JP7002447B2 - Hairdryer - Google Patents

Description

The present invention relates to a dryer that dries hair or the like using radiant heat rays such as infrared rays.

In the field of dryers, it is known to use a heat ray light source such as a halogen lamp as a heat source for heating dry air. It is also known that in a dryer using a heat ray light source as a heat source, a reflector for condensing light is provided around the light source. The dryer described in Patent Document 1 is provided with an air blower unit 8, an air heater 10, a halogen lamp 22, and a reflector 20 in this order from the downstream side inside a housing 2 having a handle 6. The reflector 20 is composed of a concave reflecting portion having a front opening and a cylindrical lamp mounting portion continuously and integrally provided in the center thereof, and the light emitted from the halogen lamp 22 fixed to the lamp mounting portion. Is directed forward by the concave reflector. A translucent cover plate 24 is attached to the front opening of the reflector 20.

FIG. 3 of Patent Document 1 discloses a dryer in which a large number of flow paths 321 are opened in the concave portion of the reflector 320 and a large number of flow paths 325 are opened in the cover plate 324. The flow path 321 extends from the base end portion closer to the rear to the tip end portion closer to the front, and is provided on the entire surface of the reflector 320. The flow path 325 is provided on the entire surface of the cover plate 324. When a large number of flow paths 321 and 325 are provided in each of the reflector 320 and the cover plate 324 in this way, the air from the flow path 321 on the downstream side passes through the reflector 320 and reaches the front through the flow path 325. Since a flow can be formed, the air in the reflector 320 can be discharged.

Forming a flow path in the reflector is also disclosed in the dryer of Patent Document 2. The reflector 13 (reflector) of the dryer described in Patent Document 2 is composed of a concave first reflecting portion 131 and a cylindrical second reflecting portion 132, and the second reflecting portion 132 reflects. A large number of through holes 133 are provided between the inside and the outside of the body 13 to allow air to flow in or out. The first reflecting portion 131 is provided with an opening s, and a heat ray light source 11 is attached to the opening s. In front of the reflector 13, a filter 15 that transmits only heat ray infrared rays among the light emitted from the heat ray light source 11 is arranged. The air sent into the reflector 13 from the opening s of the first reflector 131 by the rotation of the fan 19 is discharged to the outside of the reflector 13 from the through hole 133 of the second reflector 132, and the reflector 13 is used. It is discharged from the nozzle 173 together with the air flowing through the ventilation space between the outer periphery of the surface and the housing 17.

German Patent Application Publication No. 295001 International Publication No. 2016/072031

The present inventors are involved in the development of a dryer capable of irradiating hair with stronger infrared rays. That is, in a dryer using a heat ray light source such as a halogen lamp, the air blown out by the fan is heated by the heat ray light source, and the hair is dried by the heated warm air, and the hair is irradiated from the heat ray light source. Two drying methods are adopted, which are radiant heating methods in which hair is heated and dried by radiant heat rays such as infrared rays. The present inventors have further improved the drying ability by the latter radiant heating method. He is involved in the development of a dryer that can irradiate hair with strong infrared rays.

However, in a configuration in which a large number of through holes are formed in the reflector as in Patent Documents 1 and 2, the reflection region of the reflector becomes smaller by the amount of the through holes, and the reflection efficiency of infrared rays, which are radiant heat rays, is improved. Therefore, it is not possible to efficiently irradiate the hair with infrared rays, and it is not possible to improve the drying power of the dryer derived from the radiant heating method. The above problem can be solved, for example, by reducing the number of through holes provided in the reflector, but in that case, the exhaust efficiency of the air inside the reflector decreases and the internal temperature of the reflector rises, resulting in deformation of the reflector and deformation of the filter. There is a risk of causing problems such as damage.

The present invention has been made to solve the above-mentioned problems of the dryer using infrared rays, and to provide a dryer that can reliably exhaust heat from the inside of the reflector without reducing the reflection efficiency of the reflector. The purpose is to provide.

The dryer according to the present invention is provided in a main body case 1 having a hollow tubular air guide portion 7 from a suction port 8 on the rear side to an air outlet 9 on the front side, and a suction port 8 provided in the air guide portion 7. A blower fan 3 that generates an air flow from the air outlet 9 to the air outlet 9, a heat ray light source 4 that is arranged in front of the blower fan 3 in the wind guide portion 7 and emits radiant heat rays including infrared rays, and a wind guide portion. A reflector 10 arranged on the front side of the heat ray light source 4 in the heat ray light source 4 to reflect and guide the radiant heat rays emitted by the heat ray light source 4 toward the front, and a reflector 10 arranged on the front side of the reflector 10 in the air guide portion 7. An optical filter 11 that transmits radiant heat rays from the light radiated from the front end of the reflector 10 to attenuate visible light, and a dry air flow path 52 formed between the outer periphery of the reflector 10 and the inner surface of the main body case 1. And a heat exhaust structure for discharging the heat in the reflector 10 to the outside. The exhaust heat structure is formed only at the rear end of the reflector 10 and is formed only at the suction flow path 70 that receives a part of the air flow generated by the blower fan 3 inside the reflector 10 and the front end of the reflector 10. It is composed of a delivery flow path 71 that sends out the air in the reflector 10 toward the dry air flow path 52. The pressure in the flow path 52 of the dry air flow path 52 in the formation region of the delivery flow path 71 is set to be smaller than the pressure in the flow path of the dry air flow path 52 in the formation region of the suction flow path 70. It is a feature.

