JPS63281374A - Extreme infrared radiation generating device - Google Patents

Abstract

PURPOSE:To generate a great quantity of extreme infrared radiation with good efficiency by furnishing an AC line-of-magnetic-force giving device, which is to apply an AC line of magnetic force to an extreme infrared radiation generating material. CONSTITUTION:An extreme infrared radiation generating device is composed of an extreme infrared radiation generating material 12 consisting of carbon etc., and an AC line-of-magnetic-force giving device 16 which is to apply AC lines of magnetic force to this material. This allows generation of extreme infrared radiations, so that the extreme infrared radiation generating material will get high temp. to prevent the wave length components of generated infrared radiation to deviate to the short wave length side. Because the material does not get high temp., it can be used for aging of foods which are not favored by high temp. Further, formation of strong AC magnetic field by the AC line-of- magnetic-force giving device 16 permits generation of extreme infrared radiations with higher energy in a great quantity, that enables utilization of a great quantity of extreme infrared radiations in case it is required at a low cost.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a device for generating far infrared rays.

[Conventional technology]

Conventional devices for generating far-infrared rays include, for example, those that heat ceramics and oscillate far-infrared lasers.

[Problems to be solved by the invention]

In the former method of heating ceramics, etc., when the ceramics etc. are heated to a high temperature, the far-infrared component of the infrared rays generated decreases, and the component ratio of near-infrared rays, which have relatively short wavelengths, increases. There is a problem. Furthermore, since the far-infrared emitting material reaches a high temperature, it cannot be used in applications that dislike high-temperature atmospheres, such as for ripening foods, vegetables, and the like. Therefore, in such cases, the far-infrared rays are used without heating the far-infrared rays, so the far-infrared rays generation efficiency is low, it takes time to ripen, and furthermore, it is difficult to process large quantities of food. The problem is that it cannot be done. Further, when using the latter far-infrared laser, there is a problem that the device becomes expensive and cannot be used for home use.

[Purpose of the invention]

This invention was made in view of the above conventional problems, and it is possible to efficiently generate high-energy far-infrared rays at low cost and without heating far-infrared ray-generating materials to high temperatures. The purpose of the present invention is to provide a far-infrared ray generating device that can generate far-infrared rays.

[Means to solve the problem]

This invention has been made through experiments by the inventor, for example, when applying alternating current magnetic lines of force to a far-infrared emitting material made of carbon,
This is based on the discovery that this material emits far-infrared rays. The present invention achieves the above object by constructing a far-infrared rays generating device by a far-infrared rays-generating material and an alternating current magnetic field line applying device that applies alternating current magnetic lines of force to the material. Further, in an embodiment of the present invention, the material includes:
The above object is achieved by arranging at least one magnetic substance. Furthermore, in another embodiment, the above object is achieved by forming the magnetic body to be long in the direction of the alternating current magnetic field lines.

[Effect]

In this invention, far-infrared rays can be generated by simply applying alternating current magnetic lines of force to the far-infrared ray-generating material, so that the far-infrared ray-generating material becomes hot and the wavelength components of the generated infrared rays shift to the shorter wavelength side. It is possible to prevent deviation. Furthermore, since the far-infrared emitting material does not generate high heat, it can be used for aging foods that do not like high heat. Furthermore, by forming a strong alternating current magnetic field with an alternating current magnetic field line applying device, it is possible to generate a large amount of high-energy far infrared rays from far infrared ray generating materials, so it is possible to generate far infrared rays at low cost when a large amount of far infrared rays is required. can be used. That is, it can be used in a drying device using far infrared rays, a ripening device for large amounts of food, and a purifying device for fluids such as water, air, gas, etc.

【Example】

Embodiments of the present invention will be described below with reference to the drawings. As shown in FIG. 1, this embodiment comprises a plurality of carbon rods 14 having a steel forest 12 in the center, an AC magnetic field line applying device 16 that applies AC magnetic lines of force to the carbon rods 14, and a far infrared ray generating device. It is composed of Here, the carbon rod 14 is arranged in the direction of the magnetic lines of force formed by the AC magnetic line of force applying device 16. The AC magnetic field line imparting device includes a rectifying and smoothing circuit 20 that converts alternating current from the AC power supply 18 into direct current, a thyrisk inverter 22 that converts the direct current output from this rectifying and smoothing circuit 20 into alternating current of an appropriate frequency, and a coil 23. It is composed of. The frequency of the alternating current output from this SIRISK inverter 22 can be changed by the frequency of the gate drive device 26 of SIRISKS S1 and S2. In the above embodiment, the steel rod 1 is inside the carbon rod 14.
2 is embedded, and this steel rod 12 is arranged in the direction of AC magnetic lines of force, so the magnetic field applied to the carbon rod 14 by the coil 23 is strengthened, and far infrared rays are efficiently generated from the carbon rod 14. . Further, the steel rod 12 serves as a skeleton of the carbon rod 14 and increases its strength, so that the carbon rod 14 is difficult to break and can be stably held. In the above embodiment, the carbon rod 14 is used as the far-infrared ray generating material, but the present invention is not limited to this, and may be a material containing carbon or other far-infrared ray generating material. good. Furthermore, the far-infrared ray generating material does not have to be rod-shaped, but may be block-shaped or planar-shaped. Further, the steel rod 12 embedded in the carbon rod 14, which is a far-infrared emitting material, does not necessarily need to be provided, and further, other magnetic material or granular magnetic material, etc. may be arranged instead of the steel rod. It's okay. Furthermore, the AC magnetic field line applying device 16 is composed of a rectifying and smoothing circuit 20, a thyrisk inverter 22, and a coil 23, but the present invention is not limited to this, and the AC magnetic field line applying device Any material may be used as long as it can impart magnetic lines of force.

【effect】

Since the present invention is constructed as described above, it is possible to do so without heating the far-infrared emitting material and at relatively low cost.
It has an excellent effect of being able to efficiently generate a large amount of far infrared rays.

[Brief explanation of drawings]

FIG. 1 is a perspective view including a partial circuit diagram showing an embodiment of a far-infrared ray generator according to the present invention. 12... Steel rod, 14... Carbon rod, 16... AC magnetic field line imparting device.

Claims (3)

[Claims] (1) A far-infrared ray generating device comprising a far-infrared ray-generating material and an AC magnetic field line applying device that applies AC magnetic lines of force to the material. (2) The far-infrared ray generating device according to claim 1, wherein at least one magnetic substance is arranged in the material. (3) The far-infrared ray generator according to claim 2, wherein the magnetic body is formed to be long in the direction of the alternating current magnetic field lines.