KR101311406B1 - thermal bonding apparatus for thermosetting resin using far infrared ray - Google Patents

Abstract

The present invention relates to a device for fusion of thermosetting resin using far-infrared rays, wherein the end faces 81 of the thermosetting resin plates 80a and 80b are formed to be flat and placed perpendicular to the longitudinal axis passing through the center. In the state where the end faces 81 of the two sheets of thermosetting resin plates 80a and 80b are arranged to face each other and faced to each other, far infrared rays are applied to the opposed portions by the far infrared heaters 30 and 40. The fusion end 81a of the first thermosetting resin plate 80a and the fusion end 81b of the second thermosetting resin plate 80b are melted at the end faces 81 of the thermosetting resin plates 80a and 80b. After the heat is removed and the temperature is lowered, the reaction occurs between the polymer chains of the thermosetting resin during the curing reaction to be bonded and fused, so that the heat is applied in the state of being in close contact with each other and then melted and pressed, so that the bonding strength is strong and fusion. Later quality can be improved.

Description

Thermal bonding apparatus for thermosetting resin using far infrared ray}

The present invention relates to a device for fusion of a thermosetting resin using far infrared rays, and more particularly, two thermosetting resin pads to be bonded to each other are fixed between the heaters by facing their edges and applied with far infrared rays, thereby integrating the contact edges of the thermosetting resin pads with melting. The present invention relates to a thermosetting resin fusion apparatus using far infrared rays to be fused.

The joining technique of plastic is a welding technique in which an adherend is heated to soften and melt, or a welding rod is melted and joined. The welding technique is to weld and melt an adherend by heating. Adhesion and the like.

Welding and welding are not enough to soften and melt the joint surface and simply contact them.So, when softening, the plastic component is approached as close as possible, causing the polymer to be entangled and integrated by diffusion of the whole polymer or each polymer of the joint. It refers to a method of bringing the bonding state to the secondary bond.

There are various methods for welding and welding. There are two types of welding and welding methods. The external heating method, the internal heating method, and the friction heating method are used. The external heating method includes hot air welding and hot plate welding, and the internal heating method includes high frequency dielectric heating.

Plastic is divided into thermoplastic and thermosetting, and the former is softened and melted by heating, so welding and welding are possible, but the latter cannot be melted, so it is difficult to weld and weld, thus relying on adhesion.

Welding is advantageous in terms of 1) no adhesive application process, and in terms of hygiene and safety, and 2) short welding time and a small work space.

Therefore, there is a need for a method of making thermosetting plastics weldable. Korean Patent Publication No. 92-0002333 discloses a method of welding a thermosetting resin pipe, and the method is disclosed as shown in FIG.

1 shows a method of fusion welding a synthetic resin pipe made of a thermosetting resin according to the prior art.

The end faces 1a, 2a of the two pipes 1, 2 are arranged in alignment parallel to each other and are arranged opposite to each other. The end faces 1a, 2a are both flat and are arranged perpendicularly to the axis of the pipes 1, 2 and have a sufficiently spaced distance to accommodate the heater 3 therebetween.

The heater 3 has a flat block shape and can be formed of a number of suitable materials and, when heated, its flat opposite the end faces 1a, 2a of the pipes 1, 2. Emits infrared radiation from the surface. Heating of the ends of the pipes 1 and 2 is continued until the end portions of the pipes 1 and 2 of the end faces 1a and 2a within about 1/8 inch melt.

The melting of the end portions of the pipes 1 and 2 is clearly visible because the normal milky white opaque fluoropolymer material in the pipes 1 and 2 changes to a substantially transparent appearance when melted. Melting from the end faces 1a and 2a to a depth within about 0.125 inches is suitable.

The heater 3 is removed from the gap between the end faces 1a and 2a of the pipes 1 and 2 when the required degree of fusion has been achieved as described above, and the pipes 1 and 2 are aligned with each other. Are in close contact with each other. The end faces 1a and 2a of the pipes 1 and 2 are then engaged with each other and are welded to each other while actually being slightly pressed against each other.