The length of the reflector 10 in the front-rear direction defined by the rear end of the optical filter 11 and the rear end of the reflector 10 is defined as d1, and the rear end of the optical filter 11 and the opening edge on the rear end side of the transmission flow path 71. When the distance specified in is defined as d2, the transmission flow path 71 is formed at a position satisfying the relational expression of d2 ≦ d1 / 5.

The opening length dimension w1 of the transmission flow path 71 in the front-rear direction is set to 5 mm or less.

It is possible to adopt a configuration in which a gap E serving as a delivery flow path 71 is formed between the rear end of the optical filter 11 and the front end of the reflector 10.

The reflector 10 is composed of a front reflector 80 on the front side and a rear reflector 81 on the rear side, and a gap E serving as a transmission flow path 71 is formed between the front and rear reflectors 80 and 81. Can be taken.

The delivery flow path 71 may be a circumferential slit opening 84 opened over the entire circumference of the peripheral wall constituting the reflector 10 so as to be along the front opening edge of the reflector 10.

The delivery flow path 71 can be composed of a group of a large number of through holes 86 arranged in a row over the entire circumference of the peripheral wall constituting the reflector 10 so as to be along the front opening edge of the reflector 10.

When the blower fan 3 is rotated, the dry air is sucked into the air guide portion 7 of the main body case 1 from the suction port 8 and flows through the dry air flow path 52 to the air outlet 9. At this time, in the dryer of the present invention, the delivery flow path 71 of the reflector 10 located on the downstream side of the pressure in the flow path of the dry air flow path 52 in the formation region of the suction flow path 70 of the reflector 10 located on the upstream side. Since the pressure in the flow path of the dry air flow path 52 in the formation region is set to be small, the flow velocity of the dry air in the formation region of the delivery flow path 71 is increased more than the flow velocity of the dry air in the formation region of the suction flow path 70. Can be made to. When the flow velocity of the dry air in the formation region of the delivery flow path 71 is increased in this way, the internal air of the reflector 10 is sucked into the dry air flow path 52 through the delivery flow path 71 due to the Venturi effect, so that the internal air is introduced. It can be reliably sent out toward the dry air flow path 52 (see FIG. 6). In addition, when the internal air of the reflector 10 is sent out, the pressure difference between the pressure in the reflector 10 and the pressure in the flow path of the dry air flow path 52 in the formation region of the suction flow path 70 causes the pressure difference in the flow path 52 to pass through the suction flow path 70. The dry air sucked from the suction port 8 of the main body case 1 is sucked into the inside of the reflector 10 from the dry air flow path 52 (see FIG. 6). As described above, according to the present invention, it is possible to create an air flow from the suction flow path 70 through the inside of the reflector 10 to the dry air flow path 52 via the delivery flow path 71 by utilizing the venturi effect. Even when the air inside the reflector 10 is heated by the heat ray light source 4, the air is sent to the outside of the reflector 10 and new air is sent to the inside of the reflector 10 to efficiently dissipate the heat inside the reflector 10. It is possible to prevent the inside of the reflector 10 from falling into an overheated state. From the above, according to the present invention, it is possible to reliably prevent the reflector 10 from being deformed or the optical filter 11 from being damaged by heating by the heat ray light source 4, so that a dryer having excellent durability can be obtained. can.

Since the suction flow path 70 is formed only at the rear end portion of the reflector 10 and the delivery flow path 71 is formed only at the front end portion of the reflector 10, a large number of suction flow paths and delivery flow paths are formed over the entire reflector 10. The reflection area of the reflector 10 can be increased as compared with the conventional configuration to be formed, and the reflection efficiency and the light collection efficiency of the reflector 10 can be improved. Therefore, according to the dryer according to the present invention, it is possible to irradiate the hair or the like with radiant heat rays such as more powerful infrared rays, so that it is possible to obtain a dryer having excellent drying ability by the radiant heating method.

From the above, according to the dryer of the present invention, it is possible to simultaneously solve the conflicting problems of improving the reflection efficiency of the reflector 10 and ensuring that the reflector 10 exhausts heat. Further, since the temperature of the dry air can be raised by mixing the air sent from the delivery flow path 71 with the dry air flowing through the dry air flow path 52, the drying capacity by the convection heating method as well as the radiant heating method. It is possible to improve the temperature, and it is possible to effectively heat and dry the hair in a shorter time.

