into a V shape with the intervening connection portion lk, Lj. user, To use the arm 1 i, 1 j The front splint 2 6 grips the hair and heats the heater 27 to clean the hair.  As shown in Figure 15, A cavity is formed inside the casing 3 F forming the outer casing, In the hole, Contains a variety of electrical parts.  The housing 3 F ' on the side of the arm 1 i is mounted on both sides (left -26 - 201034598 right of Fig. 5) with a pair of covers 20F1 extending outward. 20F2. Forming a housing one of the pair of covers 20F1 20F2, It is a portion provided on the side of the rotating joint portion lk adjacent to the clamp plate 26. In the cover 20F1 20F2 and a single cavity 9F formed by the casing 3F, The metal fine particle generating portion 10 and the mist generating portion 11 are housed. Metal particle generating portion 10, To be contained in the cover,  Within 20F1. Metal particles, It is discharged from the metal fine particle discharge port 20a formed in the cover 20F1. on the other hand, The mist generating portion 11, The tolerance is 0 in the cover 20F2. The mist is discharged from the mist discharge port 20b formed in the cover 20F2.  Metal fine particle generating portion 10 and mist generating portion 11, It is placed in a single hole 9F. However, they are configured in a way that is separate from each other. Fog production unit 1,1 It is disposed at a position closer to the mist discharge port 20b. and, The direction in which the mist is discharged, It is set to the direction from the center of the cavity 9F toward the outside. therefore, Metal particle generation unit 1 〇, In comparison, it is easier to arrange outside the mist passage region Ami of the mist generating portion 11.  that is, The configuration in which the metal fine particle generating portion 1 and the mist generating portion 1 1 are disposed on both sides of the arm portion 1 i is a relatively simplified configuration. The metal fine particle generating portion 10 can be suppressed from being adversely affected by the mist generated by the mist generating portion 11.  the above, The preferred embodiment of the present invention has been described. However, the present invention is not limited to the above embodiment. Can be a variety of deformations. E.g,  a metal fine particle generating portion and a mist generating portion, In the above embodiments and modifications, the arrangement positions may be replaced with each other. also, It is also possible to integrate the shielding plate with the mounting member of the mist production section -27- 201034598. Further, the 'discharge port' is preferably provided on a cover different from the casing. However, it can also be placed in the housing itself.  Furthermore, It is preferable to form a gap between the outer casing and the shielding wall to electrically insulate the outer casing and the shielding wall. However, the insulating member may be insulated between the outer casing and the shielding wall.  BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a cross-sectional view showing a hair dryer according to a first embodiment of the hair care device of the present invention.  Fig. 2 is a front view of the above-described hair care hair dryer.  Fig. 3 is an enlarged plan view showing a metal fine particle generating portion and a mist generating portion of the hair dryer.  Fig. 4 is an enlarged plan view of the metal fine particle generating portion and the mist generating portion (first modified example). Fig. 5 is an enlarged plan view showing a metal fine particle generating portion and a mist generating portion (second modified example).  Fig. 6 is an enlarged plan view showing a metal fine particle generating portion and a mist generating portion (third modified example).  Fig. 7 is an enlarged plan view showing a metal fine particle generating portion and a mist generating portion (fourth modified example).  Fig. 8 is an enlarged plan view showing a metal fine particle generating portion and a mist generating portion (fifth modification).  Fig. 9 is an enlarged plan view of the metal fine particle generating portion and the mist generating portion | (sixth modification).  -28- 201034598 Fig. 1 is a cross-sectional view showing a hair care hair dryer according to a second embodiment of the hair care device of the present invention.  Fig. 1 is a front elevational view showing a hair care hair dryer according to a third embodiment of the hair care device of the present invention.  Fig. 2 is a cross-sectional view showing a hair styling device according to a fourth embodiment of the hair care device of the present invention.  Fig. 3 is a cross-sectional view showing a hair dryer of a fifth embodiment of the hair care device of the present invention.  Fig. 14 is a side view showing a hair straightener according to a sixth embodiment of the hair care device of the present invention.  Fig. 15 is a cross-sectional view taken along the line XV-XV in Fig. 14.  [Main component symbol description] 1 : Hair care hair dryer (hair care device) Q 1Β: Hair care hair dryer (hair care device) 1 C : Hair care hair dryer (hair care device) 1D: Hair dryer (hair care device) 1Ε: Hair dryer (hair care device) 1F: Hair straightener (hair care device) 1 a : Grip 1 b : Ontology lc : Base 1 d : Grip.  -29 - 201034598 1 e : Connector 1 f : Grip 1 g : Front end 1 h : Opening 1 k : Connection part li, lj : Arm 2 : Power cord 3 : Housing 3E : Housing 3 a : Outer tube 3 b : through hole 4 : wind tunnel 4 a : inlet opening 4 b : outlet opening 5 : fan 5 E : fan 6 : inner cylinder 6 a : cylinder 6 b : support rib 6 c : flange 7 : motor 7 E : motor 8 : Heater 9 : Cavity -30- 201034598 1 〇: Metal granule generation unit 1 0 a : Discharge electrode 1 0 b : Ground electrode 1 0c : Case 1 1 : Mist generation unit 1 1 a : Discharge electrode 1 1 b : Ground electrode 1 1 c : Cooling plate 1 2 : Second voltage application circuit 1 3 : Cavity 1 4 : First voltage application circuit 1 5 : Switch 1 6 : Switch 17 a, 1 7b : Guide line 1 8 , 1 9 : Switch knob 20: cover 20a: metal fine particle discharge port 20b: mist discharge port 20c: hole 2 0 d : discharge port 21: light-emitting portion 2 1 a : light source 2 1 b : light guide member 2 1 c : injection end - 31 - 201034598 22A, 22A1 , 22A2 : fog shielding wall 2 3 : comb 2 3 a : comb teeth 26 : splint 2 7 : heater W : air flow

