KR101767533B1 - Heating container housing and apparatus which for double lamp fluorescent powder coating - Google Patents

Abstract

The present invention relates to a double tube fluorescent lamp powder firing method, comprising: a double-tube fluorescent powder firing storage housing supply unit; A double tube firing and sequential conveyor unit for receiving at least one of the double tube fluorescent powder firing storage housings from the double tube fluorescent powder firing storage housing supply unit; A double pipe fluorescent powder firing receiving housing receiving part for receiving the fired double pipe fluorescent powder firing housing from the conveyor part; A thermal heating unit installed at the upper and lower portions of the sequential moving conveyor unit and serving as a top and bottom ground portion or a heater unit for sidewall firing; And an injection unit disposed at a side of the conveyor and injecting oxygen or purified air for discharging foreign matter and gas generated during the firing of the dual pipe adjacent to the ports at both ends of the storage housing. As described above, according to the present invention, it is possible to smoothly produce the fluorescent powder dual tube lamp developed for the first time in the world by providing a method of firing a fluorescent powder coated on the outer wall of the inner glass tube of the dual tube lamp. In addition, it is possible to contribute to productivity increase by proposing semiautomatic and automatic machinery.

Double tube, lamp, firing, fluorescent, powder

Description

Technical Field [0001] The present invention relates to a housing for housing a fluorescent lamp powder,

FIG. 1A is a schematic view of a double tube provided with a stopper at both ends for firing an outer end glass tube of both ends and an inner end glass tube of a double end tube in the embodiment of the present invention. FIG.

FIG. 1B is a schematic view of a dual tube device having a capping section at both ends for firing the same straight tube type double tube lamp according to an embodiment of the present invention. FIG.

FIGS. 2A to 2E are cross-sectional views illustrating the structure of a housing for firing a fluorescent powder in the form of an inner glass tube wrapped around an inner tube according to an embodiment of the present invention

FIG. 3 is a schematic view of a housing for firing a fluorescent powder with coupling means for preventing the stoppers mounted on both sides from falling off in an embodiment of the present invention

FIG. 4 is a schematic view of a housing for firing a fluorescent powder with a coupling means and a support member corresponding to the diameter of the inner glass tube so as to prevent the stoppers mounted on both sides in the embodiment according to the present invention from falling off

5 and 6 are schematic views of a housing for firing a fluorescent powder fired in the longitudinal direction for easy storage of the inner glass tube in the embodiment of the present invention

FIG. 7 is a schematic view of a table type double tube fluorescent powder calcining apparatus according to an embodiment of the present invention

8 is a schematic view of a conveyor type double tube fluorescent powder calcining apparatus according to an embodiment of the present invention.

