JP6030454B2 - Hair care equipment - Google Patents

Description

  The present invention relates to a hair care device that sends out charged particles to perform hair shaping.

  A conventional hair care device for delivering charged particles is disclosed in Patent Document 1. This hair care device includes a columnar gripping part gripped by a user and a brush part that is detachably connected in the axial direction of the gripping part. A large number of brush bristle materials are erected on the circumferential surface of the brush portion in a range of about a half circumference excluding a part in the circumferential direction.

  The gripping part has a suction opening at one end and an air passage is formed inside. A blower is disposed in the air passage. The air passage branches in two directions at the end on the brush portion side, and an air outlet that sends an air flow in the direction of the brush portion along the outer peripheral surface of the gripping portion opens at the tip. In addition, a charged particle generating device that has a discharge electrode disposed in the vicinity of the outlet and generates ions by discharge is provided in the grip portion.

  In the hair care device having the above-described configuration, the user performs hair styling by holding the grip portion and sliding the brush hair material on the hair. At this time, when the blower and the charged particle generator are driven, outside air flows into the air passage from the suction port, and an airflow containing ions is sent out from the blowout port. Thereby, ion is supplied to the hair which contacts a brush hair material, and the moisturizing effect of hair is acquired. In addition, static electricity generated on the hair sliding with the brush bristle material can be eliminated by ions, and the spread of the hair due to static electricity can be suppressed.

JP 2009-160184 A (pages 4-5, FIG. 7)

  However, according to the conventional hair care device, ions generated by the charged particle generator are sent outward from a blower outlet disposed at a position away from the brush bristle material. For this reason, ions diffuse into the air, and ions reaching the hair that contacts the brush bristle material are reduced. Accordingly, there has been a problem that the hair cannot be sufficiently moisturized and static electricity cannot be sufficiently eliminated, and good hair styling cannot be performed.

  An object of this invention is to provide the hair care apparatus which can perform hairdressing favorably.

  In order to achieve the above object, the present invention provides a gripping portion formed in a columnar shape by opening a suction port, and a plurality of brush bristle materials standing on the peripheral surface by being connected in the axial direction of the gripping portion. A brush portion that opens an air outlet between brush bristle materials, an air passage that communicates with the inside of the grip portion and the brush portion, and that guides an air flow from the suction port to the air outlet, and in the air passage A blower that is arranged, and a charged particle generator that generates a charged particle by having a discharge electrode facing the air passage downstream of the blower, and sends out an air flow including the charged particle from the outlet to the brush In a hair care device that performs hair styling with a hair material, the air passage has a restricting portion that restricts the passage, and the discharge electrode is disposed in a peripheral portion of the air passage downstream of the restricting portion.

  According to this configuration, the user grips the grip portion, slides the brush bristle material on the head hair, and performs brushing to perform hairdressing. When the blower and the charged particle generator are driven, the outside air flowing from the suction port flows through the air passage, and the charged particles are released from the discharge electrode. The airflow flowing through the air passage is squeezed by the squeezing part to increase the flow velocity, and sucks charged particles emitted from the discharge electrode disposed in the peripheral part downstream of the squeezing part by negative pressure. Thereby, the charged particles are included in the airflow, and the airflow including the charged particles flows through the air passage in the brush portion and is sent out from the outlet between the brush bristle materials.

  According to the present invention, in the hair care device having the above-described configuration, the charged particle generation device is detachably attached to the grip portion, and the discharge electrode is connected to the air passage through an opening portion that opens on a peripheral surface of the air passage. It is characterized by facing.

  In the hair care device having the above-described configuration, the present invention further includes: a heater disposed in the air passage; and a cover that covers the charged particle generating device and is opened and closed when the charged particle generating device is attached and detached. The generator has one end of the air passage in the air flow direction facing the opening, and a circuit board is built in the other end, and the charged particles are generated near the outer peripheral surface of the charged particle generator. The cover is provided with shielding ribs for shielding between both end portions of the apparatus.

  Further, the present invention provides the hair care device having the above-described configuration, wherein the cover is slid in the direction from the discharge electrode toward the terminal and closed, and when the cover is closed, the pressing rib that presses the charged particle generating device in the direction of the terminal. It is characterized by having.

