KR101322906B1 - High frequency rotary drying apparatus for pipe insulation cover using glassfiber - Google Patents

Abstract

The present invention relates to a rotary high-frequency drying device of pipe cover thermal insulation using glass fiber, according to the existing high-frequency drying device is difficult to maintain the vacuum state inside the drying chamber by the transfer of the product, when drying multiple products at the same time There is a problem that the dry state is not uniform depending on the location of the product.
Therefore, in the present invention, a drying chamber, a vacuum unit for maintaining the interior of the drying chamber in a vacuum state, a rotary cartridge and the rotary jig formed by applying a glass fiber pipe cover before drying is rotated through the rotating unit, and in the upper part of the drying chamber Vacuum state of drying chamber by irradiating high frequency to glass fiber pipe cover in high frequency drying device composed of (-) electrode guide which is mounted and moves up and down to the center of cartridge and high frequency generator mounted on one side of drying chamber. Moisture contained in the glass fiber pipe cover to quickly remove the moisture, and the dry state becomes uniform regardless of the position of the glass fiber pipe cover loaded in the cartridge, the second transfer rail connected in two directions with the first transfer rail By continuously supplying cartridges equipped with products to increase the efficiency of the drying process. And it is.

Description

Rotary high frequency drying device for pipe cover thermal insulation using glass fiber {HIGH FREQUENCY ROTARY DRYING APPARATUS FOR PIPE INSULATION COVER USING GLASSFIBER}

The present invention relates to a drying apparatus for drying a glass fiber pipe cover for pipe insulation to cover the surface of the pipe to maintain the heat insulation and heat insulation of the pipe, and more particularly after maintaining the drying chamber in a vacuum state through a vacuum unit A glass fiber pipe cover formed by applying an emulsion at a high frequency at a high frequency in a glass fiber, and applying an E-glass fiber, which is a type of glass fiber, and a binder to solidify the E glass fiber, in an emulsion state. The present invention relates to a rotary high frequency drying device for pipe cover thermal insulation using glass fibers for evaporating moisture contained in the interior of the apparatus.

In general, the pipe cover to insulate and insulate the pipe is made of foamed polyurethane, and the foamed polyurethane pipe cover is configured to wrap the pipe by vertically cutting the center portion.

However, since the foamed polyurethane pipe cover has a problem that the glass transition point of the foamed polyurethane is low, the foaming uniformity is lowered, and the thickness of the pipe cover is increased in the process of foaming. After mixing and molding the binder in the fiber, the moisture contained in the binder is dried to prepare a cover.

Drying by high frequency heating disclosed in Korean Patent Publication No. 10-0407828 (2003.11.19) and Korean Patent Publication No. 10-0936833 (2010.01.06) in addition to the hot air circulation method as a method of drying the moisture contained in the product. The method is mainly used, the high frequency drying device of the method disclosed in Republic of Korea Patent Publication No. 10-0407828 (Nov. 19, 2003) to maintain the vacuum state of the drying chamber by the sludge or garbage is continuously supplied and discharged from the outside by the conveyor belt The high frequency drying apparatus of the method disclosed in Republic of Korea Patent Publication No. 10-0936833 (2010.01.06) has a problem that the drying state is not uniform depending on the position of the product when a plurality of products are dried at the same time.

Republic of Korea Patent Publication No. 10-0407828 (2003.11.19) Republic of Korea Patent Publication No. 10-0936833 (2010.01.06)

In order to solve the problems as described above, in the present invention, the drying chamber, the vacuum unit for maintaining the interior of the drying chamber in a vacuum state, and the jig in which the glass fiber pipe cover before drying is mounted to rotate through the rotating unit. In the high frequency drying device consisting of a high-frequency drying device comprising a cartridge which is mounted on the top of the drying chamber, a negative electrode guide which is mounted on the upper part of the drying chamber and moves up and down to the center of the cartridge. When irradiated, it maintains the vacuum of the drying chamber to quickly remove moisture contained in the glass fiber pipe cover, and provides the effect of uniform drying condition regardless of the position of the glass fiber pipe cover loaded in the cartridge. There is this.

In order to achieve the object, the configuration includes a vacuum unit configured to connect a vacuum tank and a vacuum pump to a first pipe; The vacuum unit and the first pipe are connected to each other, and a door is mounted on the front, and a door opening and closing device operated by a hydraulic cylinder is mounted on the upper part of the door so that the door can be opened and lowered and opened and closed. A drying chamber in which one rotating unit is mounted and configured to mount a first transfer rail at a lower part of the door; A high frequency generator is mounted on one side of the drying chamber opposite to the door, and a (-) electrode guide is mounted on the upper part of the drying chamber, and the (-) electrode guide is lifted inside the drying chamber by an electrode guide lifting device equipped with a hydraulic cylinder. A high frequency unit configured to descend; The upper unit composed of the support and the first and second rotating plates, the first rotating plate and the second rotating plate having a cavity formed on the upper and lower surfaces of the supporting column are respectively coupled to each other, and a plurality of first formed on the edges of the first and second rotating plates. 2, the fixing groove is a cylindrical shape jig (jig) is formed in the upper and lower fixing pins and the lower fixing pin is connected, the upper unit is coupled to the lower unit through the rotating shaft, the lower unit and the first conveying rail Connected by hydraulic cylinder, when the hydraulic cylinder is operated, a plurality of transport wheels are mounted on the lower surface of the lower unit to slide along the first transport rail, and the second rotating unit composed of a motor and a gear is coupled to the rotary shaft to The first rotating unit and the second rotating unit are connected to each other through a cavity formed at a side end of the unit, and the cart is configured to rotate the upper unit by a motor mounted on the first rotating unit. It consists of; not.

In another aspect of the present invention, the vacuum unit further comprises a second pipe directly connecting the vacuum tank and the drying chamber.

In another aspect of the present invention, the high frequency generator generates a high frequency of 13.56 MHz or 27.12 MHz to achieve high frequency dielectric heating.

In another aspect of the invention, the cartridge is made of polyethylene.

In still another aspect of the present invention, the first and second fixing grooves have a 'Sh' shape having an acute angle. It is made to be fixed at the bend of the shape.

