JPH0265801A - Lower temperature hair drier emitting far infrared ray and far infrared radiator therefor - Google Patents

Abstract

PURPOSE:To dry hair without injuring it and to contrive the promotion of metabolism promoting blood circulation around the skin of the head by providing a radiator of far infrared rays which has an electric heater so designed as to generate the heat of a specified temperature. CONSTITUTION:A molded body 1 is formed out of ceramic having a characteristic of emitting far infrared rays. An electric heater 2 so designed as to generate the heat of a temperature of 65 deg. to 85 deg.C is integrally fixed at the back of the molded body, and the upper, lower and back faces of the electric heater 2 are covered by an insulating material 3. The insulating material 3 is fixed by being covered with an aluminum plate 4, except the front part of the molded body 1 formed out of ceramic. A radiator 5 of far infrared rays is thus formed. A connecting plate 7 having several air flow sections 6 is embedded on the periphery of the radiator 5 of far infrared rays, and the outer edge part of the connecting plate is fixed on the inner surface of a casing 8 so that the radiator 5 of far infrared rays may be placed at the center of the casing 8. Flow ways 9a are thus formed in front of the connecting plate 7 and flow ways 9b at the back thereof. A blower 10 fixed at backward part inside the casing 8 sends air sucked from an inlet port 11 to the forward side, and blows the air out of an outlet port 12.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a low-temperature hair dryer that emits far-infrared rays and a far-infrared radiator used in the low-temperature hair dryer A7-.

[Prior Art] Conventionally, both commonly used hair dryers that do not emit far-infrared rays or hair dryers that emit far-infrared rays by passing hot air through a grid-like ceramic plate have been In addition to quickly drying hair that has become wet due to washing, the main purpose of these hair dryers is to finish styling hair in a short period of time. The heated air blown from 7- to these hair dryers is set to have a temperature of 85 to 115°C when it comes into contact with the hair.

[Problem to be solved by the invention] However, the denaturation point of protein, which is the main component of hair, is 6.
85-1 upon contact with hair, despite the temperature being 5°C.
Judging from the physiological viewpoint of hair, the conventional type of hair drying method 7-, which blows hot air at a high temperature of 15°C, has the problem of accelerating hair aging, increasing hair loss, and discoloration of the hair. There was a point.

The present invention aims to solve these conventional problems by providing a low-temperature A7 hair dryer that emits far-infrared rays and a far-infrared radiator for use in the low-temperature hair dryer.

[Means for Solving the Problem] In order to achieve the above object, the hair dryer of the present invention has 6
A far-infrared radiator equipped with an electric heater set to a heat generation temperature of 5 to 85 degrees Celsius is installed.

The far-infrared radiator radiates thermal energy and far-infrared rays when the ceramic molded body is heated by energizing the electric heater integrally fixed to the back surface of the ceramic molded body.

The heat energy radiated from the far-infrared radiator is not directly radiated by the heat of the electric heater, but is radiated indirectly through the ceramic molded body, which absorbs the heat energy and blows air. The warm air blown from the mouth has a low temperature of 62°C or less.

[Effect 1] According to the present invention configured as described above, far infrared rays are radiated from the far infrared radiator to the hair and scalp of the subject through the air outlet along with warm air at a low temperature of 62°C or less, and the hair is stimulated. It dries without causing damage, and also promotes blood circulation in the scalp and stimulates metabolism.

[Example] Among ceramics, oxide-based ceramics such as alumina (A 2203 ), magnesia (MQO), and zirconia (Zr02), and non-oxides such as zircon carbide (ZrC) and titanium nitride (TiN) BACKGROUND ART Ceramics are widely known to have far-infrared radiation properties.

The present invention is directed to ceramics made of oxide ceramics, non-oxide ceramics, or composites thereof having far-infrared radiation characteristics, and is preferably rectangular with a thickness of 1 to 5 mm, although there is no need to specifically limit the ceramics. A ceramic molded body 1 is formed by molding into a plate shape or a disc shape,
Further, on the back surface of the ceramic molded body 1, a preferably planar electric heater 2, which is set at a heat generation temperature of 65 to 85° C., is integrally fixed, and an insulating material 3, such as mica, for example, is fixed.
The insulating material 3 covering the ceramic molded body 1 and the electric heater 2 is then fixed to cover the electric heater 2 so as to surround it from the top, bottom and back.
The far-infrared radiator 5 is formed by covering and fixing the front part with an aluminum temporary 4.

