JP2004047308A - Portable ion generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve minus ion generation efficiency while maintaining the simple structure of a portable ion generator which has a discharge means 12 in a given case 10 so that minus ions generated by the discharge means 12 are ejected to the outside of the case 10 from an ion outlet 24. <P>SOLUTION: In the case 10, there are provided a discharge electrode 16 which generates minus ions when subjected to a high voltage having a negative polarity, and a counter electrode 20 disposed near the discharge electrode 16. In addition, an auxiliary electrode 22 is provided to be exposed at the outer peripheral surface of the case 10. The counter electrode 16 and the auxiliary electrode 22 are connected to a ground line 18 provided in the case 10. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a portable ion generator that includes a negative ion generating means inside a case and can blow ions to a human body from a short distance.
[0002]
[Prior art]
Conventionally, the discharge means is built into portable beauty tools, mainly for treating hair, such as a dryer, brush, iron, or blosser, and by spraying negative ions in parallel during hair treatment, It is known that hydration can be efficiently performed for each one.
[0003]
[Problems to be solved by the invention]
To supply water to the hair, a high voltage of negative polarity is applied to the pointed discharge electrode to cause corona discharge, and the negatively charged oxygen is combined with minute water in the air by this discharge to form negative ions. When negative ions are attracted and neutralized by drying and positively charged hair, water molecules constituting the negative ions are directly attached to each hair to supply water to the hair. It is considered.
[0004]
As the effects of such negative ions have become known, the means of generating negative ions have also been incorporated into various portable beauty devices, but this type of device has been reduced in size and weight. As a result, it is required to manufacture products with a view to battery operation as well. As a result, development of more efficient ion generating means has been desired.
[0005]
In response to such a demand, the present inventors conducted research and found that an auxiliary electrode was provided in parallel with a conventional counter electrode, and the auxiliary electrode was exposed and disposed on the outer peripheral surface of the case. Has been substantially increased, and it has been found that negative ions can be generated efficiently.
[0006]
The present invention has been made based on such knowledge, and is provided with an auxiliary electrode having the same potential as the earth line in the case exposed at the peripheral surface position of the case, so that ion generation capable of efficiently generating negative ions is provided. It is intended to provide an instrument.
[0007]
The present invention further provides an ion generating device in which a case is constituted by a main body case and a handle, and an auxiliary electrode is provided on a handle portion, whereby contact between the auxiliary electrode and a human body during use of the device is reliably maintained. The purpose is to:
[0008]
Further, the present invention provides an ion generating device in which an ion generating device is formed into a hairbrush shape and an ion emission port and an auxiliary electrode are simultaneously provided on the brush surface, thereby automatically removing excess negative ions during ion processing. The purpose is to:
[0009]
In addition, in the iron-shaped ion generating device, by providing ion discharge ports on both sides in the longitudinal direction of the heating surface, the effect of supplying negative ion moisture before and after the hair is habituated by the heating surface is reduced by the auxiliary electrode. It is an object of the present invention to provide an ion generating device that is effectively exerted in combination with the action of removing excess ions.
[0010]
Further, at this time, the ion discharge port is configured to face the outside of the case or a rib is provided to prevent direct contact between the ion current and the auxiliary electrode, and the ion is not removed more than necessary. It is an object of the present invention to provide an ion generating device capable of performing the above-described operations.
[0011]
The present invention further provides a case, a metal screw or a metal fitting for joining, which is essential to be used at the time of assembling the equipment, a brush-like base in the case of a brush, or a hair iron in the form of an ion generator. In such a case, by using the heating surface as it is as an auxiliary electrode, it is not necessary to separately provide an auxiliary electrode, and an object of the present invention is to provide an ion generating device capable of preventing an increase in the number of parts beforehand. .
[0012]
[Means for Solving the Problems]
As shown in FIG. 1, the portable ion generator 14 according to the present invention includes a discharge unit 12 inside a predetermined case body 10 as schematically shown in FIG. 1, and is generated from the discharge unit 12. The ion can be released from the ion discharge port 24 to the outside of the case body 10.
[0013]
As shown in FIG. 5, the discharge means 12 includes, for example, a needle-shaped discharge electrode 16 capable of generating a negative ion 112 when a high voltage having a negative polarity is applied thereto, and a case in the vicinity of the discharge electrode 16. For example, a ring-shaped counter electrode 20 connected to the earth line 18 inside the body 10 is provided inside the case body 10. On the other hand, the auxiliary electrode 22 is provided so as to be exposed on the outer peripheral surface of the case body 10, and the auxiliary electrode 22 is connected to the earth line 18 provided inside the case body 10.
[0014]
As shown in FIGS. 1 and 2, the case body 10 includes a main body case 26 having an ion emission port 24 and a handle 28 extending from the main body case 26, and the auxiliary electrode 22 is provided on the handle 28. When the handle 28 is grasped, the human body and the auxiliary electrode 22 can be configured to be in contact with each other.
[0015]
When the handle 28 is made of a conductive rubber, the conductive rubber portion is used as the auxiliary electrode 22 to prevent an increase in the number of parts, and when the handle 28 is gripped in a metal case. It reduces the discomfort caused by the cold, and can be used as a non-slip.
