JP3112041U - Thermotherapy device - Google Patents

Abstract

The present invention provides a thermal treatment device capable of effectively irradiating far-infrared rays to a human body local part while suppressing excessive stimulation due to heat to the human body local part.
A heater 5 accommodated in an opening 3 of a generally square-shaped main body 2 in plan view, and an elliptical dome-shaped glass cover provided in the opening 3 so as to be spaced apart from the heater 5 and having an outer surface applied to a local body part. 6 and a far-infrared radiation layer 7 coated in a thin film on the inner surface, which is a fine uneven surface of the glass cover 6, and a heater heating surface 5 a in the glass cover 6 and a thin-film far-infrared radiation layer 7. A thermal therapy device that forms a space 9 therebetween.
[Selection] Figure 3

Description

  The present invention relates to a thermotherapy device that mainly heats a local part of a human body and irradiates far infrared rays.

  As a thermal treatment device that heats a local part of a human body and irradiates far infrared rays, there is a thermal treatment device of Patent Document 1. The thermotherapy device of Patent Document 1 is provided with a far-infrared radiation layer by coating ceramic particles such as alumina, magnesia, and zirconia on the outer surface of a hemispherical metal upper lid such as aluminum fixed to the upper end of a cylindrical body, A heating element is integrally fixed to the back side of the metal top cover.

The full text of Japanese Utility Model Publication No. 2-141445

  By the way, the thermotherapy device of Patent Document 1 is such that the heat of the heating element is transmitted to the human body through a metal top such as aluminum having a good thermal conductivity and the far-infrared radiation layer thinly coated on the outer surface thereof. There is a problem that local heat is too strong. Therefore, there is a need for a thermal treatment device that can effectively irradiate far-infrared rays to the human body part while suppressing excessive stimulation due to heat to the human body part.

  This invention proposes in view of the said subject, Comprising: While suppressing the excessive irritation | stimulation by the heat | fever to a human body local part, providing the thermotherapy device which can irradiate a far-infrared ray effectively to a human body local part. Objective.

  The thermotherapy device of the present invention is a heater, a dome-shaped far-infrared transmission cover that is provided on the outside of the heater, and the outer surface is applied to a local body part, and an inner surface that is a fine uneven surface of the far-infrared transmission cover And a far-infrared radiation layer coated on the substrate. The far-infrared transmission cover is, for example, a transparent glass cover or resin cover that transmits far-infrared rays.

  Furthermore, the thermotherapy device of the present invention has a configuration in which a space is formed between the heater in the far-infrared transmitting cover and the far-infrared emitting layer, or the heater and the far-infrared emitting layer in the far-infrared transmitting cover. And a structure in which another far-infrared radiation layer is provided between the heaters, or a structure in which the heating surface of the heater is provided in close contact along the concave curved surface of the inner surface of the far-infrared transmitting cover.

  The thermotherapy device of the present invention is a far-infrared transmission cover with low thermal conductivity, so that the heat conduction of the heater's heat generation is weakened, so that excessive stimulation due to heat to the human body part can be suppressed, and the far-infrared transmission cover By coating the far-infrared radiation layer on the inner surface, a far-infrared radiation layer having a large surface area can be secured, and the far-infrared radiation can be effectively radiated to the local body part to which the far-infrared transmission cover is applied. Furthermore, since the far-infrared radiation layer is provided on the fine uneven surface of the far-infrared transmission cover, the far-infrared radiation layer can be firmly fixed.

  In addition, when a far-infrared radiation layer is coated on the far-infrared transmission cover and another far-infrared radiation layer is not provided, the amount of expensive far-infrared radiation material can be suppressed, and the cost can be reduced. be able to. Furthermore, as a thin-film far-infrared radiation layer, the far-infrared radiation can be averaged over the entire surface of the far-infrared transmission cover.

  In addition, by forming a space between the heater in the far-infrared transmitting cover and the far-infrared radiation layer, it becomes possible to further weaken the heat conduction, further suppressing excessive stimulation by heat to the human body part. can do. On the other hand, by providing another far-infrared radiation layer in the far-infrared transmission cover, more reliable far-infrared radiation can be achieved.

  Hereinafter, embodiments of the thermotherapy device of the present invention will be described.

  As shown in FIGS. 1 to 3, the thermotherapy device 1 according to the first embodiment includes a main body 2 having a generally square shape in plan view, and an elliptical opening 3 is formed in the front portion of the main body 2. . Inside the opening 3, a heat insulating plate 4 having substantially the same shape and the same size as that of the opening 3 and having a recess 4 a in the center is fixedly provided. The heater 5 having the flat plate-like heat generating surface 5a is provided in the heat insulating plate recess 4a, and the heat generating surface 5a is disposed on the front surface of the heat insulating plate 4. A thermistor 5 b is provided in the heater 5.

  In front of the heat generating surface 5a of the heater 5, an elliptical dome-shaped glass cover 6 applied to the human body part is provided apart, and the glass cover 6 has a convex curved surface in front and an opening 3 at the periphery. The periphery is inserted, and the insertion portion is sealed with packing 8. Further, as shown in FIG. 4, fine convex portions 6a and concave portions 6b are formed on the inner surface of the concave curved surface of the glass cover 6 by sandblasting or the like, and a far infrared radiation layer is formed on the inner surface having the fine concave and convex shapes. 7 is applied and baked, and is stably fixed. A space 9 is formed between the far-infrared radiation layer 7 on the inner surface of the glass cover 6 and the heater 5.