Description of the Related Art

01: Double tube lamp 02: Outer tube glass tube

03: inner glass tube 05, 06: inner and outer fluorescent powder

       08: Stopper

       41, 50, 56, 62, 69: Housing housing body for fluorescent powder firing

       111, < / RTI > 121: housed housings for incision type fluorescent powder firing

       125: Turntable-type dual tube fluorescent powder firing device

       141: Conveyor type double tube fluorescent powder calcining device

The present invention relates to a housing for dual tube fluorescent powder firing and a double tube lamp fluorescent powder firing apparatus. Fluorescent powders of tubes located on the outside of two glass tube tubes, which are different from each other in the dual tube, are usually fired in the same manner as in the conventional single tube lamp. However, since the tube located inside the double tube is coated with the fluorescent powder on the outer wall of the tube, the space between the inner and outer glass tubes of the double tube forms a discharge space, and in order to obtain a high luminance and a large light quantity, So as to secure more fluorescent powder area. Therefore, since the outer wall of the inner tube is coated on the inner wall of the tube located outside, fluorescent powder firing method different from the method of firing the fluorescent powder of the tube located outside the two tubes is provided in the inner glass tube tube. Since the single tube type lamps are formed as a single tube, the inner tube of the glass tube is coated and the general firing method is explained. The glass tube tube is placed on the rotating roller in the horizontal direction on the ground, And the firing work is carried out. At this time, the gas torch or the heat ray are placed under the roller, and the fluorescent powder of the glass tube is fired by sequentially varying the temperature for each position. At this time, oxygen or purified air is blown in accordance with the degree of firing, so that moisture, foreign matter, gas, or polymer compound generated when the glass tube is fired in one direction from the one side to the inside of the tube is discharged from the inside of the tube . Another method is a method of firing by using a heater box. In this method, a lamp requiring firing is inserted into a heater box of a certain high temperature, and the glass tube is fixed or rotated and fired for a predetermined time. At this time, And oxygen or air is also blown in order to discharge foreign substances generated during firing. However, these methods are only possible or appropriate when fluorescent tubes are coated inside a glass tube, such as a single tube lamp. In the inner glass tube firing of the dual tube lamp, there is a problem that the unnecessary coated tongue powder should be removed between the narrow inner and outer glass tubes which can not be solved only by the single tube fluorescent lamp firing method as described above. In addition, in the dual tube lamp, since the fluorescent layer of the inner glass tube tube needs to be thicker than the fluorescent layer of the outer glass tube tube, the inner and outer simultaneous fluorescent powder coating and the co-firing can be originally limited. Of course, the scope of right of the present invention also includes simultaneous firing followed by coating of the inner and outer glass tubes.

In order to solve the above-mentioned problems, the present invention has been made to solve the above-mentioned problems by applying a housing for fusing a fluorescent powder mainly enclosing an inner glass tube tube, and thus, a fluorescent powder coated on the outer wall of the inner glass tube can be sintered without being damaged, And to provide a housing and a dual tube fluorescent powder firing apparatus. Within the scope of the present invention, the outer glass tube tube also serves as the housing housing. That is, simultaneous firing under the simultaneous coating of the inner and outer glass tubes is also within the scope of this right.

In order to solve the above-described technical problem, the present invention is characterized in that in the double tube lamp firing, an inner glass tube tube is wrapped to prevent the fluorescent powder coated on the outer wall of the inner glass tube tube during firing and uniform heat transfer A cylindrical shape in which a rolling operation is easily performed when a rolling operation is required, or a cylindrical shape in which both ends are partially extended like a dumbbell shape, and a through hole is formed at both ends of the cylindrical housing to facilitate entry and exit of air, .

The reason why the cylindrical shape having both ends extended partially as in the above-mentioned dumbbell shape is required is that the inner expandable glass tube of the both ends is taken as a countermeasure against the problem that the through hole capable of flowing air relatively can not be large. Of course, it is also possible to take a large diameter as a general uniform diameter cylindrical shape.

 The present invention also provides a housing for fluorescent powder firing, wherein the fluorescent powder firing storage housing is an outer glass tube tube itself.

