JP4509440B2 - Blower - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a blower represented by a hair dryer, and more particularly to a blower provided with means for generating ions.
[0002]
[Prior art]
This type of hair dryer is known from Utility Model Registration No. 2533456. There, an ion electrode and an ozone electrode are arranged adjacent to the air guide part in the case body, and negative ions are generated by applying a high-voltage pulse current between the two electrodes, and sent out from the fan. It is designed to blow negative ions onto the hair with an air flow. The previous ion electrode and the ozone electrode are accommodated in individual glass tubes arranged adjacent to each other, and a corona discharge is generated between the ion output needle connected to the ion electrode and the ozone electrode, and oxygen in the air and Negative ions are generated by ionizing a small mass of water. When negative ions are sprayed on the hair, hair that is often positively charged can be electrically neutralized, and further, the moisture content can be penetrated deep inside the hair to increase the moisture content and optimize the condition of the hair. Has been.
[0003]
[Problems to be solved by the invention]
According to said hair dryer, a negative ion can be sprayed on hair (delivery object). However, a sufficient amount of negative ions cannot be sprayed onto the hair. In the hair dryer, the ion generation electrode is disposed near the center of the air guide and is exposed to a swirling air stream sent from a fan. Therefore, it is inevitable that the generated negative ions diffuse into the swirling air flow and the distribution density decreases. Further, the negative ions diffused thinly in the air flow contact with the air passage between the ion generating electrode and the outlet and the surface of the part incorporated in the passage and are neutralized and disappear. In addition, a part of the air flow blown out from the air outlet of the main body case does not reach the hair and diffuses to the periphery, and the negative ions contained in the air flow whose direction has been changed by the human head (target to be fed) are hair It will diffuse into the air without being able to come into contact with it.
[0004]
In particular, in the case of a hair blosser that is used by connecting a brush unit to the air outlet of the case body, the number of negative ions that disappear while being discharged from the air outlet through the brush unit from the air guide is large. It has been confirmed that the degree of depletion reaches about half of the number generated by the ion generation electrode. As described above, in the conventional example including the ion generation electrode, there is a large gap between the number of negative ions generated by the ion generation electrode and the number of negative ions that can actually reach the hair. There was room for improvement in that the loss of ions was high and negative ions could not be effectively delivered to the hair.
[0005]
An object of the present invention is that ions generated in the ion generation unit disappear in the course of the air flow generated by the fan or are wasted without being brought into contact with the object to be supplied such as hair. It is to provide a blower such as a hair dryer that can eliminate ions and spray ions more effectively on the object to be fed. The object of the present invention is to prevent ions from being diffused thinly into the swirling air flow sent out from the fan, and to further reduce ion depletion in the air flow blown out from the air outlet of the main body case. An object of the present invention is to provide an air blower such as a hair dryer that can effectively feed the object to be fed with a high distribution density. The purpose of the present invention is to form a flow of ions almost at the center of the air flow blown from the air outlet of the main body case, thereby significantly reducing ion depletion in the air flow after being blown from the air outlet. Such as a hair dryer that can make ions reach more far, so that ions can be effectively brought into contact with the object to be infiltrated even when the direction of the air flow changes depending on the object to be delivered. The object is to provide a blower.
[0006]
[Means for Solving the Problems]
As shown in FIG. 2, the blower of the present invention includes a cylindrical main body case 1 that houses a fan 7 and a motor 6 for driving the fan, an ion generator 16 that generates ions and ozone, and an ion generator 16. And an ion passage 28 for transferring and guiding the generated ions. On one side of the main body case 1, there are provided an air outlet 11 for the air flow generated by the fan 7 and a ventilated outlet grill 21 that covers the outlet 11. The outlet 31 of the ion passage 28 protrudes from the outer surface of the blowout grill 21.
[0007]
The outlet 31 of the ion passage 28 can be disposed at the approximate center of the blowing grill 21.
[0008]
Specifically, a heater 9 that heats the air flow generated by the fan 7 is disposed along the inner surface of the cylindrical wall of the main body case 1, and is generated by the fan 7 at the windward end of the ion passage 28. Among the airflows, an inlet 30 for receiving an airflow near the center of the main body case 1 is opened, and ions generated by the ion generator 16 disposed in the middle of the ion passage 28 are flown through the ion passage 28. To be sent by.
[0009]
The cylindrical peripheral surface of the air guide tube 23 forming the ion passage 28 is supported by a support hole 29 provided in the metal blowing grill 21.
[0010]
On the outer peripheral surface of the air guide tube 23, there are provided rectifying blades 22 for rectifying the air flow generated by the fan 6 into a linear air flow.
[0011]
The ion generator 16 includes an electrode holder 33, a center electrode 34 fixed to the center of the electrode holder 33, a counter electrode 35 surrounding the center electrode 34, and a space between the center electrode 34 and the counter electrode 35. And a cylindrical dielectric 36 that separates.