  The far-infrared radiation layer 7 can be formed using an appropriate far-infrared radiation material. For example, ceramics such as alumina, magnesia, and zirconia, tourmaline, and the like can be used alone or in combination of two or more. Furthermore, it is also possible to mix and use natural radioactive rare element minerals such as thorium and radon, and carbon in the far infrared radiation material.

  A cooling fan 10 is fixedly installed in the main body 2 behind the heat insulating plate 4. Further, 11 is a power cord for supplying power for driving the heater 5, the cooling fan 10, etc., and 12 is an operation unit for controlling ON / OFF of the power supply of the thermal treatment device and temperature adjustment of the heater 5.

  When using the thermotherapy device, the operation unit 12 turns on the power to heat the heater 5 at a predetermined set temperature. The heat generated in the heater 5 is transmitted to the far infrared radiation layer 7 through the air in the space 9 having a low thermal conductivity, and is transmitted from the thin far infrared radiation layer 7 through the glass cover 6 having a low thermal conductivity to the glass cover. 6 is transmitted to the outer surface. Accordingly, it is possible to suppress excessive thermal stimulation to the local body part to which the outer surface of the glass cover 6 is applied.

  Further, the far-infrared radiation layer 7 is heated by heat generated by the heater 5 through the air in the space 9, and irradiates far-infrared rays to the local body part to which the outer surface of the glass cover 6 is applied. At this time, since the large surface area of the far-infrared radiation layer 7 is ensured over substantially the entire surface of the glass cover 6, it is possible to irradiate a large amount of far-infrared rays and to form a thin film having a substantially uniform thickness. By using the far-infrared radiation layer 7, the amount of far-infrared radiation can be averaged over the front surface of the glass cover 6, and the amount of expensive far-infrared radiation material used can be suppressed.

  The thermotherapy device of the present invention is not limited to the first embodiment. For example, instead of a configuration in which the space between the far infrared radiation layer 7 on the inner surface of the glass cover 6 and the heater 5 is a space, FIG. As shown in the second embodiment, the inside of the glass cover 6 is filled with a far-infrared radiation material such as alumina powder with good thermal conductivity or a non-combustible powder with good thermal conductivity, and the inner surface of the glass cover 6 is distant. A configuration in which a second far-infrared radiation layer 13 or a heat conduction layer having a shape corresponding to the concave portion in the glass cover 6 is provided between the infrared radiation layer 7 and the heater 5 may be employed.

  Further, for example, as in the third embodiment shown in FIG. 6, the far-infrared radiation layer 7 is formed on the concave curved surface in the glass cover 6 by welding or coating, and the heating surface 5 a of the heater 5 is formed on the glass cover 6. The far-infrared radiation layer 7 on the inner surface of the glass cover 6 and the heat generating surface 5a of the heater may be provided in close contact with each other without a gap. In the above-described configuration, the far-infrared radiation layer 7 and the heat generating surface 5a are simply arranged in close contact with each other, and the far-infrared radiation layer 7 and the extinction surface 5a are in close contact with an adhesive having good thermal conductivity. It is also possible.

  The present invention can be used as a thermotherapy device that heats by pressing against a human body part such as a shoulder and irradiates far infrared rays.

(A) is a front view of the thermotherapy apparatus of 1st Embodiment, (b) is a top view of the thermotherapy apparatus of 1st Embodiment. The longitudinal cross-sectional view of the thermotherapy apparatus of 1st Embodiment. The fragmentary longitudinal cross-section which shows the peripheral area | region of the glass cover and heater in the thermotherapy apparatus of 1st Embodiment. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a longitudinal explanatory view showing a laminated structure of a glass cover and a far infrared radiation layer in a thermotherapy device of the first embodiment. The fragmentary longitudinal cross-section which shows the peripheral area | region of the glass cover and heater in the thermotherapy apparatus of 2nd Embodiment. The fragmentary longitudinal cross-section explanatory drawing which shows the glass cover and heater in the thermotherapy apparatus of 3rd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Thermal therapy device 2 Main body 3 Opening 4 Heat insulation board 4a Recessed part 5 Heater 5a Heat generating surface 5b Thermistor 6 Glass cover 6a Convex part 6b Concavity 7, 13 Far-infrared radiation layer 8 Packing 9 Space 10 Cooling fan 11 Power supply cord 12 Operation part

Claims (4)

Far-infrared radiation coated on the inner surface, which is a minute uneven surface of the heater, a dome-shaped far-infrared transmission cover that is provided on the outside of the heater, the outer surface is applied to the human body part, and has a low thermal conductivity A thermotherapy device comprising a layer. The thermotherapy device according to claim 1, wherein a space is formed between the heater and the far-infrared radiation layer in the far-infrared transmission cover. The thermotherapy device according to claim 1, wherein another far infrared radiation layer is provided between the heater and the far infrared radiation layer in the far infrared transmission cover. The thermotherapy device according to claim 1, wherein a heating surface of the heater is provided in close contact along a concave curved surface of the inner surface of the far infrared ray transmitting cover.

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