The length of the reflector 10 in the front-rear direction defined by the rear end of the optical filter 11 and the rear end of the reflector 10 is defined as d1, and the rear end edge of the optical filter 11 and the opening edge on the rear end side of the transmission flow path 71 are defined. When the distance defined by the above is defined as d2, it is desirable to form the transmission flow path 71 at a position satisfying the relational expression of d2 ≦ d1 / 5. That is, the "front end portion of the reflector 10" on which the transmission flow path 71 is formed in the present invention means that the opening edge on the rear end side of the transmission flow path 71 is the front and rear of the reflector 10 with the rear end of the optical filter 11 as the starting point. The position is within one-fifth of the length in the direction. This is because when the delivery flow path 71 is arranged behind one-fifth of the reflector 10 in the front-rear direction, air stays on the front end side of the reflector 10 and heat is not exhausted by the air flow. If there is a possibility of dead space and the transmission flow path 71 is arranged on the rear side, the distance between the heat ray light source 4 and the transmission flow path 71 becomes short, and the radiant heat rays emitted from the heat ray light source 4 become short. Leaks directly from the reflector 10 through the transmission flow path 71, and the reflection efficiency and the light collection rate of the reflector 10 decrease (see FIG. 7B). On the other hand, if the delivery flow path 71 is arranged on the front side of the reflector 10 in the front-rear direction, there is little possibility that air will stay in the reflector 10, and the heat in the reflector 10 will be efficient. Can be discharged as a target. Since the distance between the heat ray light source 4 and the transmission flow path 71 can be increased, the radiant heat rays emitted from the heat ray light source 4 are less likely to leak directly from the reflector 10 through the transmission flow path 71. Therefore, it is possible to improve the reflection efficiency and the light source ratio by the reflector 10 (see FIG. 7A). According to the findings of the present inventors, in order to improve the heat exhaust efficiency and the reflection efficiency of the reflector 10, the transmission flow path is formed at a position satisfying the relational expression of d2 ≦ d1 / 10, that is, It is more desirable that the opening edge on the rear end side of the transmission flow path 71 is within 1/10 of the length of the reflector 10 in the front-rear direction, starting from the rear end of the optical filter 11.

It is desirable that the opening length dimension w1 of the delivery flow path 71 in the front-rear direction is set to 5 mm or less. This is because when the opening length dimension w1 of the delivery flow path 71 exceeds 5 mm, the opening becomes too large, so that the Venturi effect is not exhibited well, and the dry air flow path from the inside of the reflector 10 via the delivery flow path 71. This is because the amount of air sent to the 52 is reduced, and the reflection efficiency and the light collection rate of the reflector 10 are lowered.

As a specific form of the delivery flow path 71, a gap E to be a delivery flow path 71 is formed between the rear end of the optical filter 11 and the front end of the reflector 10 (see FIG. 2), and the reflector 10 is provided. It is composed of a front reflector 80 on the front side and a rear reflector 81 on the rear side, and a gap E serving as a transmission flow path 71 is formed between the front and rear reflectors 80 and 81 (see FIG. 8). ), The delivery flow path 71 is formed as a circumferential slit opening 84 opened over the entire circumference of the peripheral wall constituting the reflector 10 so as to be along the front opening edge of the reflector 10 (FIG. 10). (See), the delivery flow path 71 is composed of a group of a large number of through holes 86 arranged in a row over the entire circumference of the peripheral wall constituting the reflector 10 so as to be along the front opening edge of the reflector 10. Things (see FIG. 12) and the like can be mentioned. As described above, it is desirable that the delivery flow path 71 is formed in a full circumference along the opening edge of the reflector 10 only at one position at the front end portion of the reflector 10. Of these, when a gap E serving as a transmission flow path 71 is formed between the rear end of the optical filter 11 and the front end of the reflector 10, the reflector 10 may be divided into two, or the reflector 10 may be provided with a through hole. Therefore, it is possible to suppress an increase in cost of the dryer provided with the delivery flow path 71. Further, when the delivery flow path 71 is formed as a circular slit opening 84, or when it is composed of a group of a large number of through holes 86, a gap is provided between the rear end of the optical filter 11 and the front end of the reflector 10. Compared with the case of forming E, the length dimension before and after the reflector 10 defined from the front end of the optical filter 11 to the rear end of the reflector 10 can be reduced by the amount that the gap E is eliminated, so that the dryer can be used. Can contribute to the compactness of.

It is a vertical sectional side view of the dryer (hair dryer) which concerns on Example 1 of this invention. It is sectional drawing (cross-sectional plan view) of the line AA of FIG. FIG. 3 is an enlarged cross-sectional view showing a delivery flow path of the hair dryer according to the first embodiment. FIG. 2 is a cross-sectional view taken along the line BB (longitudinal front view) of FIG. It is a perspective view for demonstrating the assembly structure of the halogen lamp with respect to the reflector of the hair dryer which concerns on Example 1. FIG. It is a figure for demonstrating the flow of the air by the Venturi effect in the dryer of this invention. It is a conceptual diagram for demonstrating the relationship between the position of a delivery flow path and the amount of leakage of radiant heat rays from a reflector, and shows the case where the delivery flow path is located in front of the reflector. It is a conceptual diagram for demonstrating the relationship between the position of a delivery flow path and the amount of leakage of radiant heat rays from a reflector, and shows the case where the delivery flow path is located closer to the rear of the reflector. It is a cross-sectional plan view of the main part of the hair dryer which concerns on Example 2 of this invention. It is a perspective view of the reflector which constitutes the hair dryer which concerns on Example 2. FIG. It is a cross-sectional plan view of the main part of the hair dryer which concerns on Example 3 of this invention. It is a perspective view of the reflector which constitutes the hair dryer which concerns on Example 3. FIG. It is a cross-sectional plan view of the main part of the hair dryer which concerns on Example 4 of this invention. It is a perspective view of the reflector which constitutes the hair dryer which concerns on Example 4. FIG. It is a cross-sectional plan view of the main part of the hair dryer which concerns on Example 5 of this invention.

