WO2016072031A1

WO2016072031A1 - Dryer

Info

Publication number: WO2016072031A1
Application number: PCT/JP2014/079643
Authority: WO
Inventors: ▲琢▼磨仁衡; 池田　伸一; 大輔 ▲高▼木
Original assignee: 株式会社イデア
Priority date: 2014-11-07
Filing date: 2014-11-07
Publication date: 2016-05-12

Abstract

In this dryer (1), light emitted from a hot wire light source (11) is reflected from the inner walls of a reflector (13) comprising a first reflecting part (131) having a cross section of parabolic shape and a second reflecting part (132) of cylindrical shape, and is irradiated towards a heating direction (P direction). From the back of the hot wire light source (11), a fan (19) blows air towards the hot wire light source (11) and the reflector (13), whereby the air is heated around the hot wire light source (11) and the reflector (13). The heated air is discharged towards the P direction through a venting space between the housing (17) and the outer wall of the reflector (13).

Description

Hairdryer

The present invention relates to a dryer using radiant heating.

The dryer used for drying hair or the like is generally a hot air heating type in which air heated by a heater made of nichrome wire or the like is blown out by a blower fan. In recent years, many hair dryers have high power, and some have power consumption exceeding 1000 W.

In order to increase the thermal efficiency of such a dryer with respect to the heating object, a configuration combining a hot air heating method and a radiant heating method has been proposed (for example, Patent Document 1).

In the hair dryer described in Patent Document 1, a hot air heat source part and a radiant heat source part are arranged in order toward the downstream side of the air flow generated by the air blowing part. Explains that air heated by the heat source for hot air is blown out, and radiant heat rays are emitted from the radiant heat source and the reflecting mirror, so that the hair can be dried in a short time and power can be saved. ing.

JP 2005-177234 A

Since the hair dryer described in Patent Document 1 includes a radiant heat source unit and a reflection mirror near the opening of the hair dryer, there is a risk that strong light is irradiated from the vicinity of the object to be heated and the eyes of the user are damaged. there were. A filter is often used to block such strong visible light. However, since this hair dryer is configured to blow air in the radial direction of the radiant heat source, it is impossible to insert such a filter or the like.

Also, since power is supplied to both the hot air heat source section and the radiant heat source section, the power consumption can only be reduced slightly compared to the configuration of the hot air heat source section alone. In addition, since the number of parts is large, there is a problem that the manufacturing cost is increased as compared with the conventional configuration.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a dryer that can reduce power consumption, increase safety, and reduce manufacturing costs.

In order to achieve the above object, the dryer according to the first aspect of the present invention comprises:
A heat ray light source;
A reflector provided on the inner wall with a reflection surface that reflects at least part of the light emitted by the heat-ray source in the heating direction from the heat-source to the object to be heated;
A housing that supports the outer wall of the reflector in a state having a ventilation space between the outer wall of the reflector,
A fan that is provided behind the heat ray light source with respect to the heating direction and sends air toward the heating direction;
It is characterized by providing.

The reflector may include a plurality of through holes.

The heat ray light source may be any one of a halogen lamp, an incandescent lamp, a xenon lamp, and a metal halide lamp.

A filter that transmits the infrared light of the heat ray light source and attenuates the visible light may be further provided at the end of the reflector that is closer to the heating target.

The reflector may include a first reflecting portion having a shape in which a cross section in a plane extending in the heating direction is a parabola, or a side surface of a truncated cone having a central axis in the heating direction.

The reflector may further include a second reflecting portion that is continuous with the first reflecting portion and includes a side surface of a cylinder or a truncated cone having a central axis in the heating direction.

A control unit for controlling power supply to the heat ray light source and the fan;
The control unit may stop the power supply to the fan after a predetermined time has elapsed from the stop of the power supply to the heat ray light source.

The power source of the heat ray light source and the fan may be a power storage device.

According to the present invention, it is possible to reduce power consumption, increase safety, and reduce manufacturing costs.

