KR900001958Y1 - Infrared ray heating tube - Google Patents

Abstract

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Description

Far infrared heating tube

1 is an exploded perspective view showing the assembled state of the present invention the heating tube.

2 is a side view of the heating tube of the present invention, (a) is a side view of one embodiment, (b) (c) is a side view of another embodiment, and FIG. 3 is (a) (b) another embodiment of the heating tube of the present invention Schematic illustration showing an example.

* Explanation of symbols for main parts of the drawings

1, 1a, 1b, 11, 12: ceramic heating tube

2, 2a, 2b: waveform protrusion

3, 3a: insulator 4: insulation insert

5: Reflector 5a: Mounting hole

5b: Insulated Socket 6: Heater

11a: wrinkle 12a: embossing

The present invention improves the radiation intensity by increasing the surface area and increasing the density of the far-infrared rays which are emitted in the far-infrared heater used in the dry heat treatment process of various industrial fields, especially in the annular surface of the cylindrical ceramic heating tube to increase the surface area. I would have to.

In general, all objects that have heat emit infrared rays, and even the infrared rays of the longest wavelength having a wavelength of 5.6 μ or more are called far infrared rays. Since the far infrared rays are radiant heat, they are transmitted directly to the subject without an intermediate medium.

Therefore, far infrared rays are mainly used in industrial dry heating and heat treatment process, and for example, it is applied to automobile or home appliance paint drying, agricultural and marine product drying, and health mat (infrared sauna) to reduce installation space and installation cost.

However, the ceramic heating tube used in the above far infrared heater is manufactured by high-temperature firing with a cylindrical body, which causes bending of the heating tube during plastic processing, and also lowers the radiant strength of artificially generated far-infrared rays. There is a disadvantage that the heat resistance durability of the product is significantly lowered.

In order to solve the above disadvantages, the present invention forms a wavy concave-convex portion on an arc to prevent bending during plastic processing of the ceramic heating tube and extends in the longitudinal direction of the heating tube to maximize the surface area as well as being fired from the heating tube. The heat radiation distribution and the wavelength are made uniform with the increase of the average power density per surface area, which will be described in detail with reference to the accompanying drawings.

That is, Figure 1 is an exploded perspective view showing the assembled state of the far-infrared heating tube of the present invention, as shown in the annular surface of the heating tube (1) formed of ultra-high temperature ceramic, the corrugated protrusion (2) is formed and extends in the longitudinal direction thereof. In the insulators 3 and 3a fixed to both sides of the heating tube 1, inserting portions 4 are formed in the same shape as the heating tube 1, and are firmly fixed with a ceramic adhesive when they are bonded to each other. .

The insulators 3 and 3a are fixed to the mounting holes 5a of the ordinary reflector 5 by the insulating sockets 5b to emit far infrared rays.

On the other hand, Figure 2 shows an embodiment of the far-infrared heating tube (1), which is formed on the surface of the far-infrared heating tube (11) (12) like an pleat (11a) in an arc shape or embossed (12a) on the surface of the heating tube (12) The above object can also be achieved by molding.

Referring to the effect of the present invention configured as described above are as follows.

The ceramic heating tube 1 having a large surface area by forming the corrugated protrusion 2 artificially generates far infrared rays by the heater 6 inserted therein, and the far infrared wavelength is inversely proportional to the surface temperature of the heating tube 1. The higher the surface temperature, the shorter the wavelength, which increases the average power density per surface area.

Therefore, by increasing the infrared density emitted from the heating tube (1) it is possible to shorten the time when painting and contribute to energy saving.

As described above, the present invention extends the corrugated protrusion of the heating tube in the longitudinal direction to increase the surface area and thus increases the density of far-infrared rays emitted from the heating tube.

Claims (5)

Waveform protrusions 2 are formed on the arc of the ceramic heating tube 1 used in the far infrared heater to extend in the longitudinal direction to maximize the surface area to increase the density of the far infrared rays emitted from the heating tube 1 to improve the radiation efficiency. Far-infrared heating tube, characterized in that. The far-infrared heating tube according to claim 1, wherein a corrugated protrusion (2a) is formed on both sides of the cylindrical ceramic membrane heating tube (1a). The far-infrared heating tube according to claim 1, wherein a corrugated protrusion (2b) is formed on an inner surface of the heating tube (1b). The far-infrared heating tube according to claim 1, wherein wrinkles (11a) are formed on the surface of the heating tube (11) in an arc shape. The far-infrared heating tube according to claim 1, wherein a plurality of embossings (12a) are formed irregularly on the surface of the heating tube (12).