(Example 1)
1 to 7 show Example 1 in which the dryer of the present invention is applied to a hair dryer. The front-back, left-right, and up-down in this embodiment follow the crossing arrows shown in FIGS. 1, 2, and 5, and the front-back, left-right, and up-down indications shown in the vicinity of each arrow. In FIG. 1, the hair dryer is a axial flow type blower fan 3 rotationally driven by a fan motor 2 and a heat ray light source that radiates infrared light and visible light inside a main body case 1 that is long before and after it also serves as a grip. Halogen lamp (heat ray light source) 4 and the like are accommodated and configured. The main body case 1 is formed by joining a pair of upper and lower half-split bodies 5.6 formed in a gutter shape, and a cylindrical wind guide portion 7 is formed inside the pair of upper and lower half bodies 5.6. An air suction port 8 is formed at the rear end of the air guide portion 7, and an air outlet 9 is formed at the front end.

The blower fan 3 is arranged in the latter half of the air guide portion 7 in the main body case 1, pressurizes the air sucked from the suction port 8, and sends the air to the outlet 9. The halogen lamp 4 is arranged in the front half of the air guide portion 7 of the main body case 1, and a reflector 10 that reflects and guides the light radiated from the halogen lamp 4 toward the air outlet 9 is fixed around the halogen lamp 4. ing. An optical filter 11 is arranged in the light radiation path between the reflector 10 and the outlet 9. The outlet 9 also serves as an outlet for dry air and an irradiation port for irradiating the user's hair with infrared rays (heat rays) emitted from the halogen lamp 4.

Most of the peripheral surface of the main body case 1 is covered with a touch sensor 12 that detects contact with the human body, and an operation knob 15 of the power switch 14 is arranged facing the operation unit formed on the upper part of the touch sensor 12. ing. By sliding the operation knob 15 back and forth along the surface of the main body case 1, the power switch 14 can be switched between an on state and an off state. The power switch 14 is housed in a housing recess 17 formed in the upper part of the main body case 1, and the housing recess 18 formed in the lower part of the main body case 1 controls the driving state of the fan motor 2 and the halogen lamp 4. The control board 19 is housed.

A suction grill 22 is attached to the suction port 8 of the main body case 1, and a socket 25 for detachably connecting the power feeding plug 24 is provided in the center of the suction grill 22. An outlet grill 23 made of a metal material such as aluminum is attached to the outlet 9 of the main body case 1. The outlet grill 23 integrally includes a cylindrical outer cylinder 26, an inner cylinder 27 having a diameter smaller than that of the outer cylinder 26, and a plurality of rectifying blades 28 that radially connect both cylinders 26 and 27. There is.

The fan motor 2 and the blower fan 3 are supported by the fan case 29. The fan case 29 has a cylindrical outer cylinder 30 that surrounds the periphery of the blower fan 3, a holder portion 31 to which the rear end portion of the fan motor 2 is mounted, and a cylindrical inner cylinder that surrounds the circumference of the holder portion 31. 32, a plurality of rectifying blades 33 that radially connect the outer cylinder 30 and the inner cylinder 32, and the like are integrally provided. A flange 34 is formed so as to project outward from the front end of the outer cylinder 30, and the fan case 29 is engaged and held by the engaging groove 35 formed on the inner surface of the half-split body 5.6. It is fixed to the main body case 1.

As shown in FIGS. 2 and 5, the halogen lamp 4 is configured by connecting a bulb 38 on the front side and a socket 39 on the rear side in the front-rear direction. The bulb 38 is composed of a quartz glass glove 40 formed in the shape of a hollow container and a power feeding plug 41 formed behind the glove 40. In addition to a filament serving as a light emitter inside the glove 40. , Inert gas, halogen gas, etc. are enclosed. The glove 40 integrally has a spherical shell-shaped glove main body 42, an exhaust pipe remaining portion 43 formed at the front end of the glove main body 42, and a holder portion 44 formed behind the glove main body 42, thereafter. A plug 41 is attached to the portion. The holder portion 44 is formed in a hemispherical shell shape that expands toward the front, and its external dimension is set smaller than the external dimension of the glove main body 42. The plug 41 is formed in a flat prism with a small thickness on the left and right. The socket 39 is composed of a connector 46 having a socket hole 45 having a vertically long opening for receiving the plug 41, and a housing 47 provided behind the connector 46. The front end surface of the connector 46 is formed in a concave curved shape that substantially matches the outer shape of the holder portion 44 of the valve 38, and when the plug 41 of the valve 38 is inserted into the socket hole 45, the convex arc surface of the holder portion 44 is formed. Is received by the front end surface of the connector 46.

