JPS636765A - Infrared radiator - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a heat-resistant glass tube heater that combines a heat-resistant glass tube and a drowsy resistance wire coil, typified by the quartz tube heater already in use in the market. By coating heat-resistant glass tubes with ceramics, we aim to provide a unique infrared radiation source, expand the range of infrared wavelengths of heat-resistant glass tube heaters, and increase heating efficiency.

To explain with drawings, Fig. 1 shows an infrared radiation device in which an electric resistance wire coil 1 is coated with ceramics 3 on the entire outer surface of a heat-resistant glass tube 2 inserted into the electric resistance wire coil 1, and the electric resistance wire coil is energized. When this occurs, the ceramic is heated and its temperature is raised, and it emits infrared rays unique to that ceramic.

Figure 2 shows the electric resistance wire coil 4 inserted into it.
#i 1E Qi W on the entire inner surface of the swallow glass tube 5! 3) When an infrared radiator coated with ceramics 6 with a high degree of fringe is used to energize the 2 electric resistance wire coil, the coated heat-resistant glass is emitted from the heated and heated ceramics, and the infrared rays unique to ceramics emit heat. Infrared rays that can pass through the tube and unique infrared rays that are emitted from the heat-resistant glass tube that has been heated and heated are emitted.

Figure 8 shows an infrared radiation device in which the entire outer surface of a heat-resistant glass tube 8 inserted into an electrical resistance wire coil 7 is coated with highly insulating ceramics 9. When the electrical resistance wire coil is energized, Electrical resistance wires and ceramics that are heated and heated each emit unique infrared rays. However, the heat-resistant glass tube in this case can be replaced with a heat-resistant glass rod.

Figure 4 shows an infrared radiation device in which the entire inner surface of a heat-resistant glass tube 11 inserted into an electric resistance wire coil 10 is coated with ceramic 12. Of the infrared rays unique to ceramics emitted from ceramics, there is infrared rays that can pass through coated heat-resistant glass tubes, and infrared rays that are unique to ceramics and emitted from heated electrical resistance wires and heat-resistant glass tubes. of infrared radiation is emitted.

5 and 6 show the infrared radiation device explained in the explanation of FIG. 3 and FIG.
When the electric resistance wire coils are energized with the heat-resistant glass tubes inserted in them, the heat-resistant glass tubes in which they are inserted are exposed to the infrared radiation explained in the explanation of Figures 8 and 4. Infrared rays that can be transmitted and unique infrared rays emitted by each heat-resistant glass tube will be emitted.

In other words, coating the heat-resistant glass tube of the heat-resistant glass tube heater with ceramics provides the heat-resistant glass tube heater with another source of infrared radiation, and the unique infrared rays emitted from the ceramics are absorbed by the heat-resistant glass. This expands the range of infrared wavelengths inherent to tube heaters and increases heating efficiency.

However, everything from the explanation of FIG. 1 to the explanation of FIG. 6 is made in the infrared ray emitting device of claim 2.

In other words, in the case of Figure 1, all of the original radiant energy of the heat-resistant glass tube heater is used to heat and raise the temperature of the ceramic coated on the outer surface of the heat-resistant glass tube.
It has been consumed.

In the cases shown in Figures 2, 4, 5, and 6, the unique infrared rays emitted from the ceramics are limited by the red ray transmission characteristics of the respective coated heat-resistant glass tubes. will be done.

In this case, in order to make the most of the infrared rays inherent in the heat-resistant glass tube heater, and also to effectively radiate the infrared rays emitted from the coated ceramics, the scope of the claims is It must be an infrared emitting device as specified in Clause 8 and Clause 4 of .

To explain with reference to drawings, FIG. 7 shows an infrared radiation device according to claim 8, in which half of the outer surface of a heat-resistant glass tube 16 into which an electric resistance wire coil 15 is inserted is coated with ceramics 17.
When the electrical resistance wire coil is energized, one half of the ceramic-coated surface emits infrared rays unique to the ceramic, and the other half emits infrared rays inherent to the heat-resistant glass tube heater.

In FIG. 9, a gap 22 is provided on the outer surface of a heat-resistant glass tube 21 into which an electric resistance wire coil 20 is inserted, and a ceramic 23
When the electric resistance wire coil is energized in the infrared ray emitting device according to claim 4, which is coated with The glass tube heater's original infrared rays are emitted.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view of an infrared radiation device in which the entire outer surface of a heat-resistant glass tube into which an electric resistance wire coil is inserted is coated with ceramics. FIG. 2 is a cross-sectional view of an infrared radiation device in which the entire inner surface of a #thermal glass tube into which an electric resistance wire coil is inserted is coated with highly electrically insulating ceramics. FIG. 3 is a cross-sectional view of an infrared radiation device in which the entire outer surface of a heat-resistant glass tube inserted into an electrical resistance wire coil is coated with highly electrically insulating ceramics. FIG. 4 is a cross-sectional view of an infrared radiation device in which the entire inner surface of a heat-resistant glass tube inserted into an electric resistance wire coil is coated with ceramics. FIG. 5 is a sectional view of an infrared ray emitting device in which the infrared ray emitting device of FIG. 3 is further inserted into a heat-resistant glass tube. FIG. 6 is a sectional view of an infrared ray emitting device in which the infrared ray emitting device of FIG. 4 is further inserted into a heat-resistant glass tube. Figure 7 shows half the outer surface lζ of a heat-resistant glass tube into which an electric resistance wire coil is inserted, and which is coated with ceramics.
A cross-sectional view of an infrared radiation device. FIG. 8 is a side view of a heat-resistant glass tube whose outer half is coated with ceramics. FIG. 9 is a cross-sectional view of an infrared radiation device in which an electric resistance wire coil is inserted, a heat-resistant glass tube is coated with ceramics with a gap provided on the outer surface of the tube. FIGS. 10, 11, and 12 are side views of the #i thermal glass tube coated with ceramics with a gap provided on the outer surface. Figure 10 shows horizontal stripes. Figure 11 shows vertical stripes. Figure 12 shows a spiral shape. 1 is an electric resistance wire coil, 2 is a heat-resistant glass tube, and 3 is a ceramic. 4 is an electric resistance wire coil; 5 is a heat-resistant glass tube; 6 is a ceramic; 7 is an electric resistance wire coil; 8 is a heat-resistant glass tube; 9 is a ceramic; 10 is an electric resistance wire fill; , heat-resistant glass tube, 12: ceramics, 13: heat-resistant glass tube, 14: heat-resistant glass tube, 15: electric resistance wire coil, 16: heat-resistant glass tube, 17: ceramics, 18: heat-resistant glass tube , I9 is ceramics, 20 is electric resistance wire coil, 21 is heat-resistant glass tube, 22 is gap, 28 is ceramics, 24 is heat-resistant glass tube, 25 is ceramics

Claims (4)

[Claims] (1) Coating ceramics on the outer surface or inner surface of a heat-resistant glass tube, or on the outer surface of a heat-resistant glass rod, and placing an electric resistance wire coil inside the heat-resistant glass tube, or vice versa; Or that heat-resistant glass rod,
An infrared radiation device inserted into an electric resistance wire coil. (2) The infrared radiation device according to claim 1, the entire surface of which is coated with ceramics. (3) The infrared ray emitting device according to claim 1, wherein one half of the surface is coated with ceramics. (4) Coated with ceramics with gaps.
An infrared radiation device according to claim 1.