JP2014231021A - Hair care device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hair care device allowing a user to arrange the hair in an accentuated manner and removing static electricity according to a purpose.SOLUTION: A fan 6, a heater 5, and an ion generator 7 capable of independently generating positive ions and negative ions are disposed in a housing 1. A user can select, by means of the operation part 17, a negative ion emission mode for emitting only negative ions from the housing 1, and both ions emission mode for simultaneously emitting the positive ions and negative ions from the housing 1.

Description

  The present invention relates to a hair care device such as a dryer, a hair iron, and a roll brush.

  Conventionally, as a hair care device, there is a dryer described in JP 2008-49101 A (Patent Document 1). This dryer neutralizes the static charge in the hair by sending positive ions and negative ions to the hair at the same time as the air flow, so that the static electricity is removed and the hair is better organized. I have to.

  However, the above conventional dryer has a problem that, although it can improve the unity of the hair, for example, it is set so that only a part of the hair is applied and the hair set cannot be accented.

  The dryer can also be used to dry clothes, umbrellas, etc. However, since the conventional dryer always sends out both ions, it is easy to charge on one side, especially from a material that tends to be negatively charged. In some cases, the person who touches the dry clothes during the dry season in winter may feel uncomfortable due to static electricity.

JP 2008-49101 A

  Therefore, an object of the present invention is to provide a hair care device that can set a hair accent and can perform static elimination according to the purpose.

In order to solve the above problems, a hair care device of the present invention includes a blower and a heater in a housing having a suction port and a discharge port, and further includes a negative ion generation unit and a positive ion generation unit that are independent of each other. And an ion generator that can be driven.
In this ion generator, a negative ion discharge mode in which the negative ion generator is driven and the generated negative ions are discharged by driving the blower;
An operation unit that drives the negative ion generation unit and the positive ion generation unit and switches between a positive ion generation mode and a dual ion discharge mode in which the generated positive and negative ions are discharged by driving the blower;
In addition, the operation unit of the hair care device of the present invention can select driving or stopping of the heater, and enables the negative ion discharge mode or the both ion discharge mode to be performed with hot air or cold air.
Furthermore, in the hair care device of the present invention, the housing is provided with a foldable handle, and the handle is provided with the operation portion for mode switching.

  The hair care device of the present invention includes a dryer, a hair iron, and a roll brush.

  According to the present invention, since the negative ion discharge mode in which only negative ions are discharged can be selected, for example, the negative ion discharge mode is first selected and charged positively. By spraying negative ions on easy hair, you can make your hair moist.

  Further, according to the present invention, the ion mode selection allows selection of both ion discharge modes in which ras ions and negative ions are simultaneously discharged, so that positive ions and negative ions can be simultaneously applied to hair. Can be sent to. Therefore, the electrostatic charge in the hair can be neutralized and the static electricity can be removed to improve the unity of the hair.

According to the present invention, by selecting a negative ion discharge mode in which negative ions are discharged, for example, first, the negative ion discharge mode is selected, and negative ions are sprayed on hair that is easily charged positively. Moist feeling can be given.
In addition, according to the present invention, by selecting a both-ion discharge mode in which positive ions and negative ions are discharged simultaneously, positive ions and negative ions can be simultaneously delivered to the hair. It is possible to neutralize the static charge on the hair, and to improve the unity of the hair.

It is a perspective view of the dryer of one Embodiment of the hair care apparatus of this invention. It is a longitudinal cross-sectional view of the said dryer. It is a perspective view when the rear part side of a dryer is removed and the inside of the housing | casing 1 is seen from the rear part side of a dryer, and is a figure which shows the state in which the ion generator is not attached. It is a perspective view when the rear part side of a dryer is removed and the inside of the housing 1 is seen from the rear part side of the dryer, and is a view showing a state where an ion generator is attached. It is a perspective view when seeing an ion generator from the front side (insertion side to a crevice). It is a schematic conceptual diagram which shows the mechanism of the 1st modification which can discharge a plus ion independently, can discharge a negative ion independently, and can discharge a positive ion and a negative ion simultaneously. It is a schematic conceptual diagram which shows the mechanism of the 2nd modification which can discharge a plus ion independently, can discharge | release a negative ion independently, and can discharge a positive ion and a negative ion simultaneously. It is a schematic conceptual diagram which shows the mechanism of the 3rd modification which can discharge a plus ion independently, can discharge | release a negative ion independently, and can discharge a positive ion and a negative ion simultaneously. It is a schematic conceptual diagram which shows the mechanism of the 4th modification which can discharge a positive ion independently, can discharge a negative ion independently, and can discharge a positive ion and a negative ion simultaneously. It is a schematic conceptual diagram which shows the mechanism of the 5th modification which can discharge a plus ion independently, can discharge a negative ion independently, and can discharge a positive ion and a negative ion simultaneously. It is a figure for demonstrating neutralization of the ion in the mechanism of a 5th modification. It is a schematic conceptual diagram which shows the mechanism of the 6th modification which can discharge a plus ion independently, can discharge | release a negative ion independently, and can discharge a positive ion and a negative ion simultaneously. It is a figure explaining the mechanism of the dryer of a modification. It is a figure explaining the mechanism of the dryer of a modification. It is a schematic diagram which shows the structure of the electric power supply apparatus of a modification.