  In the hair care device having the above-described configuration, the air passage of the brush portion may be formed on the same side as the discharge electrode with respect to the axial center of the throttle portion, and the brush bristle material on the opposite side of the discharge electrode. It is characterized by being arranged.

  In the hair care device having the above-described configuration, the brush bristle material is provided in a predetermined range excluding a part in the circumferential direction of the brush portion, and the plurality of brush bristle materials are arranged in parallel in the axial direction. Are arranged side by side in a predetermined cycle in the circumferential direction, and the air outlets are provided between the adjacent brush rows and on both outer sides of the brush rows at both ends in the circumferential direction.

  In the hair care device having the above configuration, the present invention is characterized in that the outer peripheral surface of the grip portion is reduced in diameter along the throttle portion with respect to the upstream side of the throttle portion.

  According to the present invention, the outlet of the air passage communicating with the grip portion and the brush portion opens between the brush bristle materials, and the discharge electrode of the charged particle generator is disposed facing the air passage. For this reason, it is possible to increase the number of charged particles that reach the head hair by sending an air flow including charged particles from the outlet between the brush bristle materials. In addition, since the discharge electrode is disposed in the peripheral portion of the air passage downstream from the throttle portion, it is possible to suppress the disappearance of the charged particles and increase the charged particles reaching the hair. Therefore, the hair can be sufficiently moisturized and neutralized, and good hair styling can be performed.

The perspective view which shows the hair care apparatus of 1st Embodiment of this invention. Side surface sectional drawing which shows the hair care apparatus of 1st Embodiment of this invention. Top surface sectional drawing which shows the hair care apparatus of 1st Embodiment of this invention. Side surface sectional view which shows the detail of the ion mixing part of the hair care apparatus of 1st Embodiment of this invention. AA sectional view of FIG. The schematic side view which shows the charged particle generator of the hair care apparatus of 1st Embodiment of this invention. BB sectional view of FIG. The perspective view which shows the cover of the hair care apparatus of 1st Embodiment of this invention. The figure which shows the result of having measured the charge amount of the hair at the time of brushing by the hair care apparatus of 1st Embodiment of this invention. The figure which shows the test method which measures the charge amount of the hair at the time of the brushing by the hair care apparatus of 1st Embodiment of this invention. The perspective view which shows the hair care apparatus of 2nd Embodiment of this invention.

<First Embodiment>
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a perspective view of the hair care device of the first embodiment. The hair care device 1 constitutes a hair dryer, and includes a columnar gripping part 10 gripped by a user and a brush part 30 that is detachably connected in the axial direction of the gripping part 10. The brush portion 30 is provided with a large number of brush bristle materials 31 in a range of about a half circumference excluding a part in the circumferential direction, and a plurality of small holes are formed between the brush bristle materials 31.

  The grip portion 10 has a power cord 17 led out from one end in the axial direction, and a suction port 15 made up of a large number of small holes opens around the power cord 17. An operation unit 12 having operation switches 18 and 19 is provided at the end of the grip unit 10 on the brush unit 30 side. The operation switch 18 switches on and off the blower 3 and the charged particle generator 20 (both see FIG. 2), which will be described later. The operation switch 19 switches on / off of a heater 4 (see FIG. 2) described later.

  Further, the grip portion 10 is provided with a reduced diameter portion 11 adjacent to the operation portion 12. The reduced diameter portion 11 has a conical surface on the outer peripheral surface, and reduces the outer diameter of the grip portion 10 toward the operation portion 12 with respect to the suction port 15 side. The user can easily perform the movement operation of the hair care device 1 and the switching operation of the operation switches 18 and 19 by gripping the reduced diameter portion 11 having a small outer diameter adjacent to the operation portion 12.

  2 and 3 show a side sectional view and a top sectional view of the hair care device 1. A connecting portion 16 that fits into the brush portion 30 is provided at the end of the gripping portion 10, and a connecting port 16 a opens at the end surface of the connecting portion 16. The connection port 16a is formed in a mesh shape to prevent entry of foreign matter (see FIG. 8).