[0012]
The air guide tube 23 includes a tapered first tapered tube portion 26 and a second tube portion 27 that protrudes forward in succession to the small diameter front portion of the first tube portion 26. The cylindrical end of the dielectric 36 faces the middle of the first cylindrical portion 26, and an orifice portion R is formed between the dielectric 36 and the first cylindrical portion 26.
[0013]
A wind guide tube 23 is integrally provided at the center of the inner frame 20 that is mounted and fixed on the inner surface of the main body case 1, and a blow-out grill 21 that faces the blow-out port 11 is provided on the inner surface of the main body case 1. It is sandwiched between the step portion 24 and the inner frame 20.
[0014]
The main body case 1 is constituted by a main case portion 1A and an outlet tube 1B connected to the main case portion 1A, and an air guide tube 23 and an ion generator 16 are disposed inside the outlet tube 1B.
[0015]
As shown in FIGS. 8 and 9, a nozzle 50 that flows and guides the air flow generated by the fan 6 is connected to the air outlet 11 on the main body case 1 side, and the outlet of the ion passage 28 is connected to the inside of the nozzle 50. A guide passage 55 is provided for guiding the ions emitted from 31 to the opening surface of the outlet 56 of the nozzle 50.
[0016]
[Effects of the invention]
The blower of the present invention includes an ion generator 16 and an ion passage 28 that guides and transfers ions generated by the ion generator 16, and causes an outlet 31 of the ion passage 28 to protrude from the outer surface of the blowing grill 21. Thus, the ions generated by the ion generator 16 can be transferred and guided in a state of being isolated to the outside of the blowout grill 21 by the ion passage 28, so that the air through which the ions pass between the ion generator 16 and the blowout port 11 is provided. It is possible to prevent diffusion into the flow and decrease in distribution density, and it is possible to reliably prevent ions from coming into contact with the surface of the component incorporated in the air guide portion and being electrically neutralized. For example, when applied to a hair dryer, ions can be delivered to the hair with a high distribution density, so that the hair can be effectively electrically neutralized, and water can penetrate deeply into the hair and its moisture content. To improve the hair condition.
[0017]
If the outlet 31 of the ion passage 28 is arranged at the substantially center of the blowout grill 21, it is possible to feed around the flow of ions emitted from the ion passage 28 with the main airflow blown out from the blowout outlet 11. It is possible to reduce the depletion of ions after being blown out from the blower outlet 11 and to effectively supply the ions to the delivery target in a state where the distribution density is high. In addition, since the flow of ions is located approximately in the center of the main air flow, for example, even when the direction of the air flow is changed depending on the delivery target, the ions are effectively brought into contact with the delivery target and penetrated. Can be made.
[0018]
According to the air blower in which the heater 9 is arranged along the inner surface of the cylindrical wall of the main body case 1 and the inlet 30 for receiving the air flow near the center of the main body case 1 is opened at the windward end of the ion passage 28. Since the ions in the ion passage 28 can be fed by an air flow at a relatively low temperature, the outlet 31 of the ion passage 28 protruding from the blowout grill 21 is in contact with the ground surface or located in the vicinity of the ground surface. Even when the blower is used in a state, the blower can be used safely by preventing the background and hair from being exposed to high temperatures.
[0019]
If the cylindrical circumferential surface of the air guide tube 23 forming the ion passage 28 is supported by the support hole 29 provided in the blow-out grill 21, the wind guide tube 23 can be firmly fixed and supported by the metal blow-out grill 21. It is possible to prevent the position of the air guide tube 23 from being shifted when another object comes into contact with the air guide tube 23 protruding from the outer surface or a drop impact is applied.
[0020]
By rectifying the swirling air flow generated by the fan 6 with the rectifying blade 22 provided on the outer peripheral surface of the air guide tube 23, the flow of the air sent out from the air outlet 11 can be straightened, so that the ion passage The flow of ions sent out from the air outlet 28 and the air flow sent out from the air outlet 11 can be well prevented from mixing with each other, and therefore, the ions can be prevented from diffusing into the main air flow blown out from the air outlet 11. Ions can be reliably delivered to the outside of the air outlet 11.
[0021]
According to the ion generator 16 composed of the electrode holder 33 and the central electrode 34, the counter electrode 35, and the dielectric 36 fixed to the electrode holder 33, spark discharge occurs between the electrodes 26 and 27. Since ions can be generated effectively while reliably preventing the ions, the total amount of ions reaching the object to be supplied can be increased by effectively supplying ions with a higher distribution density to the object to be supplied.
[0022]
The first cylindrical portion 26 having a tapered shape and the second cylindrical portion 27 continuous with the first cylindrical portion 26 constitute an air guide tube 23, and the cylindrical end of the dielectric 36 faces the middle portion of the first cylindrical portion 26. Thus, according to the blower device in which the orifice portion R is formed between the dielectric 36 and the first cylindrical portion 26, the flow velocity of the air flow passing through the orifice portion R is increased from other parts, and the generated ions are The air flow is high but the pressure is low, so it can be quickly fed downstream. In particular, since the ions floating near the tip of the dielectric cylinder 28 and heading toward the counter electrode 31 are pushed back at a high flow velocity, they can be reliably prevented from being absorbed and neutralized and eliminated by the counter electrode 31. It is possible to effectively deliver ozone while maintaining a high distribution density. Since the second cylindrical portion 27 protruding forward is provided continuously with the tapered first tapered cylindrical portion 26, ions flow forward with an air flow having a high flow velocity after passing through the orifice portion R. The guidance distance can be increased, and the reach of the airflow can be further increased accordingly.
