JP3154490U - Dryer equipment - Google Patents

Abstract

The present invention provides an apparatus capable of heat drying from outside by irradiation of infrared rays by a dryer apparatus and uniform drying of hair by blowing and inhaling air. An infrared heater unit having a filament that emits infrared rays having a spectral radiance peak in a wavelength band of 2 μm to 4 μm, and a blower unit that blows air. And an intake part that performs intake, the infrared heater part, a radiant air blowing mechanism 2 provided with the air blowing part, an infrared heater part, and a radiant intake mechanism 3 provided with the air intake part, Configure the dryer unit. [Selection] Figure 1

Description

  The present invention relates to a dryer device used in various treatments such as permanent wave, drying, and hair dyeing in a beauty salon or a barber shop.

  Conventionally, large hair dryers used in hairdressing salons and barbers are equipped with a head that incorporates a heater and a blower in a stand, or multiple heads that incorporate multiple heaters and a blower. It has been known.

  Some conventional permanent wave devices use an electric heating rod. After the hair coated with the wave agent is wound around the electric heating rod, the electric heating rod generates heat to deform the hair.

  When a hair dryer is used to dry the hair, a heater is intensively applied to a part of the head, and it is difficult to uniformly dry the entire hair. In addition, even if the head of the hair dryer device is movable, even if the heat of the heater can be applied to the entire hair, it only heats the outer surface of the hair and does not heat and dry the interior close to the scalp. It was. An apparatus for drying hair and reducing damage by spraying mist for the purpose of reducing damage to the hair as well as simply drying is also disclosed.

  In addition, in a permanent wave device using an electric heating rod, a hair agent is applied and the hair is wound around the electric heating rod, so that the hair contacting or close to the surface of the electric heating rod is heated, but is wound around the outer hair. However, the heat of the electric heating rod was not sufficiently transmitted, and it was difficult to heat the hair uniformly. Furthermore, if the heating temperature of the electric heating rod is increased to transfer heat to the outer hair that is wrapped around, the high temperature is transmitted to the scalp, which may cause discomfort to those undergoing treatment, in addition to damage to the hair. Giving was also a problem.

JP 2001-314225 A JP-A-2005-279240

However, when the hair is dried from the outside using a hair dryer device, the surface of the entire hair is dried by the combination of heat drying by heating irradiation and drying by air blowing, and the hair from the inside of the entire hair including the vicinity of the scalp. Was not intended to dry.
In addition, even when drying using an electric heating rod, it is desirable that the heating temperature is optimum even in consideration of the treatment time and the heating temperature necessary to exhibit the original permanent wave deformation effect. Also, in order to reduce the treatment time and the man-hours of the practitioner, and to reduce the load that the treatment subject receives for a long time, etc., heat drying that sufficiently exhibits the wave effect, or easy drying There is a demand for a dryer device that achieves this.

  The present invention solves the above-mentioned problems, and can effectively dry the hair in a short time, and can reduce the damage caused by the heat applied to the hair to uniformly dry the entire hair. An object of the present invention is to provide a dryer device that can be used.

  In order to achieve the above object, the present invention is a stand-type dryer apparatus used for drying hair, and an infrared radiation unit having a filament that emits infrared light having a spectral radiance peak in a wavelength band of 2 μm to 4 μm. A blowing section that blows air, an intake section that performs intake, the infrared radiation section, a radiation blowing mechanism that is provided with the ventilation section, a radiation suction mechanism that is provided with the infrared radiation section, and the suction section. It is characterized by having.

  In the present invention, the radiant blower operates the infrared radiating unit and the blower unit simultaneously or in any combination. The radiant intake unit includes the infrared radiant unit and the intake air simultaneously or in any combination. The part is actuated.

  In the present invention, the radiation blowing mechanism is provided in an arrangement in which the infrared emission surface related to the infrared radiation portion and the wind emission surface related to the blower portion do not overlap. The infrared emission surface and the wind intake surface related to the intake portion are provided in an arrangement so as not to overlap with each other.

The present invention provides the radiant air blowing mechanism in which the infrared radiating portion is arranged in parallel, and the radiating air intake mechanism is arranged in parallel with the radiating portion between the infrared radiating portions. It is provided, and an intake part is provided in parallel between the infrared radiation parts.

  The present invention is characterized in that the radiant intake mechanism is provided at the top of a dryer device, and the radiant air blowing mechanism is provided at an upper front part, both side parts, and a middle stage part.