  A cavity portion 25 is provided inside the grip portion 10, and a cavity portion 36 is provided inside the brush portion 30. An air passage 24 communicating with the inside of the gripping part 10 and the brush part 30 is formed by the hollow parts 25 and 36. The hollow portion 36 is formed to be biased to one side (lower side in FIG. 2) with respect to the center of the connection port 16a, and the air outlet 34 facing the other side (upper side in FIG. 2) of the connection port 16a is formed at the end of the brush portion 30. Provided. The brush bristle material 31 is arranged in the axial direction of the air outlet 34.

  The blower 3 is arranged in the hollow portion 25 so as to face the suction port 15. The blower 3 is formed by an axial fan driven by a motor 3a. The blower 3 may be formed by a centrifugal fan. When the blower 3 is driven, an airflow is guided from the suction port 15 to the blowout ports 33 and 34 by the air passage 24.

  The drive circuit 5 is arranged adjacent to the downstream of the blower 3 in the cavity 25. The drive circuit 5 drives the blower 3, the heater 4 and the charged particle generator 20 described later. By disposing the drive circuit 5 in the air passage 24, the drive circuit 5 can be cooled by the airflow flowing through the air passage 24.

  In the hollow portion 25, there is provided a throttle portion 26 that narrows the flow path by inclining the inner wall surface downstream of the blower 3. The outer peripheral surface of the reduced diameter portion 11 is formed along the throttle portion 26, and the outer diameter of the reduced diameter portion 11 can be easily reduced. A coil-shaped heater 4 is disposed in the throttle unit 26 to raise the temperature of the airflow.

  An ion mixing unit 27 formed inside the operation unit 12 is provided downstream of the throttle unit 26. FIG. 4 is a side sectional view showing details of the ion mixing section 27.

  The ion mixing section 27 has a flow area substantially equal to the inlet 26 a at the downstream end of the throttle section 26. Since the airflow flowing through the restrictor 26 is restricted in the flow path, the flow velocity is increased and guided toward the center of the flow path. For this reason, the airflow heated by the heater 4 flows through the central portion of the ion mixing unit 27. The channel area of the ion mixing unit 27 may be wider than the inlet 26a.

  A flat mounting surface 27a exposed on the outer surface of the operation unit 12 is formed on the peripheral surface of the ion mixing unit 27, and the charged particle generator 20 having a rectangular shape in plan view is detachably disposed on the mounting surface 27a. A contact point (not shown) connected to the drive circuit 5 is exposed on the wall surface adjacent to the reduced diameter portion 11 of the operation unit 12. A terminal 51 (see FIG. 6) to which power is supplied via a contact is provided on the end face of the charged particle generator 20. The outer peripheral surface of the charged particle generator 20 is covered with a cover 23 that is attached to and detached from the operation unit 12.

  FIG. 5 shows a cross-sectional view taken along the line AA of FIG. FIG. 6 is a schematic side view of the charged particle generator 20. The charged particle generator 20 has a pair of needle-like discharge electrodes 21 that face the air passage 24 via an opening 27b (see FIG. 4) that opens on the mounting surface 27a. The discharge electrode 21 is disposed at one end of the air passage 24 that is the front portion of the charged particle generator 20 in the air flow direction. Thus, one end of the charged particle generator 20 is arranged facing the opening 27b. A circuit board 50 is housed at the other end, which is the rear part of the charged particle generator 20 away from the discharge electrode 21, and a terminal 51 is provided at the rear end surface.

The charged particle generator 20 is provided with a cover portion 22 that opens a through hole 22a facing the discharge electrode 21 and covers the discharge electrode 21. When the charged particle generator 20 is attached and detached by the cover portion 22, the discharge electrode 21 is protected by preventing contact between the user's finger and the discharge electrode 21.

A positive high voltage pulse is applied to one discharge electrode 21, and a negative high voltage pulse is applied to the other discharge electrode 21. Thereby, corona discharge is generated at the tip of the discharge electrode 21. Corona discharge of the discharge electrode 21 to which a positive voltage is applied ionizes water molecules in the air and generates hydrogen ions. This hydrogen ion is clustered with water molecules in the air by solvation energy. Thereby, charged particles of positive air ions composed of H ⁺ (H ₂ O) m (m is 0 or an arbitrary natural number) are generated and mixed with the airflow through the through holes 22a.