[0016]
As shown in FIG. 8, the case body 10 includes a main body case 26 provided on a lower surface side with a brush surface 132 on which a predetermined bristle is implanted by brush bristles 134, and a handle 28 extending from a side surface of the main body case 26. By forming the brush into a brush shape and providing the ion emission port 24 and the auxiliary electrode 22 on the brush surface 132, it is also possible to directly neutralize the electrons charged on the hair 150.
[0017]
In addition to providing an individual electrode as the auxiliary electrode 22, the base end of a part or all of the brush bristles 134 is fixed with a conductive member to form a brush surface 132, and the conductive member is used as the auxiliary electrode 22. can do.
[0018]
On the other hand, one or a plurality of ion discharge ports 24 are provided on the brush surface 132, and the band-shaped auxiliary electrode 22 is provided at a part or all of the peripheral position on the brush surface 132. The band-shaped auxiliary electrode 22 is disposed in the axial direction in which the handle 28 extends, and opposed to the opening position of the ion emission port 24. And it is preferable to be disposed on both sides in the width direction with the ion emission port 24 interposed therebetween.
[0019]
Further, as shown in FIG. 11, the case body 10 is provided with a main body case 26 having a heating surface and an ion emission port 24 arranged at the same time on a lower surface thereof, and a handle 28 extending from a side surface of the main body case 26. Thus, an iron type can be used. In this case, the heating surface is a sandwiching type including a pair of upper and lower hot plates, and at least one of the hot plates is formed of a conductive member such as a metal, and the hot plate formed of the conductive member is It is used as an auxiliary electrode 22.
[0020]
Further, it is also possible to set the ion emission port 24 close to the heating surface 152 and set the blowing direction to the direction away from the heating surface 152, and as shown in FIG. In addition, an isolation rib 154 for preventing ions blown out from the ion emission port 24 from directly contacting the auxiliary electrode 22 may be provided.
[0021]
In this case, it is preferable that the heating surface 152 be formed in a band shape in the axial direction in which the handle 28 extends, and that the ion emission ports 24 be provided on both sides in the width direction with the heating surface 152 interposed therebetween.
[0022]
The case body 10 may be formed of a conductive member such as a metal itself, or may be a metal screw for fixing an internal circuit component to the case body 10 or a case coupling part, or the like. In the case where at least a part of the conductive member has a structure exposed to the outside, the conductive member can be used as the auxiliary electrode 22.
[0023]
Here, as shown in FIG. 4, the discharging means 12 interrupts the DC voltage supplied from the battery 136 incorporated in the case body 10 or the pulsating voltage Vb formed by rectifying the commercial AC voltage Va to reduce the low voltage. Is applied to the input side of the step-up transformer 76, a high-voltage pulse voltage is taken out from the output side of the step-up transformer 76, and the high-voltage pulse voltage is integrated to discharge the negative-polarity high voltage Vd. The discharge is continuously performed by always applying the voltage to the electrode 16.
[0024]
The negative ions 112 generated by the discharging means 12 can be released to the outside of the case body 10 by natural convection. However, the air blowing means 30 is further provided inside the case body 10 to force the negative ions 112. It can also be discharged to the outside of the case body 10.
[0025]
Further, the discharging means 12 is further provided with a switching means 15, and the driving time of the discharging means 12 and the effective time of the auxiliary electrode 22 can be regulated in conjunction with the switching operation of the switching means 15.
[0026]
【The invention's effect】
As described above, the present invention includes the auxiliary electrode 22 having substantially the same potential as the earth line 18 inside the case body 10 exposed to the peripheral surface position of the case body 10 so that the area of the counter electrode 20 is substantially reduced. Since the area for replenishing electrons increases, the generation of negative ions 112 can be performed efficiently.
[0027]
Further, the case body 10 is composed of the main body case 26 and the handle 28, and the auxiliary electrode 22 is provided on the handle 28, so that the contact between the auxiliary electrode 22 and the human body during use of the instrument is reliably maintained, and the human body is maintained. Since it becomes a part of the auxiliary electrode 22 and the area of the counter electrode 20 further increases, the generation of negative ions can be further accelerated or increased.
[0028]
In addition, by forming the auxiliary electrode 22 provided on the handle 28 with conductive rubber, if it is a metal plate, it may feel cold and uncomfortable when grasped, but this can be prevented and also it becomes non-slip.
[0029]
Further, the ion generator is formed into a hairbrush shape as shown in FIG. 8 and the ion discharge port 24 and the auxiliary electrode 22 are provided on the brush surface 132 at the same time. Therefore, the negative ions can be effectively fed during the next brushing, and the negative ions can be effectively used.
[0030]
Furthermore, the case body 10, metal screws and metal fittings which are essential to be used at the time of assembling the equipment, the base of the brush bristles in the case of the brush shape, or the hair iron shape of the ion generating device are used. In such a case, by using the heating surface 152 as it is as the auxiliary electrode 22, it is not necessary to separately provide the auxiliary electrode 22, and it is possible to prevent an increase in the number of parts.