In the coating and firing of glass tube tubes with inner and outer glass tube tubes such as dual tube lamps, it is simple to coat both inner and outer glass tube tubes simultaneously and simultaneously at the same time. In this case, however, The bonding process can not be ignored. It is advantageous to enlarge or reduce the diameter of one or both sides of the inner and outer glass tube tubes before or during the coating process. In another case, the space of the inner and outer glass tube tubes is narrowed. As described above, In this case, in order to facilitate the joining of the subsequent joining portions, the fluorescent powder in the joining portion is removed. In the process of coating and firing the glass tube simultaneously at the same time as described above, Before and after bonding, the inner side of the outer edge should be removed at the same time by inserting a brush or other brush into the outer edge of the outer edge of both edges of the inner edge, which is difficult to work due to the narrow space . If the outer tube of glass tube is wide, the glass tube area should be melted as much as the distance of the inner tube and the outer tube. This means that the bonding time and efficiency are low and even if the diaphragm is jointed, If the glass tube is not opened, the thermal expansion coefficient changes according to the difference in the thickness of the united portion and the untreated portion. When the glass tube is cooled, the connection portion breaks due to cooling, or the process of carefully aligning the glass portion of the junction beforehand is added. . In the previous process, the inside of the heater box is exposed to a high temperature when vacuum is applied to the inside of the lamp and the inert gas is injected in the exhaust process, which is the next process, Is intended to achieve a high degree of vacuum inside the lamp. It is highly likely that the connection will not be able to withstand the inside of the high temperature heater box and break. Therefore, the process of separating the inner and outer glass tube is a more complete and efficient process. In the case of the inner glass tube tube, unlike a single tube type lamp coated with fluorescent powder coated on the outer wall, the roller is used for carrying the next stage during the uniform firing and firing of all the surfaces of the lamp. A fluorescent tube coated with fluorescent powder is liable to be peeled off or contaminated. In a heater box method, a fluorescent powder coated on the outer wall of a glass tube tube in a heater box is difficult to blow off various foreign substances generated during firing. to be. The reason is that when oxygen and air are blown outside the tube of the glass tube to discharge the foreign matter, the temperature is changed in the heater box and it is difficult to maintain a constant temperature. On the other hand, if air or oxygen is not blown, So that the foreign matter may float close to the surface of the outer wall surface, and the outer surface of the outer wall may adhere to the coating portion. However, it should be noted that even if a high-tech collector device is used, it can be fired to some extent without covering a glass tube to the outside even if it is a heater box type, and is included in the scope of the present invention. The dual tube lamp has two types of inner tubes formed to facilitate the bonding process of the inner and outer glass tube, which is the next type, There is a form in which the center part and the both ends of the tube are not the same diameter. Here, as a method for firing both types, a tubular storage housing is attached to the outside of the inner glass tube tube. In addition, the inner glass tube tube in the form of a built-in inner tube of the storage housing exhibits various built-in shapes depending on the shape of the glass tube and the shape of the stopper covering both ends. Basically, moisture, foreign matter and gas generated during the firing of the fluorescent powder can be easily discharged And the detailed description will be made by way of examples.

The fluorescent powder firing storage housing is composed of a pipe-shaped body portion surrounding the inner glass tube tube and a stopper having a through hole at both ends thereof.

In addition, the stopper may be provided with engaging means for maintaining a firmly attached state to the body portion.

Further, the coupling means is a leaf spring.

Further, the stopper is provided with a supporting member for supporting the inner diameter and outer diameter of the inner glass tube.

In addition, a ring-shaped ring for preventing damage of fluorescent powder on the outer wall of the inner glass tube tube of the straight tube type is attached to a portion where the fluorescent powder coating is not applied at both ends of the inner glass tube tube.

In addition, the support member for supporting the inner glass tube is divided into two to six in order to correspond to the inner glass tube of various diameters so that one side supports both ends of the four glass tube, one side is closely assembled and assembled in a lattice form on the outer surface of the tube, And is a supporting member which is fastened while its position is adjusted to a fastening opening.

The shape of the stopper may be such that it simply covers the outer diameter of the housing, and the entire stopper may be completely contained in the housing.

In addition, the fluorescent powder firing housing housing is provided with a fastening means at a predetermined position so that a center portion thereof is cut in the longitudinal direction so as to be easily accommodated.

The fastening means is provided at both ends with a flat protrusion having a diameter smaller than the outer diameter of the housing and a spring ring surrounding the outer circumference of the protrusion. And a groove for preventing the spring ring from being separated from the outer circumferential surface is formed.

In addition, the fluorescent powder firing storage housing includes a support member for supporting a portion of the outer wall of the inner glass tube tube where the fluorescent powder is not coated.

It is another object of the present invention to provide a dual tube fluorescent powder calcining apparatus, wherein the glass tube to be calcined is in a horizontal state in the double tube fluorescent powder calcining apparatus.

Further, the double tube fluorescent lamp powder firing housing housing supply part; A double tube firing and sequential conveyor unit for receiving at least one of the double tube fluorescent powder firing storage housings from the double tube fluorescent powder firing storage housing supply unit; A double pipe fluorescent powder firing receiving housing receiving part for receiving the fired double pipe fluorescent powder firing housing from the conveyor part; A thermal heating unit installed at the upper and lower portions of the sequential moving conveyor unit and serving as a torch portion or a heater portion provided at the upper or lower portion or mainly at the lower portion for the dual pipe firing; And an injection unit disposed at the side of the conveyor and injecting oxygen or purified air for discharging foreign matter and gas generated during the firing of the double pipe adjacent to the passages at both ends of the receiving housing. I want to.

