JP2004261610A - Blowing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To eliminate the problem that in a blowing device such as a hair dryer equipped with an ion generating device, ions formed at the ion generating unit are thinly scattered in an air stream in an air blowing path, or are neutralized/extinguished. <P>SOLUTION: This blowing device includes a fan 6, a motor 7 for driving the fan, the ion generating unit 15 which generates ions, a cylindrical main body case 1 for housing them, and a nozzle 33 which is fitted in the blowing out port 11 of the main body case 1. The nozzle 33 includes a nozzle main body 34, and a passage tube 29 which is arranged at the center through a rectifying vane 36. The passage tube 29 is made into a guiding passage 38 for ions generated at the ion generating unit 15. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

  The present invention relates to a blower represented by a hair dryer, and more particularly to a blower provided with a unit for generating ions.

  A hair dryer of this type is known from Japanese Utility Model Registration No. 2534856. There, an ion electrode and an ozone electrode are arranged adjacent to each other in the wind tunnel in the case body, and negative ions are generated by applying a high-voltage pulse current between the two electrodes, so that the air sent from the fan is discharged. The flow blows negative ions to the hair.

Utility Model Registration No. 2534856

  According to the above hair dryer, ions can be sprayed on the hair (object to be fed). However, not enough ions can be sprayed on the hair. In the hair dryer, the ion generating electrode is exposed to a swirling air flow sent from a fan in the case. Therefore, it is inevitable that the generated ions are diffused in the swirling air flow and the distribution density is reduced. Further, the ions diffused thinly in the air flow come into contact with the surface of the air passage between the ion generating electrode and the outlet and are neutralized and disappear.

  SUMMARY OF THE INVENTION It is an object of the present invention to provide a blower such as a hair dryer which can reduce the depletion of ions in an air flow blown from a nozzle outlet by forming an ion flow substantially in the center of an air flow blown out from a nozzle outlet. Is to provide. An object of the present invention is to provide a blowing device such as a hair dryer that can prevent ions generated in an ion generating section from disappearing in a blowing path and can more effectively blow ions to an object (hair). It is in.

  The blower of the present invention is mounted on a fan 6 and a motor 7 for driving the fan, an ion generator 15 for generating ions, a cylindrical main body case 1 for accommodating them, and an outlet 11 of the main body case 1. And a nozzle 33 having a nozzle body 34 and a rectifier at the center thereof. The ion generator 15 is held so as to be located substantially at the center of the air flow generated by the fan 6. And a passage tube 29 disposed via the wings 36, wherein the passage tube 29 is a guide passage 38 for the ions generated by the ion generator 15.

  Further, an ion passage 21 for transferring and guiding ions is provided between the ion generating section 15 and the guide passage 38.

  In the blower of the present invention, the ions generated in the ion generator 15 can be transferred and guided in the guide passage 38, so that the ions can be prevented from diffusing into the outside air flow passing through the inside of the nozzle. In addition, since the surroundings of the flow of ions can be wrapped and fed by the air flow blown out from the outlet of the nozzle 33, for example, when applied to a hair dryer, the ions can be fed to the hair with a high distribution density, The hair can be electrically neutralized effectively, and furthermore, moisture can penetrate deep inside the hair and the moisture content can be increased to optimize the condition of the hair. Further, the air flow passing through the inside of the nozzle can be rectified by the rectifying blades 36. (Claim 1)

  By providing the ion passage 21 for transferring and guiding the ions between the ion generator 15 and the guide passage 38, diffusion in the main body can be prevented well, and the ions can be sent to the hair with a higher distribution density. I can pay. (Claim 2)

  1 to 7 show an embodiment in which the present invention is applied to a hair dryer. In FIG. 2, a hair dryer (blower) has a horizontally long tubular main body case 1 and a handle 2 provided on one side of the lower surface thereof as a base, and a blower unit, control electric parts and the like are provided inside these. It is housed. A wind conductor 1 </ b> A that guides the flow of air generated by the fan 6 is mounted on the distal end side of the main body case 1. On the front and rear surfaces of the handle 2, there are provided a power switch knob 3 serving both as an air volume control and a heater switch, and an ion switch knob 4 for turning on / off the energization of the ion generator 15. A switch that is operated by the switch knobs 3 and 4 is accommodated inside the handle 2. As shown by the imaginary line, the handle 2 is foldably connected to the main body case 1.