[0031]
In addition, in the iron-shaped ion generating device, by providing the ion discharge ports 24 on both sides of the heating surface 152 in the longitudinal direction, the water supply effect of the negative ions before and after the hair is formed by the heating surface 152 can be reduced. This is effectively exhibited in combination with the action of the auxiliary electrode 22 for removing excess ions.
[0032]
Further, at this time, the ion discharge port 24 is configured to face the outside of the case body 10 or the rib 154 is provided, so that the direct contact between the ion flow 124 and the auxiliary electrode 22 is prevented beforehand, and the ion Can be prevented from being removed.
[0033]
Further, the low-voltage pulse voltage Vc is supplied to the input side of the step-up transformer 76, a high-voltage pulse voltage is taken out from the output side of the step-up transformer 76, and the output high-voltage pulse voltage is integrated to have a negative polarity. By generating the high voltage Vd, a continuous high voltage can be efficiently formed with substantially the same configuration regardless of whether the power supply is the commercial AC voltage Va or the battery 136.
[0034]
Further, the discharging means 12 is provided with a switching means 15, and the driving time of the discharging means 12 and the effective time of the auxiliary electrode 22 can be regulated in conjunction with the switching operation of the switching means 15, so that the amount of negative ions generated Can be manually changed to three levels. Further, by providing the air blowing means 30 at the same time and forcing the generated negative ions to be forcibly discharged, the negative ions are accurately supplied to the human body before they disappear, and are effectively used.
[0035]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the portable ion generating device according to the present invention will be described in more detail based on an example in which the portable ion generating device is applied to the hair dryer 32 shown in FIGS. Here, as schematically shown in FIG. 2, the hair dryer 32 includes a horizontally long tubular main body case 26 and a handle 28 which is swingably attached to a base end side of the main body case 26. .
[0036]
In the main body case 26, a motor that uses a commercial AC voltage Va supplied from the outside as a driving source, and has a heat generating portion 38 provided with a coil-shaped heater 36 at a front end side, and a blower capable of blowing air to the heat generating portion 38 A blower unit 44 including a fan 40 and a fan 42 is provided on the base end side, and a discharge unit 46 is provided in the heater 36 of the heat generating unit 38 to generate ions. Further, in conjunction with the electric circuit shown in FIG. 3 provided on the handle 28 side and the switching operation of the changeover switch 48, the timing of the air blowing and the generation of ions are regulated, and the power supplied to the heat generating part 38 is controlled. In addition, the air temperature at the time of blowing can be changed in a plurality of stages.
[0037]
Here, the blower unit 44 performs full-wave rectification of the commercial AC voltage Va by the diode bridge 50 and rotates the fan 42 by the DC motor 40 driven by this voltage. In response to the operation, the first contact 52 is turned on, and the air is blown at room temperature without heating in the heat generating portion 38.
[0038]
Next, in the heating section 38, the second contact 54 is turned on in addition to the first contact 52 by the slide operation of the changeover switch 48 in the second stage, and the half-wave rectified voltage is applied to the heater 36 via the diode 56. As a result, the heater 36 is driven with half the power of the rated value, and the air is blown at the medium temperature. When the switch 48 is further slid to the third stage, the third contact 58 connected in parallel with the diode 56 is also turned on, and the commercial AC voltage Va is directly supplied to the heater via the first to third contacts 52, 54, 58. As a result, the high-temperature air is blown. Since the configurations of the blower 44 and the heat generator 38 are substantially the same as those in the related art, detailed description thereof is omitted. Further, it is needless to say that the present invention can be implemented by replacing with another known configuration.
[0039]
The present invention has a feature in the configuration of the discharge unit 46 specifically exemplified in FIGS. 4 and 5, and is shown in FIG. 6A at the same time when the first contact 52 of the changeover switch 48 is turned on. The commercial AC voltage Va is applied to the low voltage rectifier circuit 60 to start operation.
[0040]
The low-voltage rectifier circuit 60 performs a half-wave rectification of the input commercial AC voltage Va by the diode 62 and then integrates the same by the resistor 64 and the capacitor 66, thereby obtaining a pulse whose peak value fluctuates around 100V as shown in FIG. Since the flowing voltage Vb is formed, the pulsating voltage Vb is used as a driving voltage for the display circuit 70 and the pulse voltage generating circuit 72.
[0041]
The display circuit 70 includes a light emitting diode 74 on the main body case 26 or the handle 28, and displays the operation of the discharge unit 46 by lighting the light emitting diode 74 with the voltage Vb output from the low voltage rectification circuit 60.
[0042]
The pulse voltage generation circuit 72 has a configuration in which a capacitor 80 is connected in series with a primary coil 78 of a step-up transformer 76, and a Sidac 82 is connected in parallel with the series connection. The Sidac 82 is off when the applied voltage is low, but is turned on when the value of the input pulsating voltage Vb exceeds, for example, 80 V. The capacitor 80 is charged, and the charging current is rapidly discharged through the Sidac 82 and the primary coil 78 when the Sidac 82 is turned on, and the Sidac 82 is turned off. This operation is periodically repeated until the pulsating voltage Vb drops to 80 V or less and the Sidac 82 is always turned off, so that the intermittently generated pulse voltage Vc as shown in FIG. It is generated in the primary coil 78 of the transformer 76.