  Hereinafter, the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a perspective view of a dryer according to an embodiment of the hair care device of the present invention.

  As shown in FIG. 1, the dryer includes a housing 1, a handle 2, and an intake filter 3.

  The casing 1 is made of a plastic having excellent heat resistance. The housing 1 is hollow inside. The housing 1 has a discharge port 15 and a suction port 16, and wind flows in the housing 1 from the suction port 16 to the discharge port 15.

  The handle 2 is connected to the housing 1 with a joint structure. The handle 2 can be folded with respect to the housing 1. The handle 2 extends in substantially the same direction as the extending direction of the casing 1 in a state of being folded with respect to the casing 1, and has a structure that can be easily accommodated.

  The handle 2 has an operation unit 17 including one or more buttons as an ion mode selection unit. The operation portion 17 is located on the front side of the handle 2 and in the vicinity of the center portion in the length direction of the handle 2.

  The intake filter 3 is detachably attached to the rear side in the axial direction of the housing 1. The intake filter 3 is made of metal or plastic and has holes in a mesh shape or a lattice shape. The intake filter 3 serves to protect large foreign substances such as dust from entering, and to prevent a finger from touching the fan (shown in FIG. 2 later) by mistake during operation.

  FIG. 2 is a longitudinal sectional view of the dryer.

  As shown in FIG. 2, the dryer includes a heater 5, a fan 6 as a blower, and an ion generator 7. Inside the casing 1, a fan motor (not shown) for driving the fan 6, wiring, and a partition plate 10 are provided.

  The user can adjust the rotational speed of the fan motor in a plurality of steps (for example, two steps) by operating the operation unit 17 and can adjust the wind strength as appropriate. Further, the user can select driving and stopping of the heater 5 by operating the operation unit 17, and can appropriately select cold air and hot air. The ion generator 7 is detachably disposed at a predetermined location in the housing 1.

  FIG. 3 is a perspective view when the rear part of the dryer (including the intake filter 3 (see FIG. 1)) is removed and the inside of the housing 1 is viewed from the rear side of the dryer, and the ion generator 7 is attached. It is a figure which shows the state which is not made. FIG. 4 is a perspective view when the rear part of the dryer is removed and the inside of the housing 1 is viewed from the rear part of the dryer, and shows a state where the ion generator 7 is attached.

  As shown in FIG. 3, this dryer has a recess 48 in which the ion generator 7 is fitted on the rear side of the fan 6 and on the lower side in the housing 1, and the ion generator 7 is easily fitted in the recess 48. The ion generator 7 can be easily removed from the recess 48. In this way, maintenance or replacement of the ion generator 7 can be easily performed. 3 and 4, reference numeral 46 indicates a locking portion. The locking portion 46 is used to lock the rear portion including the intake filter 3 to the housing 1.

  FIG. 5 is a perspective view of the ion generator 7 when viewed from the front side (insertion side into the recess 48).

  The ion generator 7 includes a positive ion generator 50 and a negative ion generator 60. The positive ion generator 50 is negative in the width direction of the dryer casing 1 when the ion generator 7 is disposed in the recess. The ion generator 60 is located at an interval. The positive ion generator 50 generates positive ions, while the negative ion generator 60 generates negative ions.

  Specifically, the positive ion generator 50 includes a needle electrode 51 and a circular induction electrode 52, and the induction electrode 52 is disposed so as to surround the needle electrode 51. The needle electrode 51 is located substantially at the center of the circular induction electrode 52 and has a needle shape with a sharp tip. The distance between the induction electrode 52 and the needle electrode 51 is 8 mm.