  The present invention is characterized in that the filament is a vegetable carbon fiber.

  A curler including a heating element inside is provided at the ends of the plurality of extended cords.

A connection port is formed at the ends of the plurality of extended cords, and a curler including a heating element is connected to the connection port.
It is characterized by that.

  The present invention is characterized in that the cord and the curler are suspended from the top of the dryer device.

  In the present invention, the radiation blower mechanism, the radiation intake mechanism, and the curler operate the infrared radiation unit, the blower unit, the intake unit, and the curler simultaneously or in any combination. It is characterized by that.

  According to the dryer device of the present invention, the heating temperature by the infrared heater or the heat transfer temperature by the curler can be easily controlled to 60 ° C. or less, and the penetration of the permanent wave agent can be sufficiently promoted. Therefore, it is possible to reduce the damage to the hair due to heat, to deform the hair, and to stabilize the shape of the hair due to drying.

In addition, the head of the person to be treated by the dryer device can be efficiently heated with respect to the hair containing a lot of moisture by irradiating infrared rays of the growing light wavelength from the outside, so that the entire hair can be uniformly dried. The drying time can be shortened as compared with the drying process in which the surface is simply heated.

  By having the heating air blowing mechanism and the heating air intake mechanism, the convection heating and the radiant heating can be simultaneously performed on the hair, thereby shortening the drying time. In addition, when using curlers, in addition to convection heating and radiation heating for the hair, heat transfer heating can be performed at the same time, so heat is also transferred to the hair near the scalp and the entire hair can be dried evenly. Can be shortened.

The front view of the device concerning one embodiment of the present invention. The rear view of the device concerning one embodiment of the present invention. The side view of the device concerning one embodiment of the present invention. Unit unit according to one embodiment of the present invention Example of use of apparatus according to one embodiment of the present invention The perspective view of the device concerning one embodiment of the present invention. The front view of the device concerning one embodiment of the present invention. Example of use of apparatus according to one embodiment of the present invention The figure showing the relation between the radiation light and water absorption spectrum concerning this invention

Hereinafter, an embodiment according to the present invention will be described with reference to FIGS.
1 to 3 are a front view, a rear view, and a side view of the dryer device 1 according to the present invention.
The dryer apparatus 1 has a plurality of unit portions as shown in FIG.
The unit portion is provided with a heater portion 4 that radiates infrared rays and a blower 6 that blows air to the irradiation surface. The unit part in this case is referred to as a radiation blower mechanism 2.
Moreover, as another unit part, the heater part 4 which radiates | emits infrared rays, and the intake device 7 which inhales from an irradiation surface are provided side by side. The unit part in this case is referred to as a radiation intake mechanism 3.
Moreover, as illustrated in FIGS. 1 to 3, in the present embodiment, one radiation intake mechanism 3 is provided at the top of the dryer device 1, and four radiation blowing mechanisms 2 are provided at the upper front portion, the middle step portion, and both side portions. It has the composition which has.

A base 23 provided with casters 25 is formed in a substantially U shape at the lower part of the dryer device 1, a shaft base plate 24 is provided, and a support cylinder 21 is provided at the center of gravity. The support tube 21 extends in the vertical direction. The upper end of the support cylinder 21 is open, and a fixing portion 22 is provided near the upper end. The support column 20 is inserted into the opening of the support tube 21. By rotating and fastening the fixing portion 22, a part of the fixing portion 22 presses and fixes the support column 20. Thereby, the support | pillar 20 can be moved up and down and the vertical height can be adjusted. It is possible to adjust the vertical height of each mechanism at the upper part of the support column 20 described later.

As shown in FIG. 2, the rod 20 is integrally formed with a cage 16 and a frame. An operation box 18 including an operation panel for operating the dryer device 1 is installed on the frame. From the operation box 18, a cord 17 for energizing each radiation blower mechanism 2 and the radiation intake mechanism 3 is extended. For example, the cord 17 can be extended from the operation box 18 to an opening formed in a predetermined portion of the arm shaft 15, inserted into the opening portion, and connected to the radiation blower mechanisms 2 on both sides through the inside of the arm shaft 15.

