JP5123832B2 - Hair care equipment - Google Patents

Description

  The present invention relates to a hair care device.

2. Description of the Related Art As a hair dryer as a conventional hair care device, one having an ion generation unit that generates ions by applying a voltage between a discharge electrode and a ground electrode to generate discharge is known (Patent Document 1). .
JP 2008-126139 A

  In this type of hair care device, when a plurality of ion generation units for generating ions by discharge are provided, a plurality of lead wires for applying a voltage from the voltage application circuit to the ion generation unit are also arranged.

  In this case, if mutual interference occurs between a plurality of lead wires, there is a possibility that the ion generation capability of each ion generation unit is lowered or unstable.

  Then, an object of this invention is to obtain the hair care apparatus which can suppress the performance fall and instability by the mutual interference of lead wires.

In the first aspect of the invention, the case has an inner cylinder that forms a wind tunnel, a discharge electrode and a ground electrode, and a discharge is performed by applying a voltage between the discharge electrode and the ground electrode. Two ion generation units that generate ions , and the first ion generation unit and the second ion generation unit are arranged on the outer periphery of the inner cylinder so as to be spaced apart in the circumferential direction, and the case A first lead wire for applying a voltage from the first voltage application circuit to the first ion generation unit, an intermediate position between the first ion generation unit and the second ion generation unit, A second wiring is arranged on a side where the first ion generation unit exists from a virtual plane including the central axis of the inner cylinder, and a voltage is applied to the second ion generation unit from a second voltage application circuit. the lead wire on the side in the presence of the second ion generation portion from the virtual plane The first lead wire includes a voltage application lead wire for applying a voltage between the first ion generation unit and the first voltage application circuit, and a ground lead wire for ground connection, A second lead wire including a voltage application lead wire for applying a voltage between the second ion generation unit and the second voltage application circuit and a ground lead wire for ground connection; The second lead wire is characterized in that the voltage applying lead wire and the ground lead wire are routed along each other and not crossing each other.

In invention of Claim 2 , it produces | generates in the outer wall of the said hair care apparatus with the 1st ion discharge port from which the ion produced | generated by the said 1st ion production | generation part is discharged | emitted, and the said 2nd ion production | generation part A second ion discharge port from which the generated ions are discharged, and the first ion generation unit is disposed to face the first ion discharge port, and the second ion generation unit is It is arranged opposite to the second ion discharge port, and the distance from the outer wall to the ground electrode of the first ion generation unit, and the distance from the outer wall to the ground electrode of the second ion generation unit, It is characterized by being substantially equal.

The invention according to claim 3 is characterized in that at least one of the ion generation parts is a metal fine particle generation part for generating metal fine particles by discharge.

The invention according to claim 4 is characterized in that at least one of the ion generation units is a mist generation unit that generates mist by reducing the supplied water by discharge.

According to the first aspect of the present invention, the first lead wire and the second lead wire are routed so as not to cross each other, so that performance degradation and destabilization due to mutual interference between the lead wires are suppressed. Can do. That is, the electric field generated in the voltage application lead wire can be reduced by the ground lead wire by arranging the voltage application lead wire and the ground lead wire to each other. Etc. can be suppressed.

In addition, by arranging the first and second lead wires separately on one side and the other side in the circumferential direction on the outer periphery of the inner cylinder, the lead wires are separated from each other, and the performance due to mutual interference Can be suppressed.

Furthermore, the voltage between the discharge electrode and the ground electrode is stabilized for the first and second ion generation units by connecting the ion generation unit and the corresponding voltage application circuit to the ground using a ground lead wire. As a result, ion generation performance can be stabilized.

According to the invention of claim 2 , it is possible to suppress the potential difference between the first ion generation unit side and the second ion generation unit side in the hair care device, and to reduce the performance or cause the deterioration in each ion generation unit. Stabilization can be suppressed.

According to invention of Claim 3 , the fall and instability of the performance which produces | generates the metal microparticles by a metal microparticle production | generation part can be suppressed.

According to invention of Claim 4 , the fall and the destabilization of the performance which produce | generate the mist by a mist production | generation part can be suppressed.

  Preferred embodiments of the present invention will be described below with reference to the drawings. In addition, the same component is contained in the following several embodiment and modification. Therefore, in the following, common reference numerals are given to those similar components, and redundant description is omitted.

  (First Embodiment) FIG. 1 is a cross-sectional view of a hair dryer as a hair care device according to this embodiment, FIG. 2 is a front view of the hair dryer as seen from the outlet opening side, and FIG. 3 is a metal in the main body of the hair dryer. It is a top view which expands and shows the part in which a fine particle production | generation part and a mist production | generation part are provided.

  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 and right direction in FIG. 1) to the outlet opening 4b is formed inside the main body 1b, and is accommodated in the wind tunnel 4. By rotating the fan 5, an air flow W is formed. That is, the air flow W 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.

  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 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.