In the positive ion generator 50, for example, a 60 Hz alternating current that switches between a voltage of effective voltage 2 kV or more and 0 V is applied to the needle electrode 51, while a direct current of 0 V is applied to the induction electrode 52. It has become. When an effective voltage of 2 kV or more is applied to the needle electrode 51, corona discharge occurs due to a potential difference with the induction electrode 52, water molecules in the air are ionized near the tip of the needle electrode 51, and hydrogen ions ( H ⁺ ) is produced. These hydrogen ions are combined (clustered) with water molecules in the air in a group state, and positive ions composed of H ⁺ (H ₂ O) m (m is an arbitrary natural number) are generated.

  On the other hand, the negative ion generator 60 also has a needle electrode 61 and a circular induction electrode 62, and the induction electrode 62 is disposed so as to surround the needle electrode 61. The needle electrode 61 is located substantially at the center of the circular induction electrode 62 and has a needle shape with a sharp tip. The distance between the induction electrode 62 and the needle electrode 61 is 8 mm.

In the negative ion generator 60, for example, a voltage of effective voltage −2 kV or less and a 60 Hz alternating current that switches 0 V are applied to the needle electrode 61, while a direct current of 0 V is applied to the induction electrode 62. And negative ions are generated. The negative ions are oxygen ions O ₂ ^{− formed} by ionization of oxygen molecules or water molecules in the air. The oxygen ions are combined (clustered) with water molecules in the air to generate negative ions composed of O ₂ ⁻ (H ₂ O) n (n is an arbitrary natural number).

  In this embodiment, the positive ion generation unit 50 and the negative ion generation unit 60 can be driven independently of each other by the operation of the operation unit 17 by the user. Specifically, only the positive ion generation unit 50 is driven. In addition, only the negative ion generator 60 can be driven, and both the ion generators 50 and 60 can be driven simultaneously. Here, not only simultaneously, the ion generators 50 and 60 are driven at the same time, but, for example, the ion generator 50 is driven during a positive period of an alternating current, and the ion generator 60 is driven during a negative period. The case of being driven is also included in the state of simultaneous driving in this patent.

  Specifically, this dryer incorporates an electronic component including a microcomputer (hereinafter referred to as a microcomputer) in the vicinity of the operation unit, and the microcomputer is a well-known circuit based on instructions from the user, and each ion generator 50 , 60 can be cut off and passed independently of each other. Alternatively, the power of each of the ion generating units 50 and 60 may be cut off and insulated independently of each other by a circuit using a switch element such as a transistor. Then, the voltage supplied from the power source is appropriately boosted by a step-up transformer and applied between the electrodes 51 and 52 of the positive ion generator 50, and between the electrodes 61 and 62 of the negative ion generator 60. It is designed to be applied.

  In this dryer, the user can select a positive ion discharge mode in which only positive ions are discharged via the operation unit 17. When the positive ion discharge mode is selected, the microcomputer energizes only the positive ion generation unit 50. Only positive ions are mixed with the air (hot air or cold air) discharged from the dryer.

  Further, the user can select a negative ion discharge mode in which only negative ions are discharged via the operation unit 17. When the negative ion discharge mode is selected, the microcomputer energizes only the negative ion generation unit 60. Thus, only negative ions are mixed with the air (hot air or cold air) discharged from the dryer.

  In addition, the user can select the dual ion discharge mode in which the positive ions and the negative ions are discharged simultaneously from the inside of the housing 1 via the operation unit 17, and when the dual ion discharge mode is selected, the microcomputer Both the positive ion generator 50 and the negative ion generator 60 are energized, and both positive ions and negative ions are mixed with the wind (hot air or cold air) discharged from the dryer. Yes.

  According to the dryer of the above embodiment, since the user has the operation unit 17 that can select the negative ion discharge mode in which only negative ions are discharged and the positive ion discharge mode in which only positive ions are discharged, the user can For example, first, select the negative ion discharge mode, spray negative ions on hair that tends to be positively charged, and make the hair moist, then select the positive ion discharge mode and apply locally to the hair. For example, positive ions can be sprayed locally and partially to make the hair stand locally. Therefore, it is possible to add an accent to the hair set.

  Further, according to the dryer of the above embodiment, since a positive ion discharge mode in which only positive ions are discharged can be selected, polypropylene, polyester / PET, acrylic, polyurethane, polyethylene, vinyl chloride, silicon, easy to be negatively charged, A plus ion discharge mode can be selected when clothes or umbrellas made of Teflon (registered trademark), rubber or the like are dried or after drying, and plus ions can be sprayed on the clothes or umbrellas. Therefore, since the negative charge on the clothes and umbrellas can be neutralized efficiently, for example, it is possible to reliably prevent a person who touches the dried clothes during the dry season in winter from feeling uncomfortable due to static electricity.