In still another aspect of the present invention, the first and second rotary units include a motor, a worm gear, a worm wheel, a first coupling gear, a main gear, an auxiliary gear, a first sprocket, a chain, a second sprocket, a first bevel gear, and a first 2 bevel gear and the second coupling gear, the motor of the first rotary unit is mounted on one side of the drying chamber, the worm gear is connected to the end of the rotating shaft of the motor, the worm wheel is connected to the worm wheel, the worm wheel is the first coupling It is connected to the gear, the main gear of the second rotary unit is coupled to the rotating shaft, the auxiliary gear is connected to the main gear, the first sprocket having the same rotation axis as the auxiliary gear is attached to the lower portion of the auxiliary gear, the first sprocket It is connected to the second sprocket through the chain, the first bevel gear having the same axis of rotation as the second sprocket is connected to the lower portion of the second sprocket, the second bevel gear is connected to the first bevel gear perpendicular to the second bevel gear, Is the second coupling gear It is connected, first and second cartridge is made of the upper unit so as to rotate when the gear coupling the motor to function after combining.

In still another aspect of the present invention, the first conveying rail is composed of a pair of rails and a first conveying device so that the cartridge can move inside and outside of the drying chamber, and the first conveying device has two bars. The center portion of the frame is coupled to be staggered by the coupling pins, and the ends of the frame, the center portion of which is staggered, are connected to the ends of the other frames by the coupling pins, and a plurality of 'X' shapes are connected in an arrangement. One end of the frame joined in an arrangement of two 'X's is connected to the underside of the lower unit of the cartridge, the opposite end is connected to the rail end opposite the drying chamber, and the hydraulic cylinder is crossed with the rail end opposite the drying chamber and the' X 'shape. By connecting with one of the center coupling pins of the frame coupled to the upper and lower frames, the cartridge is moved in and out of the drying chamber along the first transfer rail by the operation of the hydraulic cylinder. It is done to help.

In another aspect of the present invention, the first conveying rail is divided into two directions at the end of the first conveying rail to be perpendicular to the second conveying rail consisting of a rail, a second conveying device and a conveying cart, The second transfer device installed at the distal end of the rail is coupled so that the center portions of the two bar-shaped frames are staggered by the coupling pins, and the ends of the frames coupled with the center portions are staggered from each other by the coupling pins. It is connected to the end is connected to the shape of a plurality of 'X' arrangement, one end of the frame coupled to a plurality of 'X' arrangement is connected to the bottom side of the transfer cart, the other end is connected to the rail end And the hydraulic cylinder is connected with one of the rail coupling in the opposite direction of the first transfer rail and one of the center engaging pins of the frame to be staggered in the 'X' shape, thereby being transferred by the operation of the hydraulic cylinder. The agent can move and slide along the rail, a plurality of transfer wheels is connected to the bottom rail of the transfer cart is formed, made so that the extension rail which is formed the upper surface of the cart is connected to the transfer rail.

As described above, the present invention consists of a vacuum unit for making and maintaining a vacuum inside the drying chamber, a high frequency unit for drying moisture, and a cartridge equipped with a rotating unit, and the glass fiber as the interior of the drying chamber is in a vacuum state. By lowering the boiling point of the moisture contained in the glass fiber and binder in the emulsion state before drying the pipe cover, the electric energy supplied to the high frequency unit is reduced, and the drying time of the glass fiber pipe cover is reduced, and the rotating unit By rotating a plurality of products mounted on the cartridge by the high frequency generated from the high frequency unit is uniformly irradiated, the effect of obtaining a uniform dry state in the plurality of products mounted on the cartridge, and the vacuum unit Connect the vacuum tank and the drying chamber, and connect the vacuum tank without the first pipe and the vacuum pump It is made of a second pipe connected by contact, which makes it possible to quickly create a vacuum inside the drying chamber, and forms a cavity in the center of the first rotating plate of the cartridge in which the jig of the product is mounted so that the (-) electrode guide is moved into the cartridge. By allowing the lifting and lowering, the loading space of the cartridge can be effectively utilized, and the cartridge equipped with the product can be continuously supplied by the second transfer rail connected in two directions with the first transfer rail to increase the efficiency of the drying process. It has an effect.

1 is a plan view of a first embodiment of a rotary high-frequency drying device of a pipe cover thermal insulation using glass fibers according to the present invention.
Figure 2 is a plan view of a second embodiment of a rotary high-frequency drying device of the pipe cover thermal insulation using glass fiber according to the present invention.
3 is a plan view of a third embodiment of a rotary high-frequency drying device of the pipe cover thermal insulation using glass fibers according to the present invention.
4 is a front view and door operating sequence of a drying chamber according to the present invention.
5 is a front view of the drying chamber and the (-) electrode guide operation sequence according to the present invention.
6 is a sequence of operations of the (-) electrode guide and the cartridge according to the present invention.
7 is a plan view and a front view of a cartridge and a jig according to the present invention.
8 is a plan view of the first and second rotating units and the first and second coupling gears according to the present invention;
9 is a front view and a side view of the cartridge according to the present invention.
10 is a front view and an operating sequence of the first and second transfer rails and the auxiliary transfer rail according to the present invention;
11 is an operation sequence of the first and second transfer apparatus according to the present invention.

1 is a plan view of a rotary high-frequency drying device of a pipe cover insulating insulation using a glass fiber according to the present invention, Figure 2 is a second embodiment of a rotary high-frequency drying device of a pipe cover insulating insulation using a glass fiber according to the present invention 3 is a plan view of a third embodiment of a rotary high frequency drying apparatus of a pipe cover thermal insulation using glass fibers according to the present invention, FIG. 4 is a front view and a door operation sequence of the drying chamber according to the present invention, and FIG. Is a front view of a drying chamber and a (-) electrode guide operating sequence according to the present invention, FIG. 6 is an operating sequence of a (-) electrode guide and a cartridge according to the present invention, and FIG. 7 is a plan view of a cartridge and a jig according to the present invention. And a front view, FIG. 8 is a plan view of the first and second rotating units and the first and second coupling gears according to the present invention, and FIG. 9 is a front view of the cartridge according to the present invention and Shaving, and FIG. 10 is a front view and a sequence operation of the first and second transfer rail and the secondary transfer rail according to the invention, Figure 11 is a operating sequence of the first and second transfer device according to the invention.

Hereinafter, components according to the present invention will be described with reference to the drawings.

As shown in FIG. 1, the first embodiment of the rotary high frequency drying apparatus for pipe cover thermal insulation using glass fiber according to the present invention includes a vacuum tank 110, a vacuum pump 120, and a first pipe 130. Vacuum unit 100 is configured, the drying chamber 200 composed of a door (door: 210), the first conveying rail 220 and the first rotating unit 230, and the high frequency generator (310) and (-) It consists of a high frequency unit 300 consisting of an electrode guide 320, a jig 410, an upper unit 420, a lower unit 440 and a cartridge 400 consisting of a second rotating unit 450, Control of each component is possible by the operation panel 500 not shown in the figure.