  And in the main-body part 1b, the metal fine particle production | generation part (1st ion production | generation part) 10 and the mist production | generation part (2nd ion production | generation part) are carried out in the cavity 9 formed between the case 3 and the inner cylinder 6. ) 11, a second voltage applying circuit 12 for applying a voltage to the mist generating unit 11 is accommodated. The cavity 13 in the base portion 1c of the grasping portion 1a accommodates a first voltage application circuit 14 for applying a voltage to the metal fine particle generation portion 10 and a switch portion 15 for switching the operation mode. . Further, in the cavity in the distal end portion 1d of the grip portion 1a, another switch portion 16 for switching the power ON and OFF, switching the operation mode, and the like is accommodated. 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. The switch units 15 and 16 are configured to be able to switch the open / close state of the internal contacts by operating the operators 18 and 19 exposed on the surface of the case 3.

  As shown in FIG. 1, the first voltage application circuit 14 and the second voltage application circuit 12 are preferably arranged in a region that is on the extended line of the grip portion 1a in the grip portion 1a or in the main body portion 1b. It is. When the user holds the gripping portion 1a, the rotational moment (moment arm) due to gravity acting on the first voltage application circuit 14 and the second voltage application circuit 12 is reduced, and this acts on the user's hand. This is to reduce the load to be performed.

  Further, as shown in FIG. 1, in the present embodiment, the second voltage application circuit 12 and the first voltage application circuit 14 are arranged at positions opposite to each other across the inner cylinder 6. . That is, by interposing the inner cylinder 6 between the second voltage application circuit 12 and the first voltage application circuit 14, the mutual interference between the second voltage application circuit 12 and the first voltage application circuit 14 is caused. It suppresses problems such as voltage drop and instability.

  The inner cylinder 6 includes a cylindrical portion 6a, a plurality of support ribs 6b (only one place shown in FIG. 1) arranged radially extending from the cylindrical portion 6a and dispersed in the circumferential direction, and a support 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 W is branched into the cavity 9 through the gap g1 to form a branch flow Wp. ing. The gap g1 serving as an inlet for the branch flow Wp into the cavity 9 is provided at a position downstream of the fan 5 and upstream of the heater 8. Therefore, the branch flow Wp becomes a relatively cool air flow before being heated by the heater 8.

  The metal fine particle generation unit 10 has a discharge electrode 10a and a ground electrode 10b formed of a conductive metal material, and a first voltage application circuit 14 is provided between the discharge electrode 10a and the ground electrode 10b. A high voltage is applied to cause discharge (corona discharge or the like), and metal fine particles (metal molecules, ions, or the like) are discharged from the discharge electrode 10a, the ground electrode 10b, or the like by the discharge action.

  The metal fine particle generation unit 10 includes a box-shaped housing 10c, and the discharge electrode 10a is a base portion (for example, a printed board or the like not shown) fixed to the housing 10c in the housing 10c. ), For example, by soldering or caulking.

  The discharge electrode 10a can be configured as an extremely fine wire, and its width (diameter) is 10 to 400 [μm] (preferably 30 to 300 [μm], and even more preferably 50 to 200 [μm]. ) Can be set. In that case, various cross-sectional shapes such as a circle, an ellipse, and a polygon can be employed. The discharge electrode 10a may be formed in a needle shape having a pointed end.

  The ground electrode 10b can be provided, for example, as an annular and plate-like member that is spaced apart from the distal end side of the discharge electrode 10a and arranged substantially orthogonal to the extending direction of the discharge electrode 10a.

  Further, the discharge electrode 10a is, for example, a transition metal (for example, gold, silver, copper, platinum, zinc, titanium, rhodium, palladium, iridium, ruthenium, osmium, etc.), an alloy, or a member obtained by plating a transition metal. Etc. can be configured. When the metal fine particles generated and released by the metal fine particle generation unit 10 contain gold, silver, copper, zinc, or the like, an 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 part (for example, ground electrode 10b etc.) which does not discharge | release metal microparticles | fine-particles can be comprised using stainless steel, tungsten, etc.

Further, the metal fine particle generation unit 10 generates ions (for example, negative ions such as NO ₂ ⁻ , NO ₃ ^−, etc.) by the discharge action, and these ions are emitted from the discharge electrode 10a, the ground electrode 10b, other metal materials, Metal particles may be generated by colliding with a member containing a metal component. That is, the ground electrode 10b and the other member may be made of a material containing the transition metal, and the metal fine particles may be emitted therefrom.

  The mist generating unit 11 includes a discharge electrode 11a and a ground electrode 11b formed of a conductive metal material. A high voltage is applied between the discharge electrode 11a and the ground electrode 11b by the second voltage application circuit 12. A discharge (corona discharge or the like) is generated by applying a voltage. Specifically, for example, the discharge electrode 11a can be formed in a needle shape, and the ground electrode 11b can be formed as an annular and plate-like member that is spaced from the distal end side of the discharge electrode 11a. The mist generation unit 11 includes a Peltier element (not shown) as a cooling mechanism and a cooling plate 11c made of a member having thermal conductivity (for example, a metal member), and is cooled by the Peltier element. Water in the air is condensed on the surface of the plate 11c to generate condensed water. 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. In the present embodiment, the Peltier element and the cooling plate 11c correspond to the water supply unit.

