KR20040069455A - Carbon fibers lamp with double tube - Google Patents

Abstract

PURPOSE: A dual tube type heating lamp is provided to operate simultaneously two heating elements or operate selectively one of the heating elements by arranging two vacuum sealing receptacles in parallel and installing heating elements in the inside of the vacuum sealing receptacles. CONSTITUTION: A dual tube type heating lamp includes a vacuum sealing receptacle, a plurality of heating elements, and a plurality of terminals. The vacuum sealing receptacle(30) includes a first vacuum sealing receptacle(31) and a second vacuum sealing receptacle(32). The first and the second vacuum sealing receptacles are arranged in parallel. The heating elements are installed in the inside of the first and the second vacuum sealing receptacles, respectively. The terminals(3) are connected to both ends of the heating elements.

Description

Carbon fibers lamp with double tube

The present invention relates to a double tube heating lamp, and two vacuum sealing vessels constituting the heating lamp side by side to a heating element in each of the container to a double tube heating lamp to allow the heat generation is possible. The preferred heating element relates to a double tube heating lamp using the carbon yarns (carbon yarns) interwoven together and having the overlapped portions at both ends of the different carbon bodies and having the overlapped portions wound by fixed terminals.

In general, a lamp is also called a light bulb, and may be used as a lamp for a heater that uses heat generated by heating a high temperature by flowing a current through a filament installed inside the vacuum tube. This may illustrate a configuration in which a filament is installed inside the vacuum state and a terminal connected to the filament is installed at both ends of the glass tube. In addition, when tungsten filament is installed along the axis of the glass tube and the iodine gas is enclosed in the tube to send current to the filament (when power is applied), the tungsten atoms generated in the filament are combined with iodine in the tube wall to become tungsten iodide and return to the filament, where In addition, it is used as a high efficiency lamp that can be used for a long time by a so-called iodine cycle that decomposes and leaves tungsten in the filament.

However, this type of lamp has a problem that the damage of the filament is weak to external impact, the durability is weak due to deformation of the shape due to heating, etc., there is a burden such as the cost of installing the coil.

On the other hand, carbon yarns used for surface heating elements and the like use carbon fiber bundles of fine thickness as a group. For example, if the carbon fiber consists of 26400 pieces, the resistance is about 60 ohms when the length is 1 meter and the diameter is 0.3 mm. Therefore, based on this design the desired output (watt) to produce a planar heating element. Of course, in this case, the resistance Where R is the resistance, rho is the resistivity, l is the length, and s is the unit area. However, these are used as a heat generating source of the planar heating element is mainly designed to dissipate the temperature of about 50 to 70 degrees, if there is a risk of fire, it is oxidized with air and the durability is significantly reduced.

On the other hand, a heater incorporating a carbon yarn as a heat source was developed in a vacuum tube. The carbon yarn is fixed in a bundle to provide a desired output, and the technology of fixing the carbon yarn to the terminal and the technology of focusing the carbon yarn. Due to this shortcoming, industrialization has been difficult. An example of such a technique is known as a carbon-based heating element disclosed in Japanese Patent Application Laid-Open No. 2000-123960, which has a cap-type electrode part 2 at both ends of the carbon-based heating element 1 as shown in FIG. 1. ) And the cap-shaped electrode part 2 are built in the vacuum-sealing container 3, and the cap-shaped electrode part 2 is made to connect the lead wire 4 to apply power. As shown in FIG. 2, the lead wire 4 is wound around the bundle outer circumference of the carbon-based carbon yarn 6 composed of a plurality of bundles with a carbon chamber 7 to form a fixed shape.

FIG. 3 is an exemplary view configured to provide a bundle of carbon yarns 6 necessary in this case. Each of the three strands wound around a certain bundle of carbon yarns 6 with a carbon yarn 7 and wound with a carbon yarn 7 is shown. It is shown the structure which winds together with carbon chamber 7 'and makes them integral.

That is, the carbon body 1 made of the unit carbon body 5 as shown in FIG. 2 or the plural carbon body 5 wound around the three carbon strands 5 as shown in FIG. 3 with the carbon chamber 7 'is used. Both ends are combined to form a cap-shaped electrode part 2 so as to cover the vacuum hermetic container 3.

However, this method uses the desired number of bundles of desired carbon yarns (6) to create the desired resistance value to use the desired output (W), but the hassle of having to bind the carbon yarn (6) to the carbon chamber (7), If necessary, there is a problem of impregnating the liquid resin as necessary so that the bundled carbon chamber 7 is not peeled off.