In detail, the vacuum unit 100 is coupled to one end of the first pipe 130 to one side of the vacuum tank 110 having a spherical shape, the vacuum pump 120 and the middle of the first pipe 130 The valve 131 is mounted, and the other end of the first pipe 130 is combined with the drying chamber 200 to connect the vacuum tank 110 and the drying chamber 200.

In addition, the drying chamber 200 has a door 210 formed on the front, the door opening and closing device 211 which is operated by the hydraulic cylinder 212 is mounted on both sides of the upper portion of the door 210, the door 210 One side of the opposite drying chamber 200 is mounted with a high frequency generator 310 and the first rotating unit 230, the (-) electrode guide 320 is mounted on the drying chamber 200, the (-) electrode guide ( The electrode guide elevating device 321 operating as the hydraulic cylinder 321a is mounted on the upper portion of the 320, so that the (-) electrode guide 320 can move up and down inside the drying chamber 200.

Here, the first transport rail 220 to which the first transport device 222 acting as the hydraulic cylinder 222c is installed below the door 210, the rail 221 of the first transport rail 220 is installed. The cartridge 400 to move to the interior or exterior of the drying chamber 200, the coupling method of the frame 222a, the coupling pin 22b and the hydraulic cylinder 222c constituting the first transfer device 222 is As follows.

One pair of rails 221 are formed on the first transfer rail 220 in parallel with each other in the first transfer rail 220, one end of which is connected to the inside of the drying chamber 200, and a central portion thereof is coupled to the coupling pin 222b. Ends of two bar-shaped frames 222a alternately connected are connected to each other by a coupling pin 222b, and one end of the plurality of connected frames 222a is distal of the rail 221 opposite to the drying chamber 200. And the opposite ends of the plurality of connected frames 222a are connected to the bottom surface of the lower unit 440 of the cartridge 400 so as to cross the ends of the rails 221 opposite the drying chamber 200 and to form an 'X' shape. When the hydraulic cylinder 222c connected to one of the center coupling pins 222b of the frame 222a is operated, the cartridge 400 may enter and exit the interior and exterior of the drying chamber 200 along the first transfer rail 220. .

In addition, the cartridge 400 is made of polyethylene, and as shown in FIG. 7, a cavity is formed in the center, and a first fixing groove 422a having a plurality of 'し' shapes is formed at the edge. A disk-shaped first rotating plate 422 and a disk-shaped second rotating plate 423 having a plurality of 'shi'-shaped second fixing grooves 423a at the edges are respectively disposed on the upper and lower portions of the support 421. The upper unit 420 is coupled to the upper unit 420 and the rotary shaft 430 is connected by the lower unit 440 and the rotary shaft 430 is equipped with a transfer wheel 441 on the lower side is connected to the upper The jig 410 is formed of a second rotating unit 450 to allow the unit 420 to rotate, and the upper fixing pin 411 and the lower fixing pin 412 formed on the upper and lower surfaces, respectively, in a cylindrical shape. The cartridge 400 is mounted through the first and second fixing grooves 422a and 423a of the first and second rotating plates 422 and 423.

8 and 9, the first rotating unit 230 includes a motor 231, a worm gear 232, a worm wheel 233, and a first coupling gear 234, and a second rotation. The unit 450 includes a main gear 451, an auxiliary gear 452, a first sprocket 453, a chain 454, a second sprocket 455, a first bevel gear 456, and a second bevel gear 457. ) And a second coupling gear 458, the configuration and coupling of the first and second rotary units 230 and 450 will be described in detail in the method of operation of the first embodiment to be described later.

In addition, as shown in FIG. 10, the first transfer rail 220 is divided into two parts, an inner side and an outer side of the drying chamber 200 at a portion in contact with the door 210, and the outer side of the drying chamber 200. Auxiliary feed rail 600 composed of an acylinder 620 and a rail 610 is mounted at the end of the first feed rail 220 of the first feed rail 220 and the drying chamber 200 outside the drying chamber 200. ) Connect the first transfer rail 220 of the inner side.

As shown in FIG. 2, the second embodiment of the rotary high frequency drying apparatus for pipe cover thermal insulation using glass fiber according to the present invention includes a vacuum tank 110, a vacuum pump 120, a first pipe 130, And a vacuum unit 100 composed of a second pipe 140, a drying chamber 200 composed of a door 210, a first transfer rail 220, and a first rotating unit 230, and high frequency generation. High frequency unit 300 composed of device 310 and (-) electrode guide 320, jig 410, the upper unit 420, the lower unit 440 and the second rotating unit 450 It is made of a cartridge 400, it is possible to control each component by the operation panel 500, not shown in the figure.

In the components of the second embodiment, only the configuration of the vacuum unit 100 will be described except for the parts having the same components as those of the first embodiment.

As shown in FIG. 2, the vacuum unit 100 of the second embodiment of the present invention has one end of the first pipe 130 and the second pipe 140 on one side of the vacuum tank 110 having a spherical shape. The opposite ends of the first pipe 130 and the second pipe 140 are coupled to one side of the drying chamber 200, and the vacuum pump 120 and the valve 131 are disposed in the middle of the first pipe 130. It is mounted so that the vacuum tank 110 and the drying chamber 200 is connected via the vacuum pump 120, and in the middle of the second pipe 140, only the valve 141 without the vacuum pump 120 is mounted to the vacuum tank 110 And the drying chamber 200 are directly connected to each other without passing through the vacuum pump 120, so that the vacuum tank 110 and the drying chamber 200 are connected to both the first pipe 130 and the second pipe 140.

As shown in FIG. 3, the third embodiment of the rotary high frequency drying apparatus for pipe cover thermal insulation using glass fiber according to the present invention includes a vacuum tank 110, a vacuum pump 120, a first pipe 130, And a vacuum unit 100 composed of a second pipe 140, a drying chamber 200 composed of a door 210, a first transfer rail 220, and a first rotating unit 230, and high frequency generation. High frequency unit 300 composed of device 310 and (-) electrode guide 320, jig 410, the upper unit 420, the lower unit 440 and the second rotating unit 450 The cartridge 400, the rail 510, the second conveying device 520 and the conveying cart 530 is composed of a second conveying rail 500, which is not shown in the drawing by the operation panel 500 Control of each component is possible.

In the components of the third embodiment, only the configuration of the second transfer rail 500 will be described except for the parts formed of the same components as the above-described first and second embodiments.

The second transfer rail 500 of the third embodiment of the present invention is connected in two directions to be perpendicular to the first transfer rail 220 at the end of the first transfer rail 220, the second divided in two directions The two conveying rails 500 are each comprised of a rail 510, a second conveying apparatus 520, and a conveying cart 530.