A reflector 10 for collecting light is arranged around the bulb 38. The reflector 10 is made of a metal such as aluminum and is formed in a round bottom cylindrical shape that opens toward the outlet 9, and a reflective surface that reflects infrared light and visible light is formed on the inner surface thereof. .. In FIG. 2, reference numeral 50 is formed at the rear end of the reflector 10 and extends forward in a hemispherical shell-like conical portion, and reference numeral 51 extends continuously forward to the front end edge of the conical portion. A straight straight cylinder portion having a uniform diameter is shown. The outer diameter dimension of the reflector 10 is set smaller than the inner diameter dimension of the main body case 1, and a dry air flow path 52 leading to the air outlet 9 is formed between the outer circumference of the reflector 10 and the inner surface of the main body case 1. ing. Most of the air sucked into the air guide portion 7 from the suction port 8 by the blower fan 3 flows into the dry air flow path 52 along the conical portion 50 of the reflector 10, and then is sent out from the air outlet 9.

An insertion hole 53 for allowing the valve 38 to face the inside of the reflector 10 is formed at the center of the rear portion of the reflector 10, that is, at the tip of the conical portion 50. As shown in FIGS. 4 and 5, the insertion hole 53 has a round hole-shaped first insertion hole 54 formed in the center of the tip of the conical portion 50 and the insertion hole 54 in the vertical direction so as to pass through the first insertion hole 54. It is formed in a keyhole shape in a front view including a long hole-shaped second insertion hole 55 formed long. After the connector 46 of the socket 39 faces the periphery of the insertion hole 53, the holder portion 44 of the valve 38 and the plug 41 are inserted into the insertion hole 53, and the plug 41 is inserted into the socket hole 45 of the connector 46. As a result, the bulb 38 on the front side and the socket 39 on the rear side can be connected via the insertion hole 53 of the reflector 10. At this time, a slight gap is formed between the outer peripheral surface of the holder portion 44 and the inner peripheral surface of the first insertion hole 54, and between the connector 46 of the socket 39 and the inner peripheral surface of the second insertion hole 55. Will be done. This gap becomes a suction flow path 70 having a waste heat structure, which will be described later.

Inside the air guide portion 7, a support frame 57 that rectifies the wind generated by the blower fan 3 and supports the reflector 10, the halogen lamp 4, and the like is arranged. The support frame 57 is formed by assembling a pair of mica plates 58 and 58 arranged in a horizontal posture and a vertical posture in a cross shape. The rear ends of the mica plates 58 and 58 are engaged with slits 59 formed in the front ends of the fan case 29, which restricts the rotation of the support frame 57 with respect to the main body case 1. As shown in FIGS. 1 to 4, a pair of ribs 61 and 61 having engaging recesses 60 are formed so as to project outward at four locations on the upper, lower, left, and right sides of the outer peripheral surface of the leading edge (opening peripheral edge) of the reflector 10. By engaging the mica plates 58 and 58 with these engaging recesses 60, the reflector 10 is supported from all sides (up, down, left, and right). As shown in FIG. 5, engaging grooves 62 are formed on the upper and lower surfaces of the socket 39 of the halogen lamp 4, and by engaging the mica plate 58 with these engaging grooves 62, the socket 39 can be moved from the vertical direction. It is supported. A shallow mounting groove 63 is formed in a circumferential shape on the inner surface of the front end portion of the main body case 1, and the outer cylinder body 26 of the blowout grill 23 is fitted into the mounting groove 63 to fit the main body of the blowout grill 23. The displacement movement in the front-rear direction (axial direction) and the radial direction with respect to the case 1 is regulated.

The optical filter 11 is arranged in a light radiation path between the reflector 10 and the outlet 9 for the purpose of transmitting infrared rays and shielding visible light. By arranging the optical filter 11 in the light radiation path in this way, it is possible to prevent visible light from being emitted from the outlet 9 of the dryer when the hair dryer is used, and it is dazzling to the user's eyes when the hair is dried or the like. You can eliminate the light entering. As a result, the user can smoothly perform the hair styling work without feeling glare. The optical filter 11 is a disk-shaped glass body made of low-expandable glass such as black crystallized glass having a small coefficient of thermal expansion, and is internally fitted to the inner cylinder 27.

In the hair dryer provided with the halogen lamp 4 which is a heat ray light source, the reflector 10 is heated by the infrared rays emitted from the halogen lamp 4. Further, heat generated from the halogen lamp 4 is accumulated inside the reflector 10, and the temperature inside the reflector 10 rises. Therefore, a waste heat structure for exhausting the heat inside the reflector 10 is required. The heat exhaust structure of the hair dryer according to the present embodiment includes a suction flow path 70 formed only in the rear end portion of the reflector 10 and receiving a part of the air flow generated by the blower fan 3 inside the reflector 10. It is formed only at the front end portion of the reflector 10, and is composed of a delivery flow path 71 that sends out the air in the reflector 10 toward the dry air flow path 52.