It is a side view of the dryer concerning an embodiment. It is a side view of the dryer seen from the front of P direction of Drawing 1A. It is a side view of the dryer seen from the back of P direction of Drawing 1A. It is sectional drawing of the dryer which concerns on embodiment. It is a side view of a reflector. It is the side view of the reflector seen from the front of the P direction of FIG. 3A. It is the side view of the reflector seen from the back of the P direction of Drawing 3A. It is a perspective view of a reflector. It is a side view of the reflector which attached | subjected the filter. It is the side view of the reflector which attached | subjected the filter seen from the front of the P direction of FIG. 3A. It is the side view of the reflector which attached | subjected the filter seen from the back of the P direction of FIG. 3A. It is a perspective view of the reflector which attached | subjected the filter. It is an internal block diagram of a dryer. It is the figure which showed the mode of reflection of light. It is the figure which showed the mode of the airflow. It is sectional drawing of the dryer which concerns on other embodiment. It is sectional drawing of the dryer which concerns on other embodiment.

(Embodiment)
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

The dryer 1 which concerns on this embodiment is a dryer which dries a heating object by irradiating a heating object, such as hair, by releasing a warm air and irradiating a heat ray (light). As shown in FIGS. 1A to 1C, the dryer 1 includes a substantially cylindrical main body 10 and a cylindrical handle 20 extending downward from the main body 10. In the heating direction (P direction) toward the heating target, air is sucked from the rear, hot air is discharged forward, and heat rays are irradiated. The object to be heated is disposed in front of the P direction.

As shown in FIG. 2, the main body 10 includes a heat source 11 and a reflector 13 provided on the inner wall with a reflection surface that reflects light emitted from the heat source 11 and directs it in the P direction. A filter 15 that transmits only thermal linear infrared light out of the light emitted from the thermal linear light source 11, a housing 17 that supports the outer wall of the reflector 13, and a fan 19 are provided. Here, FIG. 2 is a sectional view of the dryer 1 in the plane indicated by aa in FIGS. 1B and 1C.

As shown in FIG. 2, the handle portion 20 includes a power source 21 and a control board 23 that controls power supply from the power source 21 to the heat-linear light source 11 and the fan 19. Further, a switch 25 is provided on the side surface of the gripper 20 to turn on / off the power source or switch the output power.

The heat ray light source 11 includes, for example, a halogen lamp, an incandescent lamp, a xenon lamp, a metal halide lamp, or the like. A fixture 111 including a power supply socket for the heat ray light source 11 is fixed to the housing 17.

The reflector 13 is formed by processing a material that reflects light, such as aluminum, and includes a first reflecting portion 131 and a second reflecting portion 132 that are continuous with each other about the same straight line h. The The first reflecting portion 131 has a shape in which a cross section in a plane passing through the straight line h is a parabola. The second reflecting portion 132 has a cylindrical side surface shape with the straight line h as the central axis.

The reflector 13 is fixed to the housing 17 in a state in which the heat ray light source 11 is disposed at a position close to the first reflector 131. At this time, the center point where the filament of the heat ray light source 11 is located is arranged on the straight line h which is the center axis of the reflector 13. Further, the reflector 13 aligns the straight line h of the central axis with the heating direction (P direction). That is, the first reflecting portion 131 has a shape in which a cross section in a plane extending in the P direction is a parabola, and the second reflecting portion 132 is a cylinder that is continuous with the first reflecting portion 131 and has a central axis in the P direction. From the side.

The positional relationship between the heat ray light source 11 and the reflector 13 will be described in more detail. The heat ray light source 11 is located at the focal point of a parabola having a cross-sectional shape of the first reflecting portion 131. That is, when the P direction on the straight line h is + y, and the coordinates (x, y) of the parabola of the cross-sectional shape of the first reflecting portion 131 are expressed by the following expression (1), the coordinates of the center of the heat linear light source 11 are (0, 1 / 4a).