[0043]
This pulse voltage Vc is boosted in accordance with the turn ratio between the primary coil 78 and the secondary coil 86 of the step-up transformer 76, and then a high voltage comprising a diode 88 and a capacitor 90 connected in series with the secondary coil 86. Applied to the rectifier circuit 92. The high-voltage rectifier circuit 92 integrates a high-voltage pulse voltage intermittently output from the secondary coil 86, and as shown in FIG. 6D, a negative-polarity high voltage Vd that fluctuates in a range of 2 to 4 kV. Is formed, and the voltage Vd is applied to the electrode portion 94. It should be noted that the specific circuit configuration for forming the high voltage Vd is not limited to the above, and it is needless to say that the present invention can be implemented with appropriate changes, such as using a well-known booster circuit conventionally used. .
[0044]
The electrode unit 94 is unitized as shown in FIG. 5 and is installed in a wind guide tube 98 disposed at the center position of the hot air outlet 96 in the main body case 26 shown in FIG. If the discharge to the outside of the main body case 26 is possible, for example, a ventilation path dedicated to ion release is provided on the peripheral surface of the main body case 26, and the electrode portion 94 is disposed therein. Alternatively, the arrangement position is not limited.
[0045]
The electrode portion 94 in this embodiment has a needle-shaped discharge electrode 16 having a sharp tip as a center, a cylindrical counter electrode 20 disposed around the discharge electrode 16, and an insulation between the discharge electrode 16 and the counter electrode 20. It is isolated by the member 100. The insulating member 100 includes an insulating portion 102 that fills the inside of the counter electrode 20 except for a tip portion of the discharge electrode 16, and a cylindrical isolation portion 104 that surrounds the tip portion of the discharge electrode 16 forward. In addition, a sufficient distance between the discharge electrode 16 and the counter electrode 20 to ensure corona discharge but prevent other discharges such as spark discharge is secured.
[0046]
Further, the negative electrode of the capacitor 90 of the high-voltage rectifier circuit 92 and the discharge electrode 16 are connected by a conductor 108 via a high resistance 106 of, for example, about several MΩ, while the positive electrode of the capacitor 90 and the counter electrode 20 are connected by a conductor 110. Connecting. With this configuration, a high voltage Vd of negative polarity is applied to the discharge electrode 16 to generate a corona discharge only at the tip end of the discharge electrode 16 and generate the negative ions 112 inside the isolation unit 104. And
[0047]
The air guide tube 98 is located in front of the above-mentioned isolation portion 104 and has a cylindrical first tube portion 114 having a slightly larger diameter than the first tube portion 114, and the electrode portion 94 diverging from the base end side of the first tube portion 114. And a second cylindrical portion 116 having a truncated cone shape and extending around the periphery of the second cylindrical portion 116. By maintaining a predetermined gap 122 between the air guide tube 98 and the electrode section 94 with the support arm 118, the airflow 120 sent from the blower section 44 through the air inlet 99 flows through the gap 122. When it passes through and is blown out from the ion discharge port 24 at the tip of the first cylindrical portion 114, it attracts the negative ions 112 generated in the isolation portion 104, and forms the ion flow 124 together with the air flow 120 in the main body case 26. It is released to the outside.
[0048]
In the present invention, the potential of the counter electrode 20 is maintained at substantially the ground potential by connecting the counter electrode 20 and the ground line 18 on the electric circuit side via a high resistance 126 of, for example, about 1 to several MΩ. I do.
[0049]
On the other hand, auxiliary electrodes 22 made of a conductive member such as a metal plate or a conductive rubber are provided at one or a plurality of positions on the handle 28 or the main body case 26 so as to be exposed at a portion to be touched when grasped with the palm. At the same time, the auxiliary electrode 22 and the opposing electrode 20 in the main body case 26 are connected to each other through a high resistance 128 of, for example, about several MΩ, so that they have substantially the same potential.
[0050]
The conductive member used as the auxiliary electrode 22 includes, for example, a natural rubber or a synthetic rubber, a conductive substance (conductive carbon such as furnace carbon or acetylene black, conductive titanium oxide, conductive zinc oxide, or the like). Can be used.
[0051]
By using such a conductive rubber, if it is a metal plate, it may feel cold and uncomfortable when it is gripped, but this can be prevented, and it is convenient because it also prevents slipping. Specifically, a conductive silicone rubber that does not require various additives such as a softening agent and an antioxidant that contaminate and corrode electronic components and has excellent oil resistance, heat resistance, and ozone resistance is used. The category of the conductive rubber includes a conductive elastomer obtained by filling a conductive material into an elastomer resin which is a polymer material exhibiting rubber-like elasticity at around normal temperature. In addition, various conductive resins can be used as the auxiliary electrode 22 as long as it does not have a slip-preventing effect but prevents only coldness when gripped. Note that the resistance value can be increased by adjusting the filling amount of the conductive substance to be small, so that the high resistance 128 can be omitted.