  In the present embodiment, both the metal fine particle generation unit 10 and the mist generation unit 11 correspond to an ion generation unit that generates ions.

  Further, as shown in FIG. 3, the lead wire (first lead wire) 17a connected to the metal fine particle generation unit 10 and the lead wire (second lead wire) 17b connected to the mist generation unit 11 cross each other. It is preferable to route the cables as far as possible without causing them. This is to prevent the metal fine particle generation unit 10 or the mist generation unit 11 from obtaining a desired voltage or causing the voltage to become unstable due to mutual interference between the currents flowing through the lead wires 17a and 17b. In the present embodiment, the metal fine particle generation unit 10 is disposed apart from the mist generation unit 11 on one side in the circumferential direction of the inner cylinder 6 (upper side in FIG. 3), and the lead wire 17a is disposed between the inner cylinder 6 and the outer cylinder. Between the inner cylinder 6 and the outer cylinder 3a, and the mist generating section 11 between the inner cylinder 6 and the outer cylinder 3a. On the other hand, the inner cylinder 6 is routed in a region on the other circumferential side (lower side in FIG. 3).

  In the present embodiment, the lead wire 17a is drawn from the metal fine particle generation unit 10 to the side away from the mist generation unit 11 (upper side in FIG. 3), and the lead wire 17b is drawn from the mist generation unit 11 to the metal. It is pulled out to the side away from the fine particle generation unit 10 (lower side in FIG. 3).

  Further, as shown in FIG. 3, the lead wire 17 a is in relation to a virtual plane Vp (see also FIG. 2) including an intermediate position M between the metal fine particle generation unit 10 and the mist generation unit 11 and the central axis of the inner cylinder 6. The lead wire 17b is routed on the side where the mist generation unit 11 is disposed with respect to the virtual plane Vp. Note that the virtual plane Vp is shown as a straight line in FIGS. 2 and 3. Further, the intermediate position M can be an arbitrary position between the metal fine particle generation unit 10 and the mist generation unit 11. However, the intermediate position M can be an intermediate position between the discharge electrodes 10a and 11a or the ground electrodes 10b and 11b. It is preferable to set it to a position that is exactly in the middle between the ends.

  The lead wires 17a and 17b include voltage application lead wires 17a1 and 17b1 and ground lead wires 17a2 and 17b2, respectively. For each of the lead wires 17a and 17b, the voltage application lead wires 17a1 and 17b1 and the ground lead wire 17a2 are included. , 17b2 are routed along each other, and are routed so as not to cross each other.

  As shown in FIG. 2, the case 3 is formed with an elliptical through hole 3b at a position on the exit opening 4b side of the cavity 9, and the through hole 3b is a cover made of an insulating synthetic resin material. 20 is closed. The cover 20 is formed with a metal fine particle outlet 20a and a mist outlet 20b. 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, the charged fine metal particles and mist are hardly released from the fine metal particle generation unit 10 and the mist generation unit 11 due to the charge. In this part, the cover 20 forms the outer wall of the hair dryer 1.

  Here, in this embodiment, the distance D1 from the cover 20 as the outer wall to the ground electrode 10b of the metal fine particle generation unit 10 and the distance D3 from the cover 20 to the ground electrode 11b of the mist generation unit 11 are substantially equal. Thus, the occurrence of a potential difference between the metal fine particle generation unit 10 side and the mist generation unit 11 side in the hair dryer 1 is suppressed, and the voltage in the metal fine particle generation unit 10 or the mist generation unit 11 is reduced due to this potential difference. It is suppressed that the performance of the metal fine particle production | generation part 10 or the mist production | generation part 11 falls or destabilizes by becoming stable.

  Moreover, in this embodiment, as shown in FIG. 2, the metal fine particle discharge port 20a is made smaller than the mist discharge port 20b. That is, the maintenance and state confirmation of the mist generating unit 11 through the mist discharge port 20b can be performed more easily, and erroneous entry of fingers, tools, foreign objects, etc. through the metal fine particle discharge port 20a is suppressed. It is.

  Furthermore, the hair dryer 1 according to this embodiment includes a light emitting unit 21. The light emitting unit 21 includes a light source 21a such as an LED (light emitting diode) disposed in the cavity 9, and a light guide member 21b formed of a synthetic resin material having translucency such as acrylic that guides light from the light source 21a. And have. As shown in FIG. 2, a vertically long oval hole 20c is formed between the metal fine particle outlet 20a and the mist outlet 20b of the cover 20, and is opposite to the light source 21a of the light guide member 21b. The side emission end portion 21 c is fitted into the hole 20 c and exposed outside the cover 20. Therefore, the light from the light source 21a is guided by the light guide member 21b and emitted from the emission end 21c to the outside of the cover 20. In such a configuration, when the hair dryer 1 is used, the emission end portion 21c is arranged to face the user's head.