More specifically, as shown in FIG. 2, a slight gap is formed between the bulb 38 constituting the halogen lamp 4 and the insertion hole 53 formed at the rear end of the reflector 10, and this gap blows air. The suction flow path 70 receives a part of the air flow generated by the fan 3 inside the reflector 10. On the other hand, the rear end of the optical filter 11 and the front end of the reflector 10 are not in contact with each other, and both are arranged close to each other with a slight gap E (2 mm (w1 = 2 mm) in the present embodiment). E is a delivery flow path 71 that sends out the air in the reflector 10 toward the dry air flow path 52. The flow path cross-sectional area of the dry air flow path 52 (hereinafter referred to as “downstream side flow path 72”) at the front end portion of the reflector 10 obtained by the difference between the inner diameter dimension of the main body case 1 and the outer diameter dimension of the straight cylinder portion 51 is. It is set smaller than the flow path cross-sectional area of the dry air flow path 52 (hereinafter referred to as “upstream side flow path 73”) at the rear end of the reflector 10, in other words, the downstream side in the formation region of the delivery flow path 71. The flow path cross-sectional area of the flow path 72 is set smaller than the flow path cross-sectional area of the upstream flow path 73 in the formation region of the suction flow path 70. Therefore, the pressure in the flow path of the downstream side flow path 72 is made smaller than the pressure in the flow path of the upstream side flow path 73, and the flow velocity of the dry air flowing in the downstream side flow path 72 flows through the upstream side flow path 73. It is possible to increase the flow velocity of the dry air.

As shown in the conceptual diagram of FIG. 6, when the flow velocity of the dry air in the downstream flow path 72 is increased as described above, the internal air of the reflector 10 is sent through the delivery flow path 71 due to the Venturi effect. Can be sucked into. Therefore, the internal air of the reflector 10 can be reliably sent out toward the dry air flow path 52 (downstream side flow path 72), and the heat in the reflector 10 can be discharged. In addition, when the internal air of the reflector 10 is sent out through the delivery flow path 71 in this way, the suction flow path 70 is caused by the pressure difference between the pressure inside the reflector 10 and the pressure inside the flow path of the upstream side flow path 73. The dry air can be sucked into the inside of the reflector 10 from the dry air flow path (upstream side flow path 73).

As described above, according to the hair dryer according to the present embodiment, the air flow from the suction flow path 70 to the dry air flow path 52 through the inside of the reflector 10 and the delivery flow path 71 by utilizing the venturi effect. (See FIG. 6), even if the air inside the reflector 10 is heated by the heat radiation from the halogen lamp 4, the air is sent out to the outside of the reflector 10 through the delivery flow path 71. , New air can be sent into the reflector 10 through the suction flow path 70 to exhaust heat. From the above, according to the hair dryer according to the present embodiment, it is possible to efficiently exhaust heat inside the reflector 10 and surely prevent the inside of the reflector 10 from falling into an overheated state.

As described above, in the hair dryer according to the first embodiment, a gap E is formed between the rear end of the optical filter 11 and the front end of the reflector 10, and this gap E is used as the delivery flow path 71, and the reflector 10 has a gap E. A delivery flow path 71 for sending out internal air is formed at the foremost end. Therefore, according to the hair dryer according to the first embodiment, the dead space in which the air stays is not formed in the reflector 10, and the air in the reflector 10 can be discharged evenly, so that the heat in the reflector 10 can be discharged. Can be reliably and efficiently discharged to the dry air flow path 52 via the delivery flow path 71. Further, if the heat in the reflector 10 can be efficiently discharged to the dry air flow path 52 in this way, the temperature of the dry air flowing through the dry air flow path 52 is raised, and the heat is blown out from the outlet 9 toward the front portion. Since the dried air can be efficiently heated, not only the drying capacity of the radiant heating method derived from infrared rays but also the drying capacity of the convection heating method derived from the heated drying air can be improved, and the hair can be improved. It is possible to effectively heat and dry the hair in a shorter time. However, in a hair dryer that has significantly improved the drying capacity derived from the radiant heating method, the drying capacity derived from the convection heating method may be ancillary, and in that case, it dries to the hair and skin. It suffices if the dry air is warmed to such an extent that it does not cause coldness or discomfort when exposed to the wind.

In addition, when the delivery flow path 71 is formed at the leading end of the reflector 10 as shown in FIG. 7A, the halogen lamp 4 is compared with the case where the delivery flow path 71 is formed closer to the rear part of the reflector 10 as shown in FIG. 7B. Since the direction defined by (more specifically, the center point of the globe 40 of the halogen lamp 4) and the transmission flow path 71 can be brought closer to the front-back horizontal direction, the infrared rays emitted from the halogen lamp 4 can be brought closer to the transmission flow path. It can be prevented from leaking to the outside of the reflector 10 via the 71. Therefore, it is possible to surely prevent the reflection efficiency and the light collection rate of the reflector 10 from decreasing due to the formation of the transmission flow path 71.