[0052]
By providing the auxiliary electrode 22 as described above, the area of the counter electrode 20 is substantially increased, the area for supplying electrons during discharge is increased, and negative ions can be efficiently generated. Further, when the auxiliary electrode 22 is brought into contact with the human body, the earth line 18 in the main body case 26 and the counter electrode 20 are connected to a part of the human body via the auxiliary electrode 22, and the electrons charged on the human body are discharged to the earth line 18 side. Then, while preventing the human body from being charged to a negative potential, the electric field intensity in the vicinity of the discharge electrode 16 can be maintained sufficiently large, and the generation amount of the negative ions 112 can be further increased.
[0053]
For example, as shown in FIG. 7, the generation amount of the negative ions 112 during 0 to 1 and a half minutes when the auxiliary electrode 22 is not brought into contact with the human body is at most about 250,000 per 1 cc. The ion amount increased to 500,000, which was about twice as large as the time a when the human body was brought into contact with the auxiliary electrode 22, and the amount was maintained substantially constant regardless of the passage of time. Was confirmed.
[0054]
The auxiliary electrode 22 can be used by forming a part or all of the handle 28 and the main body case 26 with a conductive material such as a metal plate, in addition to providing the auxiliary electrode 22 as described above. In addition, by increasing the number of parts by using a metal screw or metal fitting provided as an assembly for the case in a divided shape as it is or after being transformed into a size or shape that can be contacted from the outside, it is possible to prevent an increase in the number of parts.
[0055]
Also,
It is possible to set the shape and arrangement position of the auxiliary electrode 22 so as to always contact the human body during use. However, for example, by making it possible to select whether or not to touch the auxiliary electrode 22 with a fingertip, The production amount of the ions 112 may be manually changed.
[0056]
Further, it is also possible to provide a dedicated switch for restricting the operation of the discharge unit 46 without simultaneously controlling the discharge unit 46 to be turned on and off by the changeover switch 48 provided for turning on and off the blower unit 44. In this case, while the human body can always contact the auxiliary electrode 22 during use, the generation of the negative ions 112 that stop supplying power to the discharge unit 46 is interlocked with the switching operation of a separately provided dedicated ion generation switch. From the off state, to a normal ion generation state in which the discharge unit 46 is operating but the auxiliary electrode 22 is not connected to the ground line 18, the auxiliary electrode 22 is connected to the ground line 18. It is also possible to change the amount of ion generation in three stages in conjunction with the switching operation of the switch to the powerful ion generation using the method.
[0057]
Next, FIG. 8 shows an example in which the present invention is applied to a hairbrush 130. The handlebar 28 is linearly extended in the axial direction from the base end center of the main body case 26 having a brush surface 132 on the lower surface side. And the discharge part 46 a is housed in the main body case 26. Note that members having substantially the same functions as those of the configuration of the hair dryer 32 described above are denoted by the same reference numerals, and detailed description thereof is omitted.
[0058]
The brush surface 132 has an elliptical or rectangular shape that is long in the direction in which the handle 28 extends. The brush surface 132 has one or a plurality of ion emission ports 24, and brush bristles 134 are planted over substantially the entire surface excluding the ion emission ports 24. Is established.
[0059]
The configuration of the discharge portion 46a and the electrode portion 94a housed in the main body case 26 is the same or similar to the configuration illustrated in FIGS. 3 to 5 applied to the hair dryer 32 except for the heating portion 38. It is also possible. That is, the blower unit 44 is driven by using the commercial AC voltage Va to forcibly blow the negative ions 112 from the ion emission port 24 by the airflow 120, and the auxiliary electrode 22 is provided at the handle 28. .
[0060]
However, in this embodiment, various batteries 136 such as a dry battery or a secondary battery having an output voltage of about 3 V, for example, are built in the main body case 26 or the handle 28, and the output voltage from the battery 136 is not shown in an inverter (not shown). The voltage is converted into an AC voltage of about 100 V using a circuit, and this voltage is used as the input voltage of the pulse voltage generation circuit 72 and the drive voltage of the display circuit 70 shown in FIG. 4 so that the commercial AC voltage Va is not used. It can be driven only by the battery 136. Further, without providing the blower unit 44 shown in FIG. 3, the negative ions 112 are supplied to the hair using the ionic wind generated at the time of discharge or the natural convection accompanying the hair styling.
[0061]
Further, the present embodiment is characterized in that the auxiliary electrode 22 is provided on the brush surface 132 in addition to or instead of being provided on the handle 28 or the main body case 26. Here, as the auxiliary electrodes 22a and 22b provided on the brush surface 132, two narrow strips are formed along both side edges of the brush surface 132 in the width direction. Further, the auxiliary electrode 22 can be disposed only on the brush surface 132. However, in the illustrated example, the auxiliary electrode 22 extends to both side surfaces 27 of the main body case 26 and has a substantially L-shaped cross section. are doing.
[0062]
With this configuration, when the changeover switch 48a provided on the handle 28 is turned on, the switch contact 52a is turned on to drive the discharge unit 46a, and at the same time, the light emitting diode 74 of the display circuit 70 is energized to drive the discharge unit 46a. Display inside.