In detail, the pair of rails 510 are formed on the second conveying rail 500 in parallel with each other on the second conveying rail 500, and the end portions of the rails 510 opposite to the first conveying rail 220 are formed on the second conveying rail 500. The ends of the two bar-shaped frames 521, which are centrally coupled by the coupling pins 522, are connected to each other by the coupling pins 522, and one end of the plurality of connected frames 521 is one pair. Rails 510 are formed on the second transfer rail 500 in parallel with each other, and the ends of two bar-shaped frames 521 coupled to the center by the coupling pins 522 are alternately coupled to each other. 522 connected to each other, one end of the plurality of connected frames 521 is mounted to the end of the rail 510 opposite to the first transfer rail 220, the opposite end of the plurality of connected frames 521 is transfer cart It is connected to the lower surface of the (530), the end of the rail (510) opposite the first transfer device 220 and 'X' shape When the hydraulic cylinder 523 connected with one of the center coupling pins 522 of the frame 521 coupled to each other is operated, the transfer cart 530 moves along the rail 510 of the second transfer rail 500. 400) can be moved.

Referring to the operation method of the present invention configured as described above are as follows.

As shown in FIG. 7, the first embodiment of the rotary high frequency drying apparatus for pipe cover thermal insulation using glass fiber according to the present invention is a glass fiber pipe cover made by mixing glass fiber and a binder on the surface of the jig 410. (C) is applied and molded, and the upper fixing pin 411 and the lower fixing pin 412 of the jig 410, respectively, the first fixing groove 422a and the second rotating plate 423 of the first rotating plate 422. It is inserted into the second fixing groove 423a of the plurality of jig 410 is fixed to the cartridge 400, the first and second fixing grooves (422a, 423a) is a 'し' shape having an acute angle. When the cartridge 400 moves or rotates, the jig 410 may be prevented from being separated.

Thereafter, when the door opening and closing device 211 operated by the hydraulic cylinder 212 is operated, as shown in FIG. 4B, the door 210 of the drying chamber 200 is lifted upward to open, and the first transfer device 222 is opened. As shown in FIG. 1A, the cartridge 400 enters the drying chamber 200 along the first transfer rail 220.

Here, the first conveying rail 220 is divided into two parts, the inner side and the outer side of the drying chamber 200 at the portion in contact with the door 210, accordingly the rail 221 at the portion in contact with the door 210. ) Is also divided into two parts, the inner side and the outer side of the drying chamber 200, the auxiliary transport rail 600 is operated before the cartridge 400 is transferred into the drying chamber 200 along the first transfer rail 220. The rails 610 of the auxiliary transport rail 600 may be supplemented by discontinuities of the rails 221.

Specifically, as shown in FIG. 10B, when the air cylinder 620 is operated, the rail 610 connected to the air cylinder 620 rotates through a hinge connected to the end of the first transfer rail 220. The rail 610 of the auxiliary transport rail 600 connects the rail 221 divided into two parts of the inner side and the outer side of the drying chamber 200.

In addition, as shown in FIG. 11A, when the hydraulic cylinder 222c is operated, the first transfer device 222 moves the coupling pin 222b connected to the end of the hydraulic cylinder 222c together, the center portion and the amount thereof. The first transfer device 222 is completely unfolded by the chain operation of the frame 222a, the end of which is fixed to the coupling pin 222b.

At this time, one end of the first transfer device 222 is connected to the lower unit 440 of the cartridge 400, the other end is connected to the end of the first transfer rail 220, the first transfer device 222 As unfolded, a plurality of transfer wheels 441 formed on the lower surface of the lower unit 440 is rolled along the rails 221 so that the cartridge 400 moves into the drying chamber 200.

Then, as shown in FIG. 10A, when the air cylinder 620 is operated, the rail 610 connected with the air cylinder 620 rotates through a hinge connected with the end of the first transfer rail 220. The rail 610 of the auxiliary transport rail 600 is separated from the rail 221 divided into two parts, the inner side and the outer side of the drying chamber 200, and the lower unit 440 and the first transfer device 222 connected to each other. When the hydraulic cylinder 222c of the first transfer device 222 is operated after the end of the first transfer device 222 is operated, the first transfer device 222 is shown in FIG. 11B while the cartridge 400 is located inside the drying chamber 200. It will be fully folded as shown.

Thereafter, when the door opening and closing device 211 is operated, the door 210 of the drying chamber 200 descends and closes as shown in FIG. 4A.

Here, before the door 210 is closed, the auxiliary transport rail 600 is separated from the rail 221, and the first transport device 222 is folded to be positioned outside the drying chamber, thereby between the door 210 and the drying chamber 200. The confidentiality of the can be increased.

Then, as shown in FIG. 1, when the valve 131 is opened and the vacuum pump 120 is operated, air in the drying chamber 200 moves inside the vacuum tank 110 along the first pipe 130. As a result, the interior of the drying chamber 200 is reduced in pressure.

Here, since the boiling point of the liquid is lowered when the inside of the drying chamber 200 is decompressed, the moisture at a lower temperature when drying the moisture contained in the glass fiber pipe cover C formed on the surface of the jig 410. It is possible to remove, thereby reducing the amount of electrical energy consumed in the high frequency unit, it is possible to shorten the drying time of the glass fiber pipe cover.

Then, as shown in FIG. 5B, when the electrode guide elevating device 321 operating as the hydraulic cylinder 321a is operated, the (-) electrode guide 320 is lowered into the drying chamber 200. As shown in the drawing, the negative electrode guide 320 is positioned inside the cartridge 400 through a cavity formed in the center of the first rotating plate 422.

Then, when the high frequency unit 300 is operated, a high frequency of 12.56 MHz or 25.12 MHz is generated from the high frequency generator 310 of the positive pole to the negative electrode guide 320 of the negative pole, thereby generating the high frequency generator 310 and (- Irradiated to the glass fiber pipe cover (C) applied to the surface of the jig 410 located between the electrode guide 320, the first and second rotary plates (422,423) and (-) electrode guide 320 Since the first and second fixing grooves 422a and 423a are formed at the edges of the first and second rotating plates 422 and 423 at equal intervals, the jig 410 is attached to the cartridge 400. When mounted, the (-) electrode guide 320 and each jig 410 can maintain the same distance, so that the upper unit 420 of the cartridge 400 when the first and second rotating units 230 and 450 are operated. By adjusting to rotate at constant speed, each jig 410 is equalized with the size of the high frequency radiated onto each jig 410 and the time exposed to the high frequency. 410 may be able to maintain a uniform dry state of the glass fiber pipe cover (C) applied to the surface.

In addition, the cartridge 400 is made of polyethylene, the cartridge 400 is heated by a high frequency generator 310 for generating a high frequency of 13.56 MHz or 25.12 MHz due to the nature of the polyethylene dielectric heating at a frequency of 2400 Hz It acts as an insulator so as not to.