Then, on the peripheral wall of the far-infrared radiator 5 having the above configuration,
A connecting plate 7 provided with a plurality of ventilation portions 6 is implanted and fixed, and the outer peripheral edge of the connecting plate 7 is fixed to the inner peripheral wall surface of the casing 8, so that the infrared radiator 5 is placed in the center of the casing 8. The front and rear parts of the connecting plate 7 are connected to the ventilation passage 9.
a, gb, and when the air sucked from the intake port 11 is sent forward by the blower 10 fixed at the rear part of the casing 8, the air is sent to the outer edge of the far-infrared radiator 5. It passes through the ventilation path 9b, and further passes through the ventilation section 6J3 of the connecting plate 7 and the ventilation path 9a to reach the front side of the ceramic molded body 1, and the heat from the electric heater 2 heats the ceramic molded body 1, and this ceramic molding The air passing through the ventilation path 9a absorbs the indirect thermal energy emitted from the body 1 and becomes hot air of 62° C. or less, which is blown through the air outlet 12, and far infrared rays are emitted from the ceramic molded body 1. is configured to do so.

Preferably, by fixing a conical air conditioning plate 13 on the back of the far-infrared radiator 5, the air from the blower 10 is directed through the air passage 9b at the outer edge of the far-infrared radiator 5. Since the air is diffused and rectified to the side, uniform air supply can be achieved.

The operation of the embodiment will be explained.

When the power is turned on and electricity is applied to the blower 10 and the electric heater 2, the air sucked through the intake port 11 is blown forward by the blower 10, and the electric heater 2 heats the air.
Most of the thermal energy is not lost to the back through the insulating material 3, but is directly conducted to the ceramic molded body 1, which has far-infrared radiation characteristics, and heats it to around 65°C. The ceramic molded body 1 that has undergone the heat conduction emits far-infrared radiant energy along with thermal energy, but the aluminum plate 4 has a reflectance of 95 to 97% and has a high reflection efficiency, so that the ceramic molded body 1 radiates far-infrared radiant energy. Of the far-infrared radiant energy, the far-infrared radiant energy radiated in the aluminum plate 4 direction is reflected 180 degrees by the aluminum plate 4, and the far-infrared radiant energy radiated by the ceramic molded body 1 is all directed in one direction (aluminum plate 4). The air blown from the blower 10 is radiated only in the direction opposite to the direction 4) to increase the radiation efficiency, and the air blown from the blower 10 is radiated through the ceramic molded body 1 at the front surface of the far-infrared radiator 5. It efficiently absorbs the heat energy indirectly radiated by the air outlet 12 and blows the air as warm air of 62°C or less, and the temperature drops to 60'C or less when it comes into contact with the hair and scalp of the subject. At the same time, far-infrared radiant energy is absorbed by the hair and scalp.

The blown thermal energy can dry and style the hair, but the temperature of the blown warm air is as low as 60'C or less when it comes into contact with the hair and scalp, which is the main component of the hair. In addition, far infrared rays are emitted from the ceramic molded body 1 without damaging the proteins, and since living bodies are far infrared absorbers, they efficiently absorb far infrared rays, and the action of far infrared rays promotes blood circulation in the scalp. This can promote metabolism and prevent hair loss.

Figure 3 shows the far infrared rays of a typical oxide ceramic when the surface temperature of the ceramic molded body is 100°C.
This shows the Gl"l spectral distribution. In the figure, curve a is the radiation spectrum of alumina, curve C is the radiation spectrum of magnesia, and curve C is the radiation spectrum of zirconia. Figure 4 shows the surface temperature of the ceramic molded body. This shows the far-infrared radiation spectrum distribution of typical non-oxide ceramics when is 'loo'c. In the figure, curve d is the radiation spectrum of zircon carbide, and curve e is the radiation spectrum of titanium nitride. It is understood that it has excellent far-infrared radiation characteristics and emits a large amount of far-infrared rays with strong penetrating power.

That is, the hair is warmed and heated by the thermal energy and far-infrared radiation energy from the ceramic molded body 1 heated by the thermal energy from the electric heater 2, and the scalp absorbs the far-infrared rays, causing heating. In addition, it can be expected to have medical effects by promoting blood circulation.

