JPH0321262Y2 - - Google Patents

Description

[Detailed Description of the Invention] Industrial Application Field This invention relates to a thermotherapy device that utilizes far infrared rays and is attached directly to the human body.

BACKGROUND ART Conventionally, electric heaters and near-infrared radiators have been used as thermotherapy devices.

There has never been a heat treatment device that uses far infrared rays and can be attached directly to the human body.

The problem that the invention aims to solve: With conventional heat treatment devices such as electric heaters and near-infrared radiators, heat reaches only the surface of the skin or shallow areas under the skin, and does not reach the muscles deep under the skin. However, it was not possible to treat internal organs and bones by heating them.

Furthermore, the above-mentioned electric heaters and near-infrared radiators are large-sized equipment, and there is the inconvenience of having to go to a hospital or the like to receive treatment using these devices.

This idea was made in view of the above,
The purpose is to provide a heat treatment device that can heat muscles, internal organs, bones, etc. at home.

Means for Solving the Problems This invention consists of a far-infrared surface heater, a skin patch made of an elastic material such as silicone rubber that is brought into contact with the far-infrared surface heater, and the far-infrared surface heater and skin patch. The far-infrared surface heater includes a heat generating portion in which a heating element made of a mixture of polyethylene glycol and carbon graphite powder is coated on a planar base member; It is characterized by comprising a reflective material attached to the back surface of the heat generating part to reflect the heat and far infrared rays generated from the heat generating part, and an exterior insulating covering material that wraps around the heat generating part and the reflective material.

Effect: When the thermotherapy device is attached to a predetermined location on the human body and energized, the surface and interior of the predetermined location of the human body are heated by the heat emitted from the far-infrared surface heater and the far-infrared rays, respectively. .

Embodiment FIG. 1a shows a perspective view, partially in section, of an embodiment of the present invention.

The thermotherapy device 10 includes a far-infrared surface heater 12 and a skin pad 19 facing the far-infrared surface heater 12 inside a cover 11 made of cloth or the like. The skin pad 19 made of an elastic material such as silicone rubber is provided to soften the contact of the thermotherapy device against the skin. Also,
The four bands 20 are used to attach the thermotherapy device 10 to a predetermined part of the human body.

One end of the cord 21 is introduced into the end portion 11a of the cover 11. The other end of the cord 21 is connected to the low voltage side of the transformer 22.
One end of a cord 23 is connected to the high voltage side of the . The other end of the cord 23 is connected to a timer 24, and the other end of a cord 25, which has one end connected to a plug 26, is connected to the timer 24. The high voltage side of the transformer 22 is, for example, AC100V, and the low voltage side is, for example, AC12V, and the voltage on the low voltage side is selected to be safe for the human body.

FIG. 1b shows a state in which the outer insulating coating of the far-infrared surface heater is partially removed, taken along the line AA in FIG. 1a. FIG. 2 shows a section of the far-infrared surface heater taken along the line BB in FIG. 1b.

The far infrared surface heater 12 has electrodes 13a and 1
3b, an exterior insulating coating material 14, a reflective material 15, a base material 16, and a heating element 17.

The heating element 17 is, for example, a mixture of powders of polyethylene glycol, which is a high-molecular organic substance, and carbon graphite. 16 forms a heat generating part 18. The upper end portion of the heat generating portion 18 is bonded to an electrode 13a such as copper foil over the entire width of the heat generating portion 18, and the lower end portion of the heat generating portion 18 is bonded to an electrode 13b such as copper foil over the entire width of the heat generating portion 18. ing.

A heat and far-infrared reflective material 15 such as aluminum foil or copper foil is attached to the back surface of the base material 16, and all of these electrodes 13a, 13b, base material 16, heating element 17, and reflective material 15 are ,
It is covered with an exterior insulation covering material 14 made of polypropylene or the like. Moreover, at the ends 121a and 121b of the electrodes 13a and 13b,
Conductors 211a and 211b at one end of the cord 21 are connected to each other.

Now, the plug 24 is inserted into a receptacle (not shown) to energize the thermotherapy device 10.