  Moreover, according to the dryer of the said embodiment, since both ion discharge mode in which positive ion and negative ion are discharged simultaneously can be selected with the operation part 17 which is an ion mode selection part, it is positive ion to hair. And negative ions can be simultaneously delivered to the hair. Therefore, the electrostatic charge in the hair can be neutralized and the static electricity can be removed to improve the unity of the hair.

  In the dryer of the above embodiment, the positive ion generator 50 and the negative ion generator 60 can be driven independently of each other so that positive ions can be discharged alone, and positive ions can be discharged alone. It became possible to discharge. However, in the present invention, other mechanisms may be used so that positive ions can be discharged alone, or negative ions can be discharged independently.

In the above embodiment, the state in which positive ions, negative ions, positive ions, and negative ions can be discharged simultaneously is switched by switching the driving of the ion generator by a microcomputer or a circuit. Hereafter, an example in which the ion state is switched by means other than the ion generator will be described.
FIG. 6 is a schematic conceptual view showing a mechanism of a first modified example that can eject positive ions alone, can eject negative ions alone, and can simultaneously eject positive ions and negative ions.

  In the mechanism of the first modified example, the ion generator (ion generating element) 107 includes a positive ion generator 150 and a negative ion generator 160, and the positive ion generator 150 and the negative ion generator 160. Are always driven at the same time. Here, not only simultaneously, the ion generators 50 and 60 are driven at the same time, but, for example, the ion generator 50 is driven during a positive period of an alternating current, and the ion generator 60 is driven during a negative period. The case of being driven is also included in the state of simultaneous driving in this patent.

  As shown in FIG. 6, the mechanism of the first modification is that an ion generator 107 is arranged on the downstream side of the flow of wind generated by the fan 106 rather than the fan 106 that is a blower, and each ion generation Each of the parts 150 and 160 has a needle electrode that discharges and a circular induction electrode, as in the above embodiment, and the induction electrode is disposed so as to surround the needle electrode. In addition, the positive ions generated from the positive ion generation unit 150 are accommodated on the leeward side of the positive ion generation unit 150, and the partition wall has an opening on the leeward side and an air inlet (not shown) on the upper side And a first opening / closing device 190 that opens and closes the leeward opening of the positive ion storage chamber 180. The first opening / closing device 190 can be configured by a known shutter mechanism, electromagnetic valve, or the like, and receives a signal generated by an operation through a user operation unit (also serving as an ion mode selection unit). Opening and closing is controlled by the received microcomputer.

  The negative ion generation chamber 160 stores negative ions generated from the negative ion generation unit 160, has an opening on the leeward side, and has an air inlet on the windward side, And a second opening / closing device 191 for opening and closing the leeward opening of the negative ion storage chamber 181. The second opening / closing device can be configured by a known shutter mechanism, electromagnetic valve, or the like, and the opening / closing is controlled by a microcomputer that has received a signal generated by an operation through a user operation unit. ing.

  In the first modified example, when the ion generator 107 is driven, the fan 106 is driven, and only the opening on the leeward side of the plus ion storage chamber 180 is opened by the user's operation (illustrated). The heater that does not operate may be in any driven state or stopped state), and a wind containing only positive ions is discharged from the dryer.

  Further, when the ion generator 107 is driven, the fan 106 is driven, and only the leeward side opening of the negative ion storage chamber 181 is opened by the user's operation (the heater is in any driving state or The air containing only negative ions is discharged from the dryer.

  Further, when the ion generator 107 is driven, the fan 106 is driven, and both the positive ion storage chamber 180 and the negative ion storage chamber 181 are opened by the user's operation (the heater is A drive state or a stop state may be used), and a wind containing positive ions and negative ions is discharged from the dryer.

  FIG. 7 is a schematic conceptual diagram showing a mechanism of a second modified example that can eject positive ions alone, can eject negative ions alone, and can simultaneously eject positive ions and negative ions.

  In the mechanism of the second modification, the ion generator (ion generation element) 207 includes a positive ion generation unit 250 and a negative ion generation unit 260, and the positive ion generation unit 250 and the negative ion generation unit 260. Are always driven at the same time. Here, not only simultaneously, the ion generators 50 and 60 are driven at the same time, but, for example, the ion generator 50 is driven during a positive period of an alternating current, and the ion generator 60 is driven during a negative period. The case of being driven is also included in the state of simultaneous driving in this patent.