In addition, oxygen molecules or water molecules in the air are ionized by corona discharge of the discharge electrode 21 to which a negative voltage is applied, and oxygen ions are generated. This oxygen ion is clustered with water molecules in the air by solvation energy. Thereby, charged particles of negative air ions composed of O ₂ ⁻ (H ₂ O) n (n is an arbitrary natural number) are generated and mixed with the airflow through the through holes 22a.

  At this time, the pair of discharge electrodes 21 are arranged in the circumferential portion of the ion mixing unit 27 by a predetermined amount in the circumferential direction of the ion mixing unit 27. In addition, an air flow whose flow velocity is increased by the throttle portion 26 upstream of the ion mixing portion 27 flows through the central portion of the ion mixing portion 27. For this reason, the ions generated at the discharge electrode 21 in the peripheral part are sucked and mixed by the negative pressure into the airflow flowing through the central part of the ion mixing part 27.

  When the airflow flows through the periphery of the ion mixing unit 27, ions that collide with the inner wall of the air passage 24 and disappear are increased by the airflow. For this reason, ions can be sucked and mixed by the airflow that has passed through the throttle portion 26 to reduce the disappearance of the ions. Further, if the discharge electrode 21 is arranged at the center of the ion mixing unit 27, the pressure loss of the air passage 24 becomes large. For this reason, the discharge electrode 21 can be arrange | positioned in the surrounding part of the ion mixing part 27, and ventilation efficiency can be improved.

  In addition, as shown in FIG. 2, a cavity 36 is disposed on the same side as the discharge electrode 21 with respect to the axial center of the narrowed portion 26, and a brush bristle material 31 is disposed on the opposite side of the discharge electrode 21. Thereby, ions generated at the discharge electrode 21 are smoothly guided to the cavity 36. Therefore, ions diffusing into the air from the air outlet 34 can be reduced, and many ions can be sent out from the air outlet 33 between the brush bristle materials 31.

  FIG. 7 shows a perspective view of the cover 23. The cover 23 is formed of a resin molded product, and slides in the axial direction of the operation unit 12 (see FIG. 1) to open and close the operation unit 12. Locking claws 23a are provided on both sides of the cover 23 on the brush portion 30 (see FIG. 1) side, and locking claws 23b are provided on both sides on the reduced diameter portion 11 (see FIG. 1) side. A pressing rib 23 d is provided on the end surface of the cover 23 on the brush portion 30 side.

  The cover 23 is slid in the direction from the discharge electrode 21 toward the terminal 51 (see FIG. 6), and the locking claws 23a and 23b are engaged with the operation portion 12 and closed. At this time, the charged particle generator 20 is covered with the cover 23 and pressed toward the terminal 51 by the pressing rib 23d. Thereby, the terminal 51 of the charged particle generator 20 can be reliably brought into contact with the contact.

  Further, the cover 23 is slid from the terminal side to the discharge electrode 21 side and opened to be removed. Thereby, the charged particle generator 20 (refer FIG. 2) can be attached or detached, and the discharge electrode 21 can be cleaned or the charged particle generator 20 can be replaced.

  On the inner surface of the cover 23, lattice-shaped shielding ribs 23 c that are close to the outer peripheral surface of the charged particle generator 20 are provided. The shielding rib 23 c shields between the front part and the rear part of the charged particle generator 20 inside the cover 23. In the charged particle generator 20, the terminal 51 disposed on the rear end surface comes into contact with the contact point, and as shown by the arrow D in FIG. 4 described above, a high-temperature air current flows from the gap between the opening 27 b and the front end surface of the charged particle generator 20. May leak. At this time, the airflow is shielded by the shielding ribs 23c, and the temperature rise of the circuit board 50 disposed at the rear of the charged particle generator 20 can be prevented.

  FIG. 8 shows a cross-sectional view taken along the line BB of FIG. The brush bristle material 31 is formed of a resin such as polyacetal and is implanted on a base material 35 formed of rubber or the like. Further, a plurality of brush rows 32 (see FIG. 3) in which a plurality of brush bristle materials 31 are arranged in the axial direction are arranged in parallel at a predetermined period in a range of about a half circumference excluding a part in the circumferential direction. The blower outlet 33 opens to the base member 35, and has a blower outlet 33a disposed between the adjacent brush rows 32, and a blower outlet 33b provided on both outer sides of the brush rows 32 at both ends in the circumferential direction.