  As shown in FIG. 2, the blower unit includes a motor case 5, a fan 6 and a motor 7 assembled to the motor case 5, a heater 9 spirally wound around an insulating frame 8 assembled in a cross shape, and the like. The fan 6 is driven to rotate in one direction, pressurizes air sucked from a suction port 10 at a rear end of the main body case 1, and blows out from an air outlet 11 of a wind conductor 1A mounted at a front end. At this time, if the heater 7 is energized, hot air is blown out. The wind conductor 1A is made of a molded product made of polycarbonate.

  The hair dryer incorporates ion generating means for generating negative ions. The ion generating means includes a circuit board 13 on which a rectifier circuit and a pulse generating circuit are mounted as shown in FIG. 2, a step-up transformer 14, an ion generating unit 15, and the like. 14 is arranged in a space formed by cutting out the insulating frame 8 for the heater 9, and the ion generating unit 15 is incorporated in the wind conductor 1A.

  In FIG. 3, a rectifying cylinder 17 and a blow-out grill 18 are incorporated inside the wind conductor 1 </ b> A, and the ion generator 15 using the rectifying cylinder 17 is provided at substantially the center of the airflow generated by the fan 6. It is held to be located. The rectifying cylinder 17 is made of a polycarbonate plastic molded article integrally formed with a cylindrical wall 19 having a circular cross section, a rectifying wing 20 radially provided at an inner front end thereof, and an ion passage 21 provided at the center of the cylindrical wall 19. Become. In FIG. 5, the blowout grill 18 is formed of a press-formed product having concentric arc ribs 18a and two long and short radial straight ribs 18b. After the blowout grill 18 is fitted inside the wind conductor 1A, the rectifying cylinder 17 is fixed inside the wind conductor 1A, whereby these three members can be handled as one unit component. The straightening vane 20 of the straightening cylinder 17 and the long straight rib 18b in the assembled state of FIG. 6 are arranged so as to overlap with each other in the front-back direction, whereby the air flow generated by the fan 6 is straightened by the straightening vane 20. The subsequent linear airflow is prevented from being disturbed by the linear rib 18b.

In FIG. 3, the ion passage 21 includes a first cylindrical portion 23 having a tapered tapered shape and a second cylindrical portion 24 continuously projecting forward from a small-diameter end in front of the first cylindrical portion 23. The ion generating section 15 is incorporated inside the cylindrical section 23. The front end of the second tubular portion 24 projects forward and outward from the opening surface of the air outlet 11 in a state where the front end is located at the center of the air outlet 11 of the wind conductor 1A. Therefore, even when the hair dryer is placed with the outlet 11 facing the floor, the second cylindrical portion 24 comes into contact with the floor and a gap is formed between the outlet 11 and the floor. Can be formed. Reference numeral 40 in FIG. 1 denotes an inlet of the ion passage 21, and 41 denotes an outlet of the ion passage 21. The cross-sectional area of the ion passage 21 in the second cylindrical portion 24 is sufficiently smaller than the cross-sectional area of the airflow in the wind conductor 1A. Therefore, even if the second cylinder portion 24 is positively charged, the charged state can be neutralized in a very short time, and thus more negative ions can be supplied. Even in the relationship between the nozzle body 34 and the passage cylinder 29 described later, negative ions can be effectively supplied for the same reason. Incidentally, in this embodiment, when the diameter of the ion passage 21 in the second cylindrical portion 24 is 9 mm, the diameter of the inner surface of the rectifying cylinder 17 is 53 mm.

  3 and 5, the ion generating unit 15 includes an electrode holder 25, a needle electrode 26 fixed to the center of the electrode holder 25, a surrounding electrode 27 surrounding the needle electrode 26, and a needle electrode 26. And an insulating cylinder 28 for partitioning a space between the electrode and the surrounding electrode 27. The electrode holder 25 is made of a plastic molded article in which a boss 30 and a radial holding arm 31 provided on the peripheral surface of the boss 30 are integrally formed. The electrode holder 25 has ozone resistance and heat resistance. Molded with an excellent plastic such as polyphenylene sulfide (PPS). The electrode holder 25 can be integrated with the rectifying cylinder 17 by fitting and holding the holding arm 31 into the concave portion 23 a (see FIG. 5) provided on the inner surface of the first cylindrical portion 23.