  As shown in FIG. 7, the mechanism of the second modified example is that an ion generator 207 is arranged on the downstream side of the wind flow generated by the fan 206 rather than the fan 206 that is a blower, and each ion generation is performed. Each of the parts 250 and 260 has a needle electrode that discharges and a circular induction electrode, as in the above-described embodiment, and the induction electrode is disposed so as to surround the needle electrode. The positive ion generation chamber 250 accommodates positive ions generated from the positive ion generation unit 250 from the windward side to the leeward side of the positive ion generation unit 250 and has an opening on the windward side and an air outlet on the leeward side. And a first opening / closing device 290 that opens and closes the opening on the windward side of the plus ion storage chamber 280. The first opening / closing device 290 can be configured by a known shutter mechanism, electromagnetic valve, or the like, and receives a signal generated by an operation through a user operation unit (also serving as an ion mode selection unit). Opening and closing is controlled by the received microcomputer.

  The negative ion generation chamber 260 accommodates negative ions generated from the negative ion generation unit 260 from the windward side to the leeward side of the negative ion generation unit 260 and has an opening on the windward side and an air outlet on the leeward side. And a second opening / closing device 291 that opens and closes the opening on the windward side of the negative ion storage chamber 281. The second opening / closing device 291 can be configured by a known shutter mechanism, electromagnetic valve, or the like, and the opening / closing is controlled by a microcomputer that receives a signal generated by an operation through a user operation unit. It has become.

  In the second modification, when the ion generator 207 is driven, the fan 206 is driven, and only the opening of the plus ion storage chamber 280 is opened by the user's operation (the heater is driven in any manner). The air containing only positive ions is discharged from the dryer.

  Further, when the ion generator 207 is driven by the user's operation, the fan 206 is driven, and only the opening of the negative ion storage chamber 281 is opened (the heater may be in any driving state or stopped state). ), A wind containing only negative ions is discharged from the dryer.

  In addition, when the ion generator 207 is driven by the user's operation, the fan 206 is driven, and both the positive ion storage chamber 280 and the negative ion storage chamber 281 are opened (the heater is A drive state or a stop state may be used), and a wind containing positive ions and negative ions is discharged from the dryer.

  FIG. 8 is a schematic conceptual diagram showing a mechanism of a third modified example that can eject positive ions alone, can eject negative ions alone, and can simultaneously eject positive ions and negative ions.

  In the third modification, the ion generator (ion generating element) 307 includes a positive ion generator 350 and a negative ion generator 360, and the positive ion generator 350 and the negative ion generator 360 are: They are always driven simultaneously. Here, not only simultaneously, the ion generators 50 and 60 are driven at the same time, but, for example, the ion generator 50 is driven during a positive period of an alternating current, and the ion generator 60 is driven during a negative period. The case of being driven is also included in the state of simultaneous driving in this patent. Each of the ion generators 350 and 360 has a needle electrode that discharges and a circular induction electrode, as in the above embodiment, and the induction electrode is disposed so as to surround the needle electrode.

  Further, the positive ions generated from the positive ion generation unit are accommodated on the leeward side of the positive ion generation unit 350, and the airflow outlet is provided on the leeward side, and the positive ions include a partition wall having an air inlet on the leeward side. It has a storage chamber 380 and a first fan 390 as a first air blower disposed on the leeward side of the positive ion generator 350 of the positive ion storage chamber 380.

  In addition, negative ions generated from the negative ion generation unit 360 are accommodated on the leeward side of the negative ion generation unit 360, and a negative wall including a partition wall having an air outflow port on the leeward side and an air outflow port on the leeward side. It has an ion storage chamber 381 and a second fan 391 as a second air blower disposed on the leeward side of the negative ion generation section 360 of the negative ion storage chamber 381.

  In the third modification, the microcomputer can drive the first fan 390 and the second fan 391 independently of each other by an operation through a user operation unit.

  In the third modification, when the ion generator 307 is driven by the user's operation and only the first fan 390 is driven (the heater may be in any driving state or stopped state), the generated negative ions are On the other hand, the generated positive ions are sent toward the discharge port, and the air containing only the positive ions is discharged from the dryer.

  Further, when the ion generator 307 is driven by the user's operation and only the second fan 391 is driven (the heater may be in any driving state or stopped state), the generated positive ions are directed toward the discharge port. On the other hand, the generated negative ions are sent to the discharge port, and the air containing only the negative ions is discharged from the dryer.