In the conventional method of fusion of the pipe of thermoplastic resin, when the end surface of the thermoplastic resin pipe is melted by applying a heater between the pipes of the thermoplastic resin to dissolve the end surface of the pipe of the thermoplastic resin, the heater is removed and pressurized to be fused so that they are separated from each other. There was a defect that the bonding strength was weak and the quality after fusion was poor because heat was melted and then tightly pressed.

The present invention has been made in order to solve the above problems, an object of the present invention is a thermosetting resin fusion apparatus using a far infrared ray to heat fusion by applying heat to the far infrared in the state in which the thermosetting resin pads face the edge end face fixed To provide.

It is another object of the present invention to provide a fusion apparatus of a thermosetting resin using far-infrared rays which prevents rolling and bending due to elongation force generated by thermal expansion during fusion of a thermosetting resin pad.

In order to achieve the above object, the thermosetting resin fusion apparatus according to the present invention includes a base plate having a lower heater mounted on an upper surface thereof and supporting a top plate on which the upper heater is mounted; An upper plate installed at a predetermined height on the base plate and having a through groove formed at a width greater than a width of the lower heater to allow radiant heat of the lower heater to pass therethrough; An upper heater installed side by side with the through groove so as to face the lower heater through the through groove; A pair of first and second press plates installed on the upper plate to fix two thermosetting resin plates on which the fusion end portions are placed in parallel in the through grooves; First and second clamps provided to block opposite ends of the fusion end portions of the two thermosetting resin plates; It is characterized by consisting of a reflector for covering the upper heater to prevent the heat is emitted to the outside.

According to one embodiment of the invention the lower heater and the upper heater and the outer tube made of a metal material; A heating wire wound in a spiral shape in the outer tube; A heating member interposed between the heating wire and the outer tube to raise heat conduction; The outer surface of the outer tube is characterized by consisting of a far-infrared generator which is formed with a predetermined thickness to generate far-infrared rays.

In one embodiment of the invention the through groove and the width W ₁ is the far infrared generated from the lower heater so as to not be blocked by the upper panel reaches the welding end of the thermosetting resin sheet is characterized in that a larger than the thickness of the lower heater .

According to an embodiment of the present invention, the upper heater has a length L ₀ of the outer tube of which the width W ₀ of the thermosetting resin plate to be fused and a length L ₁ of the outer tube of the lower heater. It is possible to be formed longer, it is possible to be installed side by side with the through groove of the upper plate is characterized in that it is configured to face the lower heater through the through groove.

According to one embodiment of the present invention, the first and second clamps are respectively installed on the left side and the right side of the corners of the upper plate, the upper and lower pressing plate which is fixed by pressing the end of the corner portion of the upper plate, respectively; A rotary knob attached to the upper pressing plate and lowering the upper pressing plate to tighten the upper and lower pressing plates, and lift the upper pressing plate to release the tightening force of the upper plate; An auxiliary pressing plate interposed between the upper pressing plate and the upper plate to transfer the pressure exerted by the upper pressing plate to the upper plate; An upper support having a circular groove to which the rotary handle is coupled and having a screw in the circular groove so as to be coupled to a screw formed on the side of the rotary handle and extending from a clamp support supported on a base plate; It is characterized by consisting of a lower support extending from the clamp support for supporting the lower pressing plate.

According to an embodiment of the present invention, the auxiliary pressing plate is placed on the middle portion of the thermosetting resin plate, and is configured to press the middle portion of the thermosetting resin plate heat-sealed with a pair of first and second pressing plates.

According to the present invention, the thermosetting resin pads are bonded to each other by the edge end faces thereof, the upper surface is fixed with a pressing plate, and the opposite end is fixed with a clamp. Due to the bending and bending can be prevented, heat is applied in a state in close contact with each other and melted, and then close and pressurized, so that the bonding strength is strong and the quality after fusion can be improved.