Here, the operation method of the first and second rotary units 230 and 450 will be described.

As shown in FIG. 1, the first rotating unit 230 is mounted on one side of the drying chamber 200 in the opposite direction to the door 210, and as shown in FIG. 8A, a worm gear (or shaft) is disposed on the rotation shaft of the motor 231. 232 is connected, the worm wheel 233 is connected to the worm gear 233.

In addition, as shown in FIG. 8A, the second rotation unit 450 includes a sub-gear 452 connected to the main gear 451 and a sub-axis 452 having the same rotation axis as the sub-gear 452. The first sprocket 453 is coupled, the first sprocket 453 is connected to the second sprocket 455 through the chain 454, the second sprocket 455 has the same rotation axis as the second sprocket 455 The first bevel gear 456 is coupled, and the second bevel gear 457 is connected to be perpendicular to the first bevel gear 456.

Here, as shown in FIG. 9A, the main gear 451 is mounted to the rotation shaft 430 of the cartridge 400, and the first and second sprockets 453 and 455, the chain 454, and the first and second bevel gears. 456 and 457 are mounted on the lower unit 440, and the first coupling gear 234 and the second coupling gear 458 are formed at the ends of the worm wheel 233 and the second bevel gear 457, respectively, along the rotation axis. Therefore, when the cartridge 400 enters the drying chamber 200, the first coupling gear 234 and the second coupling gear 458 are connected, and thus the rotational force of the motor 231 is increased to the main gear 451. The upper unit 420 connected to the main gear 451 through the rotating shaft 430 may rotate.

Then, when the drying of the glass fiber pipe cover (C) is completed, the operation of the high frequency generator 310 is stopped and the hydraulic cylinder 321a is operated to operate the electrode guide elevating device 321 to operate the (-) electrode guide. After raising the 320, the air stored in the vacuum tank 110 is injected into the drying chamber 200 until the pressure inside and outside the drying chamber 200 becomes the same, and the air is injected into the drying chamber 200. When the hydraulic cylinder 212 is completed, the door opening and closing device 211 is operated to open the door 210, and the air cylinder 620 is operated so that the rail 610 of the auxiliary feed rail 600 is transferred to the first. It is connected to the rail 221 of the rail 220, operating the hydraulic cylinder 222c to fully open the first transfer device 222 to separate the lower unit 440 and the end of the first transfer device 222 After connecting, when the hydraulic cylinder 222c of the first transfer device 222 is operated again to completely fold the first transfer device 222, in FIG. 1B. Display by the cartridge (400) moves along the first transfer rail 220, as will come out to the outside the drying chamber 200.

Then, the jig 410 is separated from the cartridge 400, and the dried glass fiber pipe cover C is separated from the separated jig 410. The first embodiment process is completed.

As shown in FIG. 7, the second embodiment of the rotary high frequency drying apparatus for pipe cover thermal insulation using glass fiber according to the present invention is a glass fiber pipe cover made by mixing glass fiber and a binder on the surface of the jig 410. (C) is applied and molded, and the upper fixing pin 411 and the lower fixing pin 412 of the jig 410, respectively, the first fixing groove 422a and the second rotating plate 423 of the first rotating plate 422. It is inserted into the second fixing groove 423a of the plurality of jig 410 is fixed to the cartridge 400, the first and second fixing grooves (422a, 423a) is a 'し' shape having an acute angle. When the cartridge 400 moves or rotates, the jig 410 may be prevented from being separated.

Thereafter, when the door opening and closing device 211 operated by the hydraulic cylinder 212 is operated, as shown in FIG. 4B, the door 210 of the drying chamber 200 is lifted upward to open, and the first transfer device 222 is opened. 2), the cartridge 400 enters into the drying chamber 200 along the first conveying rail 220, as shown in FIG. 2A. The method of operating the first conveying apparatus 222 is described in the first embodiment. As described above, it will be omitted here.

Here, the first conveying rail 220 is divided into two parts, the inner side and the outer side of the drying chamber 200 at the portion in contact with the door 210, accordingly the rail 221 at the portion in contact with the door 210. ) Is also divided into two parts, the inner side and the outer side of the drying chamber 200, the auxiliary transport rail 600 is operated before the cartridge 400 is transferred into the drying chamber 200 along the first transfer rail 220. The rail 610 of the auxiliary transport rail 600 to supplement the discontinuous point of the rail 221, and the operation method of the auxiliary transport rail 600 is the same as described above in the first embodiment, and is omitted here. Let's do it.

Then, as shown in FIG. 10A, when the air cylinder 620 is operated, the rail 610 connected with the air cylinder 620 rotates through a hinge connected with the end of the first transfer rail 220. The rail 610 of the auxiliary transport rail 600 is separated from the rail 221 divided into two parts, the inner side and the outer side of the drying chamber 200, and the lower unit 440 and the first transfer device 222 connected to each other. When the hydraulic cylinder 222c of the first transfer device 222 is operated after the end of the first transfer device 222 is operated, the first transfer device 222 is shown in FIG. 11B while the cartridge 400 is located inside the drying chamber 200. It will be fully folded as shown.

Thereafter, when the door opening and closing device 211 is operated, the door 210 of the drying chamber 200 descends and closes as shown in FIG. 4A.

Here, before the door 210 is closed, the auxiliary transport rail 600 is separated from the rail 221, and the first transport device 222 is folded to be positioned outside the drying chamber, thereby between the door 210 and the drying chamber 200. The airtightness of can be improved as described above in the first embodiment.

Then, as shown in FIG. 2, after opening the valve 131 of the first pipe 130, the vacuum pump 120 is operated, and when the valve 141 of the second pipe 140 is opened, the drying chamber ( Air inside the 200 is moved to the inside of the vacuum tank 110 along the first and second pipes 130 and 140 to decompress the interior of the drying chamber 200, and close the valve 141 of the second pipe 140 to close the vacuum tank. The air moved to 110 is prevented from entering the drying chamber 200 again along the second pipe 140.

Here, by opening the valve 141 of the second pipe 140 connected to the vacuum tank 110 in a vacuum state, it is possible to move the rapid air from the drying chamber 200 to the vacuum tank 110, the vacuum pump 120 ) Is allowed to move the air remaining in the drying chamber 200 to the vacuum tank 110 through the first pipe 130 is connected, the drying chamber 200 compared to the first embodiment consisting of only the first pipe 130 ) Can be quickly depressurized, and the effects obtained by depressurizing the interior of the drying chamber 200 are the same as described above in the first embodiment, and will be omitted herein.