As mentioned above, the heating element 17 is, for example, a mixture of polyethylene glycol and carbon graphite powder, and FIG. 3 shows an example of the relationship between the temperature and resistance value of the heating element 17 when energized, and the energization time. FIG. 4 shows an example of a state in which the temperature of the heating element 17 and the current flowing through the heating element 17 change accordingly.

As is clear from FIG. 3, this is a special phenomenon in which the temperature of the heating element 17 increases when electricity is applied, and when the temperature exceeds a certain point, the polyethylene glycol completely melts and the resistance value of the heating element 17 rapidly increases. occurs. As a result, as shown in FIG. 4, the current decreases and settles at a constant value, and the temperature of the heating element 17 also becomes a constant value (approximately 50 degrees Celsius).

The constant temperature reached by this heating element 17 varies between approximately 30 and 60 degrees Celsius, which is an appropriate temperature as a heat source for low-temperature heating, by adjusting the amount of carbon graphite mixed in polyethylene glycol. I can do it. In this way, the heating element 17
It can be seen that it has a self-temperature regulating function.

Furthermore, it has been found that the heating element 17 also emits far infrared rays when energized.

Therefore, when the thermotherapy device 10 is energized, not only heat but also far infrared rays are emitted from the heating element 17, so that the surface of the human body is exposed to the heat, and the inside of the human body is affected by the far infrared rays. The muscles, internal organs, and bones in the body become heated.

The timer 24 shown in FIG. 1a is a timer that is set to turn on for 5 minutes, turn off for 5 minutes, and turn off the power after 1 hour of power, for example, to prevent low-temperature burns caused by the far-infrared surface heater. The purpose is to

Effects of the Invention As explained above, according to the present invention, the far-infrared surface heater is built into the thermotherapy device, so there are the following advantages.

The heat generation temperature of the far-infrared surface heater is kept below 60 degrees Celsius by adjusting the mixture ratio of the heating element, polyethylene glycol and carbon graphite, so there is no need for special insulation for the heating element. Furthermore, since the power supply voltage is reduced to, for example, AC12V by a transformer, there is no risk of the thermal treatment device catching fire or electric shock even if the insulation of the far-infrared surface heater is damaged.

In far-infrared surface heaters, as the temperature of the heating element increases, the current flowing through the heating element decreases, so the current consumption, that is, the power consumption, is small, and far-infrared rays are generated in a short time after electricity is applied to the heat treatment device. Therefore, a warm sensation can be obtained in a short time after electricity is applied to the thermotherapy device.

In conventional thermotherapy devices, only the surface of the human skin is heated, but in this thermotherapy device, the surface of the skin and the inside of the human body are heated by the heat emitted from the far-infrared surface heater and the far-infrared rays, respectively. Therefore, comfortable heating is achieved.

This thermotherapy device can be attached directly to the human body, so
It can be used at home.

Since the heating element has a self-temperature control function, a temperature control device is not required.

[Brief explanation of drawings]

Fig. 1a shows a perspective view showing a partial cross-section of an embodiment of the present invention, and Fig. 1b shows a cross section taken along line A-A in Fig. 1a, partially showing the exterior insulation coating of the far-infrared surface heater. Shows the removed state. Figure 2 is B- in Figure 1 b.
B shows a section of the far-infrared surface heater. Figure 3 shows an example of the relationship between the temperature of the heating element and the resistance value when it is energized, and Figure 4 shows an example of the state in which the temperature of the heating element and the current flowing through it change with the energization time. . 10... Heat treatment device, 12... Far infrared surface heater, 13a, 13b... Electrode, 14... Exterior insulation coating material, 15... Reflective material, 16... Base material, 1
7...Heating element, 18...Heating part, 19...Skin pad.

Claims (1)

[Scope of utility model registration request] A thermotherapy device comprising a far-infrared surface heater, a skin pad made of an elastic material such as silicone rubber that is in contact with the far-infrared surface heater, and a cover that encloses the far-infrared surface heater and the skin pad, Further, the far-infrared surface heater includes a heat-generating portion in which a heating element made of a mixture of polyethylene glycol and carbon graphite powder is coated on a planar base member, and a heat generating portion that reflects heat and far-infrared rays generated from the heat-generating portion. 1. A thermotherapy device comprising: a reflective material attached to the back surface of a heat generating section; and an exterior insulating covering material that envelops the heat generating section and the reflective material.