1 is a method for fusing a synthetic resin pipe made of a thermosetting resin according to the prior art,
2 is a perspective view of a state in which two thermosetting resins are bonded to each other by fusion end portions of the thermosetting resin fusion apparatus according to the present invention and pressed together with a clamp;
Figure 3 is a schematic diagram showing the configuration of the lower heater and the upper heater according to the present invention,
Figure 4 is a perspective view showing a lower heater installed on the base plate by separating the base plate and the top plate of the fusion apparatus according to the present invention,
5 is a plan view of a through hole formed in a portion corresponding to the lower heater in the center of the upper plate according to the present invention,
6 is a perspective view of a state in which the first and second pressing plates of the fusion apparatus according to the present invention are opened and folded, and a thermosetting resin is placed on the upper plate;
FIG. 7 is a side view of the first and second clamps of the fusion apparatus according to the present invention as viewed from the side. FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the present invention, embodiments of the present invention will be described in more detail. This is for a better understanding of the present invention, and the scope of the present invention is not limited thereto.

Fig. 2 shows a perspective view of the thermosetting resin fusion apparatus according to the present invention in which two thermosetting resins are pressed against each other with their fusion end portions pressed together by a clamp.

The fusion apparatus 100 according to the present invention includes: a base plate 10 supporting a top plate 20 on which a lower heater 30 is mounted and an upper heater 40 mounted thereon; An upper plate 20 installed at a predetermined height on the base plate 10 and having a through groove 22 formed in a width greater than the width of the lower heater 30 so that radiant heat of the lower heater 30 can pass therethrough; An upper heater 40 installed side by side with the through groove 22 and installed side by side to face the lower heater 30 through the through groove 22; A pair of first and second press plates 50a and 50b installed in the upper plate 20 to fix two thermosetting resin plates 80a and 80b having their fusion end portions in parallel to the through grooves 22. and; It consists of the 1st and 2nd clamps 60 and 70 provided so that the opposite end part of the fusion | melting end part of the two thermosetting resin plates 80a and 80b may be provided.

The far infrared rays generated from the upper heater 40 and the lower heater 30 are reflected by the reflector 90 to cover the reflector 90 to prevent heat generated from the upper heater 40 from being discharged to the outside. It is returned to the thermosetting resin plates 80a and 80b on which the fusion ends are placed in the through grooves 22 so as to be applied to the thermosetting resin plates 80a and 80b.

The portions of both wings 90a and 90b are downwardly shaped to be inverted “U” so that the reflector plate 90 is covered without being in contact with the upper portion of the upper heater 40, and the fasteners 41 and 41 of the upper heater 40 are formed. Between the blades 90a and 90b is formed to fit.

The fusion apparatus 100 according to the present invention is formed so that the end surfaces 81 of the thermosetting resin plates 80a and 80b are flat surfaces and are placed perpendicular to the longitudinal axis GL (indicated by the dotted lines) passing through the center. Then, in the state where the end faces 81 of the two sheets of thermosetting resin plates 80a and 80b are arranged to face each other and faced to each other, far infrared rays are applied to the opposed portions by the far infrared heaters 30 and 40.

By the heating of such far-infrared rays, the fusion end 81a of the first thermosetting resin plate 80a and the fusion end of the second thermosetting resin plate 80b are joined to the end faces 81 of the thermosetting resin plates 80a and 80b. After (81b) is melted, the heat is removed to lower the temperature, and during the curing reaction, a reaction occurs between the polymer chains of the thermosetting resin to be bonded and fused.

The base plate 10 according to the present invention is supported on the bottom to support the fusion apparatus 100 according to the present invention on the floor, so that the upper plate 20 and the lower heater 30 are mounted and supported. In the present embodiment, the base plate 10 is displayed in the form of a rectangular plate, but does not necessarily have to be a rectangular plate, and may be a polygonal plate.

Base plate 10 according to the present invention is not necessarily composed of a plate, if the upper plate 20 and the lower heater 30 can be supported may be composed of various materials such as concrete floor or steel sheet. In particular, when the thermosetting resin plates 80a and 80b are large, the base plate 10 may be formed of a concrete floor to withstand the weight of the large plate.