Y = a · x ^ 2 (1)

The second reflecting portion 132 is provided with a plurality of through holes 133 as shown in FIGS. 3A and 3D. The through hole 133 is for inflowing and outflowing air between the inside and the outside of the reflector 13. The size of the through hole 133 is determined so as to have an optimum inner diameter in consideration of the amount of reflected light and the amount of air flowing in and out.

The reflector 13 has a circular opening q as shown in FIG. 3B when viewed from the front in the P direction. The inner diameter of the opening q is the same as the inner diameter of the cylinder of the second reflecting portion 132. On the other hand, when viewed from the rear in the P direction, it has a circular opening s as shown in FIG. 3C. The inner diameter of the opening s is set so that the socket of the heat ray light source 11 can pass and the opening q does not come into contact with the socket when fixed to the housing 17.

The filter 15 blocks visible light out of light emitted from the heat ray light source 11 and transmits heat ray infrared light. As shown in FIGS. 4A to 4D, the filter 15 is provided so as to close the opening q of the reflector 13.

The casing 17 of the main body 10 surrounds the outer periphery of the reflector 13 and supports the outer wall of the reflector 13 with a ventilation space between the outer wall of the reflector 13. More specifically, a plurality of supporting protrusions 171 are provided on the outer wall of the reflector 13, and the protrusions 171 are fixed inside the casing 17 of the main body 10.

The fan 19 is arranged behind the heat ray light source 11 in the P direction. A vent 172 covered with a net is provided at the rear end of the housing 17. The fan 19 rotates to suck air from the vent 172 and blow air toward the heat ray light source 11 and the reflector 13.

The front end of the housing 17 is provided with a nozzle 173 fitted to the end. The nozzle 173 has a shape in which the opening located on the opposite side of the fitting portion with the housing 17 is smaller than the fitting portion. The nozzle 173 makes it difficult for the user to touch the reflector 13 and the filter 15 that are at a high temperature, and can reduce the hot air discharge area and increase the strength of the hot air.

A power supply 21 is provided at the lower part of the grip 20. In the present embodiment, the power source 21 is a power storage device including a capacitor or a storage battery, and may be a device that can be repeatedly charged. When a conventional heater made of nichrome wire or the like is used, it is necessary to supply power of about 1000 W, and thus a power source is obtained from an AC (Alternating Current) outlet. In this embodiment, a hot wire of 50 to 500 W is used. Since the luminescent light source 11 is used, power can be supplied from various power storage devices.

When the power source 21 is a chargeable power storage device, the power source 21 is connected to a charging terminal exposed to the outside of the housing 17 of the gripping unit 20 and stored by a charger externally connected to the charging terminal. It is stored in the device. In addition, since the power supply 21 which is an electrical storage device supplies direct current (DC) power, the fan 19 is a DC fan.

A control board 23 is provided above the power supply 21 of the grip portion 21. As shown in FIG. 5, the control board 23 is connected to the heat ray light source 11, the fan 19, the power source 21, and the switch 25.

The control board 23 includes a power control unit 231 and a timer 232. The switch 25 switches between warm air output, cold air output, and OFF according to the operation of the operator. For the warm air output, the output power may be switched stepwise.

When the operator sets the switch 25 to the cold air output, the power control unit 231 supplies power from the power source 21 only to the fan 19. Thereafter, when the operator sets the switch 25 to OFF, the power control unit 231 stops the power supply.

When the operator sets the switch 25 to the warm air output, the power control unit 231 supplies power from the power source 21 to the hot-wire light source 11 and the fan 19. When the output power can be switched in a stepwise manner, power corresponding to the setting of the switch 25 is supplied. Thereafter, when the operator sets the switch 25 to OFF, first, the power supply to the heat ray light source 11 is stopped, and at the same time, the timer 232 is started. When the timer 232 indicates that a predetermined time has elapsed, the power control unit 231 stops the power supply to the fan 19. Thereby, after stopping the heat ray light source 11, the residual heat of the heat ray light source 11 or the reflecting plate 13 can be released to the outside of the housing 17 by air blown from the fan 19 and cooled.