[0023]
When the blowing grill 21 is sandwiched and fixed between the step 24 (see FIG. 1) on the inner surface of the main body case 1 and the inner frame 20, the step 24 and the inner frame 20 are placed under the state where the blowing grill 21 is fitted in the main body case 1. Can be firmly fixed and held. Therefore, it is possible to prevent the position of the blow grill 21 from being displaced or being pushed into the case when other objects come into contact with the blow grill 21. According to the air blower in which the air guide tube 23 is integrally provided in the center of the inner frame 20, the main body case 1 and the air guide tube 23 can be properly positioned, and the manufacturing cost of the air blower can be reduced by the amount that can reduce the number of parts. Can be reduced.
[0024]
According to the air blower in which the main case 1 is constituted by the main case 1A and the outlet cylinder 1B connected to the main case 1A, and the air guide cylinder 23 and the ion generator 16 are assembled inside the outlet cylinder 1B. For example, the ion generator 16, the air guide tube 23, and the exit tube 1B can be unitized. In such a unitized state, the ion generator 16 is housed in the air guide tube 23 and the outlet tube 1B and is isolated from the surroundings. Therefore, the ion generator 16 is performed before the outlet tube 1B is assembled to the main case portion 1A. The ion generation test of the generator 16 can be performed safely. However, the situation is different when the ion generator 16 is assembled to the air guide tube 23 later. Moreover, the assembly of the ion generator 16 and the ion passage 28 with respect to the main body case 1 can be performed simply by assembling the outlet tube 1B to the main body case 1.
[0025]
When the nozzle 50 is connected to the air outlet 11 on the main body case 1 side and used, the ions that have exited from the outlet 31 of the ion passage 28 are transferred inside the nozzle 50 to the opening surface of the air outlet 56 of the nozzle 50. By providing the guide passage 55, the ions can be prevented from diffusing into the air flow passing through the inside of the nozzle. Therefore, even when the nozzle 50 is used in combination, the ions are distributed in the distribution density. Can be effectively fed in a high state. In particular, when the outlet of the guide passage 55 is arranged at the substantially center of the outlet 56 of the nozzle 50, the flow of ions exiting the guide passage 55 is surrounded by the main air stream blown from the outlet 56. Since it can be fed in a state, the depletion of ions after being blown out from the blowout port 56 is reduced, and ions can be effectively fed to the feeding object in a state where the distribution density is high.
[0026]
【Example】
1 to 9 show an embodiment in which the present invention is applied to a hair dryer. In FIG. 2, the hair dryer (blower) includes a horizontally long cylindrical main body case 1 and a handle 2 provided on one side of the lower surface thereof. The main body case 1 is composed of a plastic main case portion 1A occupying most of the main body case 1 and a plastic outlet tube 1B attached to the front side end of the main case portion 1A. It contains parts and so on. On the front and rear surfaces of the handle 2, there are provided a power switch knob 3 that functions both as an air flow control and a heater switch, and an ion switch knob 4 that turns on / off energization of an ion generator 16, which will be described later. The handle 2 accommodates a switch that is switched by the previous switch knobs 3 and 4. As indicated by an imaginary line, the handle 2 is foldably connected to the main body case 1.
[0027]
As shown in FIG. 2, the air blower unit is spirally wound around a motor case 5, a motor 6 and a fan 7 assembled to the motor case 5, and a mica-made insulating frame 8 assembled in a cross-shaped manner. The heater 9 is disposed along the inner surface of 1A. The air taken in from the inlet 10 at the rear end of the main body case 1 is pressurized and fed forward by the fan 7 and blown out from the outlet 11 of the outlet cylinder 1B attached to the front end of the case. At this time, if the heater 9 is energized, the flow of the peripheral portion that flows along the inner surface of the main case portion 1A in the air flow is heated and the hot air blows out. The outlet tube 1B is a molded product made of polycarbonate.