  In the hair care device 1 having the above configuration, the blower 3, the charged particle generator 20, and the heater 4 are driven by operating the operation switches 18 and 19 while holding the grip 10. As a result, outside air flows into the air passage 24 through the suction port 15. The air flowing through the air passage 24 is heated by the heater 4 at the throttle unit 26 and flows into the ion mixing unit 27 through the inlet 26a.

  The air current flows through the central portion of the ion mixing unit 27 at a high speed, and ions generated from the discharge electrode 21 of the charged particle generator 20 are sucked and mixed by a negative pressure. The airflow containing ions is sent in the axial direction from the blowout port 34 to the brush bristle material 31 through the connection port 16a. Further, the air flow containing ions flows through the hollow portion 36 and is sent in the radial direction from the outlet 33 to the brush bristle material 31. The brush bristle material 31 slides on the hair by the movement of the gripping part 10 and is brushed. At this time, the hair is dried by the high-temperature airflow sent from the air outlets 33 and 34 and the hair is trimmed by the brush hair material 31.

  Moreover, since the airflow containing ion is sent between the bristles 31 from the blower outlets 33 and 34, the ion which reaches | attains hair can be increased. The ions moisturize the hair and static electricity generated by sliding with the brush bristle material 31 is removed. Thereby, the hair can be moisturized, and the hair can be spread well due to static electricity and good hair styling can be performed. At this time, since the blower outlets 33 are provided on both outer sides of the brush rows 32 at both ends in the circumferential direction, static electricity generated when the brush bristle material 31 is separated from the hair can be efficiently eliminated.

The blower 3 and the charged particle generator 20 can be driven with the heater 4 turned off by switching the operation switch 19.

  Table 1 and FIG. 9 show the results of a measurement test of the charge amount of the hair and the brush hair 31 during the brushing of the hair care device 1 of the present embodiment. Three human black hairs (BS-PGM manufactured by Beaulux Co., Ltd.) were used as samples, and 3 hairs were applied to each person's hair in an environment of temperature 27 ° C. and humidity 31% RH. Tests were performed.

  In Sample H, a hair bundle of 30 cm length and 15 g bundled with a rubber band 40 (see FIG. 10) was swung up and down 10 times in a 1% sodium dodecyl sulfate aqueous solution and then immersed for 10 minutes. Thereafter, the sample H is washed with water and dried with warm air. In the test method, as shown in FIG. 10, the suspended sample H is brushed five times by the hair care device 1 at a speed of 5 seconds / 30 cm.

  The test conditions were performed in a state where the blower 3, the charged particle generator 20, and the heater 4 of the hair care device 1 of the present embodiment were driven (Example). For comparison, in Comparative Example 1, the charged particle generator 20 was stopped and the blower 3 and the heater 4 were driven. In Comparative Example 2, the blower 3, the charged particle generator 20, and the heater 4 were driven and the air outlets 33b (see FIG. 8) on both outer sides of the brush row 32 were closed.

  As shown in FIG. 10, the charge amount was measured by a static electricity measuring device 41 from a position 2 cm away from a charged potential at a position 15 cm below the rubber band 40 of the sample H. Further, the electrostatic potential measuring device 41 measured the charging potential of the brush bristle material 31 from a position 2 cm away. The vertical axis in FIG. 9 indicates the charge amount (unit: kV), and the horizontal axis indicates each test condition.

  According to said test result, in the state (Example) which driven the air blower 3, the charged particle generator 20, and the heater 4, the charge amount of hair and the brush hair material 31 is low. On the other hand, in the comparative example 1 which stopped the charged particle generator 20, the charge amount of the hair and the brush hair material 31 is high. Moreover, the charge amount of the hair is high in the state where the outlet 33b is closed. Therefore, by providing the outlet 33b and driving the charged particle generator 20, static electricity generated when the brush bristle material 31 is separated from the hair can be efficiently eliminated.

  According to the present embodiment, the air outlet 33 of the air passage 24 communicating with the grip portion 10 and the brush portion 30 opens between the brush bristle materials 31, and the discharge electrode 21 faces the air passage 24. For this reason, it is possible to increase the number of ions that reach the head hair by sending an airflow containing ions from the blower outlet 33 between the brush bristle materials 31. Moreover, since the discharge electrode 21 is arranged in the peripheral part of the air passage 24 (ion mixing part 27) downstream from the throttle part 26, the disappearance of ions can be suppressed and ions reaching the hair can be increased. Therefore, the hair can be sufficiently moisturized and neutralized, and good hair styling can be performed.