  The light emitting unit 21 can be used as display means for the operation mode of the hair dryer 1. For example, when the heater 8 is used and hot air is blown out, the color is red. When the heater 8 is not used and cold air is blown out, the metal fine particle generator 10 is operating and the metal fine particles are released. It is possible to change the color according to the operation state, such as yellow in a state where the mist is generated, and blue in a state where the mist generation unit 11 is operating and the mist is released. In this case, for example, a control circuit (not shown) mounted on the same substrate as the second voltage application circuit 12 or the like can control the light emission of the light source 21a according to the operation state of each part. In this case, a plurality of light sources 21a corresponding to the respective colors are mounted, and the control circuit controls light emission of the plurality of light sources 21a. The light source 21a can be blinked by the control circuit, the blinking interval can be controlled, and the light emission intensity can be changed. These light emission modes can be set in association with various operation modes. Is possible.

  Further, it is possible to give a predetermined effect to the human body by the light from the light emitting unit 21. For example, when a high-brightness LED having a wavelength of 415 [nm] is used as the light source 21a, the blue light emitted from the light source 21a causes sterilization effect due to destruction of bacteria, reduction of pores, decrease in sebum secretion, and the like. It has been confirmed that a preventive effect for acne can be obtained. Further, when a high-intensity LED having a wavelength of about 630 [nm] is used as the light source 21a, red light emitted from the light source 21a promotes blood circulation, activation of metabolism by angiogenesis, and generation of collagen and elastin. It has been confirmed that effects such as Furthermore, it has been confirmed that when the number of times of red light irradiation is repeated, it is effective for improving photo-aged skin such as fine lines, spots, dullness, and open large pores and scars after acne. These effects vary depending on the person.

  Furthermore, the light emitting unit 21 can be used as an irradiation unit that illuminates the metal fine particle generation unit 10 or the mist generation unit 11. This makes it easy to visually recognize the state of the metal fine particle generation unit 10 and the mist generation unit 11, and also provides an effect of improving the work efficiency by improving the visibility when performing maintenance such as cleaning.

  As described above, the hair dryer 1 as the hair care device according to the present embodiment accommodates the metal fine particle generation unit 10 and the mist generation unit 11 in the same cavity 9, but is generated in the mist generation unit 11. When the mist reaches the metal fine particle generation unit 10, the metal fine particle generation unit 10 is charged and the voltage or electric field changes to destabilize the generation of metal fine particles, or the metal part of the metal fine particle generation unit 10 is corroded by moisture. There is a risk that.

  Therefore, in the present embodiment, the metal fine particle generation unit 10 is arranged away from the mist passage region Ami through which the mist generated by the mist generation unit 11 passes. Specifically, as shown in FIG. 3, the metal fine particle generation unit 10 is arranged apart from the mist generation unit 11 in a direction Dn substantially perpendicular to the direction Dp through which the mist passes in the mist passage region Ami. It is. Since the mist flows out from the mist generation unit 11 in the direction Dp, it is difficult for the mist generation unit 11 to reach the metal fine particle generation unit 10 arranged in the direction Dn orthogonal to the direction Dp. Therefore, with this configuration, the metal fine particle generation unit 10 is not easily affected by the mist flowing out of the mist generation unit 11.

  In the present embodiment, in the cavity 9, the metal fine particle generation unit 10 is disposed at a position relatively close to the metal fine particle discharge port 20a so as to face the metal fine particle discharge port 20a, and the mist generation unit 11 is At a position relatively close to the mist discharge port 20b, the mist discharge port 20b is opposed to the mist discharge port 20b. Furthermore, the distance D3 between the mist generating unit 11 and the cover 20 is shorter than the distance D2 between the mist generating unit 11 and the metal fine particle generating unit 10. Further, in the cavity 9, the branch flow Wp flowing from the gap g1 is discharged to the outside from the metal fine particle discharge port 20a and the mist discharge port 20b.

  Therefore, in this embodiment, the metal fine particles generated by the metal fine particle generation unit 10 are discharged relatively smoothly from the metal fine particle discharge port 20a, and the mist generated by the mist generation unit 11 is relatively smooth. It is discharged from the mist outlet 20b. That is, the metal fine particles generated by the metal fine particle generation unit 10 are difficult to flow to the mist generation unit 11 side, and the mist generated by the mist generation unit 11 is difficult to flow to the metal fine particle generation unit 10 side. . The branched flow Wp contributes to the discharge of the metal fine particles and the mist. However, even when there is no branch flow Wp, the metal fine particles and the mist are discharged from the corresponding discharge ports 20a and 20b.

  Furthermore, in this embodiment, by providing a shielding wall in the cavity 9, it is possible to more reliably suppress the mist from reaching the metal fine particle generation unit 10. In the present embodiment, the light guide member 21b and the attachment member 6d for attaching the metal fine particle generation unit 10 to the inner cylinder 6 are used as shielding walls.