[0028]
Inside the main body case 1, ion generating means for generating negative ions is incorporated. In FIG. 3, the ion generating means includes a rectifier circuit 13 for half-wave rectifying a current from a commercial power supply (100 V), a pulse generating circuit 14 for converting the rectified current into a pulse current, and a pulse current as high as 4 kV, for example. A transformer 15 that boosts the voltage, an ion generator 16, a diode 17 provided between the transformer 15 and the ion generator 16, and the like. The rectifier circuit 13 and the pulse generation circuit 14 are mounted on a circuit board 18, and the circuit board 18 and the step-up transformer 15 are arranged in a space formed by cutting out the insulating frame 8 for the heater 9. These electrical components are assembled into the main body case 1 together with the motor 6 and the fan 7 from the suction port 10 side. At this time, the ion generator 16 is also incorporated at the same time. According to the above ion generating means, the current from the commercial power supply (100 V) is half-wave rectified by the rectifier circuit 13 and then converted into a pulse current by the pulse generator circuit 14. Next, the pulse current is boosted by the transformer 15, and a high voltage boosted to, for example, 4 kV is applied to the central electrode 34, and electrons are emitted from the electrode 34 toward the counter electrode 35. As a result, oxygen, minute water droplets, dust and the like in the air are negatively charged and negatively ionized.
[0029]
In FIG. 1, a flow straightening tube (inner frame) 20 and a blow grill 21 are incorporated in the outlet tube 1 </ b> B, and the ion generator 16 is supported by the flow straightening tube 20, and the air flow generated by the fan 7. The ion generator 16 is located in the approximate center. The rectifying cylinder 20 is formed in a circular cross section, and is formed of a polycarbonate plastic molded product in which a rectifying blade 22 provided radially at the front end of the rectifying cylinder 20 and an air guide cylinder 23 provided in the center of the cylinder wall are integrally formed. After the blowing grill 21 is fitted into the stepped portion 24 provided on the inner surface of the outlet cylinder 1B, the rectifying cylinder 20 is fitted and fixed to the outlet cylinder 1B, thereby fixing the blowing grill 21 so as to be non-movable. It can be handled as a single unit component. In this embodiment, the rectifying cylinder 20 and the outlet cylinder 1B are internally fitted and fixed around the entire circumference. However, the present invention is not necessarily limited thereto, and dents are formed in several places on the outlet cylinder 1B, and the rectifying cylinder 20 is fitted into the recess. The rectifying cylinder 20 may be fixed via an integrally formed claw, or the rectifying cylinder 20 and the outlet cylinder 1B may be ultrasonically welded. The blow-out grill 21 is provided in order to restrict contact with the heater 9 and the motor 6 as before, but also serves to prevent contact with the ion generation circuit. The rectifying blade 22 rectifies the swirling air flow generated by the fan 6 into a linear air flow.
[0030]
In FIG. 4, the air guide tube 23 is formed by a tapered first tapered tube portion 26 and a second tube portion 27 that protrudes forward continuously from the small diameter front portion of the first tube portion 26. The ion generator 16 is incorporated in the ion passage 28 partitioned by the first cylindrical portion 26. The negative ions generated by the ion generator 16 are fed by the air flow passing through the ion passage 28, but in order to prevent the air flow containing negative ions from being diffused by the air flow blown out from the blowing grill 21. The front end of the second cylindrical portion 27 protrudes outward from the outer surface of the blowout grill 21. Specifically, the rear end surface of the second cylindrical portion 27 on the outlet side of the air guide tube 23 is supported by a support hole 29 provided in the center of the blow grill 21, and most of the second cylindrical portion 27 is supported. Protrudes from the front of the blowout grill 21. Further, the front end of the second cylindrical portion 27 protrudes further forward than the opening surface of the outlet 11. Reference numeral 30 denotes an inlet of the wind guide tube 23, and 31 denotes an outlet of the wind guide tube 23.
[0031]
4 to 6, the ion generator 16 includes an electrode holder 33, a central electrode 34 fixed to one side center portion of the electrode holder 33, a counter electrode 35 surrounding the central electrode 34, a central electrode 34, and the like. It consists of a dielectric 36 that insulates and blocks the space between the counter electrode 35. The electrode holder 33 is made of a plastic molded product in which a multi-stage shaft-like boss portion 37 and a radial holding arm 38 provided on the peripheral surface of the boss portion 37 are integrally formed, and has ozone resistance and heat resistance. Moreover, it is molded from a plastic having excellent insulating properties, such as polyphenylene sulfide. A cylindrical wall 39 that supports the counter electrode 35 is formed on one side of the boss portion 33, and a relief recess 40 is formed on the other side. The electrode holder 33 can be positioned and fixed to the air guide tube 23 by fitting and fixing the holding arm 38 into the recess 41 provided on the inner surface of the first tube portion 26. Specifically, as described above, the holding arm 38 of the electrode holder 33 assembled in the main body case 1 together with the electrical components constituting the ion generating means is fitted and fixed to the recess 41. Thereafter, the outlet cylinder 1B in which the rectifying cylinder 20 and the blowout grill 21 are unitized is attached to the main case portion 1A, and the joining surfaces of both are ultrasonically welded. In a state in which the outlet cylinder 1B is mounted on the main case 1A, the claw portion provided at the rear end of the rectifying cylinder 20 is engaged with the main case 1A. This is useful for firmly fixing the cylinder 20 to the outlet cylinder 1B. The ion generator 16 (electrode holder 33) is not connected to other electrical components and incorporated from the suction port 10 side of the main case portion 1A, but is assembled into the air guide tube 23 in advance and united into four units. A lead wire may be connected to the other electrical component side incorporated in the case portion 1A, and then the unit may be welded and fixed to the main case portion 1A.