The lower heater 30 and the upper heater 40 according to the present invention is configured to generate far-infrared rays in the ceramic coating layer by radiant heat by treating the surface with a ceramic coating to a predetermined thickness so that far-infrared rays may occur.

Figure 3 is a schematic diagram showing the configuration of the lower heater and the upper heater according to the present invention.

As shown, the heating wire 31 for converting electricity into heat is installed in a spiral in the outer tube 33 made of a metal material, and an electric heat for raising heat conduction between the heating wire 31 and the outer tube 33. The ash 32 is interposed.

The outer tube 33 may withstand 500 ° C or more and may be made of any material unless surface corrosion occurs at a high temperature. Preferably, stainless steel is the best.

The heat transfer material 32 is filled in the form of a powder or solid state, it is possible to select any material when the heat resistance and excellent heat resistance, preferably magnesium oxide powder.

In addition, the heating wire 31 is a material having electrical resistance that changes electricity into heat, but may be any material having a certain mechanical strength or higher, but is preferably a nichrome wire having excellent material properties at high temperature.

On the outer surface of the outer tube 33, a far infrared ray generator 34 generating far infrared rays is formed to a predetermined thickness. The far-infrared generator 34 generates far-infrared rays by heat, and may be made of any material as long as it has a constant strength in a solid state, for example, ceramic, loess, stone, and loess mixture.

The far-infrared generator 34 is coated by a predetermined thickness on the surface of the outer tube 33 of the heater 30 and then dried by a drying process, and is formed by being heated and bonded at a temperature of 1200 ° C. or more by a sintering process. Can be.

Far infrared rays are usually generated when heat is applied to a material containing a ceramic or ocher component. The generator is configured to generate far infrared rays from the ceramic coating layer by radiant heat by ceramic coating treatment on a surface of the radiant heat generator. It is common.

Therefore, as another embodiment of the heaters 30 and 40 according to the present invention, a general electric heating wire is spirally wound, and a cylindrical tube pipe structure composed of mica or the like is disposed on the outside of the spiral heating wire, and a ceramic coating is applied to the outside of the cylindrical pipe pipe to provide far infrared rays. Can be generated.

4 is a perspective view showing a lower heater installed on the base plate by separating the base plate and the top plate of the fusion apparatus according to the present invention.

Lower heater 30 according to the present invention is formed long to cross the center of the base plate 10 up and down as shown in Figure 4 and its length L ₀ is the width of the thermosetting resin plates (80a, 80b) to be fused It is formed longer than W ₀ , and both ends thereof are supported by a pair of fixed support members 35 and 35, and are installed at a predetermined height on the base surface 10, and the electric heating wire 31 is installed in the lower heater 30. The conductive line for supplying the illustration is omitted.

The height of the support 21 attached to the four corners of the top plate 20 to support the top plate 20 to the base plate 10 is formed higher than the height of the lower heater 30 so that the top plate 20 is installed on the base plate 10. Do not touch the lower heater (30).

In addition, an elliptical through-hole 22 is formed in the center of the upper plate 20 so as to allow far infrared rays generated from the lower heater 30 to pass through a portion corresponding to the lower heater 30. The through groove 22 is because the far-infrared rays generated from the lower heater 30 is formed to so as to reach the melting end of without being blocked by the top plate 20, the thermosetting resin sheet (80a, 80b), the width W ₁ is lower The thickness of the heater 30, that is, larger than the diameter d ₀ of the outer tube 33, so that far infrared rays generated from the lower heater 30 are not blocked by the upper plate 20, and the fusion end portions of the thermosetting resin plates 80a and 80b are not blocked. To reach.

6 is a perspective view of a state in which the first and second press plates of the fusion apparatus according to the present invention are opened and flipped and a thermosetting resin is placed on the upper plate.