A needle electrode 26 is fixed to the center of the axis of the boss 30, and a peripheral electrode 27 is concentrically mounted on the peripheral surface of the boss 30. In this mounted state, the front ends of the two electrodes 26 and 27 are coplanar. Located in. The insulating cylinder 28 is formed in a cylindrical shape from a material having a high degree of insulating properties, such as mica, glass, and ceramics. In a state in which the insulating tube 28 is fitted and fixed in the recess at the front end of the boss portion 30, the front end of the insulating tube 28 is provided so as to protrude forward more than the front ends of the needle-like electrode 26 and the peripheral electrode 27. It faces the front end of the cylindrical portion 23. When the insulating cylinder 28 protrudes largely forward, sparks are prevented from being generated between the needle electrode 26 and the surrounding electrode 27, and negative ions can be generated effectively. As shown in FIG. 3, the needle electrode 26 and the surrounding electrode 27 are connected to the transformer 14 by lead wires, respectively. In order to prevent a spark from occurring between the soldered portions of the lead wires, the needle electrode 26 and the peripheral electrode 27 are connected. 26 and the lead wire are sealed with an insulating adhesive 32 filled in a concave portion on the rear side of the boss portion 30.

  FIG. 8 schematically shows an electric circuit for generating negative ions. There, a current from a commercial power supply (100 V) is half-wave rectified by a rectifier circuit, and then converted into a pulse current by a pulse generation circuit. Next, the pulse current is stepped up by the transformer 14, and a high voltage stepped up to, for example, 4 Kv is applied to the needle electrode 26, and electrons are emitted from the needle electrode 26 to the surrounding electrode 27. As a result, oxygen, minute water droplets, dust and the like in the air are negatively charged and negatively ionized. Although the diode in FIG. 8 is provided to obtain only a negative output on the needle electrode 26, it can be omitted. In that case, positive ions and negative ions are generated alternately.

  In the hair dryer, as shown in FIG. 1, a nozzle 33 may be added to the front end side of the wind conductor 1A, that is, the outlet 11 as necessary. The nozzle 33 is composed of a nozzle body 34 having a tapered cylindrical shape (which may be widened) and an inner cylinder 35 mounted on the inner surface of the nozzle body 34, and is detachably attached to the outlet 11 on the body case 1 side. It is attached to. A leaf-shaped straightening vane 36 is provided inside the inner cylinder 35, and a front-rear holding boss 37 is integrally provided at the center thereof. The passage cylinder 29 is loaded into the hollow inside of the holding boss 37. A guide passage 38 that runs in the front-rear direction is provided. The cross-sectional area of the guide passage 38 is sufficiently smaller than the cross-sectional area of the airflow passage in the nozzle body 34. Therefore, as described in the ion passage 21, even if the passage tube 29 is positively charged, the charged state can be neutralized in a very short time, and thus more negative ions can be supplied. .

  As shown in FIG. 1, when the nozzle 33 is attached to the air outlet 11 of the wind conductor 1 </ b> A, the rear end opening surface of the guide passage 38 is provided adjacent to the outlet 41 of the ion passage 21. The negative ions coming out of the nozzle 33 are transferred and guided to the opening surface of the outlet 39 at the front end of the nozzle 33. The nozzle body 34, the inner cylinder 35, and the passage cylinder 29 are each made of a molded product made of polycarbonate. In addition, when each of the nozzle body 34 and the inner cylinder 35 is formed of a transparent or translucent plastic material, and a decorative sheet 46 rich in gloss is loaded between the passage cylinder 29 and the transparent holding boss 37, Since the decorative sheet 46 can be seen through the holding boss 37, the design effect of the nozzle 33 can be improved.

According to the hair dryer configured as described above, the negative ions generated in the ion generator 15 can be supplied to the outlet 11 in a state where the negative ions are sealed in the ion passage 21, so that the negative ions are blown to the ion generator 15. It can be prevented from being diffused into the main airflow passing through the wind guide portion between the outlet 11 and the distribution density thereof, and the negative ions can be prevented from being installed in the case such as the case and the blowout grill 18 where the negative ions are incorporated in the wind guide portion. Electrical neutralization by contact with the surface can also be reliably prevented. Furthermore, since the outlet 41 of the ion passage 21 is located at the center of the outlet 11 and protrudes forward from the opening surface of the outlet 11, the negative ions emitted from the outlet 41 of the ion passage 21 Wrapped in the center of the airflow blown out from the hair and can reach the hair. A rectifying vane 20 is provided immediately before the air outlet 11 to prevent the main air flow blown out from the air outlet 11 from turning, so that the negative ions from the ion passage 21 are diffused into the main air flow. And the amount of negative ions reaching the hair is improved. The negative ions allow moisture to penetrate deep into the hair, increase the moisture content, and optimize the condition of the hair.