Then, as shown in FIG. 5B, when the electrode guide elevating device 321 operating as the hydraulic cylinder 321a is operated, the (-) electrode guide 320 is lowered into the drying chamber 200. As shown in the drawing, the negative electrode guide 320 is positioned inside the cartridge 400 through a cavity formed in the center of the first rotating plate 422.

Then, when the high frequency unit 300 is operated, a high frequency of 12.56 MHz or 25.12 MHz is generated from the high frequency generator 310 of the positive pole to the negative electrode guide 320 of the negative pole, thereby generating the high frequency generator 310 and (- Irradiated to the glass fiber pipe cover (C) applied to the surface of the jig 410 located between the electrode guide 320, the first and second rotary plates (422,423) and (-) electrode guide 320 Since the first and second fixing grooves 422a and 423a are formed at the edges of the first and second rotating plates 422 and 423 at equal intervals, the jig 410 is attached to the cartridge 400. When mounted, the (-) electrode guide 320 and each jig 410 can maintain the same distance, so that the upper unit 420 of the cartridge 400 when the first and second rotating units 230 and 450 are operated. By adjusting to rotate at constant speed, each jig 410 is equalized with the size of the high frequency radiated onto each jig 410 and the time exposed to the high frequency. 410 may be uniformly maintained in a dry state of the glass fiber pipe cover (C) applied to the surface.

In addition, the cartridge 400 is made of polyethylene, the cartridge 400 is heated by a high frequency generator 310 for generating a high frequency of 13.56 MHz or 25.12 MHz due to the nature of the polyethylene dielectric heating at a frequency of 2400 Hz It acts as an insulator so as not to.

In addition, since the operation method of the first and second rotating units 230 and 450 is the same as described above in the first embodiment, a description thereof will be omitted.

Then, when the drying of the glass fiber pipe cover (C) is completed, the operation of the high frequency generator 310 is stopped and the hydraulic cylinder 321a is operated to operate the electrode guide elevating device 321 to operate the (-) electrode guide. After raising the 320, the air stored in the vacuum tank 110 is injected into the drying chamber 200 until the pressure inside and outside the drying chamber 200 becomes the same, and the air is injected into the drying chamber 200. When the hydraulic cylinder 212 is completed, the door opening and closing device 211 is operated to open the door 210, and the air cylinder 620 is operated so that the rail 610 of the auxiliary feed rail 600 is transferred to the first. It is connected to the rail 221 of the rail 220, operating the hydraulic cylinder 222c to fully open the first transfer device 222 to separate the lower unit 440 and the end of the first transfer device 222 After connecting, when the hydraulic cylinder 222c of the first transfer device 222 is operated again to completely fold the first transfer device 222, in FIG. 2B Display by the cartridge (400) moves along the first transfer rail 220, as will come out to the outside the drying chamber 200.

Here, when the air stored in the vacuum tank 110 is injected into the drying chamber 200, opening the valve 141 of the second pipe 140 enables rapid air movement from the vacuum tank 110 to the drying chamber 200. When the valve 141 of the second pipe is closed and the vacuum pump 120 connected to the first pipe 130 is operated, the air remaining in the vacuum tank 110 is completely moved to the drying chamber 200 to dry the chamber 200. Since the internal and external pressures can be the same, the pressure of the drying chamber 200 can be increased faster than that of the first embodiment consisting of only the first pipe 130.

Then, the jig 410 is separated from the cartridge 400, and the dried glass fiber pipe cover C is separated from the separated jig 410. The second embodiment process is completed.

As shown in FIG. 7, the third embodiment of the rotary high frequency drying apparatus for pipe cover thermal insulation using glass fiber according to the present invention is a glass fiber pipe cover made by mixing glass fiber and a binder on the surface of the jig 410. (C) is applied and molded, and the upper fixing pin 411 and the lower fixing pin 412 of the jig 410, respectively, the first fixing groove 422a and the second rotating plate 423 of the first rotating plate 422. It is inserted into the second fixing groove 423a of the plurality of jig 410 is fixed to the cartridge 400, the first and second fixing grooves (422a, 423a) is a 'し' shape having an acute angle. When the cartridge 400 moves or rotates, the jig 410 may be prevented from being separated.

Thereafter, when the second transfer device 520 is operated, the transfer cart 530 is positioned at the end of the first transfer rail 220 along the second transfer rail 500, as shown in FIG. 3B.

Here, as shown in FIG. 11A, when the hydraulic cylinder 523 is operated, the second transfer device 500 moves the coupling pins 522 connected to the ends of the hydraulic cylinder 523 together. By the chain operation of the frame 521, the end of which is fixed to the coupling pin 522, the second transfer device 520 is fully unfolded.

At this time, as shown in Figure 3, the second transfer device 520, one end is connected to the lower surface of the transfer cart 530, the other end is connected to the end of the second transfer rail 500, 2 As the transfer device 520 is unfolded, a plurality of transfer wheels 531 formed on the lower surface of the transfer cart 530 are rolled along the rail 510 so that the cartridge 400 is connected to the end of the first transfer rail 220. Will be located.

Thereafter, when the door opening and closing device 211 operated by the hydraulic cylinder 212 is operated, as shown in FIG. 4B, the door 210 of the drying chamber 200 is lifted upward to open, and the transfer cart 530 An extension rail 532 is formed on the upper surface thereof, so that when the transfer cart 530 is positioned at the end of the first transfer rail 220, the rail 221 and the extension rail 532 of the first transfer rail 220 are separated from each other. Connected.

Then, when the first transfer device 222 is operated, the lower surface of the lower unit 440 of the cartridge 400 and the end of the first transfer device 222 are connected to each other, as shown in Figure 3a, the cartridge ( 400 is entered into the drying chamber 200 along the rail 221 of the expansion rail 531 and the first transfer rail 220, the operation method of the first transfer device 222 described above in the first embodiment As it is, it will be omitted here.

Here, the first conveying rail 220 is divided into two parts, the inner side and the outer side of the drying chamber 200 at the portion in contact with the door 210, accordingly the rail 221 at the portion in contact with the door 210. ) Is also divided into two parts, the inner side and the outer side of the drying chamber 200, the auxiliary transport rail 600 is operated before the cartridge 400 is transferred into the drying chamber 200 along the first transfer rail 220. The rail 610 of the auxiliary transport rail 600 to supplement the discontinuous point of the rail 221, and the operation method of the auxiliary transport rail 600 is the same as described above in the first embodiment, and is omitted here. Let's do it.