In this type of heating lamp, the heating element is built in one vacuum sealing container to generate heat. Therefore, two lamps are used to adjust the intensity by using two lamps or by installing a separate variable resistor to adjust the output height. In the case of using, it is a factor of cost increase because additional lamps have to be purchased, and the method in which the variable resistor is additionally installed has a problem in that it consumes energy because there is electrical loss through the variable resistor.

The present invention is to solve this, it is an object of the present invention to provide a heating lamp that can be controlled by controlling the strength of at least one by attaching two lamps side by side.

Another object of the present invention is to use a carbon body as a heating means of each lamp, the carbon body is to provide a heating lamp having a heating means to bind the carbon yarn bundles to each other without a separate bonding means by binding the carbon bundle to each other. will be

To this end, two vacuum sealed containers used as heating lamps are formed side by side, and a heating element is built in each container, and the heating elements need separate carbon yarn coupling means separately from each other in order to separate the carbon yarn into a certain one. It is to provide a heating lamp that is easy to manufacture and reduce the cost by using a carbon body as a heat source.

1 is a configuration diagram of a typical carbon-based heating element,

FIG. 2 is an enlarged view of main parts of the carbon body used in FIG. 1; FIG.

3 is a view showing a state of binding using three carbon bodies of FIG.

4 is a lamp configuration of the present invention,

5 is a cross-sectional view taken along the line A-A of FIG.

6 is a configuration diagram showing an example of a carbon body used in the present invention;

7 is an enlarged view illustrating a main part of the coupling structure of the fixed terminal and the carbon body according to the present invention;

8 is a view showing another example of the fixed terminal of the present invention,

9 is an exemplary diagram of wiring of a carbon body used in the present invention.

Explanation of symbols for the main parts of the drawings

6; carbon company 10; carbon body

11; first carbon yarn 12; second carbon yarn

13; third carbon yarn 14; overlap

15; overlap hole 20; fixed terminal

21; connecting piece 23; winding part

25; Spring 30; Vacuum sealed container

31; first vacuum sealed container 32; second vacuum sealed container

That is, the present invention is a heating lamp for an electric stove made of a built-in heating element in a vacuum glass tube (sealed container) to supply power to an external terminal,

Two vacuum sealed containers are formed side by side in the longitudinal direction,

It is to provide a double tube heating lamp that is configured to have a heating element built in each vacuum sealed container, and each heating element is exposed by coupling terminals at both ends.

The heating element stored in each vacuum-sealing container includes a carbon body having a predetermined length separated from the first to third carbon yarns divided by carbon bundles, which are carbon yarns, and

It may be configured to include a fixed terminal to be bent at both ends of the carbon body by winding each carbon yarn so as not to loosen and fixed to the external terminal.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a configuration diagram of the present invention, a vacuum sealed container 30 having two vacuum glass tubes (sealed containers) made up of first and second vacuum sealed containers 31 and 32 side by side;

Each vacuum sealing container (31, 32) consists of a terminal (3) exposed to the outside to be connected to the built-in heating element.

FIG. 5 is a cross-sectional view taken along the line A-A of FIG. 4, wherein a vacuum body is incorporated in each vacuum sealing container 31, and a preferred example of the heating element is a carbon body. This is fixed to both ends of the carbon body 10 is divided into a certain number of fixed terminals 20, the fixed terminal 20 is fixed to the terminal 3 through the connecting piece 21. (3) is a vacuum sealed container. 3-1) is made to fix the terminal 3 while sealing both ends of the vacuum hermetic container 3.

Fig. 6 is an enlarged configuration of the main body of the carbon body forming the main part of the present invention. The carbon yarn 6, which is a carbon yarn composed of a bundle, is divided into first to third carbon bundles 11, 12, and 13, The carbons (11, 12, 13) are mutually different, as if they were winning. Then, the carbon yarns 6 are grouped and bound together in a predetermined length.

FIG. 7 is a main configuration of the main body of the carbon body 10 according to the present invention. Each of the ends of the carbon body 10 is partially bent to include an overlapping portion 14, and an overlapping hole formed by the overlapping portion 14. One end of the fixed terminal 20 is inserted into (15), and then the overlapped portion 14 is wound around the winding portion 23 to be fixed.

8 is another configuration of the fixed terminal constituting the present invention, the overlapping portion 14 is placed on both ends of the carbon body 10, the overlapping portion 14 is wound around the fixed terminal 20 through the overlapping hole 15 The spring portion 25 is added to the interface with the overlapping portion 14 of the fixed terminal 20.

9 is an exemplary wiring configuration of the present invention, in which two carbon bodies 10 are used, and each carbon body 10 is operated by selectively or simultaneously operating the switches SW1 and SW2. 10) can be operated in various ways as desired by the user.