In addition, the pillars 16 integrally formed with the support column 20 and the frame are formed on both sides in the horizontal direction. Both ends of the cage tube 16 are formed in openings, and the arm shaft 15 can be fixed by inserting the arm shaft 15. The cage tube 16 extends in the horizontal direction. The arm shaft 15 is bent in a substantially L shape. A substantially rectangular annular arm 14 is provided in the distal direction of the arm shaft 14 opposite to the direction of the cylinder 16. The distance between the arms 14 installed on both sides of the dryer device 1 can be adjusted according to the length of the arm shaft 15 to be inserted. The horizontal position of the arm 14 and the connected heated air blowing mechanism 2 can be adjusted. In addition, since the arm shaft 15 is bent, the elevation angle of the arm 14 at the distal end portion can be adjusted by fixing the arm shaft 15.

The fixing portion 13 can be slid or fixed with the arm 14 having a substantially rectangular ring shape as a movable range. By fixing the fixing portion 13, the position on the arm 14 of the radiation blower mechanism 2 to be connected can be adjusted.
Furthermore, the fixed portion 13 has a structure that allows the radiant air blowing mechanism 2 to be coupled to be rotatable while being fixed to the arm 14. For example, as shown in FIG. 2, the radiation blower mechanism 2 can be fixed so that the arm 14, the infrared heater unit 4, and the blower 4 are parallel to each other. On the other hand, as shown in FIG. 3, it can fix so that the arm 14 and the radiation ventilation mechanism 2 may become non-parallel.

As shown in FIG. 3, the support shaft 19 provided in the upper part of the dryer apparatus 1 extends in the vertical direction, is bent at an obtuse angle, and extends forward from the top.
The radiation blower mechanism 4 is fixed to the tip portion of the support shaft 19. Further, near the top of the dryer device 1, the radiation intake mechanism 3 is fixed to the support shaft 19 by a fixing portion 13. Further, as shown in FIG. 2, the radiation blower mechanism 2 is fixed to the proximal end portion of the support shaft 19 at a height at which the operation box 18 is positioned.

FIG. 4 shows the discharge surface of the unit portion.
As described above, the unit section includes the radiation blower mechanism 2 and the radiation intake mechanism 3. The radiation blower mechanism 2 includes an infrared heater unit 4 that radiates infrared rays and a blower 6 that blows air to the irradiation surface. On the other hand, the radiation intake mechanism 3 is provided with an infrared heater unit 4 that radiates infrared rays and an intake device 7 that intakes air from an irradiation surface.
As shown in FIG. 4, the infrared heater part 4 is arranged in parallel in the unit part. Further, a fan 5 is provided in parallel with the infrared heater unit 4 and is interposed.
In addition, if the fan 5 is a blower 6 having a structure that blows air to the irradiation surface, the unit portion becomes the radiation blower mechanism 2. On the other hand, in the case of the intake device 7 having a structure in which intake is performed from the irradiation surface, the unit portion is the radiation intake mechanism 3.

The infrared heater unit 4 includes a filament 8, a heater tube, and a reflection plate 9.
A filament 8 is inserted into the inside of the cylindrical heater tube, and conductive wires are connected to the periphery of both ends of the filament 8 so as to be energized. The cord 17 is energized through the power source, and the heater tube of the infrared heater unit 4 is energized. At this time, the filament 8 is energized and emits infrared rays.
A substantially arc-shaped reflecting plate 9 is formed on the back surface of the heater tube with respect to the emission surface. The reflector 9 reflects infrared rays. The infrared light emitted from the filament 8 is reflected by the reflecting plate 9 toward the emission surface. Thereby, from the emission surface, the infrared ray directly radiated from the filament 8 and the infrared ray reflected by the reflecting plate 9 are concentrated and radiated to the irradiation surface.
In addition, the material which comprises the reflecting plate 9 is not limited, What is necessary is just to be comprised with the substance which can reflect efficiently, without absorbing infrared rays. The shape of the exemplified reflector 9 is a shape similar to a substantially semicircular cylindrical side surface, but is not limited to this and may be any shape that allows efficient reflection.
The emission surface of the infrared heater unit 4 may be a flat surface or a curved surface. When the emission surface is a curved surface, the shape of the reflecting plate 9 may be curved along the curved surface.