  In addition, the charged particle generator 20 is provided so as to be detachable with respect to the grip portion 10, and the discharge electrode 21 faces the air passage 24 through an opening portion 27 b that opens on the peripheral surface of the air passage 24 (ion mixing portion 27). Arranged. Thereby, the charged particle generator 20 can be removed and the discharge electrode 21 can be easily cleaned, and the charged particle generator 20 in which the circuit board 50 and the discharge electrode 21 are integrated can be easily replaced. Further, since the discharge electrode 21 is disposed in the peripheral portion of the air passage 24, the charged particle generator 20 can be configured to be detachable with a simpler structure than that in the central portion.

  Further, the cover 23 has a shielding rib 23 c that is close to the peripheral surface of the charged particle generator 20 and shields between the front portion and the rear portion of the charged particle generator 20. Thereby, the temperature rise of the circuit board 50 by the high temperature airflow which leaks from the clearance gap between the opening part 27b and the charged particle generator 20 can be prevented, and the reliability of the hair care apparatus 1 can be improved.

  The cover 23 is slid in the direction from the discharge electrode 21 toward the terminal and closed, and has a pressing rib 23d that presses the charged particle generator 20 in the direction of the terminal when the cover 23 is closed. Thereby, the terminal of the charged particle generator 20 can be reliably brought into contact with the contact.

  Further, a cavity 36 is formed on the same side as the discharge electrode 21 with respect to the axis of the narrowed portion 26, and a brush bristle material 31 is disposed on the opposite side of the discharge electrode 21. As a result, ions generated at the discharge electrode 21 are smoothly guided to the cavity 36, and a large number of ions can be sent out from the air outlet 33 between the brush bristle materials 31.

  Further, the brush bristle material 31 is provided in a predetermined range excluding a part of the brush portion 30 in the circumferential direction, and the air outlets 33 are provided between the adjacent brush rows 32 and on both outer sides of the brush rows 32 at both ends in the circumferential direction. Thereby, the static electricity generated when the brush bristle material 31 is separated from the hair can be efficiently eliminated.

  Further, since the outer peripheral surface of the reduced diameter portion 11 of the grip portion 10 is formed along the narrowed portion 26, the outer diameter of the reduced diameter portion 11 can be easily reduced, and the user can easily hold it. That is, the reduced diameter portion 11 is formed with a conical surface on the outer peripheral surface, and reduces the outer diameter of the grip portion 10 toward the operation portion 12 with respect to the suction port 15 side. For this reason, the user holds the reduced diameter portion 11 having a small outer diameter adjacent to the operation portion 12. Further, the charged particle generator 20 is disposed downstream of the reduced diameter portion 11, and operation switches 18 and 19 are provided at locations where the volume is increased by the storage of the charged particle generator 20 (operation unit 12). Thereby, movement operation of the hair care apparatus 1 and switching operation of the operation switches 18 and 19 can be performed easily.

Second Embodiment
Next, FIG. 11 has shown the perspective view of the hair care apparatus 1 of 2nd Embodiment. For convenience of explanation, the same reference numerals are given to the same parts as those in the first embodiment shown in FIGS. In this embodiment, the brush bristle material 31 is provided on the entire circumference of the brush portion 30 in the circumferential direction. Other parts are the same as those in the first embodiment.

  In the brush portion 30, a plurality of brush rows 32 (see FIG. 3) in which a plurality of brush bristle materials 31 are arranged in the axial direction are arranged in parallel at a predetermined cycle over the entire circumference in the circumferential direction. Between the adjacent brush rows 32, an air outlet 33 made up of a large number of small holes is provided. A hollow portion 36 (see FIG. 2) provided inside the brush portion 30 is formed to have substantially the same diameter as the connection port 16a (see FIG. 2). Thereby, the airflow containing ion is sent out from the blower outlet 33 between the bristle materials 31.

