JPS5836156Y2 - infrared heating element - Google Patents

Description

[Detailed explanation of the idea] This invention relates to an infrared heating element.

It is known that infrared radiant energy is used as a heat source for heating, drying, etc.

Until now, infrared lamps, quartz tube heaters, sheathed heaters, and the like have been generally used as means for utilizing this infrared radiant energy.

However, since the wavelength of infrared rays emitted from these conventional heaters has a peak of 1 to 3μ,
When heating substances that have an absorption peak in the far infrared region, such as water or polymer compounds, not only is the heating efficiency low, but the heating element itself has low thermal shock resistance and chemical resistance.
It has the disadvantage that it is easily damaged when it comes into contact with cold objects when hot, or when it comes into contact with acids or alkalis.

This invention provides a heating element for an infrared heater that has a simple structure and is easy to handle, which improves the drawbacks of these conventional infrared heating elements.

This invention will be explained with reference to the accompanying drawings. In FIG. 1, the heating element is composed of two insulating plates 1 and 2 and a metal resistor 3 inserted between them.

At least one of the two insulating plates is made of a dense ceramic having a low coefficient of thermal expansion selected from β-sposizamen ceramics, aluminum titanate ceramics, cordierite ceramics, and mullite ceramics; Porous ceramics other than those mentioned above may be used, or something like an asbestos board may be used.

If both insulators are made of the above-mentioned dense infrared heat emitting ceramics with a low coefficient of thermal expansion, a large amount of infrared heat radiant energy will be emitted from both sides, but if only one is made of this, This means that less infrared thermal radiant energy is emitted from the other surface.

The infrared heat emitting ceramic used in this invention is β-spodumene (e.g. Li2O3, Al2O3, 4SiO
2), aluminum titanate (e.g. Al2O3・Ti
02), Kozierai I- (e.g. 2Mg0・2A12
03.5SiO2) and mullite (e.g. 3A1203
・25102) type ceramics, which are disclosed in, for example, JP-A-50144706 and JP-A-50-1447.
It is manufactured by the method described in JP-A No. 07, JP-A-50-144944, JP-A-50-145900, and the like.

Because these ceramics have a non-porous, dense structure, they exhibit good acid resistance and alkali resistance even at high temperatures, as well as excellent insulation properties.They also have a low coefficient of thermal expansion, so they have good thermal shock resistance. shows.

Next, examples of metal resistors inserted between two insulating plates include nichrome wire, Kanthal wire (product name), etc., and these can be in any shape such as spiral, ribbon, or plate shape. It can take any shape.

The two insulating plates and the intermediate metal resistor can be bonded using a heat-resistant binder such as glass or heat-resistant paint.

Alternatively, a metal resistor can be inserted between two insulating plates and fixed with bolts or the like.

The heating element of this invention does not necessarily have to be formed into a flat plate shape, but can also be formed into a curved shape or a cylindrical shape as desired.

The heating element of this invention can be used as an infrared heater by providing two terminals connected to metal resistors at appropriate locations and connecting it to a power source via these terminals.

This infrared heater has excellent acid resistance and alkali resistance at high temperatures, making it suitable as a heater for direct heating of reactors for chemical manufacturing.It also has good thermal shock resistance, so it will not damage even if it comes into direct contact with cooling objects. It is also suitable as a cooking heater.

Furthermore, it has the characteristics of a simple structure, easy handling, and being an insulated and safe electric heater.

The heating element of this invention uses a metal resistor to heat a special ceramic, emits far-infrared radiant energy, and uses this to heat an object. A type of heater that uses infrared heat as a heat source was not known.

Next, a β-spodumene ceramic plate (140 m in diameter)
m, thickness 10mm) groove provided between two pieces (width 8mm, depth 4mm) spiral nichrome wire (100cm, 600W)
Graph I shows the relationship between the wavelength of the hot ray and the relative radiation intensity when a current is passed through a heater in which ceramic plates of 800 mm are inserted and screwed together.

For comparison, the case of a commercially available infrared lamp II and sheathed heater III is also shown.

As can be seen from this figure, the heating element of this invention emits significantly higher radiant energy in the far-infrared region than an infrared lamp or sheathed heater.

[Brief explanation of drawings]

Figure 1 is a cross-sectional view showing an example of the structure of the heating element of this invention. 1 and 2 are dense ceramics with a low coefficient of thermal expansion, 3 is a metal resistor, and Figure 2 is the heating element of this invention. 2 is a graph showing the radiant energy emission state of two examples of conventional heating elements.

Claims (1)

[Scope of utility model registration request] A metal resistor 3 is placed between two insulating plates 1 and 2, at least one of which is made of an infrared heat emitting ceramic selected from β-spodumene ceramics, aluminum titanate ceramics, cordierite ceramics, and mullite ceramics. The structure of an infrared heating element is made by inserting and joining.