  Further, when the ion generator 307 is driven by the user's operation and the first and second fans 390 and 391 are driven (the heater may be in any driving state or stopped state), it is generated in the positive ion generator 350. The positive ions are sent to the discharge port, and the negative ions generated in the negative ion generation unit 360 are sent to the discharge port, and the wind containing the positive ions and the negative ions is discharged from the dryer. It has become so.

  FIG. 9 is a schematic conceptual view showing a mechanism of a fourth modified example that can eject positive ions alone, can eject negative ions alone, and can simultaneously eject positive ions and negative ions.

  In the fourth modification, the ion generator 407 includes a positive ion generation unit 450 and a negative ion generation unit 460, and the positive ion generation unit 450 and the negative ion generation unit 460 are always driven simultaneously. It is like that. Here, not only simultaneously, the ion generators 50 and 60 are driven at the same time, but, for example, the ion generator 50 is driven during a positive period of an alternating current, and the ion generator 60 is driven during a negative period. The case of being driven is also included in the state of simultaneous driving in this patent. Each of the ion generators 450 and 460 has a needle electrode for discharging and a circular induction electrode, as in the above-described embodiment, and the induction electrode is disposed so as to surround the needle electrode.

  A partition wall that accommodates positive ions generated from the positive ion generator 450 from the windward side to the leeward side of the positive ion generator 450 and has an air outlet on the leeward side and an air inlet on the windward side. And a first fan 490 serving as a first air blower disposed on the windward side of the positive ion generator 450 of the positive ion storage chamber 480.

  A partition wall that stores negative ions generated from the negative ion generator 460 from the windward side to the leeward side of the negative ion generator 460 and has an air outlet on the leeward side and an air outlet on the windward side. And a second fan 491 as a second air blower disposed on the windward side of the negative ion generation part of the negative ion storage chamber 481.

  In the fourth modification, the microcomputer can drive the first fan 490 and the second fan 491 independently of each other by an operation through a user operation unit.

  In the fourth modified example, when the ion generator 407 is driven by the user's operation and only the first fan 490 is driven (the heater may be in any driving state or stopped state), the negative ion generating unit 460 is operated. The negative ions generated in the above are not sent toward the discharge port, while the positive ions generated in the positive ion generator 450 are sent toward the discharge port, and the wind containing only the positive ions is discharged from the dryer. It has become so.

  Further, when the ion generator 407 is driven by the user's operation and only the second fan 491 is driven (the heater may be in any driving state or stopped state), the positive ions generated in the positive ion generator 450 are On the other hand, the negative ions generated in the negative ion generator 460 are sent toward the discharge port, and the air containing only the negative ions is discharged from the dryer. Yes.

  Further, when the ion generator 407 is driven by the user's operation and both the first and second fans 490 and 491 are driven (the heater may be in any driving state or stopped state), the positive ion generation unit 450 The positive ions generated at the discharge port are sent toward the discharge port, and the negative ions generated at the negative ion generation unit 460 are sent toward the discharge port and include both positive ions and negative ions from the dryer. Wind is discharged.

  FIG. 10 is a schematic diagram showing an ion generator according to a modification.

  In this modification, an ion generator (ion generating element) 507 is present downstream of the flow of wind generated by the fan 563 rather than the fan 563. As shown in FIG. 10, the positive ion generator 550 of the ion generator 507 includes a needle electrode 551 that emits positive ions, and an electrode 552 that is located upstream of the needle electrode 551 and can be negatively charged. Have. If the electrode 552 is negatively charged, positive ions emitted from the needle electrode 551 and the negative charge of the electrode 552 (or the negative charge of the electrode 552) are neutral as shown in FIG. It has been adapted. Similarly, the negative ion generator 560 of the ion generator 507 includes a needle electrode 561 that emits negative ions, and an electrode 562 that is located upstream of the needle electrode 561 and can be positively charged. ing. If the electrode 562 is positively charged, the negative ions emitted from the needle electrode 5561 and the positive charge of the electrode 562 are neutralized. In the modification shown in FIG. 10, the electrodes 552 and 562 located upstream of the needle electrodes 551 and 561 are charged, so that the ions that are not released are appropriately neutralized, so that at least one of positive ions and negative ions is obtained. Is selectively released.

  FIG. 12 is a schematic diagram showing an ion generator of a modification.