Based on the above findings, the length of the reflector 10 in the front-rear direction defined by the trailing edge of the optical filter 11 and the trailing edge of the reflector 10 is defined as d1, and the trailing edge of the optical filter 11 and the sending flow. When the distance defined by the opening edge on the rear end side of the road 71 is defined as d2, it is desirable to form the transmission flow path 71 at a position satisfying the relational expression of d2 ≦ d1 / 5 (see FIG. 2). That is, from the viewpoint of improving the heat exhaust efficiency and the reflection efficiency, it is optimal to form the delivery flow path 71 at the foremost end of the reflector 10 as in the present embodiment. As shown, when the delivery flow path 71 is formed at the front end of the reflector 10, it is desirable to form the delivery flow path 71 at a position satisfying the relational expression of d2 ≦ d1 / 5. This is because when the delivery flow path 71 is arranged behind one-fifth of the reflector 10 in the front-rear direction, air stays at the front end side of the reflector 10 and heat is not exhausted by the air flow. When there is a possibility of dead space and the transmission flow path 71 is arranged on the rear side, it is defined by the halogen lamp 4 (more specifically, the center point of the globe 40 of the halogen lamp 4) and the delivery flow path 71. Since the direction of the light approaches the direction orthogonal to the front-back direction (see FIG. 7B), the infrared rays emitted from the halogen lamp 4 leak directly from the reflector 10 through the transmission flow path 71 and are reflected by the reflector 10. This is due to the decrease in efficiency and light collection rate.

In addition, it is desirable to set the opening length dimension (w1) of the transmission flow path 71 in the front-rear direction to 5 mm or less. This is because when the length width dimension (w1) of the delivery flow path 71 exceeds 5 mm, the opening becomes too large, so that the Venturi effect is not exhibited well, and the delivery flow path 71 is sent out to the dry air flow path 52. This is due to the decrease in the amount of air generated and the decrease in the reflection efficiency and the light collection rate of the reflector 10.

(Example 2)
8 and 9 show Example 2 of the dryer (hair dryer) according to the present invention in which the structure of the delivery flow path 71 is modified. In the second embodiment, the reflector 10 is divided into a short cylindrical front reflector 80 having a small front-rear length dimension and a rear reflector 81 having a straight cylinder portion 51 and a conical portion 50, and both reflectors 80. It differs from the previous embodiment 1 in that a gap E is formed between 81 and this is used as a transmission flow path 71. The front reflector 80 is supported by the mica plates 58 and 58 by a pair of ribs 61 and 61. The total length of the reflector 10 including the front reflector 80, the gap E, and the rear reflector 81 is defined as d1, and the distance defined by the rear end edge of the optical filter 11 and the opening edge on the rear end side of the transmission flow path 71 is d2. When the above is specified, the delivery flow path 71 is formed at a position satisfying the relational expression of d2 ≦ d1 / 5. The length dimension of the gap E in the front-rear direction is set to 5 mm or less (w1 ≦ 5 mm). Since the other points are the same as those in the first embodiment, the same members are designated by the same reference numerals and the description thereof will be omitted. The same applies to the following examples.

As described above, it is assumed that the reflector 10 is composed of the front reflector 80 and the rear reflector 81, and both reflectors 80 and 81 are arranged so as to face each other with the gap E interposed therebetween, and the gap E is used as the transmission flow path 71. Compared to the case where a gap E is formed between the rear end edge of the optical filter 11 and the front end edge of the reflector 10, the length dimension from the rear end edge of the reflector 10 to the front end edge of the optical filter 11 Can be reduced by the amount of the gap E, which can contribute to the compactness of the hair dryer. The same applies to the following Examples 3 and 4.

(Example 3)
10 and 11 show Example 3 of the dryer (hair dryer) according to the present invention in which the structure of the delivery flow path 71 is modified. In the third embodiment, the delivery flow path 71 is formed as a circular slit opening 84 opened over the entire circumference of the peripheral wall constituting the reflector 10 so as to be along the front opening edge of the reflector 10. , Different from the first embodiment above. When the length of the reflector 10 is defined as d1 and the distance defined by the rear end edge of the optical filter 11 and the opening edge on the rear end side of the transmission flow path 71 (slit opening 84) is defined as d2, d2 ≦ The delivery flow path 71 is formed at a position satisfying the relational expression of d1 / 5. The length dimension (w1) of the slit opening 84 in the front-rear direction is set to 5 mm or less. The slit opening 84 is equally divided into four, and a connecting rib 85 is formed between the adjacent slit openings 84.