[0032]
The central electrode 34 is composed of a discharge needle 43 made of tungsten having a low discharge resistance and a positioning boss 44 fixed to the rear end of the discharge needle 43. The front end of the discharge needle 43 is sharpened to form a discharge portion 45. . The discharge needle 43 is positioned on the central axis of the electrode holder 33 by fitting the previous positioning boss 44 into the mounting hole at the center of the electrode holder 33 and fixing it. As shown in FIG. 5, the counter electrode 35 is formed of a pressed metal fitting made of a copper or iron thin plate, and has a ring-shaped electrode portion 46 with one peripheral surface divided, and a rear edge of the electrode portion 46. And four mounting legs 47 extending rearward from each other. The electrode portion 46 is externally fitted to the cylindrical wall 39 having a circular cross section of the electrode holder 33, and its mounting leg 47 is bent and fixed to the peripheral step, thereby positioning the electrode portion 43 concentrically with respect to the central electrode 34. Can be fixed. In this attached state, the front ends of the electrodes 34 and 35 are located on the same plane including the opening surface of the cylindrical wall 39 and orthogonal to the central axis of the central electrode 34 (see FIG. 4).
[0033]
The dielectric 36 is formed in a cylindrical shape with a material having high insulating properties such as mica, glass, ceramics, and one end thereof is fitted and fixed to the inner surface of the cylindrical wall 39 to be integrated with the electrode holder 33. In this fixed state, the counter electrode 35 and the dielectric 36 are arranged concentrically with the center electrode 34 as the center. The front cylindrical end of the dielectric 36 faces the portion near the front end of the first cylindrical portion 26 to form an orifice portion R between the dielectric 36 and the first cylindrical portion 26. In order to prevent irregular discharge between the central electrode 34 and the counter electrode 35 and to effectively generate negative ions, the dielectric 36 protrudes greatly forward from the discharge portion 45 of the central electrode 34. As shown in FIG. 1, when the center electrode 34, the counter electrode 35, and the transformer 15 are connected by the lead wire 48, the center electrode 34, the counter electrode 35, and the transformer 15 are arranged in order to prevent a spark from occurring between the portions where the lead wire 48 is soldered. The electrode 34 and the lead wire 48 are accommodated in a relief recess 40 on the rear side of the boss portion 37 and sealed with an insulating sealing material 49 filled in the recess 40. As the sealing material, an insulating adhesive such as silicon can be used.
[0034]
The cross-sectional area of the ion passage 28 in the second cylindrical portion 27 is sufficiently smaller than the cross-sectional area of the air flow passage in the outlet cylinder 1B. Therefore, even if the second cylindrical portion 27 is positively charged, the charged state can be neutralized in a very short time, and therefore more negative ions can be fed. Incidentally, in this embodiment, when the diameter dimension of the ion passage 28 in the second cylinder portion 27 is 9 mm, the diameter dimension of the inner surface of the rectifying cylinder 22 is 53 mm.
[0035]
In the hair dryer, as shown in FIG. 8, the front end side of the outlet tube 1B, that is, the constricted nozzle (which may be widened) is added to the outlet 11 and used as necessary. There is. An inner cylinder 51 made of plastic is fixed to the inner surface of the nozzle 50, and this inner cylinder 51 is detachably attached to the outlet 11 of the outlet cylinder 1B. Inside the inner cylinder 51, a leaf-shaped rectifying wing 52 is provided, and a holding boss 53 facing forward and backward is provided at the center of the rectifying blade 52 as a single unit. A guide passage 55 that is long in the front-rear direction is provided inside the holding boss 53 by loading a separately formed passage cylinder 54 from the front side. The front end of the guide passage 55 slightly protrudes forward from the opening surface of the nozzle 50. The cross-sectional area of the guide passage 55 is sufficiently smaller than the cross-sectional area of the air flow on the inner surface of the nozzle 50. Therefore, as described in the ion passage 28, even if the passage cylinder 54 is positively charged, the charged state can be neutralized in a very short time, and thus more negative ions can be fed. . Of course, there is no problem because the negative ions are not neutralized if the passage cylinder 54 is negatively charged.
[0036]
As shown in FIG. 8, the rear end opening surface of the guide passage 55 is adjacent to the outlet 31 of the ion passage 28 in a state where the nozzle 50 is mounted on the outlet 11 of the outlet cylinder 1 </ b> B. Accordingly, the negative ions that have exited from the ion passage 28 are guided to the guide passage 55 and fed to the outside of the air outlet 56 at the front end of the nozzle. The nozzle 50, its inner cylinder 51, and the passage cylinder 54 are each made of a molded product made of polycarbonate. The rear end of the guide passage 55 may be formed so as to be rearwardly widened so as to cover the front end of the ion passage 28. In that case, if a slight gap is formed between the rear end of the guide passage 55 and the front end of the ion passage 28, they can be reliably prevented from interfering with each other when the nozzle 50 is attached and detached, and damage can be prevented.