It is still another object of the present invention to provide a double tube fluorescent powder calcining apparatus in which a glass tube to be calcined is in a vertical state in a double tube fluorescent powder calcining apparatus.

Further, a circular table in which a flat section is placed horizontally with its flat section facing upward and which is rotated by a pitch; A mounting part disposed close to an outer circumferential surface of the circular table, the mounting part being rotatably mounted at a right angle to the double pipe fluorescent powder firing housing; A thermal heating unit in which the lamp housing for firing a dual tube fluorescent powder mounted on the mounting unit rotates while the circular table rotates and sequentially enters and is heated by a heater unit or a toothed unit; And an oxygen or refined air provided in a mounting portion for mounting the fluorescent powder fusing storage housing or for mounting the fluorescent powder fusing storage housing in order to discharge foreign materials and gas generated during the firing of the double tube through the through holes at the upper or lower end of the receiving housing for fluorescent powder firing And an injection unit for injecting the fluorescent lamp powder into the double tube fluorescent powder firing apparatus.

 Further, a circular table in which a flat section is placed horizontally with its flat section facing upward and which is rotated by a pitch; A mounting part disposed close to an outer circumferential surface of the circular table and mounted at a right angle with the inner glass tube in a state of a tube and having a rotation function; A thermal heating unit in which the inner glass tube mounted on the mounting unit rotates while the circular table rotates and is sequentially heated and heated by a heater or a torch; And a collecting part for collecting foreign matter and gas generated during firing of the inner glass tube tube. The present invention also provides an inner glass tube fluorescent powder firing device.

  In addition, the dual tube fluorescent powder calcining apparatus is characterized in that a mounting portion to be mounted in a state of an inner glass tube tube or to be mounted in a receiving housing for fluorescent powder firing is arranged in a straight line.

Further, the thermal heating unit of the dual pipe firing apparatus is characterized in that a function of opening and closing is added.

The body and the stopper are made of a glass tube, a ceramic or a metal.

It is another object of the present invention to provide a housing for firing housing, which is provided with a hinged door member at a predetermined position on the incision surface.

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

However, these drawings are for illustrative purposes only and the present invention is not limited thereto. Hereinafter, the present invention will be described in detail with reference to examples. However, these embodiments are for illustrative purposes only, and the present invention is not limited thereto.

Example 1

FIG. 1A is a schematic view of a double tube having a capping hole 08 at both ends for firing both ends-reduced outer glass tube and both-end-extended inner glass tube 2-tube lamp 01 according to an embodiment of the present invention. ) And an inner glass tube tube 03 in the form of a built-in fluorescent tube. The inner wall 05 and the outer wall 06 are coated with a fluorescent powder. A stopper 08 is attached to both ends of the inner tube 05 and the outer wall 06, And is used as a hole for discharging moisture, foreign matter, gas or the like generated in the space portion 04. [ The stopper has support members (10, 11, 12) which come in close contact with the outer wall at both ends of the inner glass tube and closely contact the inner wall of the outer glass tube. The space portion 07 of the inner glass tube can be sealed or open.

FIG. 1B is a schematic view of a dual tube device in which a cap 28 is provided at both ends for firing the same straight tube double tube lamp 21 according to an embodiment of the present invention. The outer tube 21 and the outer tube An inner glass tube tube 23 in the form of a built-in tube, and a stopper coupled to both ends. The stopper has a through hole 27 to discharge internal foreign substances. The detailed description of the inner and outer fluorescent layers 25 and 26 and the stopper support members 29, 30, 31, and 32 will be omitted.