  When the nozzle 33 is connected to the outlet 11 of the wind conductor 1 </ b> A, the negative ions coming out of the outlet 41 of the ion passage 21 are transferred to the outlet 39 of the nozzle 33 through the guide passage 38 in the nozzle 33. Since it is possible to prevent the negative ions from diffusing into the main air flow passing through the inside of the nozzle, it is possible to wrap the periphery of the flow of the negative ions with the air flow blown out from the outlet 39 and to feed the negative ions. The ions can be effectively delivered to the hair with a high distribution density. In the hair dryer of this embodiment, the negative ions were supplied, but the ozone generated at the same time as the generation of ions was also supplied. it can. However, ozone is sent for the purpose of deodorization. The first cylindrical portion 23, the second cylindrical portion 24, and the passage tube 29 for feeding the negative ions are formed by using a material whose charging column is lower (negative) than other passage constituting members. Is preferred. When the material is selected in consideration of the charging sequence as described above, at the time of use, the passage constituting member is negatively charged due to contact friction at the joint portion between the previous cylindrical members 23, 24, and 39 and other passage constituting members. Therefore, it is possible to prevent the negative ions flowing along the passage constituting member from being adsorbed on the passage wall, and to reduce the consumption of the negative ions in the middle of the feeding path.

  9 to 13 show another embodiment of the present invention. In each of the other embodiments, only the points that are significantly different from the previous embodiment will be described, and the same members as those in the previous embodiment will be denoted by the same reference numerals and description thereof will be omitted. The hair dryer of FIG. 9 differs from the previous embodiment in that the ion passage 21 is formed in a straight tube running in the front-rear direction, and that the nozzle 33 is externally fitted to the wind conductor 1A. The ion generator 15 is incorporated inside the ion passage 21 as in the previous embodiment.

In FIG. 10, the ion passage 21 is divided and arranged so as to be deviated to one inner surface of the cylindrical wall 19 of the wind conductor 1A so that the flow rate of the air flowing into the ion passage 21 is increased. A passage 43 corresponding to the guide passage 38 of the previous embodiment is provided integrally with the cylindrical wall 19, following the ion passage 21. In this case, since the flow of air containing negative ions is formed around the main airflow, there is some depletion of negative ions while reaching the hair. However, since the flow of the air containing the negative ions has strong momentum, the negative ions can be blown to the hair near the scalp. The ion passage 21 may be formed integrally with the passage 43 if necessary.

  In FIG. 11, the inlet 40 of the ion passage 21 is arranged so as to be deviated to one inner surface of the cylindrical wall 19 of the wind conductor 1A similarly to the ion passage 21 of FIG. 10, but the ion passage 21 is bent, The outlet 41 is located at the center of the outlet 11.

  In FIG. 12, a hook-shaped ion passage 21 is arranged from the upper portion of the outer surface of the main body case 1 to the outlet 11, and the ion generator 15 is provided near the inlet 40. The ion generating section 15 includes a ring-shaped peripheral electrode 27 fixed to the inner surface of the ion passage 21, and a needle-like electrode 26 disposed on the central axis of the peripheral electrode 27 so as to be spaced apart from the opening surface of the peripheral electrode 27. To effectively generate the ion wind. In this embodiment, instead of using the air flow generated by the fan 6 to transfer the negative ions, the negative ions are sent to the outlet 41 only by the sending action of the ion wind generated by the corona discharge. . The outlet 41 of the ion passage 21 is arranged at the center of the outlet 11 of the main body case 1 as in the embodiment shown in FIG.