  In this modification, an ion generator (ion generating element) 617 is present downstream of the flow of wind generated by the fan 663 rather than the fan 663. As shown in FIG. 12, the positive ion generator 660 of the ion generator 617 has a needle electrode 661 that emits positive ions and a hole that can be negatively charged while being located on the downstream side of the needle electrode 661. An electrode 662. If the electrode 662 is negatively charged, the positive ions released from the needle electrode 661 and the negatively charged electrode 662 are neutralized. Similarly, the negative ion generator 670 of the ion generator 617 is a needle electrode 671 that emits negative ions, and an electrode 672 that is located upstream of the needle electrode 671 and has a hole that can be positively charged. And have. When the electrode 672 is positively charged, the negative ions released from the needle electrode 671 and the positively charged electrode 672 are neutralized. In the modified example of FIG. 12, by charging the electrodes 662 and 672 located upstream of the needle electrodes 661 and 671, the ions that are not released are appropriately neutralized, so that at least one of positive ions and negative ions is obtained. Is selectively released.

  FIG. 13 is a schematic diagram showing an ion generator of a modification.

  In this modification, the ion generator 807 is present downstream of the wind flow generated by the fan 805 rather than the fan 805. As shown in FIG. 13, this ion generating element 807 has an ion generating element 811 and a wire mesh electrode 880 having a hole and being located downstream of the ion generating element 811. doing. In this modification, for example, the electrode 880 located near the discharge port or the like is charged positively or negatively to neutralize one ion and discharge only the other ion, or charge the electrode 880. By not charging, both ions are ejected.

  In the dryer of the above embodiment, positive ions and negative ions can be ejected independently. However, in the present invention, the positive ion generation unit varies the number of positive ions generated per unit time. Even in a configuration in which the number of positive ions generated per unit time can be adjusted as appropriate, either may be used. For example, a configuration in which the number of positive ions generated per unit time can be adjusted as appropriate is a configuration in which the effective value of the voltage applied between the electrodes is varied, or a configuration in which the opening / closing device varies the rate at which the opening is closed (for example, the opening And the like (which can be configured by sliding the shutter)) or the like. Similarly, the negative ion generation unit can appropriately adjust the number of negative ions generated per unit time even if the number of negative ions generated per unit time cannot be varied. But either is fine. In the present invention, the number of positive ions that can be ejected per unit time and the number of negative ions that can be ejected per unit time may be the same or different.

  FIG. 14 is a diagram for explaining a mechanism of a dryer according to a modified example. When an ion generator that simultaneously generates positive ions and negative ions is used, a mechanism that separates and discharges positive ions and negative ions is shown. It is a figure explaining an example.

  As shown in FIG. 14, the dryer includes an ion generator 607, an electric field applying device 620, positive and negative ion partitioning portions 630, and a blower (not shown). The electric field applying device 620 applies an electric field in a direction perpendicular to the direction of the flow of wind generated by the blower. Further, the electric field applying device 620 is located further down the wind flow than the ion generator 607.

  The dryer sends positive ions and negative ions generated simultaneously by the ion generator 607 along with the wind generated by the blower to the leeward side, and passes through the electric field application region. In this way, the negative ions 640 passing through the electric field application region are advanced to the high potential side as shown by the arrow A and distributed to the high potential side, while the positive ions 650 passing through the electric field application region are As shown by B, it is advanced to the low potential side and distributed to the low potential side. In this way, the positive ions 650 and the negative ions 640 are separated from each other with the partition portion 630 as a boundary. Thereafter, using the existing shutter technology or the like, only one of the positive ions 650 and the negative ions 640 can be easily discharged from the housing.

  In this dryer, when the positive ions 650 and the negative ions 640 are to be discharged at the same time, the electric field applying device 607 is stopped by the microcomputer that has received a signal through the operation unit of the user. The positive ions 650 and the negative ions 640 can be discharged simultaneously without being separated.

  In addition, since the wind speed, which is the moving speed of ions, is much lower than the speed of the electron beam, positive ions 650 and negative ions can be adjusted by appropriately adjusting the strength of the electric field applied by the electric field applying device 620. The traveling direction of 640 can be changed, and the positive ions 650 and the negative ions 640 can be separated.

  Moreover, in the said embodiment, the plus ion generation | occurrence | production part 50,150,250,350,450,550 and the negative ion generation | occurrence | production part 60,160,260,360,460,560 are each driven independently, or both By driving simultaneously, a positive ion discharge mode, a negative ion discharge mode, and a dual ion discharge mode can be realized. However, in this invention, the structure which has three ion generation parts called the positive ion generation part, the negative ion generation part, and the both ion generation part which generates both ions simultaneously may be sufficient. Then, as shown in FIG. 15, that is, a schematic diagram showing the configuration of the power supply device of the modification, after the voltage supplied from the commercial power source is boosted by the booster circuit 700, the switching circuit 710 May be supplied to the driver 720 for use, or may be supplied to the current driver 730 for the positive ion generation unit, or may be supplied to the current driver 740 for both ion generation units. Then, current is supplied from each current driver to the positive ion generation unit, the negative ion generation unit, or both ion generation units, and the positive ion generation unit, the negative ion generation unit, or both ion generation units are driven independently of each other. It may be.