  The light guide member 21 b is formed in a plate shape, and the thickness direction of the light guide member 21 b is along the circumferential direction of the inner cylinder 6, and the discharge end side (left side in FIG. 3) of the metal fine particle generation unit 10 and the discharge of the mist generation unit 11. The metal fine particle passage region (that is, the region on the left side of FIG. 3 with respect to the metal fine particle generation unit 10) Ame side and the mist passage region (that is, the mist generation unit) 11 is a shielding wall that divides the area Ami on the left side of FIG.

  The attachment member 6 d is a member that protrudes radially outward from the tubular portion 6 a of the inner cylinder 6, and is a member that attaches the metal particulate generation unit 10 to the inner cylinder 6. And it has the shielding wall part 6e extended toward the metal microparticle discharge port 20a side from the metal microparticle production | generation part 10 side. Since this shielding wall portion 6e is provided on the attachment member 6d, it is inevitably disposed close to the metal fine particle generating portion 10, and the mist reaches the metal fine particle generating portion 10 side with a relatively small configuration. Can be efficiently suppressed.

  Further, a gap g2 is provided between the shielding wall portion 6e of the mounting member 6d and the cover 20, and the electric charge staying in the cover 20 arrives at the metal particulate generation portion 10 side through the shielding wall portion 6e to generate metal particulates. Inhibition of the formation of metal fine particles in the portion 10 is suppressed. Instead of providing the gap g2, a low-conductivity or insulating member may be interposed between the attachment member 6d and the cover 20.

  As shown in FIG. 3, the light guide member 21b and the mounting member 6d functioning as a shielding wall are disposed substantially parallel to the direction Dp through which the mist passes in parallel in the cavity 9, and are thus double shielding walls. Thus, the mist is more effectively suppressed from reaching the metal fine particle generation unit 10.

  As described above, in this embodiment, the lead wire 17a and the lead wire 17b are routed in the case 3 so as not to cross each other. Therefore, it is possible to suppress a decrease in performance and instability due to mutual interference between the lead wires 17a and 17b. In the present embodiment, since the metal fine particle generation unit 10 and the mist generation unit 11 are provided as the ion generation unit, the generation of metal fine particles and mist is caused by the mutual interference of the lead wires 17a and 17b for applying a voltage to them. It is possible to suppress the amount from being lowered or destabilized.

  Further, in the present embodiment, the lead wire 17a is drawn out from the metal particle generation unit 10 to the side away from the mist generation unit 11 and wired, and the lead wire 17b is connected from the mist generation unit 11 to the metal particle generation unit 10. Pulled out and routed to the side away. If these lead wires 17a and 17b are pulled out to the side close to each other, there is a risk of crossing close to each other. In this respect, in such a configuration, the lead wires 17a and 17b can be pulled out to the side away from each other. Therefore, a portion where the lead wire 17a is connected to the metal particulate generation unit 10 and a portion where the lead wire 17b is connected to the mist generation unit 11 Can be more reliably separated from each other, and performance degradation and instability due to mutual interference between the lead wires 17a and 17b at this portion can be more reliably suppressed.

  Moreover, in this embodiment, the metal fine particle production | generation part 10 and the mist production | generation part 11 are arrange | positioned on the outer periphery of the inner cylinder 6 and spaced apart in the circumferential direction, and the lead wire 17a is connected to the metal fine particle production | generation part 10 and the mist production | generation part. 11 from the virtual plane Vp including the intermediate position M and the center axis of the inner cylinder 6 on the side where the metal fine particle generation unit 10 exists, and the lead wire 17b is connected to the mist generation unit 11 from the virtual plane Vp. Arranged on the existing side. That is, by arranging the lead wires 17a and 17b separately on the outer circumference of the inner cylinder 6 on one side and the other side in the circumferential direction, the lead wires 17a and 17b are separated from each other, thereby causing mutual interference. Performance degradation and instability can be suppressed. Further, in this configuration, when the lead wires 17a and 17b are routed relatively long, the inner cylinder 6 is interposed between the lead wires 17a and 17b, and mutual interference between the lead wires 17a and 17b occurs. It can suppress more reliably.

  In the present embodiment, the lead wires 17a and 17b are configured to include voltage application lead wires 17a1 and 17b1 and ground lead wires 17a2 and 17b2, respectively. Therefore, using the ground lead wires 17a2 and 17b2, the metal fine particle generation unit 10 and the mist generation unit 11 as the ion generation unit and the first and second voltage application circuits 14 and 12 corresponding thereto are grounded. Thus, it is possible to stabilize the voltage between the discharge electrodes 10a and 11a and the ground electrodes 10b and 11b, thereby stabilizing the generation of metal fine particles and mist.