The upper heater 40 may have the same shape as the lower heater 30, although the length L ₀ of the outer tube 33 is not the same shape than the width W ₀ of the thermosetting resin plates 80a and 80b to be fused. Long and the length L ₁ of the outer tube 33 of the lower heater 30. It is possible to be formed longer, it is installed side by side with the through groove 22 of the upper plate 20 to face the lower heater 30 through the through groove (22).

Therefore, when the fusion ends of the thermosetting resin plates 80a and 80b to be fused to the through grooves 22 of the upper plate 20 are placed, the fusion end 81 of the thermosetting resin plates 80a and 80b is connected to the upper heater 40. The far-infrared rays generated between the lower heater 30 and the upper heater 40 and the lower heater 30 heat the fusion end portions 81 of the thermosetting resin plates 80a and 80b to heat the first thermosetting resin plate 80a. When the fusion end of the) and the fusion end of the second thermosetting resin plate 80b are melted to turn off the power applied to the upper heater 40 and the lower heater 30 to remove heat, the curing temperature is lowered. And the reaction occurs between the polymer chains of the thermosetting resin plates 80a and 80b to be bonded and fused.

When the far infrared rays generated from the upper heater 40 and the lower heater 30 are applied to heat the fusion ends of the thermosetting resin plates 80a and 80b, the fusion ends of the thermosetting resin plates 80a and 80b are expanded by heat. The expansion may push the fusion ends of the thermosetting resin plates 80a and 80b to each other, resulting in incomplete fusion.

The first and second clamps 60 and 70 are provided at opposite ends 82 of the fusion end 81 of the thermosetting resin plates 80a and 80b to fusion end portions 81 of the thermosetting resin plates 80a and 80b. Do not push against each other by thermal expansion.

FIG. 7 is a side view of the first and second clamps of the welding apparatus according to the present invention, which are clamped to the upper plate, viewed from the side.

The first and second clamps 60 and 70 according to the present invention are installed on the left and right corners of the upper plate 20, respectively, and are fixed by pressing the end portions of the upper and lower edges of the upper plate 20, respectively. Lower pressing plates 62 and 67; The upper and lower pressing plates 62 and 67 are attached to the upper pressing plate 62 to lower the upper and lower pressing plates 62 and 67 to tighten the upper plate 20, and then lift the upper pressing plate 62 to raise the upper plate 20. A rotary knob 63 for releasing the force; An auxiliary pressing plate (61) interposed between the upper pressing plate (67) and the upper plate (20) to transfer the pressure exerted by the upper pressing plate (67) to the upper plate (20); The rotary knob 63 has a circular groove coupled thereto, and the screw 64a is provided inside the circular groove such that the screw 63a formed on the side of the rotary knob 63 is coupled to the base plate 10. An upper support 64 extending from the clamp support 65; It is composed of a lower support (66) extending from the clamp support (65) to support the lower pressing plate (62).

The first and second clamps 60 and 70 according to the present invention are installed at the left and right corners of the upper plate 20, respectively, to push the opposite ends 82 of the fusion end portions of the thermosetting resin plates 80a and 80b. To prevent the thermosetting resin plates 80a and 80b from being pushed by the stretching force generated while the fusion end 81 is heated by heat, thereby incompletely bonding at the fusion end 81 of the thermosetting resin plates 80a and 80b. To prevent them.

On the other hand, when heat is applied to the fusion end 81 of the thermosetting resin plates 80a and 80b, the heat-induced portion is increased, and the opposite end 82 of the fusion end 81 of the thermosetting resin plates 80a and 80b is backward. It will be pushed back, but will not be pushed by the first and second clamps 60 and 70, and will be convexly raised upward in the middle.

In order to prevent this from rising, the auxiliary pressing plate 51 is placed on the middle portion of the thermosetting resin plates 80a and 80b as shown in FIG. 6 and heat-sealed with a pair of first and second pressing plates 50a and 50b. Press the middle portion of the thermosetting resin plates 80a and 80b.