  Needless to say, a new embodiment of the present invention can be created by combining two or more invention-specific matters among all the invention-specific matters described in the above-described embodiment and the plurality of modified examples described above.

  Moreover, in the said embodiment and modification, although description was given about this invention taking the dryer as an example, it cannot be overemphasized that the hair care apparatus of this invention is not restricted to a dryer. For example, the present invention may be a hair iron or a roll brush, or any device that can be used for hair care.

  The hair care device of the present invention includes a housing, a heater disposed in the housing, an ion generator disposed in the housing, capable of generating positive ions and negative ions, and a plus from the housing. A positive ion discharge mode in which only ions are discharged, a negative ion discharge mode in which only the negative ions are discharged from the housing, and both the positive ions and the negative ions are simultaneously discharged from the housing. An ion mode selection unit capable of selecting an ion discharge mode.

  According to the present invention, since the positive ion discharge mode in which only positive ions are discharged and the negative ion discharge mode in which only negative ions are discharged are provided, for example, first, , Select the negative ion discharge mode, spray negative ions on the positively charged hair to make the hair moist, and then select the positive ion discharge mode to apply locally and partially to the hair The positive ions can be sprayed to make the hair stand locally. Therefore, it is possible to add an accent to the hair set.

  In addition, according to the present invention, it is possible to select a positive ion discharge mode in which only positive ions are discharged. Therefore, polypropylene, polyester / PET, acrylic, polyurethane, polyethylene, vinyl chloride, silicon, Teflon (registered) are easily charged negatively. Trademarks), clothing and umbrellas made of rubber, etc., and after drying, a positive ion discharge mode can be selected to spray positive ions on the clothing and umbrella.

  Therefore, since the negative charges charged on the clothes and the umbrella can be efficiently removed, it is possible to reliably prevent a person who touches the dried clothes from feeling uncomfortable due to static electricity, for example, during the dry season in winter.

  Further, according to the present invention, the ion mode selection unit can select both ion discharge modes in which the positive ions and the negative ions are discharged at the same time, so that the positive ions and the negative ions are applied to the hair. It can be delivered to the hair at the same time. Therefore, the electrostatic charge in the hair can be neutralized and the static electricity can be removed to improve the unity of the hair.

  In one embodiment, the ion generator includes a positive ion generation chamber having an opening, a negative ion generation chamber having an opening, a positive ion generation unit that generates positive ions in the positive ion generation chamber, and the negative ion generation chamber. A negative ion generator for generating negative ions in the ion generation chamber; a first opening / closing device for opening / closing the opening of the positive ion generation chamber; and a second opening / closing device for opening / closing the opening of the negative ion generation chamber. Yes.

  According to the above embodiment, the present invention can be realized with a simple configuration.

DESCRIPTION OF SYMBOLS 1 Housing 5 Heater 6,106,206,563,663,805 Fan 7,107,207,307,407,607,617,807 Ion generator 17 Operation part 50,150,250,350,450,550 Positive ion Generating part 51 Needle electrode of positive ion generating part 52 Inductive electrode of positive ion generating part 60,160,260,360,460,560 Negative ion generating part 61 Needle electrode of negative ion generating part 62 Inductive electrode of negative ion generating part 180 , 280, 380, 480 Positive ion storage chamber 181, 281, 381, 481 Negative ion storage chamber 190, 290 First switch 191, 291 Second switch 390, 490 First fan 391, 491 Second fan 640 Negative ion 650 plus ion

Claims (3)

In the case having a suction port and a discharge port, in a hair care device provided with a blower and a heater,
The hair care device further includes an ion generator that can drive the negative ion generator and the positive ion generator independently of each other,
A negative ion discharge mode for driving the negative ion generation unit and discharging the generated negative ions by driving the blower;
A hair care device having an operation unit that drives the negative ion generation unit and the positive ion generation unit and switches between both ion discharge modes for discharging the generated positive and negative ions by driving the blower. The operation unit selects driving or stopping of the heater,
The hair care device according to claim 1, wherein the negative ion discharge mode or the both ion discharge mode can be performed with hot air or cold air. The housing is provided with a foldable handle,
The hair care device according to claim 1, wherein the operation unit for mode switching is provided on the handle.

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