KR20110050768A - Tube bulb heater with carbon heating element - Google Patents

Abstract

PURPOSE: A tube bulb heater with a carbon heating element is provided to improve durability by installing carbon heating elements on the interior of an insulating tube to prevent mutual thermal impact. CONSTITUTION: A tube bulb heater with a carbon heating element includes a glass tube(1), a heating element(3), and a lead line(4). The heating element is installed in a plurality of insulating tubes inside the glass tube. The lead line is connected to the one side of the heating element through the one side of the glass tube. The heating element is inserted into each insulating tube.

Description

Tube bulb heater with carbon heating element

The present invention relates to a tube bulb heating element using carbon fibers, wherein a pair of heating elements inserted into a cylindrical carbon fiber in close contact with the inner surface are installed side by side inside the glass tube, and are installed on the pair of heating elements and electrically connected to each other. The electrode supports that connect the heating elements and maintain a constant distance from the glass tube are in contact with each other in a circular shape to support the opposite inner surface of the glass tube, so that the contact portion of the electrode support is not damaged when high heat is generated, thereby improving the electrical connection force, such as disconnection. The present invention relates to a tube bulb heating element using a carbon fiber having a structure that overcomes the problem and solves by the insulation tube that the durability of the pair of heating elements is lowered by the thermal effect of each other.

The heating element using the carbon fiber is a carbon fiber woven in a mesh shape to have a cylindrical shape, which is directly installed in a space of a vacuum glass tube or inserted into an outer surface of an insulating tube such as a glass tube.

The heating element is bound to the lead wire, and this connection structure is an important problem directly related to the endurance life of the carbon fiber heating element. In the structure as shown in [Prior FIG. 1] and [Prior FIG. 2] below, the carbon yarn heating element 2 is wound spirally on the outside of the insulating tube 3, and the electrode wires 6 are formed at both ends of the carbon yarn heating element 2. Connected. The electrode wire 6 is connected to fasteners 5a and 5b connected while fixing the carbon yarn heating element 2.

[Primary Figure 1]

[Priority Figure 2]

In the above conventional structure, the projections 7 and the pedestal 8 are provided on the fastener 5b so that the carbon yarn heating element 2 does not come into contact with the glass tube 1 and is supported on the inner wall of the glass tube 1. The electrode wire 6 is connected by welding to the fasteners 5a and 5b on which the carbon yarn heating element 2 is pressed.

In addition, unlike the conventional structure, it may have a different structure, in which a configuration in which the carbon yarn heating element is spirally wound on the outside of the insulating tube in one glass tube may be installed side by side.

In the conventional structure, the electrode wire 6 is connected to the fasteners 5a and 5b connected while fixing the carbon yarn heating element 2, and is fixed by welding or the like. The connection of the carbon yarn heating element 2 and the electrode wire 6 is very important, and in a configuration in which high heat is generated, high temperature and low temperature are repeated according to on and off, and thus, it is necessary to overcome the weakness of the connection part. However, in the conventional case, since the structure is completely fixed by fusion, there is a problem that the fusion point falls due to repeated changes such as expansion at high temperature and contraction at low temperature.

In the case where two or more carbon yarn heating elements 2 are installed inside one glass tube, the carbon yarn heating elements 2 are wound around the outer side of the insulating tube 3, so that the adjacent carbon yarn heating elements 2 are directly connected to each other. It becomes a structure facing. In such a structure, the heat generation of one carbon yarn heating element 2 affects the other carbon yarn heating element 2, and thus, the durability life is sharply reduced.

Accordingly, an object of the present invention is to provide a structure that fundamentally solves the conventional problems as described above.

In order to achieve the object of the present invention, it is composed of an electrode support that only contacts the portion to which the electrode wire is connected without contact and fixed to the contact hole to provide a structure that is more closely contacted during expansion and contraction and at the same time the heating element of the glass tube It provides a structure that serves as a pedestal so as not to hit the inner wall.

And the carbon fiber heating element is inserted into the adjacent insulated tube, thereby providing a structure to prevent the negative role of the adjacent carbon fiber heating elements.

According to the present invention, when a plurality of carbon fiber heating elements are installed adjacent to one glass tube, each carbon fiber heating element is installed inside the insulated tube, or only one is installed inside to prevent mutual thermal shocks and thus endurance life. Is increased. And the electrode support connecting each carbon fiber heating element is reliably contacted by the close contact, and even if the expansion and contraction caused by high and low temperature is repeated, it is not a fused structure, so it is not short-circuited. The effect is closer to the sphere.

Tube bulb heating element using a carbon fiber according to the present invention is a glass tube (1); A heating element (3) installed in the plurality of insulating tubes (2) installed inside the glass tube (1); In the tube bulb heating element using carbon fiber, comprising: a lead wire (4) penetrating one side of the glass tube (1) and connected to one side of each heating element (3), each of the heating elements (3) It is inserted into and installed inside the insulated tube 2, or one is inserted into the insulated tube 2 and the other is installed outside the insulated tube 2; One end of the electrode support 5 is connected to the other side of each of the heating elements 3 and has a round arc shape and is supported on the inner side of the glass tube 1 so that the heating element 3 is disposed in the inner space of the glass tube 1. Floating support; The electrode holders 5 are in contact with each other and cross; It is characterized in that the close contact 6 is installed so as to press the intersection portion of the electrode support (5).

The close contact 6 may be provided with a magnet to attach a foreign material such as iron, which may exist in the glass tube 1.

The coupling relationship between the electrode holders 5 and the contact hole 6 is shown in detail in FIG. 3, in which all the components are in contact with each other without being fused, and this contact state is made more stable by the contact hole 6. maintain. In addition, the electrode holder 5 has a circular arc shape, and the diameter of the arc becomes large when it is extended by high temperature.