Then, as shown in FIG. 10A, when the air cylinder 620 is operated, the rail 610 connected with the air cylinder 620 rotates through a hinge connected with the end of the first transfer rail 220. The rail 610 of the auxiliary transport rail 600 is separated from the rail 221 divided into two parts, the inner side and the outer side of the drying chamber 200, and the lower unit 440 and the first transfer device 222 connected to each other. When the hydraulic cylinder 222c of the first transfer device 222 is operated after the end of the first transfer device 222 is operated, the first transfer device 222 is shown in FIG. 11B while the cartridge 400 is located inside the drying chamber 200. It will be fully folded as shown.

Thereafter, when the door opening and closing device 211 is operated, the door 210 of the drying chamber 200 descends and closes as shown in FIG. 4A.

Here, before the door 210 is closed, the auxiliary transport rail 600 is separated from the rail 221, and the first transport device 222 is folded to be positioned outside the drying chamber, thereby between the door 210 and the drying chamber 200. The airtightness of can be improved as described above in the first embodiment.

Then, as shown in Figure 3a, to operate the first pipe 130 and the second pipe 140, the operation method and the effect of the first pipe 130 and the second pipe 140 is As described above in the embodiment and the second embodiment, a description thereof will be omitted.

Then, as shown in FIG. 5B, when the electrode guide elevating device 321 operating as the hydraulic cylinder 321a is operated, the (-) electrode guide 320 is lowered into the drying chamber 200. As shown in the drawing, the negative electrode guide 320 is positioned inside the cartridge 400 through a cavity formed in the center of the first rotating plate 422. A high frequency of 12.56 MHz or 25.12 MHz is generated from the high frequency generator 310 to the negative electrode guide 320 of the cathode so that the jig 410 is located between the high frequency generator 310 and the negative electrode guide 320. Irradiated onto the glass fiber pipe cover (C) applied to the surface of the), the operation method and the effect of the high frequency unit 300 are the same as described above in the first and second embodiments will be omitted here.

Here, since the cartridge 400 is made of a polyethylene material, the effect and operation method of the first and second rotating units 230 and 450 are the same as described above in the first embodiment, and thus the description thereof will be omitted.

Then, when the drying of the glass fiber pipe cover (C) is completed, the operation of the high frequency generator 310 is stopped and the hydraulic cylinder 321a is operated to operate the electrode guide elevating device 321 to operate the (-) electrode guide. After raising the 320, the air stored in the vacuum tank 110 is injected into the drying chamber 200 until the pressure inside and outside the drying chamber 200 becomes the same, and the air is injected into the drying chamber 200. When the hydraulic cylinder 212 is completed, the door opening and closing device 211 is operated to open the door 210, and the air cylinder 620 is operated so that the rail 610 of the auxiliary feed rail 600 is transferred to the first. It is connected to the rail 221 of the rail 220, operating the hydraulic cylinder 222c to fully open the first transfer device 222 to separate the lower unit 440 and the end of the first transfer device 222 After connecting, when the hydraulic cylinder 222c of the first transfer device 222 is operated again to completely fold the first transfer device 222, in FIG. 2B Display by the cartridge (400) moves along the first transfer rail 220, as will come out to the outside the drying chamber 200.

Here, when the air stored in the vacuum tank 110 is injected into the drying chamber 200, the first pipe 130 and the second pipe 140 are operated. The first pipe 130 and the second pipe 140 are operated. The effects obtained by operating simultaneously) are the same as described above in the second embodiment, and will be omitted here.

Then, when the cartridge 400 moves along the first transport rail 220 and is positioned on the transport cart 530, the first transport device 222 is separated from the lower unit 440 of the cartridge 400. When the hydraulic cylinder 523 is operated to completely fold the second transfer device 520, the cartridge 400 is positioned at the end of the second transfer rail 500.

Then, the jig 410 is separated from the cartridge 400, and the dried glass fiber pipe cover C is separated from the separated jig 410, and is connected in two directions with the first transfer rail 220. By repeating the above process by alternately operating the second transfer rail 500, the third embodiment process of the rotary high-frequency drying device of the pipe cover thermal insulation using glass fibers is completed.

Here, in the process of the third embodiment by repeatedly operating the first transfer rail 220 and the second transfer rail 500 connected in two directions to repeat the above process, compared to the cartridge 400 compared with the second embodiment When the jig 410 is separated from the jig 410 and the glass fiber pipe cover C which is dried from the jig 410 is removed, the breakage of the process does not occur. To enable efficient operation of the high frequency drying equipment.

Although the present invention has been shown and described with respect to specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Anyone who can afford it will know.

100: vacuum unit 110: vacuum tank
120: vacuum pump 130: first pipe
131 valve 140 second pipe
141: Valve
200: drying chamber 210: door
211: door opening and closing device 212: hydraulic cylinder
220: first transfer rail 221: rail
222: first transfer device 222a: frame
222b: coupling pin 222c: hydraulic cylinder
230: first rotation unit 231: motor
232: worm gear 233: worm wheel
234: first coupling gear
300: high frequency unit 310: high frequency generator
320: (-) electrode guide 321: electrode guide lifting device
321a: Hydraulic cylinder
400: cartridge 410: jig
411: upper fixing pin 412: lower fixing pin
420: upper unit 421: prop
422: first rotating plate 422a: first fixing groove
423: second rotating plate 423a: second fixing groove
430: shaft 440: lower unit
441 transfer wheel 450 second rotation unit
451: main gear 452: auxiliary gear
453: first sprocket 454: chain
455: second sprocket 456: first bevel gear
457: second bevel gear 458: second bevel gear
500: 2nd transfer rail 510: rail
520: second transfer device 521: frame
522: coupling pin 523: hydraulic cylinder
530: transfer cart 531: transfer wheel
532: extension rail
600: auxiliary feed rail 610: rail
620: air cylinder
700: operation panel

Claims (9)