The filament 8 emits infrared rays when energized. In particular, it is desirable as a filament emitting infrared rays having a peak wavelength of spectral radiance in a wavelength band of 2 μm to 4 μm. The filament 8 can emit infrared rays having a high spectral radiance in the 3 μm peripheral band where the absorption wavelength of water peaks.
The material of the filament 8 includes a carbon material filament. Among these, vegetable carbon fiber is desirable as a material.
For example, the use of vegetable carbon fiber called cotton, which is carbonized from cotton, using cotton as a raw material. Or the material itself of the filament 8 is not restricted to vegetable carbon fiber, The filament which coated the surface of the filament with vegetable carbon fiber, or a heater pipe | tube may be sufficient.
Here, the filament of carbon material is illustrated, but any filament that can emit infrared rays having high spectral radiance in the water absorption wavelength band may be used.

The wavelength band of light emitted by the filament using the plant carbon fiber is a wavelength band overlapping with the wavelength band in which water absorbs light. By radiating light in a wavelength band with a high water absorption rate, the interatomic motion of irradiated and absorbed water molecules becomes active, and heat energy is easily emitted. Therefore, the irradiation target can be efficiently heated with respect to the irradiation amount. It becomes efficient to generate vibration and heat of water molecules by emitting the growing light.
The table illustrated in FIG. 9 will be described.
The horizontal axis represents wavelength (μm), and the vertical axis represents spectral radiance (w / sr / m ² / nm) and water absorption rate (%). The solid curve represents the relationship between the wavelength of the radiant light and the spectral radiance, and the broken curve represents the relationship between the water absorption spectrum and the water absorption rate.
The example illustrated in FIG. 9 is an example and is not intended to limit the numerical values. It suffices if light in the wavelength band can be radiated in a wavelength region having a high water absorption rate.

Moreover, in the dryer apparatus 1, the infrared heater part 4 adjoins to a to-be-treated person's head. By using vegetable carbon fiber for the filament 8, the infrared heater portion 4 having the property that the color temperature of the heater tube is lower than that of a halogen heater that similarly emits infrared rays. Since the color temperature is low, the luminance is weak, and since the filament 8 emits light of a color closer to white than red, the effect of not applying a load to the eyeball of the patient is also achieved.
Furthermore, by using plant carbon fiber for the filament 8, radiation is started in a short time with high electrical conductivity and high energization time. For example, the amount of heat required for the same object to be heated exhibits the same effect with a small amount of current compared to a normal heater due to the conductivity of the vegetable carbon fiber and the characteristics of the wavelength band of the radiating infrared rays. It is. Further, it becomes easy to keep the temperature of the filament constant.

The fan 5 illustrated in FIG. 4 is exemplified as the blower 6 that blows air to the irradiation surface. However, FIG. 4 exemplifies the heated air blowing mechanism 2. If it is the heated air intake mechanism 3, the intake device that is the fan 5 that performs intake from the irradiation surface and intake toward the opposite surface to the infrared irradiation surface. 7 That is, the structure of the unit as a housing may be the same. It is good also as a structure from which ventilation differs from intake by the difference in the rotation direction of the wing | blade structure contained in the fan 5. FIG.
Here, the driving structure of the fan 5 can be provided with a motor capable of quietness and vibration, such as a flat brushless motor and a linear motor, so that a thin casing can be obtained.
The wing structure that is a rotating body of the fan 5 has a wing structure that generates wind blown to the irradiation surface in the case of the blower 6, and has a wing structure that sucks air from the irradiation surface in the case of the intake device 7. Here, the number of the fans 5 is two, and they are arranged in parallel with each infrared heater unit 4 at a position between the infrared heater units 4. Further, the fan 5 has an open structure on the back surface as well as the irradiation surface, and has a structure that allows ventilation.
Moreover, the rotational speed of the wing | blade structure which concerns on the fan 5 can be the rotational speed which generate | occur | produces the ventilation | gas_flowing of the grade which a patient does not feel wind pressure. Needless to say, the operator can control the increase or decrease of the blowing force or the suction force by the operator using the operation panel.
Furthermore, instead of a conventional structure in which warm air is blown using the heat generated by the heater tube, the present invention is arranged so that the emission surface of the infrared heater section 4 and the emission surface of the fan 5 do not overlap. For this reason, the infrared rays emitted from the filament 8 of the heater tube are all reflected by the reflecting surface of the reflecting plate 9. A part of the reflecting surface is not overlapped and a fan is not provided. Thereby, infrared rays can be radiated from the emission surface more efficiently than when the heater tube is arranged on the emission surface to be blown.