The operation of the dryer 1 configured as described above will be described with reference to FIGS. 6 and 7 are cross-sectional views of the main body 10 viewed from the opposite side of the gripping part 20, that is, from above.

When the operator sets the switch 25 to the warm air output, power is supplied to the thermal linear light source 11 and the fan 19, the thermal linear light source 11 emits light, and the fan 19 blows air toward the thermal linear light source 11 and the reflector 13. To do.

The light from the heat ray light source 11 is emitted in all directions except the socket portion of the heat ray light source 11. The emitted light is reflected by the first reflecting part 131 and the second reflecting part 132 of the reflector 13 and travels in the heating direction (P direction). Of the light reaching the filter 17, the heat-ray infrared light is transmitted in the P direction, but other visible light is attenuated by the filter 17.

That is, in the P direction, only heat-ray infrared light is emitted in front of the filter 17, so that the infrared light is irradiated onto the object to be heated and the object to be heated can be heated.

When the light of the heat ray light source 11 is reflected by the inner wall of the reflector 13, the reflector 131 is also heated and the temperature rises. Further, the temperature of the heat ray light source 11 itself rises due to light emission. The temperature of the surrounding air also rises due to the heat of the heat ray light source 11 and the reflector 13.

Here, the fan 19 blows air toward the heat ray light source 11 and the reflector 13, and air flows inside and outside the reflector 13 as shown in FIG. Air from the fan 19 behind the heat ray light source 11 flows into the reflector 13 through the opening s of the first reflecting portion 131. The air that has flowed into the reflector 13 is heated by the heat of the heat source 11 and the inner wall of the reflector 13, and then flows out of the reflector 13 through the through hole 133 of the second reflector 132.

The air that has not flowed from the fan 19 into the opening s of the first reflecting portion 131 passes through the ventilation space between the outer periphery of the reflector 13 and the housing 17. At this time, air is heated by the heat of the reflector 13, and the temperature of the air rises. The air whose temperature has risen flows out from the nozzle 173 in the P direction. That is, the warm air flows out in the P direction.

In this way, by simultaneously driving the heat ray light source 11 and the fan 19, heat rays are radiated from the filter 17 and hot air is emitted from the outer periphery of the filter 17. The heat ray light source 11 consumes less power than a nichrome wire or the like, and the heat of the heat ray light source 11 and the reflector 13 is also output as warm air by the fan 19. For this reason, the thermal efficiency is dramatically improved as compared with the conventional configuration.

Here, since the conventional dryer was equipped with a hot light source at the hot air discharge location, it could not be inserted because the hot air was blocked when the filter was inserted. However, since the dryer 1 of the present embodiment emits heat rays from the inside of the reflector 13 and emits warm air from the outside, the visible light can be blocked by the filter 15 without blocking the discharge of warm air. As a result, the user does not hurt his eyes and is highly safe.

As described above, in the present embodiment, the dryer 1 reflects the light emitted from the heat ray light source 11 by the first reflecting portion 131 having a parabolic cross section and the second reflecting portion 132 having a cylindrical shape. The light was reflected from the inner wall of the body 13 and irradiated in the heating direction (P direction). In addition, the fan 19 blows air toward the heat ray light source 11 and the reflector 13 from the rear of the heat ray light source 11, thereby releasing the air heated around the heat ray light source 11 and the reflector 13 in the P direction. It was decided. Thereby, the power consumption of the dryer 1 can be reduced, safety can be increased, and the manufacturing cost can be reduced.

As described above, according to the present invention, at least a part of the light emitted from the heat ray light source is reflected in the heating direction toward the heating target by the reflector having the reflection surface on the inner wall, and the fan provided behind the heat ray light source. Sends air in the heating direction, warms the air by passing it around the heat source and the ventilation space between the outer wall of the reflector and the housing, and releases it in the heating direction. . As a result, the power consumption of the dryer can be reduced, the safety can be increased, and the manufacturing cost can be reduced.