In the drying apparatus for pipe cover thermal insulation using glass fiber,
A vacuum unit 100 configured to connect the vacuum tank 110 and the vacuum pump 120 to the first pipe 130;
The door opening and closing device 211 connected to the vacuum unit 100 and the first pipe 130, and equipped with a door 210 on the front side, and operated by a hydraulic cylinder 212 on the door 210. The door 210 may be opened and closed by being mounted up and down, and the first rotation unit 230 is mounted on the opposite side of the door 210, and the first transport rail 220 is mounted on the bottom of the door 210. Drying chamber 200 and;
The high frequency generator 310 is mounted on one side of the drying chamber 200 in the opposite direction to the door 210, and the (-) electrode guide 320 is mounted on the drying chamber 200, and the (-) electrode guide ( 320 is a high frequency unit 300 configured to move up and down inside the drying chamber 200 by the electrode guide lifting device 321 equipped with a hydraulic cylinder (321a);
The upper unit 420 including the support 421 and the first and second rotating plates 422 and 423 has a first rotating plate 422 and a second rotating plate 423 having a cavity formed on an upper surface and a lower surface of the support 421. These are coupled to each of the plurality of first and second fixing grooves 422a and 423a formed at the edges of the first and second rotating plates 422 and 423, and have upper and lower fixing pins 411 and lower fixing pins 412 on the upper and lower surfaces thereof. Jig (410) is formed is connected, the upper unit 420 is coupled to the lower unit 440 through the rotation shaft 430, the lower unit 440 is the first transfer rail 220 and hydraulic When the hydraulic cylinder 222c is connected to the cylinder 222c, a plurality of transfer wheels 441 are mounted on the lower surface of the lower unit 440 to slide along the first transfer rail 220, and the rotary shaft ( 430, the first rotary oil through a cavity formed in the side end of the lower unit 440 by coupling the second rotary unit 450 consisting of a motor 231 and a gear 230 and the second rotary unit 450 is connected, the cartridge 400 is configured to rotate the upper unit 420 by the motor 231 mounted on the first rotary unit 230; Rotary high frequency drying device for pipe cover thermal insulation using glass fiber. The method of claim 1,
The vacuum unit 100 is a rotary high-frequency drying apparatus of the pipe cover thermal insulation using glass fibers, characterized in that further comprises a second pipe 140 for directly connecting the vacuum tank 110 and the drying chamber 200. The method of claim 1,
The high frequency generator 310 generates a high frequency of 13.56 MHz or 27.12 MHz high frequency dielectric heating is a rotary high frequency drying device of the pipe cover thermal insulation using glass fibers, characterized in that the. The method of claim 1,
The cartridge 400 is a rotary high-frequency drying device of the pipe cover thermal insulation using glass fibers, characterized in that made of polyethylene material. The method of claim 1,
The first and second fixing grooves 422a and 423a have an acute angle, and when combined with the upper fixing pin 411 and the lower fixing pin 412, the upper fixing pin 411 and the lower fixing pin. Rotary high-frequency drying device of the pipe cover thermal insulation using glass fibers, characterized in that the pin 412 is fixed at the 'sh' shaped bend. The method of claim 1,
The first and second rotary units 230 and 450 may include a motor 231, a worm gear 232, a worm wheel 233, a first coupling gear 234, a main gear 451, an auxiliary gear 452, and a first sprocket ( 453, a chain 454, a second sprocket 455, a first bevel gear 456, a second bevel gear 457, and a second coupling gear 458, and the first rotation unit 230. The motor 231 is mounted on one side of the drying chamber 200, the worm gear 232 is connected to the rotary shaft end of the motor 231, the worm wheel 232 is connected to the worm wheel 233, the worm wheel 233 Is connected to the first coupling gear 234, the main gear 451 of the second rotary unit 450 is coupled to the rotation shaft 430, the auxiliary gear 452 is connected to the main gear 451, A first sprocket 453 having the same axis of rotation as the auxiliary gear 452 is attached to the lower portion of the auxiliary gear 452, the first sprocket 455 is connected to the second sprocket 455 through the chain 454, Lower portion of the second sprocket 455 has the same rotation axis as the second sprocket 455 The first bevel gear 456 is connected, the second bevel gear 457 is connected to the first bevel gear 456 perpendicularly, the second bevel gear 457 is connected to the second coupling gear 458 High frequency drying of the pipe cover thermal insulation using glass fibers, characterized in that the upper unit 420 of the cartridge 400 is rotated when the motor 231 operates after the first and second coupling gears 234 and 458 are coupled to each other. Device. The method of claim 1,
The first conveying rail 220 is composed of a pair of rails 221 and the first conveying device 222 so that the cartridge 400 can move inside and outside the drying chamber 200, the first conveying device ( 222 is coupled to the center of the two bar-shaped frame (222a) to be staggered by the coupling pins (222b), the end of the frame 222a to the center is staggered by the coupling pins (222b) One end portion of the frame 222a, which is connected to the end of the frame 222a and connected in a shape in which a plurality of 'X' shapes are arranged, and the plurality of 'X' is arranged in a shape, is arranged in the lower unit of the cartridge 400. 440 is connected to the lower side, the opposite end is connected to the end of the rail 221 opposite the drying chamber 200, the hydraulic cylinder 222c is coupled to cross the end of the rail 221 opposite the drying chamber 200 and 'X' shape By connecting with one of the center coupling pins (222b) of the frame (222a), by the operation of the hydraulic cylinder (222c) Rotary high-frequency drying device of the pipe cover thermal insulation using glass fibers, characterized in that the cartridge 400 is made to enter and exit the drying chamber 200 along the first transfer rail (220). 8. The method of claim 1 or 7,
The first conveying rail 220 is divided into two parts, the inner side and the outer side of the drying chamber 200 at a portion in contact with the door 210, the divided of the first conveying rail 220 outside the drying chamber 200 The rail 610 is rotated around the hinge by the air cylinder 620 and the hinge mounted at the end, and the rotated rail 610 is connected to the inside of the drying chamber 200 of the first transfer rail 220. By being inserted between the rails 221 divided into the outer side, the auxiliary transport rail 600 consisting of the rail 610 and the air cylinder 620 to connect the first transfer rail 220 divided into two parts further Rotary high frequency drying apparatus for pipe cover thermal insulation using glass fibers, characterized in that comprises. The method of claim 8,
The first conveying rail 220 is the end of the first conveying rail 220 to be perpendicular to the second conveying rail 500 consisting of the rail 510, the second conveying device 520 and the conveying cart 530 The second transfer device 520 is divided into two directions in the second transfer device 520 is installed at the distal end of the rail 510, the center of the two bar-shaped frame 521 is crossed by the coupling pin 522. The ends of the frame 522 which are coupled to each other and the center portion is staggered are connected to the ends of the other frames 521 by the coupling pins 522 so that a plurality of 'X' shapes are connected to each other. One end portion of the frame 521 coupled to form an 'X' is connected to the bottom surface of the transfer cart 530, the opposite end portion is connected to the end of the rail 510, and the hydraulic cylinder 523 is transferred to the first. One of the center coupling pins 522 of the frame 521 coupled to the end of the rail 510 opposite to the rail 220 and staggered in an 'X' shape. By being connected, the transfer cart 530 can slide along the rails 510 by the operation of the hydraulic cylinder 523, and a plurality of transfer wheels 531 connected to the rails 510 on the lower surface of the transfer cart 530. ) Is formed, and the upper side of the transfer cart 530, the rotary high-frequency drying device of the pipe cover insulation insulation using glass fibers, characterized in that the extension rail 532 is formed to be connected to the rail 221 is formed.

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