FIG. 5 shows an example of use of the dryer device 1.
For example, it is a case where the radiation ventilation mechanism 2 comprised on both sides is adjusted to the height of the side of the person to be treated to dry the hair.
The dryer device 1 does not cover the head of the patient and has a releasable structure. A plurality of radiation blowing mechanisms 2 are arranged so as to surround the head of the patient, and the radiation intake mechanism 3 provided at the top can inhale and efficiently inhale humid air.
Accordingly, infrared irradiation, air blowing, and inhalation are performed on the hair of the subject, and the hair can be dried in a short time by convection heating, radiation heating, and inhalation.
In this case, the temperature of the filament or the heater tube including the filament is 300 ° C. or less. Since the filament 8 is a vegetable carbon fiber, the temperature stability is high, and it is easy to maintain a constant temperature. For this reason, it becomes easy to keep the irradiation surface at a constant low temperature by radiating infrared rays from the radiation blowing mechanism 2 and the radiation intake mechanism 3.
For example, the environmental temperature can be maintained at 32 ° C. The ambient temperature is low and can be kept in the range of 30-35 ° C. The temperature is lower than general human body temperature.
Moreover, the effective drying with respect to hair is enabled by irradiating at the temperature of 35 degrees C or less. In addition, according to the present embodiment, the hair drying time can be shortened even when irradiated at a lower temperature than in the prior art. Furthermore, since the temperature is 35 ° C. or lower and lower than the conventional temperature, the effect of reducing damage to the hair by heat is also achieved.
The low temperature range does not mean that the environmental temperature varies with the same radiant heat. The variation range depends on the range in which the radiant heat is adjusted by adjusting the power supplied to each radiation mechanism. Therefore, the ambient temperature is maintained at a constant low temperature with respect to the radiant heat having a fixed intensity.

(Example 2)
Next, a description will be given of an embodiment of the present invention with reference to FIGS. The same configuration as that of the first embodiment will be omitted, and the added configuration will be mainly described.
In the second embodiment, for example, when a permanent wave is applied to a person to be treated, a curler for shaping the shape of the hair is used. When drying the hair, there is a part of the hair that cannot be sufficiently irradiated with infrared rays by wrapping it around the curler, so heat is transferred from the curler and promotes uniform drying even from inside the wrapped hair. .

From the operation box 18, in addition to a plurality of cords 17 that extend to the radiation blower mechanism 2 and the radiation intake mechanism 3, a cord extends toward the concentration box 32. The collecting box 32 is for connecting the cords extended from the operation box 18 and for connecting the cord 30 to which the curler 31 is connected.
Further, the installation position of the concentrating box 32 is installed on the support shaft 19. It can also be provided on the fixed portion 13 connected to the radiation intake mechanism 3. In this case, in order to hang down by the weight of the curler 31 itself provided at the tip of the cord 30, it is desirable to extend from the upper part of the head of the patient. Furthermore, the cord 30 may constitute a connection port having a structure that can be connected to and removed from the line collecting box 32.

  Further, the cord 30 extending from the wire collecting box 32 has a curler 31 at the end of each cord. In FIG. 6 etc., the case where it already has the curler 31 is illustrated. However, the present invention is not limited to this, and the end of the cord 30 may have a connection port, and the curler 31 may be appropriately removable. The curler 31 has a plurality of shapes, and has a structure in which the connection port of the cord 30 and the connection port of the curler 31 can be connected. In addition, not only the shape of the curler 31 but also the curler having a structure for heating or generating heat can be appropriately changed.

FIG. 8 illustrates an example of use.
The curler 31 connected to the cord 30 extended from above the head of the person to be treated is in a state of being set on the hair, and is an example of use in performing permanent wave treatment.
The same effect as in the case of Example 1 described above can be obtained, and heat transfer heating is performed on the hair of the person to be treated by the curler 31.
Heat transfer to the hair by heating or heat generation of the curler 31 here can enhance the average drying effect. For example, the heat transfer temperature by the curler 31 is maintained at 60 ° C. or lower.
In addition to the radiation heating and convection heating based on each radiation mechanism described above, the hair drying time can be further shortened by the heat transfer heating from the curler 31. Thereby, the environmental temperature by radiation heating by each radiation mechanism is in the range of 30 to 35 ° C., and drying can be promoted sufficiently even at a low temperature of 60 ° C. or less.