Example 2

FIGS. 2A to 2E are cross-sectional views illustrating a structure of a housing for fusing a fluorescent powder enclosing an inner glass tube in an embodiment of the present invention. FIG. Referring to FIG. 2A, the following will be described. The inner glass tube 42 is coated with a fluorescent powder on the outer wall 44 and is provided with a stopper 46 at both ends thereof to cover the housing body 41 for firing the fluorescent powder for protecting the fluorescent glass powder tube 42 At the same time, the stopper is provided with a support member 49 for supporting the inner glass tube, and the detailed description of the stopper through-holes 47, 54, 60, 68, 75, 84 and 95 will be omitted.

2B shows a housing body 50 for fusing a fluorescent powder used in a fluorescent powder firing apparatus for a tube-expanding tube 52 at both ends, and a stopper 53 is mounted at both ends of the housing body 50, And an end portion 55 is formed to be coupled to the fluorescent powder firing storage housing. In this way, the coated surface 52 can be protected. It is preferable that the diameter of the outer peripheral surface of the stopper is smaller than the diameter of the outer peripheral surface of the housing. Both ends of the tube are placed on the end of the stopper, and in this case, the present invention can be applied to a tube having the same diameter.

The same diameter tube 57 is embedded in the housing body 56 for firing the fluorescent powder and both ends of the tube 57 are restrained by the end portion 61 of the stopper 59. As a result, The surface 58 is protected.

FIG. 2D shows a state in which both end enlarged tubes 63 are housed in the fluorescent powder firing housing body 62 and both ends 66 of the both end tubes are in close contact with the inner wall of the housing for firing the fluorescent powder So that the fluorescent powder coated surface 64 is naturally protected. In this case, the space portion 65 is enlarged, which is advantageous for discharging foreign matter through the stopper through-hole 68.

FIG. 2E shows that a ring-shaped ring is mounted on a portion of the tube not coated at both ends of the tube to protect the coating surface 72 of the tube 70 having the same diameter. The space portion 71 is enlarged and the discharge to the through hole 75 is facilitated. In this case, there is a disadvantage that materials are added.

FIG. 3 is a schematic view of a housing for firing a fluorescent powder having coupling means for preventing the stopper 83 mounted on both sides in the embodiment according to the present invention from falling off, and is a means for coupling the housing body 81 with the stopper 3 to 6 grooves 85 are provided at the ends of the end portions of the stopper, and the plate spring 86 is mounted in the end portions of the stopper 85, so that the mounting state can be maintained relatively securely by the elasticity of the leaf spring. The tube to be fired is of course embedded in the space portion 82.

Figure 4 is a perspective view of a support member 99 having a coupling means 97 in the groove 96 and corresponding to the diameter of the inner glass tube 98 so that the stoppers mounted on both sides in the embodiment of the present invention do not fall off, And the same diameter tube 92 having the coating surface 93 is installed at the center. When the diameters of the tubes 92 are different, a separate stopper must be used. However, according to the present invention, The supporting member 99 has two to six variable supporting members 99. The supporting member 99 has a groove for supporting both ends of the glass tube 98 at one end and the other end 100 is bent at a right angle, (101) to indicate a support member to be combined with a fastener (102).

Although not shown in the drawings, the shape of the stopper may include a shape covering the outer diameter of both ends of the housing housing, and the entire stopper may be completely contained in the housing.

Also, although not shown in the drawing, a plurality of glass tube tubes may be arranged in a line at the same time, and a predetermined separating member may be provided between the glass tube tubes.

5 is a schematic view of a fluorescent powder fusing storage housing 111 having a cut-out surface 112 cut in the longitudinal direction for easy storage of both end-fasciated inner glass tube 117 in the embodiment of the present invention And the fastening means is provided at a predetermined position. The fastening means is provided at both ends and includes a protruding portion 114 having a flat shape with a diameter smaller than the outer diameter of the housing, And a groove 115 for preventing the spring ring from being separated from the outer circumferential surface of the spring ring 116 is formed. The through holes 113 are formed at both ends of the housing for the fluorescent powder firing, so that the discharge of foreign matter and the like is facilitated.