  In the present embodiment, the voltage application lead wires 17a1, 17b1 and the ground lead wires 17a2, 17b2 are routed so as not to cross each other for both of the lead wires 17a, 17b. Therefore, it is possible to suppress the voltage drop due to the crossing of the voltage application lead wires 17a1 and 17b1 and the ground lead wires 17a2 and 17b2, and hence the deterioration of ion generation performance and instability.

  In the present embodiment, the distance D1 from the cover 20 to the ground electrode 10b of the metal fine particle generation unit 10 and the distance D3 from the cover 20 to the ground electrode 11b of the mist generation unit 11 are substantially equal (D1 = D3). ). Therefore, it is possible to suppress the occurrence of a potential difference between the metal fine particle generation unit 10 side and the mist generation unit 11 side in the hair dryer 1, and in the metal fine particle generation unit 10 and the mist generation unit 11, voltage fluctuations associated with the potential difference, and thus It can suppress that the production performance of metal fine particles or mist is lowered or unstable.

(First Reference Example ) FIG. 4 is a cross-sectional view of a hair brush as a hair care device according to a first reference example of the present invention.

A hair brush 1D as a hair care device according to the present reference example is formed in a rod shape, and the user holds the holding portion 1f and applies the brush portion 23 provided at the distal end portion 1g to the hair to shape the hair ( It is a thing. A plurality of bristles 23 a are projected from the brush part 23.

  The case 3D that forms the outer wall is formed by joining a plurality of divided bodies. A cavity is formed in the case 3D, and various electrical components are accommodated in the cavity.

  Further, a cover 20D having a bulged outer wall is attached to a portion of the gripping portion 1f close to the brush portion 23, and metal fine particles are generated in a cavity 9D formed by the cover 20D and the case 3D. The unit 10 and the mist generating unit 11 are accommodated. The cover 20D is formed with a discharge port 20d opened toward the bristle 23a, and the metal fine particles generated by the metal fine particle generation unit 10 and the mist generated by the mist generation unit 11 are exposed to the outside from the discharge port 20d. Released and affects hair and skin. A voltage is applied from the circuit unit 24 to the metal fine particle generation unit and the mist generation unit 11. That is, the circuit unit 24 includes a first voltage application circuit and a second voltage application circuit (both not shown). The circuit unit 24 is configured such that the first voltage application circuit and the second voltage application circuit are arranged close to each other, and the first and second voltage application circuits are mounted on the same substrate. However, mounting on the same substrate is not essential, and the substrates may be different. Further, it may be provided separately on the front and back sides.

Further, in this reference example , the charge part 25 is exposed on the surface of the grip part 1f in order to suppress the release of the metal fine particles from being inhibited by the charging of the user. The charging unit 25 is charged to a polarity opposite to the polarity of the metal fine particles and mist to be discharged (for example, plus in the case of a configuration in which the negative ions of the metal fine particles and mist are discharged). Is charged to the opposite polarity. Note that at least the outermost layer of the charging unit 25 is made of an insulating material.

  Further, the shielding wall 22 </ b> D is provided to suppress the mist generated by the mist generation unit 11 from reaching the metal fine particle generation unit 10.

Also in the above reference example , the lead wire 17a and the lead wire 17b are routed in the case 3D so as not to cross each other. Therefore, it is possible to suppress a decrease in performance and instability due to mutual interference between the lead wires 17a and 17b.

In this reference example , the circuit unit 24 including the first voltage application circuit and the second voltage application circuit is accommodated in the case 3D, and the lead wires 17a and 17b are separated from the circuit unit 24 in a direction away from each other. Pulled out and routed. If these lead wires 17a and 17b are pulled out to the side close to each other, there is a risk of crossing close to each other. In this respect, in such a configuration, since the lead wires 17a and 17b can be drawn out to the side away from each other, the portions where the lead wires 17a and 17b are connected to the circuit portion 24 are reliably separated from each other. It is possible to more reliably suppress the performance degradation and instability of the metal fine particle generation unit 10 and the mist generation unit 11 due to mutual interference.

In this reference example , the voltage application lead wires 17a1 and 17b1 and the ground lead wires 17a2 and 17b2 are routed along the lead wires 17a and 17b. Thereby, the electric field generated in the voltage application lead wires 17a1 and 17b1 can be reduced by the ground lead wires 17a2 and 17b2, and the electric field is applied to the metal fine particle generation unit 10, the mist generation unit 11, and other electrical components. It is possible to suppress the influence of.

Also in this reference example , the lead wire 17a is drawn from the metal fine particle generation unit 10 to the side away from the mist generation unit 11 and wired, and the lead wire 17b is connected from the mist generation unit 11 to the metal fine particle generation unit 10. Pulled out and routed to the side away. Therefore, the portion where the lead wire 17a is connected to the metal fine particle generation unit 10 and the portion where the lead wire 17b is connected to the mist generation unit 11 are reliably separated from each other, and the performance due to mutual interference between the lead wires 17a and 17b at this portion. Can be more reliably suppressed.

( Second Reference Example ) FIG. 5 is a sectional view of a hair brush as a hair care device according to a second reference example of the present invention.