For example, a description will be added as an example of use when performing a permanent wave.
The head hair is composed of hairy skin, fur and medulla, and is composed of protein, lipid, trace element and water. The structure of amino acids constituting the main protein is composed of peptide bonds in the main chain and disulfide bonds, ionic bonds, and hydrogen bonds in the side chains. It is keratin, the main protein of hair, and the main amino acid is cystine. This drug is called a drug that causes a reduction reaction that cuts the disulfide bond constituting cystine and reduces it to cysteine. It causes an oxidation reaction that oxidizes cysteine to re-bond disulfide bonds and oxidizes to cystine. Is a drug called two drugs, and this is an explanation of the simple principle of permanent wave that deforms hair.
Here, only the disulfide bond is bonded by the two oxidizing agents, and the ionic bond and the hydrogen bond are rebonded by drying the hair and causing a bonding reaction.

Here, the timing of the permanent wave treatment according to FIG. 8 will be described.
The curler 31 is wrapped around the hair with one agent applied to the hair of the patient, and then the reduction reaction proceeds sufficiently, and then the connection port of the curler 31 and the cord 30 is connected to fix the deformation. In other words, it can be used in the oxidation reaction that permeates the two agents.
When the two agents are applied and penetrated into the hair, it is more likely that the ionic bond and the hydrogen bond are recombined by drying the hair at the same time than the shaping of the hair by simply recombining the disulfide bonds. The effect is great. Therefore, after applying the two agents, it is possible to perform radiation heating by an infrared heater, drying by convection heating by air blowing / intake, and infiltration and drying of the two agents by heat transfer heating by a curler.

DESCRIPTION OF SYMBOLS 1 Dryer apparatus 2 Radiant blower mechanism 3 Radiant intake mechanism 4 Infrared heater part 5 Fan 6 Air blower 7 Intaker 8 Filament 9 Reflector 10 Release | release surface 13 Fixing part 14 Arm 15 Arm axis | shaft 16 Saws 17 Code 18 Operation box 19 Support axis 20 support 21 support tube 22 fixing portion 23 base 24 base plate 25 caster 30 cord 31 curler 32 collecting box

Claims (10)

A stand-type dryer device used for drying hair,
An infrared radiation portion having a filament that emits infrared light having a spectral radiance peak in a wavelength band of 2 μm to 4 μm;
A blower unit for blowing air;
An intake section for performing intake,
The infrared radiation unit, and a radiation blowing mechanism provided with the blowing unit;
The infrared radiation unit, and a radiation intake mechanism provided with the intake unit;
A dryer apparatus comprising: The radiation blower operates the infrared radiation unit and the blower unit simultaneously or in any combination,
The radiant intake machine operates the infrared radiation unit and the intake unit simultaneously or in any combination,
A dryer apparatus according to claim 1, characterized in that: The radiation blowing mechanism is provided side by side with an arrangement in which the infrared emission surface related to the infrared radiation portion and the wind emission surface related to the blower portion do not overlap.
The radiation intake mechanism is provided side by side in an arrangement where the infrared emission surface related to the infrared radiation portion and the wind intake surface related to the intake portion do not overlap.
The dryer apparatus according to claim 1 or 2, wherein the dryer apparatus is provided. In the radiation blower mechanism, the infrared radiation part is arranged in parallel, and the blower part is arranged in parallel between the infrared radiation parts,
In the radiation intake mechanism, the infrared radiation part is provided in parallel, and the intake part is provided in parallel between the infrared radiation parts.
The dryer apparatus according to any one of claims 1 to 3, wherein the dryer apparatus is provided. The radiation intake mechanism is provided at the top of the dryer device, and the radiation blower mechanism is provided at the upper front part, both side parts, and the middle stage part.
The dryer apparatus according to any one of claims 1 to 4, wherein the dryer apparatus is provided. The filament is a vegetable carbon fiber,
A dryer apparatus according to any one of claims 1 to 5, wherein Curlers including a heating element inside at the ends of a plurality of extended cords;
A dryer apparatus according to any one of claims 1 to 6, characterized by comprising: A connection port is formed at the ends of the plurality of extended cords, and a curler including a heating element is connected to the connection port.
A dryer apparatus according to any one of claims 1 to 6, wherein the dryer apparatus is provided. The cord and curler are suspended from the top of the dryer device.
9. A dryer apparatus according to claim 7, wherein the dryer apparatus is characterized in that: The radiation blowing mechanism, the radiation suction mechanism, and the curler operate the infrared radiation section, the blowing section, the suction section, and the curler simultaneously or in any combination.
10. A dryer apparatus according to any one of 7 to 9 above.