[0063]
In this state, the discharge unit 46a is driven, and in a state where negative ions are blown out from the ion emission port 24, the brush bristles 134 are inserted into the hair 150 as shown in FIG. Then, first, the first auxiliary electrode 22a provided on the front edge discharges unnecessary electrons charged on the hair 150. In this state, after brushing is performed with the brush bristles 134 while the ion flow 124 emitted from the center of the brush surface 132 is applied to the hair 150, excess electrons are discharged by the second auxiliary electrode 22b. The charged state of the hair 150 is neutralized and restored. Here, by extending the auxiliary electrode 22 to the side surface 27 of the main body case 26, even when brushing while curling, the auxiliary electrodes 22a and 22b can be brought into contact with the hair 150 to effectively neutralize the negatively charged state. It is.
[0064]
The auxiliary electrode 22 may be provided along the entire periphery of the brush surface 132, or may be provided only on one side edge. However, in the case where a plurality of ion emission ports 24 are provided in a dispersed manner or the diameter thereof is made elliptical in the axial direction, the ion emission ports 24 are sandwiched in the width direction, and the length of the ion emission ports 24 in the longitudinal direction is increased. And the length of the auxiliary electrode 22 are preferably set to be substantially equal or longer. With this configuration, the charging of the hair due to the negative ions blown out from the ion discharge port 24 is reliably neutralized.
[0065]
The auxiliary electrode 22 is formed of a metal material separate from the main body case 26, and the brush surface 132 for fixing the base end of the brush bristles 134 is formed of a conductive member such as conductive rubber. Can be used as the auxiliary electrode 22. In this case, the conductive member can be provided on the entire surface of the brush surface 132, but it is preferable to provide the conductive member only at the above-described peripheral position in order to enhance the effect of spraying the negative ions 112.
[0066]
Further, the brush bristles 134 can be made of a conductive resin or a conductive rubber to serve as the auxiliary electrode 22. In this case, since the brush bristles 134 reach the deep portion of the hair 150, the charged state of the hair 150 due to the negative ions can be effectively neutralized, and the negative ions can be effectively supplied at the next brushing.
[0067]
9 to 11 show an example in which the present invention is applied to a hair iron 138. In this embodiment, the brush surface 132 of the hairbrush 130 is replaced with the lower surface side of the main body case 26. An ironing unit 140 is provided. Members having substantially the same functions as those of the hair dryer 32 and the hair brush 130 described above are denoted by the same reference numerals, and detailed description thereof is omitted.
[0068]
The ironing section 140 includes a main body case lower surface 142 and a pair of an upper surface 146 of a holding arm 144 that is swingably attached to a rotating shaft 143 provided at a base end position of the handle 28. The holding arm 144 is normally urged to open by a spring body 145 such as a coil spring. As illustrated in FIG. 11, the hair is opposed to the spring body 145 between the lower surface 142 of the main body case and the upper surface 146 of the holding arm 144. By sandwiching the hair 150, it is possible to heat and press the hair 150 with the rectangular heating surfaces 152 provided in the longitudinal direction of the center while combing the hair 150 with the hair styling comb 148 provided on both sides in the width direction. I do.
[0069]
The heating surface 152 is formed of a hot plate such as a metal plate, and the heating of the hot plate is performed by using a heater 36a using a known heating element such as PTC in this embodiment, for example, by using silicone rubber. Although it is performed by being built in contact with the back side of the heating surface 152 in a state of being electrically insulated through such an insulating member, the configuration is limited such that the heating plate itself is integrally formed with the heater. Not something. Further, it is not necessary to provide the heater 36a on both of the upper and lower heating surfaces 152, 152. The heater 36a is provided on only one heating surface to generate heat, and is heated and pressed in pairs with the other heating surface. You can also. Even in such a case, since the overall configuration of the ironing unit 140 is substantially the same as that of the related art, detailed description will be omitted.
[0070]
In the present invention, the discharge section 46 is further provided in the main body case 26 so that negative ions can be sprayed on the hair 150 being processed. The circuit configuration of the discharge unit 46 is the same as or similar to that of FIG.
[0071]
The electrode portion 94b provided in the discharge portion 46 is provided in a pair at a peripheral position of the lower surface 142 of the main body case and further in parallel outside the hairdressing comb 148, and one or a plurality of the electrode portions 94b are provided at predetermined intervals (this embodiment). In this example, three (3) discharge electrodes 16 are provided, and a ring-shaped counter electrode 20 is provided slightly apart from each of the discharge electrodes 16 so that corona discharge is caused near the tip of the needle-shaped discharge electrode 16. , It is possible to generate negative ions in a substantially band shape.
[0072]
It is needless to say that the configuration of the electrode portion 94b is not limited as long as it can generate negative ions, such as that shown in FIG. Also, the number of the electrode portions 94b does not need to be provided plurally outside the hair dressing comb 148, but may be provided one by one on both sides. At least one electrode at the center is sufficient, for example.
[0073]
Here, the ion emission port 24 has a narrow slit shape corresponding to the disposition position of the above-described electrode portion 94b, and furthermore, the opening direction is inclined obliquely outward, so that the negative electrode generated near the discharge electrode 16 is formed. The ions are blown out in the direction away from the main body case 26 by the air flow 120 from the fan 42.