Fig. 10 is a table showing an example of the number of strands of carbon aggregates used in the present invention and the resistance thereto.

The carbon yarn assembly used in the present invention was installed in a vacuum glass tube (vacuum airtight container) to be able to withstand high heat, and used as a planar heating element, so that the carbon yarn assembly can be used as a lamp for an electric stove. It is possible to design the required output (watts) by using the principle of the difference of the resistance value and the length increase, the resistance value increases, the resistance value decreases when the number of bundles of carbon yarn increases. In addition, the present invention is because the built-in carbon body 10 in the vacuum sealing container 3 of the glass tube, the oxidation of the carbon body 10 is basically blocked, so the durability is semi-permanent.

At the time of design, for example, when the power supply is 220 volts, the carbon aggregate is 60 ohms per meter, and the length is 1 meter, the output (watt) is ( ) Therefore, if the length is folded and shortened based on the basis of such output, it is possible to manufacture the lamp of the same output by selecting the glass tube length of the lamp as desired. In fact, it was confirmed that the heat generation of 700-800 degrees, satisfactory conditions for use as a heater. This is because the inside of the glass tube 5 is a vacuum, the oxidation is fundamentally blocked, it is determined that the desired output can be provided by adjusting the resistance value according to the length.

In addition, according to the present invention, according to the first to third carbon yarns 11-13 consisting of a bundle of carbon yarns 6, the carbon yarns 6 having a predetermined bundle form the carbon body 10. In particular, the present invention is because the carbon body 10, as shown in Fig. 6, the shape is picked up so that the thickness is thinner can form the overlapping portion 14, one end of the fixed terminal 20 between the overlapping portion 14 It is inserted into the overlap hole (15) of the to be wound by the winding portion (23).

In addition, according to the present invention, when the spring portion 25 is placed on the fixed terminal 20 as shown in FIG. 8, the fixed terminal 20 is wound around the winding portion 23, and at the same time, the spring portion 25 is elastically elastic to form a carbon body. Provide tension to (10).

In addition, in the present invention, when one carbon body 10 is turned on, one of the switches SW1 and SW2 as shown in FIG. 9, one of the first vacuum sealing container 31 and the second vacuum sealing container 32 is turned on. Normally one heater operates as it does, producing a heat source of moderate intensity. However, when the switches SW1 and SW2 are turned on at the same time, the first vacuum-sealing container 31 and the second sealed container 32 are simultaneously turned on to provide the same effect as operating two heaters at the same time. Function to select.

The present invention described above is not limited to the above-described embodiments and drawings, and various permutations, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those who have That is, the double tube heating lamp of the present invention can be implemented as a tungsten spring that serves as a heating source of the halogen heater instead of the carbon body as a means for heating.

As described above, the present invention attaches two vacuum sealed containers side by side and uses a built-in heating element, respectively, so that the two can be used simultaneously or selectively in various ways, and as a heating element, a carbon aggregate (carbon yarn) is used. The carbon yarns are divided into several carbon yarns, which are separated from each other to form carbon bodies in the form of a dendrite.These carbon bodies are used as heating elements for the carbon yarn lamps, so that the carbon yarns are separated into carbon bodies. Since no means is required, the manufacturing process is simplified, and the overlapped portions are placed at both ends of the carbon body to be fixed and wound with fixed terminals, and thus used as a power supply terminal.

If necessary, if the spring part is placed on the fixed terminal, the tensile force of the spring prevents the carbon body from bending or stretching, thereby improving durability.

Claims (3)

In a heating lamp for an electric stove made of a heating element embedded in a vacuum glass tube (sealed container) to supply power to an external terminal, A vacuum sealed container 30 in which two first and second vacuum sealed containers 31 and 32 are formed side by side in a longitudinal direction; A heating element built into each vacuum sealing container (31,32), A double tube heating lamp comprising a terminal (3) configured to be coupled to both ends of each heating element to be exposed to the outside of the hermetic container. The method of claim 1, The heating element stored in each vacuum-sealing container (31, 32) is a carbon body of a predetermined length separated from the first to third carbon yarns (11, 12, 13) by dividing the carbon yarn (6) of the carbon yarn into several bundles ( 10), and Double bent heating lamp, characterized in that consisting of a fixed terminal 20 to be fixed to the external terminal by winding both ends of the carbon body (10) so that each carbon yarn (6) is not loosened. The double tube heating lamp according to claim 2, further comprising a spring portion (25) provided at the center of the fixed terminal (20) to provide a tensile force for pulling both ends of the carbon body (10).