[0037]
According to the hair dryer configured as described above, the negative ions generated by the ion generator 16 can be supplied to the outlet 11 in a state of being sealed in the ion passage 28, so that the negative ions are blown from the ion generator 16. Parts such as a case where the negative ions are incorporated in the air guide portion and the blow grill 21 can be prevented from diffusing into the main air flow passing through the air guide portion between the outlet 11 and the distribution density. It is possible to reliably prevent electrical neutralization in contact with the surface of the substrate. Further, since the air guide tube 23 protruding from the outer surface of the blow-out grill 21 comes into contact with the ground or the like before other parts, it is advantageous in that the ground or the like can be prevented from coming into contact with the high-temperature blow-out grill 21. is there. The air guide tube 23 also serves as a protector for the dielectric 36. Further, the outlet 31 of the ion passage 28 is located at the center of the outlet 11 and protrudes from the outlet grill 21 and faces the opening surface of the outlet 11 or protrudes forward from the opening surface. The negative ions released from the outlet 31 can reach the hair by being wrapped in the center of the air flow blown out from the outlet 11. Since the rectifying blade 22 is provided immediately before the air outlet 11, the main air flow blown out from the air outlet 11 can be prevented from swirling, so that negative ions emitted from the ion passage 28 diffuse into the main air flow. The amount of negative ions reaching the hair is also improved in this respect. With negative ions, moisture can penetrate deeply into the hair and the moisture content can be increased to optimize the condition of the hair.
[0038]
When the nozzle 50 is connected to the outlet 11 of the outlet cylinder 1 </ b> B, the negative ions that have exited from the outlet 31 of the ion passage 28 are transferred to the outlet 56 of the nozzle 50 through the guide passage 55 in the nozzle 50. Therefore, the negative ions can be prevented from diffusing into the main air flow passing through the inside of the nozzle, and the periphery of the negative ion flow can be wrapped in the air flow blown out from the outlet 56 and fed. Ions can be effectively delivered to the hair with a high distribution density. In the hair dryer of this embodiment, negative ions are targeted for delivery. However, the above-mentioned effects are also exhibited when ozone generated simultaneously with the generation of ions is targeted for delivery. it can. However, ozone is supplied for the purpose of deodorization.
[0039]
FIG. 10 shows another embodiment of the air guide tube 23. There, the air guide tube 23 is formed of a straight double tube, and the ion passage 28 and the air passage 58 are provided inside and outside thereof. The holding arm 38 of the electrode holder 33 was omitted, and the boss portion 37 was fitted and fixed in the mounting hole 59 at the rear end of the ion passage 28. Note that the protruding end of the inner cylindrical wall 60 that defines the ion passage 28, that is, the outlet 31 of the ion passage 28, is positioned at substantially the same front and rear position as the protruding end surface of the dielectric 36, and the air flow passing through the blower passage 58 is ionized. Can be reliably delivered.
[0040]
FIG. 11 shows an embodiment in which the present invention is applied to a hair blosser (blower). In this case, a fan 7, a motor 6, a heater 9 and the like are accommodated in a straight cylindrical main body case 1. A suction port 10 is provided at the right rear end of the main body case 1, and a brush body 65 that is selectively used as an attachment is detachably attached to the air outlet 11 at the left front end. A metal blowing grill 21 and an inner frame 20 are fixed inside the blower outlet 11, and the ion generator 16 is supported by an air guide tube 23 provided inside the inner frame 20. That is, the blowing grill 21, the inner frame 20, the air guide tube 23, and the ion generator 16 are fixedly supported on the main body case 1 side. The outlet 31 of the air guide tube 23 protrudes from the outer surface of the blow-out grill 21, but is provided flush with the opening surface of the blow-out port 11. Even with this configuration, since negative ions are not adsorbed by the blow grill 21 and other components, negative ions having a high distribution density can be fed to the hair. Further, since the outer periphery of the front end of the air guide tube 23 is supported by the inner periphery of the support hole 29 provided in the center of the blowing grill 21, even if an external force such as a drop impact is applied, the air guide tube 23 can be damaged. Can be prevented. Inside the brush body 65, a curved channel cylinder 54 having a guide channel 55 is fixed via a guide channel fixing support arm. The brush body 65 includes a large number of bristles 72 arranged side by side in the axial direction, and a group of small holes for sending a main air flow between the bristles 72, that is, blowout holes 66. The passage cylinder 54 has an inlet that is continuous with the outlet 31 of the air guide cylinder 23, and an outlet that is open at the center of the numerous outlets 66. The brush body 65 can be removed by pressing a detachable button (not shown). 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 50 in the present invention includes an attachment for a hair blosser as in this embodiment.