[0074]
Further, at least one of the heating plates constituting the heating surfaces 152 approaching each other is formed of a conductive member such as a metal plate, and the heating surface 152 formed of the conductive member is used as the auxiliary electrode 22. The auxiliary electrode 22 may be provided with a separate electrode on or near the heating surface 152 instead of or in addition to using the heating surface 152 as an electrode, and similarly to the case of the hair dryer 32. The auxiliary electrode 22 may be provided on the handle 28 or the main body case 26.
[0075]
When the upper and lower heating surfaces 152 are made of metal, the entire surface is further covered with a conductive rubber or a conductive resin, and this is used as a hot plate and an auxiliary electrode 22. Can be. As a result, the charged state of the hair due to the negative ions can be neutralized, and the feeling of being hot when touching the heating surface 152 can be reduced.
[0076]
With this configuration, when the switch 48 is turned on, the motor 40 of the blower 44 that rotationally drives the fan 42, the heater 36 a that heats the heating surface 152, the discharge unit 46, and the light emitting diode that indicates that the discharge unit 46 is being driven The driving power is simultaneously supplied to 74 and the operation starts. At this time, the power supply to the heater 36a is automatically controlled so that the temperature of the heating surface 152 is maintained at, for example, about 140 ° C.
[0077]
Then, the hair 150 is slid in the direction of the arrow in FIG. Then, the negative ions blown out from the ion emission port 24a on the leading edge side in the sliding direction adhere to the hair 150, so that the hair 150 is replenished with moisture and moisturized to become soft.
[0078]
The hydrated portion of the hair 150 passes between the upper and lower heating surfaces 152 as the hair iron 138 slides, and is compressed at the same time as the heating, so that the heating surface 152 is flat or corrugated. At the same time, a predetermined habit corresponding to the difference in shape is performed, and at the same time, the charged state is neutralized by the action as the auxiliary electrode 22. Further, the neutralized hair 150 passes under the ion emission port 24b on the trailing edge side, and is again sprayed with the negative ions 112. As a result, the hair compressed and dried between the upper and lower heating surfaces 152 It is possible to replenish the water to the 150 and to regain moisture.
[0079]
At this time, as shown in FIG. 10, the pair of ion discharge ports 24a and 24b and the heating surfaces 152 and 152 have substantially the same axial length, so that one of the ion discharge ports 24a has negative ions (water content). ) Can be reliably pressed after the hair 150 is replenished, and the replenished and charged negative ions can be uniformly removed and neutralized. Even after the pressing, a small amount of water remains but is insufficient. Therefore, after the removal, the negative ions are continuously fed through the ion discharge port 24b on the rear side in the sliding direction, so that the hair can be regained moisture.
[0080]
Further, since the ion emission port 24 is formed to be inclined outward, a sufficient isolation state is provided between the auxiliary electrode 22 at the center of the ironing section 140 and the ion flow 124 blown out from the ion emission port 24. It is maintained and prevents the negative ions from being captured by the auxiliary electrode 22 and disappearing before reaching the hair 150. The same effect can be achieved by providing a rib 154 between the auxiliary electrode 22 and the ion emission port 24 to isolate them from each other as shown in FIG.
[0081]
In addition, the portable ion generator 14 to which the present invention is applied is not limited to the products for hair care as described above, and the negative ion 112 is sprayed directly or indirectly on a human body for use. If it is, it can be implemented in substantially the same manner and is not limited. For example, as shown in FIG. 12, the number of the electrode portions 94 may be limited to one, and the negative ions generated therefrom may be divided into a plurality of ion flows 124 by the air flow 120 and the ventilation passage 156.
[Brief description of the drawings]
FIG. 1 is an explanatory view schematically showing a basic configuration of a portable ion generator according to the present invention.
FIG. 2 is a central longitudinal sectional view showing an example in which the present invention is applied to a hair dryer.
FIG. 3 shows an entire electric circuit provided in the hair dryer.
FIG. 4 is an electric circuit diagram showing an example of a discharge unit.
FIG. 5 is an enlarged cross-sectional view showing a mounting state of a discharge electrode.
FIG. 6 is a waveform diagram showing an operation state of a discharge unit.
FIG. 7 is a graph showing a change in the amount of generated ions before and after using an auxiliary electrode.
8A and 8B show an example in which the present invention is applied to a hairbrush. FIG. 8A is a plan view, FIG. 8B is a cross-sectional view taken along the line AA in FIG. The figure seen in the BB line direction in a) is shown respectively.
FIG. 9 is a side view showing an example in which the present invention is applied to a hair iron.
FIG. 10 is a view of a lower surface side of a main body case in the curling iron.
FIG. 11 is an enlarged cross-sectional view taken along a line CC in FIG. 9;
FIG. 12 is a view similar to FIG. 11, showing another embodiment.