FIG. 13 shows an embodiment in which the present invention is applied to a hair blower (blower). Here, a fan 6, a motor 7, a heater 9, and the like are housed inside a main body case 1 having a straight cylindrical shape. A suction port 10 is provided at the rear end on the right side of the main body case 1, and a brush body 45 selectively used as an attachment is detachably mounted on the air outlet 11 on the left front end. The brush body 45 has the wind conductor 1A assembled inside the connection port with the main body case 1, and the ion passage 21 and the ion generating section 15 provided inside the wind conductor 1A. A guide passage 38 that is continuous with the ion passage 21 is provided in an air guide portion inside the brush body 45, and an outlet 46 thereof faces the center of an air outlet 47 of the brush body 45 including a group of small holes. A power switch 3 and an ion switch 4 are provided on the upper surface of the main body case 1. The concept of the nozzle 33 in the present invention includes an attachment for a hair crosser as in this embodiment.

In addition to the above, the ion generator 15 and the ion passage 21 can be provided inside a nozzle 33 that is detachably attached to the air outlet 11, and when the main body case 1 has a left-right split structure, the main body The ion generator 15 and the ion passage 21 can be directly assembled inside the case 1. The ion passage 21 can be formed of an elastically deformable tube. The negative ions may be sent by a dedicated blower fan provided in the ion generator 15. The ion generating unit 15 has a surface discharge type structure in which a discharge electrode and an induction electrode are arranged on the front and back of a plate-like insulator (dielectric) made of mica, ceramic, or the like, or two needle-like electrodes are opposed to each other. The electrode structure can be changed to an arranged electrode structure, and the structure is not limited as long as ions can be generated. The blower of the present invention includes devices such as a hand dryer and a foot dryer. In addition, a blower or a fan without a heater is included in the blower of the present invention.

  The wind conductor 1A can be formed integrally with the main body case 1. In this case, after the rectifying cylinder 17 and the ion generator 15 are assembled into the main body case 1 from the side of the suction port 10, the insulating frame 8, the heater 9, the circuit board 13, and the transformer 14 are attached to the main body case 1. Good to cross. When the nozzle 33 is used in combination, a nozzle body 34 having a peripheral surface provided with an opening for taking in outside air may be used. In that case, the outside air is introduced into the nozzle 33 from the opening by the ejector action by the air flow generated by the fan 6, and the hot air passing through the nozzle 33 is mixed with the outside air containing moisture to be supplied. As a result, hair damage can be reduced as compared to a case where only hot air is blown. Note that, in the embodiment, the case where negative ions are supplied has been described.However, the supply target may be positive ions. Can be sent effectively. When generating positive ions, the diodes in FIG. 8 are connected in a state where they are inverted left and right.

It is a vertical side view of the principal part of an ion generator. It is the whole longitudinal side view. It is a vertical side view which shows an ion generation part and an ion channel. It is an exploded perspective view of a wind conductor and a nozzle. FIG. 4 is an exploded perspective view illustrating a relational structure between a rectifying cylinder and an ion generation unit. FIG. 4 is a sectional view taken along line AA in FIG. 3. It is a front view of a nozzle. FIG. 2 is an explanatory view schematically showing an ion generation circuit. It is a vertical side view which shows 1st another Example of an ion generation part. It is a vertical side view which shows 2nd another Example of an ion generation part. It is a vertical side view which shows 3rd another Example of an ion generation part. It is a vertical side view which shows 4th another Example of an ion generation part. It is the longitudinal side view and side view which show another Example which applied this invention to the hair blower.

Explanation of reference numerals

DESCRIPTION OF SYMBOLS 1 Main body case 1A Wind conductor 6 Fan 7 Motor 9 Heater 11 Outlet 15 Ion generation part 20 Rectifier blade 21 Ion passage 25 Electrode holder 26 Needle electrode 27 Surrounding electrode 28 Insulating cylinder 33 Nozzle 38 Guide passage 39 Outlet 40 Inlet 41 Outlet

Claims (2)

A blower including a fan 6 and a motor 7 for driving the fan, an ion generator 15 for generating ions, a cylindrical main body case 1 for accommodating them, and a nozzle 33 attached to the outlet 11 of the main body case 1 A device,
The ion generator 15 is held so as to be located substantially at the center of the airflow generated by the fan 6,
The nozzle 33 includes a nozzle main body 34 and a passage cylinder 29 disposed at the center of the nozzle main body 34 via a straightening vane 36.
A blower, wherein the passage tube (29) is a guide passage (38) for ions generated by the ion generator (15).   The air blower according to claim 1, wherein an ion passage (21) for transferring and guiding the ions is provided between the ON generating part (15) and the guide passage (38).

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