(Example 4)
12 and 13 show Example 4 of the dryer (hair dryer) according to the present invention in which the structure of the delivery flow path 71 is modified. In the fourth embodiment, the delivery flow path 71 is composed of a group of a large number of through holes 86 arranged in a row over the entire circumference of the peripheral wall constituting the reflector 10 so as to be along the front opening edge of the reflector 10. The point is different from the first embodiment. When the length of the reflector 10 is defined as d1 and the distance defined by the rear end edge of the optical filter 11 and the opening edge on the rear end side of the transmission flow path 71 (through hole 86) is defined as d2, d2 ≦ The delivery flow path 71 is formed at a position satisfying the relational expression of d1 / 5. The length dimension (w1) of the through hole 86 in the front-rear direction is set to 5 mm or less.

(Example 5)
FIG. 14 shows Example 5 of the dryer (hair dryer) according to the present invention in which the structure of the reflector 10 is modified. This Example 5 is different from the previous Example 1 in that the entire reflector 10 has a hemispherical shell shape. More specifically, the reflective portion of the reflector 10 is formed in a front-spreading taper shape in which the diameter dimension gradually increases toward the front. A gap E serving as a delivery flow path 71 is formed between the front end of the reflector 10 and the rear end of the optical filter 11.

In each of the above embodiments, the heat ray light source can be configured by an incandescent lamp, a xenon lamp, a metal halide lamp, or the like, in addition to the halogen lamp 4. The touch sensor 12 can be omitted. In that case, a cold air mode in which only the blower fan 3 is driven by switching the power switch 14 and a low temperature weak wind mode in which the blower fan 3 and the heat ray light source 4 are driven at the same time. It is possible to switch to the high temperature strong wind mode, which has a higher temperature and a larger air volume than the weak wind mode. The main body case 1 can be formed into an elliptical tubular shape, a polygonal tubular shape, or the like in addition to the cylindrical shape, and a foldable grip may be provided on the lower surface side of the main body case 1 if necessary. The present invention can be applied not only to humans but also to dryers for animals such as dogs and cats.

1 Main body case 3 Blower fan 4 Heat ray light source (halogen lamp)
7 Wind guide 10 Reflector 11 Optical filter 52 Dry air flow path 70 Suction flow path 71 Outlet flow path 80 Front reflector 81 Rear reflector 84 Slit opening 86 Through hole

Claims (7)

A main body case (1) having a hollow cylindrical air guide portion (7) extending from the suction port (8) on the rear side to the air outlet (9) on the front side.
A blower fan (3) provided in the air guide portion (7) to generate an air flow from the suction port (8) to the air outlet (9).
A heat ray light source (4), which is arranged in front of the blower fan (3) in the air guide portion (7) and emits radiant heat rays including infrared rays,
A reflector (10) arranged on the front side of the heat ray light source (4) in the wind guide portion (7) and guiding the radiant heat rays emitted by the heat ray light source (4) forward.
An optical filter (11) arranged on the front side of the reflector (10) in the wind guide portion (7) to transmit radiant heat rays and attenuate visible light among the light radiated from the front end of the reflector (10). ,
A dry air flow path (52) formed between the outer circumference of the reflector (10) and the inner surface of the main body case (1), and
A waste heat structure for exhausting the heat inside the reflector (10) to the outside,
Equipped with
The exhaust heat structure is formed only at the rear end of the reflector (10), and has a suction flow path (70) that receives a part of the air flow generated by the blower fan (3) inside the reflector (10). It is formed only at the front end of the reflector (10), and is composed of a delivery flow path (71) that sends out the air in the reflector (10) toward the dry air flow path (52).
The pressure in the flow path of the dry air flow path (52) in the formation region of the delivery flow path (71) is smaller than the pressure in the flow path of the dry air flow path (52) in the formation region of the suction flow path (70). A dryer characterized by being configured. The length of the reflector (10) in the front-rear direction defined by the rear end of the optical filter (11) and the rear end of the reflector (10) is defined as d1, and the rear end of the optical filter (11) and the transmission flow path ( 71) When the distance specified by the opening edge on the rear end side is specified as d2,
The dryer according to claim 1, wherein the delivery flow path (71) is formed at a position satisfying the relational expression d2 ≦ d1 / 5. The dryer according to claim 2, wherein the opening length dimension (w1) of the delivery flow path (71) in the front-rear direction is set to 5 mm or less. The invention according to any one of claims 1 to 3, wherein a gap (E) serving as a transmission flow path (71) is formed between the rear end of the optical filter (11) and the front end of the reflector (10). Hairdryer. The reflector (10) is composed of a front reflector (80) on the front side and a rear reflector (81) on the rear side.
The dryer according to any one of claims 1 to 3, wherein a gap (E) serving as a transmission flow path (71) is formed between the front and rear reflectors (80, 81). The delivery flow path (71) is formed as a circular slit opening (84) opened over the entire circumference of the peripheral wall constituting the reflector (10) so as to be along the front opening edge of the reflector (10). The dryer according to any one of claims 1 to 3. A group of a large number of through holes (86) arranged in a row over the entire circumference of the peripheral wall constituting the reflector (10) so that the delivery flow path (71) is along the front opening edge of the reflector (10). The dryer according to any one of claims 1 to 3, which is composed of the above.

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