A hairbrush 1E as a hair care device according to this reference example basically includes the same components as the hairbrush 1D according to the first reference example .

However, in this reference example , a fan 5E that generates an air flow W in the cavity 9D and a motor 7E that rotates the fan 5E are provided, and the metal fine particles generated by the metal fine particle generator 10 and the mist generated by the mist generator 11 are used. The difference from the first reference example is that it can be discharged on the branch flow Wp.

In this reference example , the motor 7E and the fan 5E as the air blowing mechanism are accommodated in a cavity formed in the case 3E. The motor 7E is rotationally driven by a drive circuit included in the circuit unit 24. An opening 1h serving as an air inlet is formed on the base end side (lower side in FIG. 5) of the case 3E. When the fan 5E rotates, air enters the cavity 9D from the outside through the opening 1h. An air flow W that flows in and is discharged from the discharge port 20d toward the brush portion 23 through the cavity 9D is formed, and air is also emitted from the blowout hole 23b formed at the base of the bristle 23a of the brush portion 23. Is blown out. In this reference example , electric power is supplied to the electrical components via the power cord 2.

Also in the above reference example , the lead wire 17a and the lead wire 17b are routed in the case 3E so as not to cross each other. Therefore, it is possible to suppress a decrease in performance and instability due to mutual interference between the lead wires 17a and 17b.

Also in this reference example , the lead wires 17a and 17b are drawn from the circuit portion 24 in a direction away from each other. Accordingly, the portions where the lead wires 17a and 17b are connected to the circuit unit 24 are more reliably separated from each other, and the performance of the metal fine particle generation unit 10 and the mist generation unit 11 is deteriorated due to mutual interference between the lead wires 17a and 17b at this portion. And destabilization can be suppressed more reliably.

Also in this reference example , the voltage application lead wires 17a1 and 17b1 and the ground lead wires 17a2 and 17b2 are routed along the lead wires 17a and 17b. Therefore, the electric field generated in the voltage application lead wires 17a1 and 17b1 can be attenuated by the ground lead wires 17a2 and 17b2, and the electric field is applied to the metal fine particle generation unit 10, the mist generation unit 11, and other electrical components. It is possible to suppress the influence.

Also in this reference example , the lead wire 17a is drawn from the metal fine particle generation unit 10 to the side away from the mist generation unit 11 and wired, and the lead wire 17b is connected from the mist generation unit 11 to the metal fine particle generation unit 10. Pulled out and routed to the side away. Therefore, the portion where the lead wire 17a is connected to the metal fine particle generation unit 10 and the portion where the lead wire 17b is connected to the mist generation unit 11 are reliably separated from each other, and the performance due to mutual interference between the lead wires 17a and 17b at this portion. Can be more reliably suppressed.

( Third Reference Example ) FIGS. 6 and 7 show a third reference example of the present invention. Of these, FIG. 6 is a side view of a hair iron as a hair care device according to the reference example . These are the VII-VII sectional views of FIG.

As shown in FIG. 6, a hair iron 1F as a hair care device according to this reference example includes two arm portions 1i and 1j that can be expanded in a substantially V shape via a rotation connecting portion 1k. The hair is sandwiched between the leading ends of the arm portions 1i and 1j, and the hair is heated by the heating unit 27 for hair shaping.

  As shown in FIG. 7, a cavity is formed inside the case 3F forming the outer wall, and various electrical components are accommodated in the cavity.

  A pair of covers 20F1 and 20F2 that form outer walls projecting in opposite directions (left and right directions in FIG. 7) are provided on a portion of the case 3F of the arm portion 1i adjacent to the sandwiching portion 26 on the side of the rotation connecting portion 1k. The metal fine particle generation unit 10 and the mist generation unit 11 are accommodated in a cavity 9F formed by the covers 20F1 and 20F2 and the case 3F. The metal fine particle generation unit 10 is accommodated in the cover 20F1, and the metal fine particles are discharged from a metal fine particle discharge port 20a formed in the cover 20F1. On the other hand, the mist production | generation part 11 is accommodated in the cover 20F2, and mist is discharge | released from the mist discharge port 20b formed in the cover 20F2.

Although the metal fine particle generation unit 10 and the mist generation unit 11 are disposed in the cavity 9F as the same space, the metal fine particle generation unit 10 and the mist generation unit 11 are disposed apart from each other, and the mist generation unit 11 is disposed in the mist discharge port 20b of the cover 20F2. Since the mist discharge direction is set in a direction away from the central portion of the cavity 9F, the metal fine particles are generated as is apparent from FIG. The unit 10 can be arranged relatively easily at a position removed from the mist passage region Ami from the mist generating unit 11. That is, in this reference example , the mist generation unit is compared with the metal particle generation unit 10 by a relatively simple configuration in which the metal particle generation unit 10 and the mist generation unit 11 are arranged on both sides of the central portion of the arm 1i. 11 can suppress the adverse effect caused by the mist generated in No. 11.