  Therefore, the same effect as the first embodiment can be obtained. Moreover, the blower outlet 33 is provided between the brush bristle materials 31 distribute | arranged to the perimeter of the brush part 30. FIG. For this reason, the static electricity generated when the brush bristle material 31 is separated from the head hair can be efficiently eliminated regardless of the position of the brush portion 30 in the circumferential direction.

  In the first and second embodiments, the hair care device 1 may be a hair dryer that omits the heater 4 and sends out cold air. Further, only negative charged particles may be generated from the discharge electrode 21. At this time, charged particles may be generated by a single discharge electrode 21 instead of the pair of discharge electrodes 21.

  The charged particle generator 20 generates air ions, but is not limited thereto. For example, the charged particle generator 20 may be configured by an electrostatic atomizer. That is, condensation water is generated on the surface of the discharge electrode 21 by cooling the discharge electrode 21 provided in the electrostatic atomizer by the Peltier element. Next, when a negative high voltage is applied to the discharge electrode 21, charged fine particle water containing negative ions is generated from the dew condensation water. Further, when a positive high voltage is applied to the discharge electrode 21, charged fine particle water containing positive ions is generated from the dew condensation water. As a result, charged particles made of charged fine particle water can be sent out to perform moisture retention and static elimination of the hair.

  At this time, by disposing the discharge electrode 21 on the peripheral portion of the air passage 24 and providing the throttle portion 26 on the upstream side, the charged fine particle water is produced by the evaporation of the charged fine particle water by direct contact of the air flow with the charged fine particle water. Disappearance can be prevented.

  According to the present invention, the present invention can be used in a hair care device that sends out charged particles to perform hair shaping.

DESCRIPTION OF SYMBOLS 1 Hair care apparatus 3 Blower 4 Heater 5 Drive circuit 10 Gripping part 11 Reduced diameter part 12 Operation part 15 Suction port 16 Connection part 16a Connection port 18, 19 Operation switch 20 Charged particle generator 21 Discharge electrode 22 Cover part 23 Cover 23a, 23b Locking claw 23c Shielding rib 23d Pressing rib 24 Air passage 25, 36 Cavity part 26 Throttle part 26a Inlet 27 Ion mixing part 27a Mounting surface 27b Opening part 30 Brush part 31 Brush bristle material 32 Brush row 33, 33a, 33b, 34 Air outlet 35 Base material 40 Rubber band 41 Static meter 50 Circuit board 51 Terminal

Claims (4)

A gripping part that is formed in a columnar shape by opening the suction port, and a brush that is connected in the axial direction of the gripping part and has a large number of brush bristle materials standing on the peripheral surface and that opens an air outlet between the brush bristle materials An air passage that is provided in communication with the inside of the grip portion and the brush portion and guides an air flow from the suction port to the blowout port, a blower disposed in the air passage, and downstream of the blower In the hair care device comprising a discharge particle generator that has a discharge electrode facing the air passage and generates charged particles, and sends out an air flow containing the charged particles from the air outlet to adjust hair by the brush hair material, the air The passage has a restriction portion for restricting the flow path, and the discharge electrode is disposed in a peripheral portion of the air passage downstream from the restriction portion ;
A hair care device, wherein the charged particle generating device is detachably attached to the grip portion, and the discharge electrode faces the air passage through an opening portion that opens to a peripheral surface of the air passage . A heater disposed in the air passage; and a cover that covers the charged particle generating device and is opened and closed when the charged particle generating device is attached and detached, wherein the charged particle generating device is one of the air flow directions in the air passage. A shield rib for shielding the gap between both ends of the charged particle generator close to the outer peripheral surface of the charged particle generator. The hair care device according to claim 1 , wherein the hair care device is provided on a cover. Claim 1, wherein the air passage of the brush portion on the same side as the discharge electrode with respect to the axis of the narrowed portion is formed, the brush bristles on the opposite side of the discharge electrode is disposed Or the hair care apparatus of Claim 2 . The brush bristle material is provided in a predetermined range excluding a part in the circumferential direction of the brush part, and a plurality of brush rows in which the plurality of brush bristle materials are arranged in the axial direction are arranged in parallel at a predetermined cycle in the circumferential direction. The hair care device according to any one of claims 1 to 3 , wherein the air outlets are provided between the adjacent brush rows and on both outer sides of the brush rows at both ends in the circumferential direction.

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