[Explanation of symbols]
10 Case body
12 Discharging means
14 Ion generator
15 Switching means
16 Discharge electrode
18 Earth line
20 Counter electrode
22 Auxiliary electrode
24 ion emission port
26 Body case
27 Body Case Side View
28 handle
30 Blowing means
32 hair dryer
36 heater
38 Heating part
40 motor
42 fans
44 Blower
46 Discharge section
48 Changeover switch
52 1st contact of changeover switch
60 Low voltage rectifier circuit
70 Display circuit
72 pulse voltage generation circuit
74 light emitting diode
76 Step-up transformer
78 Primary coil
80 Capacitor for pulse voltage generation circuit
82 Sidak
86 Secondary coil
88 diode
90 Capacitor for high voltage rectifier circuit
92 High voltage rectifier circuit
94 Electrode section
98 Wind guide tube
100 insulating material
102 insulation
104 Isolation unit
106 High resistance
112 Negative ion
120 air flow
122 gap
124 ion flow
126 High resistance
128 High resistance
130 Hairbrush
132 brush side
134 brush hair
136 batteries
138 Curling Iron
140 Iron part
142 Lower surface of body case
144 pinching arm
146 Upper side of pinching arm
148 Hairdressing comb
150 hair
152 heating surface
154 rib
156 Ventilation path

Claims (17)

In a portable ion generating device having a discharge means (12) inside a predetermined case body (10) and capable of discharging ions generated from the discharge means (12) to the outside of the case body (10),
The discharging means (12)
A discharge electrode (16) to which a high voltage of a negative polarity is applied to generate negative ions, and a ground electrode (18) in the vicinity of the discharge electrode (16) and inside the case body (10). And the provided counter electrode (20) inside the case body (10).
The auxiliary electrode (22) is disposed so as to be exposed on the outer peripheral surface of the case body (10), and the auxiliary electrode (22) is connected to the earth line (18) inside the case body (10). Characteristic portable ion generator. The case body (10) includes a main body case (26) having an ion emission port (24), and a handle (28) extending from the main body case (26).
The ion generator according to claim 1, wherein the auxiliary electrode (22) is disposed on the handle (28). The ion generator according to claim 2, wherein the auxiliary electrode (22) provided on the handle (28) is made of conductive rubber. The case body (10) includes a main body case (26) provided on a lower surface side with a brush surface (132) on which predetermined flocking is performed, and a handle (28) extending from a side surface of the main body case (26).
The ion generator according to claim 1, wherein the ion emission port (24) and the auxiliary electrode (22) are provided on the brush surface (132). The base end of a part or all of the brush bristles (134) is fixed to the brush surface (132) with a conductive member,
The ion generator according to claim 4, wherein the conductive member is used as the auxiliary electrode (22). On the brush surface (132), one or more ion emission ports (24) are provided.
The ion generating device according to claim 4, wherein a band-shaped auxiliary electrode (22) is provided at a part or all of a peripheral position on the brush surface (132). The ion generator according to claim 6, wherein the band-shaped auxiliary electrode (22) is disposed in the axial direction in which the handle (28) extends and opposed to the opening position of the ion emission port (24). The ion generator according to claim 7, wherein the band-shaped auxiliary electrode (22) has a length substantially equal to or longer than a length of the ion discharge port (24). The ion generator according to claim 8, wherein the band-shaped auxiliary electrode (22) is disposed on both sides in the width direction with the ion emission port (24) interposed therebetween. The case body (10) includes a main body case (26) having a heating surface (152) and an ion emission port (24) disposed on a lower surface thereof, and a handle (28) extending from a side surface of the main body case (26). With
The heating surface (152) is a sandwich type comprising a pair of hot plates, and at least one of the hot plates is formed of a conductive member, and the hot plate formed of the conductive member is used as the auxiliary electrode (22). The ion generator according to claim 1, wherein The ion generator according to claim 10, wherein the ion discharge port (24) is set so as to approach the heating surface (152) and to blow the air away from the heating surface (152). An isolation rib (154) between the auxiliary electrode (22) and the ion emission port (24) for preventing ions blown from the ion emission port (24) from directly contacting the auxiliary electrode (22). 11. The ion generating device according to claim 10, further comprising: The heating surface (152) is formed in the shape of a band in the axial direction in which the handle (28) extends, and is provided with ion emission ports (24) on both sides in the width direction across the heating surface (152). The ion generator according to claim 10. The case body (10) has a structure in which at least a part of a conductive member required for its configuration is exposed to the outside,
The ion generating device according to claim 1, wherein the conductive member is used as the auxiliary electrode (22). The discharging means (12) supplies a low-voltage pulse voltage to the input side of the step-up transformer (76) by intermittently applying a DC or pulsating voltage, and outputs a high-voltage pulse voltage from the output side of the step-up transformer (76). 2. The ion generator according to claim 1, wherein a high voltage of a negative polarity is generated by extracting the high voltage and integrating the high voltage pulse voltage. The discharging means (12) is further provided with a switching means (15). In conjunction with the switching operation of the switching means (15), the driving time of the discharging means (12) and the effective time of the auxiliary electrode (22) are determined. The ion generating device according to claim 1, wherein the ion generating device can be regulated. The case body (10) is further provided with a blowing means (30), and the negative ions generated by the discharging means (12) are forcibly externally formed by the blowing means (30). The ion generating device according to claim 1, wherein the ion generating device is discharged to the device.

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