5 is a perspective view of a housing for a fluorescent powder firing cut in the longitudinal direction for easy storage of the same diameter inner glass tube 124 according to an embodiment of the present invention, And that it is coupled by the spring ring 122. [0064] As shown in Fig.

Example 3

FIG. 7 is a schematic view of a table-type double tube fluorescent powder firing apparatus 125 according to an embodiment of the present invention. The circular table 126 is placed in a thin cylindrical shape with its flat surface facing upward, ; A mounting part 128 disposed close to the outer circumferential surface of the circular table and having a rotatable 129 function, the receiving housing for double tube fluorescent powder powder being mounted at right angles; A heating unit 131 having a heating unit 132 which rotates the circular table and is sequentially heated to be heated by the heater unit or the toothed unit while the receiving furnace for double tube fluorescent powder firing mounted on the mounting unit rotates 127, ; And an injection unit 133 installed in the thermal heating unit to inject oxygen or purified air for discharging foreign matter and gas generated during the firing of the double tube through the through hole at the upper or lower end of the fluorescent powder fusing storage housing. It is preferable that a mounting portion 130, an inspection portion 134, a good-quality take-out portion 136, and a defective take-out portion 135 to which a tube to be fired is mounted are additionally provided. It is also possible to adopt a configuration in which the mounting portion is arranged in a straight line by applying a chain sprocket method, for example, as well as a rotary type such as the turntable type.

Example 8

8 is a schematic view of a conveyor type double tube fluorescent powder firing apparatus 141 according to an embodiment of the present invention. This apparatus comprises a housing housing supply part 145 for double tube fluorescent powder firing; A double pipe firing and sequential conveyor unit for receiving at least one of the dual pipe fluorescent powder firing storage housings 146, 158, 161 from the double pipe fluorescent powder firing storage housing supply unit; And a housing housing discharge outlet 159 for double tube fluorescent powder firing which receives the baked double tube fluorescent powder firing housing from the conveyor section. The feeding and extraction of the double tube fluorescent powder are carried out through the inlet 147 of the firing furnace 142 and the outlet 160 ). A thermal heating unit 153 installed at the upper and lower parts of the sequential moving conveyor unit and serving as a top and bottom grounded part 154 for sintering the double pipe; And an injection unit (157) disposed at the side of the conveyor and adjacent to the through holes at both ends of the housing to inject oxygen or purified air for discharging foreign substances and gas generated during the double pipe firing. The conveyor part is driven by a pulley or a sprocket 152 and a belt or a chain 151 and is constituted by a rotating disc 148 and a holding part 150 of a receiving housing 158 provided on a part of the rotating disc. Basically, it is heated by the flame 155 while idling between the rotary disks, and at the same time, the discharge of the foreign substances is performed by the nozzle 157. And that when the predetermined time has elapsed, the housings are caused to advance one pitch by the holding portion of the rotating disk. The discharged foreign substances and the like are accumulated in the burning furnace, and it is preferable to further include a discharge port 144 for discharging them. The sintering furnace is preferably of a vertically separable type so as to facilitate the work. In addition, it is advantageous for smooth product movement that the rotating discs are arranged so as to overlap with each other. In addition, a product in the figure represents a moving state, and is practically held between rotating discs for a predetermined time. For example, fluorescent powder has foreign matter or gas discharged at 300 ° C, and there is something to be discharged at 700 ° C, and the conveyor part will place the torch part for this purpose. The number of oxygen or refined air injection nozzles in the turntable-type firing furnace or the conveyor-type firing furnace may have various numbers depending on the situation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the scope of the claims of the patent as well as equivalents thereof.

As described above, according to the present invention, there is provided a fluorescent powder calcining apparatus coated on the outer wall of an inner glass tube of a dual tube lamp, and a fluorescent powder coated on a glass tube outer wall It enables the firing of the powder from the desired temperature to the desired state and firing of the coated fluorescent powder of the double tube lamp can be carried out in the same manner as in the conventional single tube type glass tube furnace, It is possible to solve problems related to the handling of the fluorescent powder coated on the outside of the glass tube during transportation and other works. By providing this solution for the first time, it is possible to produce the fluorescent powder dual tube lamp developed for the first time in the world. In addition, it is possible to contribute to productivity increase by proposing semiautomatic and automatic machinery.