[0041]
As described above, if the cross-sectional area of the ion passage 28 or the guide passage 55 is sufficiently smaller than the cross-sectional area of the air flow generated by the fan 7 (the cross-sectional area of the main body case 1) or the cross-sectional area of the brush body 65, Even if the peripheral walls of the ion passage 28 and the guide passage 55 are positively (or negatively) charged, the charged state is neutralized in a very short time by the negative ions (or positive ions) generated by the ion generator 16. Therefore, many negative ions (or positive ions) can be immediately delivered to the object. The comparison between the cross-sectional area of the ion passage 28 and the guide passage 55 and the cross-sectional area of the air flow generated by the fan 6 or the cross-sectional area of the brush body 65 is understood as the difference in the inner surface area of both passages. In short, it is only necessary to use a physical quantity that means a difference in the total amount of ions when negative ions (or positive ions) are neutralized and reduced on the inner surface of the passage.
[0042]
FIG. 12 shows another embodiment in which the invention is applied to a hair blosser (blower). The basic structure of the hair blosser in this embodiment is the same as that of the hair blosser described in FIG. 11, but the air guide tube 23 in the embodiment of FIG. The point provided in the passage tube 54 is greatly different from the previous embodiment. Specifically, the inlet side of the passage cylinder 54 is protruded outward from the connection opening of the brush body 65 with the main body case 1 so that the brush body 65 is connected to the main body case 1. The ion passage 28 is formed by the passage tube 54 so that the portion of the portion surrounds the periphery of the ion generator 16. Reference numeral 67 denotes a support arm that protrudes from the outer surface of the passage cylinder 54 and holds the passage cylinder 54 at the center of the cylinder. The ion generator 16 in this case is configured by accommodating each of the pair of discharge needles 43 and 68 in a glass tube 69.
[0043]
According to the hair blosser configured as described above, the ion passage 28 does not exist in a state where the brush body 65 that is selectively used as an attachment is removed from the main body case 1. However, when the brush body 65 is mounted on the main body case 1, the passage cylinder 54 covers the ion generator 16 and the generated negative ions are passed between the bristle 72 of the brush body 65 via the guide passage 55. It can discharge | release from the center part of the blowing hole 66 formed in this. Further, since a part of the air flow generated by the fan 7 is taken into the guide passage 55 and negative ions are fed by the air flow passing through the guide passage 55, the ion generator 16 and the outlet of the guide passage 55 are connected to each other. Despite being far away, it can reliably deliver and release negative ions. Further, since the extended portion of the passage cylinder 54 is fixedly supported by the support hole 29 of the blowout grill 21, the passage cylinder 54 floats when a drop impact is applied, and the passage cylinder 54 surrounds the discharge needles 43 and 68. It is possible to reliably prevent contact with 69. The number of parts can be reduced by the amount that the air guide tube 23 can be omitted, and the manufacturing cost can be reduced accordingly. In the present embodiment, the brush body 65 that is selectively used as an attachment has a detachable structure, but is handled as a part of the main body case 1. The guide passage 55 corresponds to the ion passage 28, and the blowout hole 66 corresponds to the blowout port 11. When the brush body 65 as shown in FIG. 12 is mounted, the guide passage 55 (ion passage 28) is formed. This is because, as a result, it is possible to prevent the negative ions from adsorbing to the blow grill 21 and other components.
[0044]
In FIG. 13, a bowl-shaped ion passage 28 is arranged from the upper outer surface of the main body case 1 to the outlet 11, and the ion generator 16 is provided in the vicinity of the inlet 30. The ion generator 16 includes a ring-shaped counter electrode 35 fixed to the inner surface of the ion passage 28, and a needle-shaped electrode 70 disposed on the central axis of the counter electrode 35 at a position away from the opening surface of the counter electrode 35. It is configured so that ion wind can be generated effectively. In this embodiment, the negative ions are not transferred by using the air flow generated by the fan 7, but are supplied to the outlet 31 only by the action of sending the ion wind generated along with the corona discharge. . The end of the passage cylinder 71 defining the ion passage 28 on the outlet 31 side is supported by the blowing grill 21, and the outlet 31 protrudes from the outer surface of the central portion of the blowing grill 21. A passage tube 54 is provided inside the nozzle 50 attached to the blower outlet 11 to form a guide passage 55 continuous with the ion passage 28.
[0045]
In addition to the above embodiment, the ion passage 28 can be formed by a straight passage in the front-rear direction. The ion passage 28 or the outlet 31 thereof can be arranged so as to be offset from the central portion of the outlet 11. For example, the ion passage 28 can be partitioned in a state of being biased to one place on the inner surface of the cylinder wall of the outlet cylinder 1B. The middle portion of the ion passage 28 may be bent obliquely or bend. The ion passage 28 can be formed by an elastically deformable tube, and the outlet 31 thereof can be constituted by a plurality of openings.