The heating element 3 is formed of cylindrical carbon fibers. In addition, the structure in which the lead wire 4 is connected to one side of the heating element 3 may be various, and one example of the lead wire 4 is formed in the coil part 7 in which a part of the end portion of the lead wire 4 is wound in the form of a coil. The coil part 7 is inserted into both sides of the heating element 3 so that the outside of the coil part 7 is in contact with the inner surface of the heating element 3, and the heating element having the coil part 7 inserted therein ( The carbon fastening ring 8 is installed outside the end of 3).

The carbon fastening ring 8 is manufactured using tungsten or iron in the prior art, but the present invention is a carbon body formed by processing a carbon body. Therefore, there is no deformation at a high temperature and has a strong characteristic against thermal shock, thereby increasing the endurance life.

1 and 2, the lead wires 4 are drawn out to the outside of the glass tube 1, and in the embodiment of FIGS. 4 to 6, the lead wires 4 are placed only inside the glass tube 1. The fastening part 9 which is located and the threaded part which penetrates the glass tube 1 is connected to the lead wire 4 is formed.

4 to 6 is a simple structure in which the fastening part 9 can be fastened directly to another connection part, and the direct force by the fastening can be transmitted to the glass tube 1, thereby dispersing the glass tube 1. In order to protect the inside of the glass tube 1, the insulator 10 and the corrugated insulator cap 11 surrounding the insulator 10 is installed.

And the fastening portion 9 is composed of two parts, as shown in Fig. 5, the concave-convex coupling, the threaded portion of the two parts can be rotated to rotate freely without damaging the glass tube 1 The fastening can be made safely and easily.

And the corrugated insulator cap 11 is a structure divided by the number of fastening portions 9 passing through the glass tube 1, each fastening portion 9 is divided wrinkles as shown in FIG. It is connected and fixed to the insulator cap 11. The lead wires 4 are connected to the corrugated insulator caps 11 that penetrate through the insulators 10. In addition, the insulator 10 has a protrusion 12 formed therein to prevent the divided corrugated insulator cap 11 from being in contact with each other.

The present invention has a structural feature in which a plurality of heating elements 3 are installed in one glass tube 1, and lead wires 4 and fastening portions 9 are drawn out only on one side of the glass tube 1. Therefore, the other side of the plurality of the heating element (3) has a structural feature that the electrode support (5) serving as a lead wire is installed in contact with each other.

The power is supplied by the lead wire 4 or the fastening part 9 located on one side of the glass tube 1, and the coil part 7 of the lead wire 4 is in contact with the heat generating element 3 to generate heat. When the heat is generated, the electrode holder 5 is also heated to increase its volume. At this time, the length is increased by the arc-shaped shape of the electrode holder 5, and the force is supported by the inner wall of the glass tube 1 and pushed to the opposite side. Is generated. This force makes contact with the electrode support 5 further inside the contact hole 6, and the two electrode support 5 has good contact inside the contact hole 6, so that the electrode support 5 is energized. It also becomes clear.

As the electrode holder 5 is extended, the arc-shaped diameter is increased, which makes it more firmly supported by the inner wall of the glass tube 1, so that the heating element 3 and the insulating tube 2 are spaced in the center of the glass tube 1. It is fixed to the part.

In this way, the electrode holder 5 is not fixed by fusion but is brought into contact only with each other, and furthermore reliability is provided by the contact hole 6, so that there is no problem of short circuit even if the expansion and contraction are repeated. .

In addition, since the present invention has a structure in which all of the heating elements 3 are inserted into the insulator tube 2 as shown in FIG. 1, thermal shock with the adjacent heating elements 3 can be reduced. That is, when the heating element 3 is wound on the outside of the insulated tube 2, the heat generating elements 3 adjacent to each other have a thermal adverse effect, but the present invention eliminates or alleviates the thermal shock by the insulated tube 2 to generate the heating element. It increases the service life of (3).

And any one of the heating element 3 is inserted into the inside of the insulated tube 2, the other heating element 3 can achieve the above effect even if it is installed to surround the outside of the insulated tube (2).

1 is a perspective view of the present invention

2 is a cross-sectional view of the present invention

3 is an installation state of the electrode support and the close contact

4 to 6 is another exemplary embodiment

[Description of Drawings]

1: glass tube 2: insulated tube

3: heating element 4: lead wire

5: electrode support 6: close contact

7: coil portion 8: carbon fastening ring

9: fastener 10: insulator

11: azacap 12: stone

Claims (2)

Glass tube 1; A heating element (3) installed in the plurality of insulating tubes (2) installed inside the glass tube (1); In the tube bulb heating element using carbon fiber, comprising: a lead wire (4) penetrating one side of the glass tube (1) and connected to one side of each heating element (3), each of the heating elements (3) Inserted into the insulated tube 2 and installed therein; One end of the electrode support 5 is connected to the other side of each of the heating elements 3 and has a round arc shape and is supported on the inner side of the glass tube 1 so that the heating element 3 is disposed in the inner space of the glass tube 1. Floating support; The electrode holders 5 are in contact with each other and cross; Tube bulb heating element using a carbon fiber, characterized in that the close contact portion 6 is installed so as to press the intersection portion of the electrode support (5). 2. The heating device 3 according to claim 1, wherein both ends of the heating element 3 are connected to a coil portion 7 formed at one end of the lead wire 4 and the electrode support 5, and both ends and the coil portion 7 of the heating element 3 are formed. The tube bulb heating element using a carbon fiber, characterized in that the carbon body is bonded by a carbon fastening ring (8) formed by processing.

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