Claims (21)

An outer glass tube which forms an outer surface and has an inner wall formed on an inner circumferential surface thereof, an inner glass tube which is spaced apart from the outer glass tube and has an outer wall formed on the outer circumference thereof, And a cap for shielding both ends of the outer glass tube and the inner glass tube; Wherein a space portion is formed between the outer glass tube and the inner glass tube and a through hole communicating with the space is formed in the stopper so that the material inside the space is guided to the outside. Further comprising: a support member for supporting both ends of the outer glass tube and the inner glass tube in close contact with the outer wall at both ends of the inner glass tube and the inner wall at both ends of the outer glass tube, Wherein the stopper is further provided at one side of the stopper so that the stopper is not detached from the body part forming the outer tube or the outer glass tube, Wherein the coupling means comprises a leaf spring provided in a groove formed to be recessed inwardly from an outer surface of the stopper, wherein ring-shaped rings are further provided at both ends of the inner tube glass tube to prevent fluorescent powder damage To prevent it; Wherein the support member comprises: And two ends of the inner glass tube are supported by one end and the other end is tightly combined with the outer surface of the stopper in a lumped configuration and the other end is tightened while adjusting its position with a separate fastener. The fastening means, And a spring ring which is positioned at both ends of the inner glass tube and has a flat shape having a diameter smaller than an outer diameter of the housing to form an outer tube, and a spring ring surrounding the outer circumference of the projection; And a groove is formed on an outer circumferential surface of the protruding portion to prevent the spring ring from being separated. A circular table (126) having a cylindrical shape and horizontally laid with the flat portion facing upward, and rotatingly feeding the pitches one by one; A mounting part 128 disposed at one side of the outer circumferential surface of the circular table, the mounting part 128 having a function of rotation 129 mounted at right angles to the double pipe fluorescent powder firing housing; The heating housing 132 for heating the double tube fluorescent powder loaded in the mounting portion is heated and heated by the rotation 127 and the heating portion 132 having the heater portion or the torch portion sequentially in accordance with the rotation of the circular table, 131); An injection unit 133 installed in the heat heating unit 131 for injecting oxygen or purified air to discharge foreign materials and gas generated during the firing of the double tube through the through holes at the upper or lower end of the fluorescent powder firing storage housing; Wherein the fluorescent powder is fired. A double tube firing and storage chamber housing supply part 145 for firing the dual tube fluorescent powder and a double pipe firing and sequential moving conveyor part 150 for receiving at least one of the double tube fluorescent powder firing storage housings 146, 158 and 161 from the double tube fluorescent powder firing storage housing supply part A double tube fluorescent powder firing receiving housing 159 for receiving the fired dual tube fluorescent powder firing housing from the conveyor part, a double tube fluorescent lamp powder firing housing 159 formed on the right and left sides of the firing furnace 142 146 and 161 for introducing and discharging the sludge into and out of the sintering furnace 142 and a heat heating unit (not shown) provided at the upper and lower portions of the sequential moving conveyor unit and having upper and lower earthed portions 154 153) provided at one side of the conveyor and adjacent to the through-holes at both ends of the housing housing, An injecting part 157 for injecting oxygen or purified air into the baking furnace 142 for discharging a foreign substance and a gas and an exhaust part 157 formed at one side of the baking furnace 142 for discharging accumulated substances inside the baking furnace 142 And a guiding outlet (144); The conveyor portion A pulley sprocket 152 for driving, a belt or a chain 151, and a receiving housing 158 holding part 150 formed on a part of the rotating disk 148 and the rotating disk; The double pipe fluorescent powder fusing storage housing 158 is mounted on the holding portion 150 of the rotary disk and is rotated by a pitch in accordance with the rotation of the disk and the rotation of the rotary disk, 155). ≪ / RTI > delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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