[0046]
The outlet tube 1B can be formed integrally with the main body case 1. In that case, after the flow straightening cylinder 20 and the ion generator 16 are assembled to the main body case 1 from the suction port 10 side, the insulating frame 8 in which the heater 9, the circuit board 13 and the transformer 14 are assembled is mounted on the main body case 1. It is good to assemble. In that case, the blow grill 21 is fitted and fixed from the blow outlet 11 side. In addition, in the Example, although the case where negative ion and ozone were supplied was demonstrated, plus ion may be sufficient as a sending object. The ion generator 16 has a creeping 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, and two needle-like electrodes are opposed to each other. The structure is not limited in any way as long as the structure can be changed to an electrode structure and the like and ions can be generated. When generating positive ions, the diode 17 in FIG. The blower of the present invention includes devices such as a hair blosser and a foot dryer. Moreover, the air blower which is not provided with heaters, such as an electric fan, is also contained in the air blower of this invention.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of an outlet of a hair dryer.
FIG. 2 is a longitudinal side view of a hair dryer.
FIG. 3 is an explanatory diagram showing an outline of ion generating means.
FIG. 4 is a cross-sectional view of an ion generator and its peripheral structure.
FIG. 5 is an exploded perspective view showing a relational structure between a flow straightening cylinder and an ion generation unit.
FIG. 6 is an exploded perspective view of an outlet tube and a nozzle.
7 is a cross-sectional view taken along line AA in FIG.
FIG. 8 is a longitudinal side view showing a usage state of a nozzle.
FIG. 9 is a front view of a nozzle.
FIG. 10 is a cross-sectional view showing another embodiment of the wind guide tube.
FIG. 11 is a side view and a sectional view showing an embodiment in which the present invention is applied to a hair blosser.
FIG. 12 is a cross-sectional view showing still another embodiment of a hair blosser.
FIG. 13 is a cross-sectional view showing another embodiment of the ion generating means.
[Explanation of symbols]
1 Body case
6 Motor
7 fans
11 Air outlet
16 Ion generator
21 Outlet grill
28 Ion passage
31 Exit

Claims (10)

A cylindrical main body case 1 that houses the fan 7 and the motor 6 for driving the fan, an ion generator 16 that generates ions, and an ion passage 28 that transfers and guides the ions generated by the ion generator 16 are provided. And
On one side of the main body case 1, there are provided an air outlet 11 for the air flow generated by the fan 7 and a ventilated air outlet grill 21 that covers the air outlet 11.
An air blower characterized in that the outlet 31 of the ion passage 28 protrudes from the outer surface of the blowout grill 21. The blower device according to claim 1, wherein the outlet 31 of the ion passage 28 is disposed substantially at the center of the blowing grill 21. A heater 9 for heating the air flow generated by the fan 7 is disposed along the inner surface of the cylindrical wall of the main body case 1.
An inlet 30 for receiving an air flow near the center of the main body case 1 among the air flow generated by the fan 7 is opened at the windward end of the ion passage 28.
The blower according to claim 1 or 2, wherein ions generated by the ion generator (16) disposed in the middle of the ion passage (28) are supplied by an air flow flowing through the ion passage (28). The air blower according to claim 1, 2, or 3, wherein a cylindrical peripheral surface of the air guide tube 23 forming the ion passage 28 is supported by a support hole 29 provided in the metal blowing grill 21. The air flow according to claim 1, 2, 3, or 4, wherein a rectifying blade 22 for rectifying the air flow generated by the fan 6 into a straight air flow is provided on the outer peripheral surface of the air guide tube 23 forming the ion passage 28. apparatus. The ion generator 16 includes an electrode holder 33, a center electrode 34 fixed to the center of the electrode holder 33, a counter electrode 35 surrounding the center electrode 34, and a space between the center electrode 34 and the counter electrode 35. The air blower according to claim 1, 2, 3, 4 or 5, wherein the air blower is configured with a cylindrical dielectric body 36 that separates the two. The air guide tube 23 is composed of a tapered first tapered tube portion 26 and a second tube portion 27 protruding forward in succession to the small diameter end in front of the first tube portion 26,
The cylindrical end of the dielectric body (36) faces the middle of the first cylindrical section (26), and an orifice section (R) is formed between the dielectric body (36) and the first cylindrical section (26). Blower device. A wind guide tube 23 is integrally provided in the center of the inner frame 20 that is attached and fixed to the inner surface of the main body case 1.
The blower according to claim 4, 5, 6, or 7, wherein the blow-out grill 21 disposed facing the blow-out opening 11 is sandwiched between the provided step 24 and the inner frame 20 on the inner surface of the main body case 1. The main body case 1 is composed of a main case portion 1A and an outlet tube 1B connected to the main case portion 1A.
The blower according to claim 4, 5, 6, 7 or 8, wherein the air guide tube 23 and the ion generator 16 are disposed inside the outlet tube 1B. A nozzle 50 that flows and guides the air flow generated by the fan 6 is connected to the air outlet 11 on the main body case 1 side.
The air blower according to claim 1 or 2, wherein a guide passage 55 is provided inside the nozzle 50 to guide the ions that have exited from the outlet 31 of the ion passage 28 to the opening surface of the air outlet 56 of the nozzle 50.

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