Also in the above reference example , the lead wire 17a and the lead wire 17b are routed in the case 3F so as not to cross each other. Therefore, it is possible to suppress a decrease in performance and instability due to mutual interference between the lead wires 17a and 17b.

Also in this reference example , the lead wires 17a and 17b are drawn from the circuit portion 24 in a direction away from each other. Accordingly, the portions where the lead wires 17a and 17b are connected to the circuit unit 24 are more reliably separated from each other, and the performance of the metal fine particle generation unit 10 and the mist generation unit 11 is deteriorated due to mutual interference between the lead wires 17a and 17b at this portion. And destabilization can be suppressed more reliably.

Furthermore, in the present reference example , the circuit unit 24 is arranged on the center side of the arm unit 1i, and the metal fine particle generation unit 10 and the mist generation unit 11 are arranged on both sides of the circuit unit 24. Therefore, the lead wires 17a, 17b can be routed away from the circuit unit 24 in a direction away from each other, and the performance and destabilization of the metal fine particle generation unit 10 and the mist generation unit 11 due to mutual interference between the lead wires 17a and 17b are more reliably ensured. Can be suppressed.

Also in this reference example , the voltage application lead wires 17a1 and 17b1 and the ground lead wires 17a2 and 17b2 are routed along the lead wires 17a and 17b. Therefore, the electric field generated in the voltage application lead wires 17a1 and 17b1 can be attenuated by the ground lead wires 17a2 and 17b2, and the electric field is applied to the metal fine particle generation unit 10, the mist generation unit 11, and other electrical components. It is possible to suppress the influence.

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

It is sectional drawing of the hair dryer as a hair care apparatus concerning 1st Embodiment of this invention. It is the front view which looked at the hair dryer as a hair care apparatus concerning 1st Embodiment of this invention from the exit opening side. It is a top view which expands and shows the part in which the 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 1st Embodiment of this invention. It is sectional drawing of the hairbrush as a hair care apparatus concerning the 1st reference example of this invention. It is sectional drawing of the hairbrush as a hair care apparatus concerning the 2nd reference example of this invention. It is a side view of the hair iron as a hair care apparatus concerning the 3rd reference example of the present invention. It is VII-VII sectional drawing of FIG.

Explanation of symbols

1 Hair dryer (hair care device)
1D, 1E hair brush (hair care device)
1F curling iron (hair care device)
4 Wind tunnel 6 Inner cylinder 10 Metal fine particle generator (first ion generator)
10a discharge electrode 10b ground electrode 11 mist generator (second ion generator)
11a discharge electrode 11b ground electrode 12 second voltage application circuit 14 first voltage application circuit 17 lead wire 17a (first) lead wire 17b (second) lead wire 17a1, 17b1 voltage application lead wire 17a2, 17b2 ground Lead wire 20, 20D, 20F1, 20F2 Cover (outer wall)
20a Metal particulate outlet 20b Mist outlet 24 Circuit part M Intermediate position Vp Virtual plane

Claims (4)

In the case, the inner cylinder forming a wind tunnel, and two ion generation unit that generates ions by discharge by applying a voltage between said and a discharge electrode and a ground electrode discharge electrode and the ground electrode With
The first ion generation unit and the second ion generation unit are arranged on the outer periphery of the inner cylinder and spaced apart in the circumferential direction,
In the case, a first lead wire for applying a voltage from the first voltage application circuit to the first ion generation unit is intermediate between the first ion generation unit and the second ion generation unit. From the virtual plane including the position and the central axis of the inner cylinder, route on the side where the first ion generation unit exists,
A second lead wire for applying a voltage from a second voltage application circuit to the second ion generation unit is routed on the side where the second ion generation unit exists from the virtual plane, and the first ion generation unit The lead wire includes a voltage application lead wire for applying a voltage between the first ion generation unit and the first voltage application circuit and a ground lead wire for ground connection,
The second lead wire includes a voltage application lead wire for applying a voltage between the second ion generation unit and the second voltage application circuit and a ground lead wire for ground connection,
The hair care device, wherein the first and second lead wires are arranged so that the voltage application lead wire and the ground lead wire are along each other and do not cross each other. A first ion outlet from which ions generated by the first ion generator are discharged and a second ion from which ions generated by the second ion generator are discharged to the outer wall of the hair care device. An ion outlet is formed,
While disposing the first ion generation unit facing the first ion discharge port, arranging the second ion generation unit facing the second ion discharge port,
According to claim 1, characterized in that the distance from the outer wall to the ground electrode of the first ion generation portion, the distance from the outer wall to the ground electrode of the second ion generator, and substantially equal Hair care equipment. The hair care device according to claim 1 or 2, wherein at least one of the ion generation units is a metal particle generation unit that generates metal particles by discharge. The hair according to any one of claims 1 to 3 , wherein at least one of the ion generation units is a mist generation unit that generates mist by refining supplied water by discharge. Care equipment.

Images