The present invention is capable of various embodiments and modifications without departing from the broad spirit and scope of the present invention. The above-described embodiments are for explaining the present invention and do not limit the scope of the present invention. That is, the scope of the present invention is shown not by the embodiments but by the claims. Various modifications within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

For example, in the said embodiment, although the 1st reflection part 131 of the reflector 13 was made into the shape of a parabola in cross section, it is the shape which reflects at least one part of the light of the heat ray light source 11 to a heating direction (P direction). Other shapes are possible as long as they are present. For example, the cross section may have a semicircular arc shape. Or as shown in FIG. 8, the shape of the side surface of the truncated cone which the 1st reflection part 231 of the dryer 2 has a central axis in a heating direction may be sufficient.

Moreover, although the 2nd reflection part 132 of the reflector 13 was made into the shape of the side surface of the cylinder which has a central axis in a heating direction, the shape which reflects at least one part of the light of the heat ray light source 11 to a heating direction (P direction). Any other shape may be used. For example, as illustrated in FIG. 9, the second reflecting portion 332 of the dryer 3 may have a shape of a side surface of a truncated cone having a central axis in the heating direction.

Further, although the dryer 1 is composed of the main body 10 and the grip 20, other forms may be used. For example, a configuration including only the main body 10 may include a power supply 21 and a control board 23 in the main body 10. In the case of a configuration composed of only the substantially cylindrical main body 10, the dryer closer to the fan 19 can be gripped and used.

Although the power source 21 is composed of a power storage device, a power cable is provided instead of the power storage device, AC power is obtained from the AC outlet via the power cable, and AC power is supplied to the thermal linear light source 11 and the fan 19. You may do it. In this case, the fan 19 is an AC fan driven by an AC power source.

DESCRIPTION OF

SYMBOLS

1, 2, 3 ... Dryer 10 ... Main part 11 ... Heat ray light source 111 ... Fixing tool 13 ... Reflector 131,331 ... 1st reflection part 132,232 ... 2nd reflection part 133 ... Through-hole 15 ... Filter 17 ... Housing Body 171 ... Protrusion 172 ... Vent 173 ... Nozzle 19 ... Fan 20 ... Grasping part 21 ... Power supply 23 ... Control board 231 ... Power supply control part 232 ... Timer 25 ... Switch

Claims

A heat ray light source;
A reflector provided on the inner wall with a reflection surface that reflects at least part of the light emitted by the heat-ray source in the heating direction from the heat-source to the object to be heated;
A housing that supports the outer wall of the reflector in a state having a ventilation space between the outer wall of the reflector,
A fan that is provided behind the heat ray light source with respect to the heating direction and sends air toward the heating direction;
Equipped with a dryer.
The reflector includes a plurality of through holes.
The dryer according to claim 1.
The heat ray light source is any one of a halogen lamp, an incandescent lamp, a xenon lamp, and a metal halide lamp.
The dryer according to claim 1 or 2.
A filter that transmits the infrared light of the heat ray light source and attenuates the visible light at the end of the reflector closer to the heating target;
The dryer according to any one of claims 1 to 3.
The reflector includes a first reflector formed of a shape in which a cross section in a plane extending in the heating direction is a parabola, or a side surface of a truncated cone having a central axis in the heating direction.
The dryer according to any one of claims 1 to 4.
The reflector further includes a second reflecting portion that is continuous with the first reflecting portion and includes a side surface of a cylinder or a truncated cone having a central axis in the heating direction.
The dryer according to claim 5.
A control unit for controlling power supply to the heat ray light source and the fan, and
The control unit stops the power supply to the fan after a predetermined time has elapsed from the stop of the power supply to the thermal linear light source,
The dryer according to any one of claims 1 to 6.
The power source of the heat ray light source and the fan is a power storage device.
The dryer according to any one of claims 1 to 7.
An opening that is fitted to a front end portion in the heating direction of the housing and is positioned opposite to the fitting portion with the housing;
The dryer according to any one of claims 1 to 8.