Hereinafter, a general-purpose hair dryer of a type that does not emit far-infrared rays, a general-purpose far-infrared hair dryer of a type that emits far-infrared rays by passing hot air through a grid-like ceramic plate, and a hair dryer A7- of the present invention will be described. The comparative results are shown in the attached table. The hair dryer of the present invention used in this test uses a ceramic molded body made of alumina with a wall thickness of 2 m, its surface temperature is set to 65°C, and the air flow rate from the blower is set to 0.8/-. In addition, the air outlet was used with an EffE degree of 62°C.

From the above, it is clear that the hair dry N-fu of the present invention
The thermal energy generated by J is far infrared rays, so the lipids and moisture on the surface of the hair,
In other words, even if it is oily or dry hair, hair is made of protein, so when hair receives the principle of far-infrared rays/I'i radiation energy, the reaction effect is large and the temperature is relatively low (below 60'C). Therefore, it has become clear that hair dryer A7- of the present invention can dry hair without damaging it.

[Effects of the Invention] Since the present invention is configured as described above, it produces the following effects.

In the A7 dry A7- of claim 1, when the electric heater is heated to a low temperature of 65 to 85 degrees Celsius at the same time as electricity is turned on and the blower is operated, the thermal energy of the electric heater is heated. is conducted to the ceramic molded body to heat it, and the heat of the electric heater is not applied directly.
In addition to radiating indirectly through the ceramic molded body,
Far-infrared rays are emitted from the ceramic molded body, and the air blown from the blower passes through the ventilation section and efficiently absorbs thermal energy at the front part of the far-infrared ray radiating body, causing 62 In addition to blowing warm air at a temperature below .degree. C. from an air outlet, far-infrared rays are radiated to dry the hair without damaging it, and promote blood circulation in the scalp to promote metabolism. In addition, the A2 dry A7- according to the present invention consumes less electricity than the conventional dryer and can save energy.

In the hair dryer according to the second aspect of the present invention, the air from the blower can be uniformly diffused and rectified by the air baffle plate and sent to the ventilation section.

In the far-infrared radiator of claim 3, the thermal energy of the electric heater is blocked by the insulating material and is conducted only to the ceramic molded body, which is efficiently heated and the heat of the electric heater is not directly transmitted. In addition to radiating heat energy indirectly through the ceramic molded body, far-infrared rays are also radiated by the ceramic molded body made of ceramics that has far-infrared generation properties, but this far-infrared ray is reflected by the aluminum plate. Emitted only in the forward direction.

Therefore, the amount of far-infrared rays emitted from the air outlet of the hair dryer increases and is absorbed by the hair and scalp of the subject.

[Brief explanation of the drawing]

Figure 1 is a longitudinal cross-sectional view of the whole, Figure 2 is a cross-sectional view taken along line AA in Figure 1, Figure 3 is a far-infrared radiation spectrum distribution diagram of oxide-based ceramics, and Figure 4 is a far-infrared radiation spectrum distribution diagram of non-oxide-based ceramics. It is an infrared radiation spectrum distribution map. In the figure, 1 is a ceramic molded body, 2 is an electric heater, and 3
is an insulating material, 4 is an aluminum plate, 5 is a far-infrared radiator, 6 is a ventilation section, 7 is a connecting plate, 8 is a casing, 9a, 9b are air passages, 10 is an air blower, 11 is an intake port, 12 is an air blower mouth, 13
is covered with a wind regulating board. August 31, 1988 Diagram circulation μjn)- Diagram n skin & (μm) −

Claims (1)

[Claims] 1. On the inner circumferential wall of the casing on the front side from the blower, 65
A far-infrared radiator is formed by integrally fixing an electric heater set at a heat generation temperature of ~85°C to the back of a ceramic molded body, and a ventilation portion is provided on the peripheral wall of the far-infrared radiator. A low-temperature hair dryer that radiates far-infrared rays and is characterized in that the hair dryer is connected and fixed via a connecting plate, and the hot air blown from the air outlet is kept at 62°C or less. 2. The low-temperature hair dryer that emits far-infrared rays according to claim 1, further comprising a conical air regulating plate fixed to the back of the far-infrared radiator. 3. Forming a ceramic molded body from an oxide ceramic, a non-oxide ceramic, or a composite of these ceramics having far-infrared radiation characteristics,
In addition, an electric heater set at a heat generation temperature of 65 to 85° C. is integrally fixed to the back of the ceramic molded body, and the electric heater is covered with an insulating material, and an aluminum plate is further covered except for the front part of the ceramic molded body. A far-infrared radiator for a low-temperature hair dryer that emits far-infrared rays and is coated and fixed with.