Wp: split flow

Wpl: split flow

Wp2 : split turbulence g 1 : void g2 : void g3 : void

Ami: fog passing area

Ame: metal particle passage area

Dp: fog passing direction

Dn: orthogonal to the direction of the direction Dp -32-

Claims (1)

201034598 VII. Patent application scope 1. A hair care device comprising: a housing; and a metal microparticle generating portion for generating metal microparticles in a divided region provided in the housing; and the above-mentioned housing provided in the housing A mist generating portion for generating a mist in the divided region, wherein the metal fine particle generating portion is disposed outside the mist passing region through which the mist generated by the mist generating portion passes. 2. The hair care device according to claim 1, wherein the metal microparticle generating portion is disposed in a direction substantially perpendicular to a direction in which the mist passes through the mist passing region from the mist generating portion. 3. The hair care device according to claim 1, wherein the metal fine particle discharge port for discharging the metal fine particles and the mist Q discharge port for discharging the mist are formed in an outer casing of the hair care device, wherein the metal fine particle generating portion is The metal fine particle discharge port is provided to face the discharge port, and the mist generation unit is provided to face the mist discharge port. 4. The hair care device according to claim 3, wherein a distance between the metal microparticle generating portion and the mist generating portion is longer than a distance between the mist generating portion and the cover. 5. The hair care device of claim 3, wherein the housing having a lower electrical conductivity than the housing and the housing is a separate component, the -33-201034598 is mounted as the housing on the housing . 6. The hair care device according to claim 1, wherein the shielding wall for preventing the mist from moving to the metal fine particle generating portion is further provided. 7. The hair care device of claim 5, wherein the protective cover is further provided with a shielding wall for preventing the mist from moving to the metal fine particle generating portion, and the cover is electrically insulated from the shielding wall. 8. The hair care device of claim 7, wherein the cover is electrically insulated from the shield wall by forming a gap between the cover and the shield wall. 9. The hair care device according to claim 6, wherein the shielding wall is integrated with a mounting member that mounts the metal fine particle generating portion or the mist generating portion in the casing. 10. The hair care device of claim 6, wherein the light source is further provided with a light source and a light guiding member that guides the light from the light source and functions as the shielding wall. 1. The hair care device according to the first aspect of the invention, further comprising: the light guide member further comprising: an integral member integrated with the metal microparticle generating portion or the mist generating portion mounted in the casing The shielding wall, the light guiding member and the other shielding walls are arranged in parallel. -34-