In this case, as shown in FIG. 2, when the auxiliary pressing plate 51 is pressed between the first and second pressing plates 50a and 50b and the thermosetting resin plates 80a and 80b, the pressing force may be stronger.

 It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

10: base plate 20: top plate
30: lower heater 40: upper heater
50a, 50b: first and second press plates 60, 70: first and second clamps
80a, 80b: thermosetting resin plate 81a, 81b: fusion end
90: reflector

Claims (6)

A base plate 10 having a lower heater 30 mounted on an upper surface thereof and supporting a top plate 20 on which the upper heater 40 is mounted;
An upper plate 20 installed at a predetermined height on the base plate 10 and having a through groove 22 formed in a width greater than the width of the lower heater 30 so that radiant heat of the lower heater 30 can pass therethrough;
An upper heater 40 installed side by side with the through groove 22 and installed side by side to face the lower heater 30 through the through groove 22;
A pair of first and second press plates 50a and 50b installed in the upper plate 20 to fix two thermosetting resin plates 80a and 80b having their fusion end portions in parallel to the through grooves 22. and;
First and second clamps (60, 70) provided to block opposite ends of the fusion end portions of the two thermosetting resin plates (80a, 80b);
Fusion apparatus of a thermosetting resin using far-infrared rays, characterized in that consisting of a reflector plate 90 to cover the upper heater 40 to prevent heat from being released to the outside. The method of claim 1,
The lower heater 30 and the upper heater 40 and the outer tube 33 made of a metal material; A heating wire 31 spirally wound in the outer tube 33; A heat transfer member (32) interposed between the heating wire (31) and the outer tube (33) to raise heat conduction; A fusion apparatus of the thermosetting resin using far-infrared rays, characterized in that the outer surface of the outer tube (33) is formed of a far-infrared generator 34 is formed with a predetermined thickness to generate far infrared rays. The method of claim 1,
The through groove 22 has a width W ₁ of the lower heater 30 so that far-infrared rays generated from the lower heater 30 reach the fusion ends of the thermosetting resin plates 80a and 80b without being blocked by the upper plate 20. A fusion apparatus of a thermosetting resin using far infrared rays, characterized in that formed larger than the thickness. The method of claim 1,
The upper heater 40 has a length L ₀ of the outer tube 33 of the width W ₀ of the thermosetting resin plates 80a and 80b to be fused and a length L ₁ of the outer tube 33 of the lower heater 30. It is possible to be formed longer, it is installed side by side with the through groove 22 of the upper plate 20 through the through groove 22, the thermosetting using far infrared rays, characterized in that configured to face the lower heater 30 Resin fusion apparatus. The method of claim 1,
The first and second clamps 60 and 70 are respectively installed on the left and right corners of the upper plate 20, and the upper and lower crimps are fixed by pressing the end portions of the upper and lower corners of the upper plate 20, respectively. Plates 62 and 67; The upper and lower pressing plates 62 and 67 are attached to the upper pressing plate 62 to lower the upper and lower pressing plates 62 and 67 to tighten the upper plate 20, and then lift the upper pressing plate 62 to raise the upper plate 20. A rotary knob 63 for releasing the force; An auxiliary pressing plate (61) interposed between the upper pressing plate (67) and the upper plate (20) to transfer the pressure exerted by the upper pressing plate (67) to the upper plate (20); The rotary knob 63 has a circular groove coupled thereto, and the screw 64a is provided inside the circular groove such that the screw 63a formed on the side of the rotary knob 63 is coupled to the base plate 10. An upper support 64 extending from the clamp support 65; Fusion apparatus of the thermosetting resin using far-infrared rays, characterized in that consisting of a lower support (66) extending from the clamp support (65) to support the lower pressing plate (62). The method of claim 1,
The auxiliary pressing plate 51 is placed on the middle portion of the thermosetting resin plates 80a and 80b, and the middle portion of the thermosetting resin plates 80a and 80b heat-sealed by the pair of first and second pressing plates 50a and 50b is pressed. Fusion apparatus of a thermosetting resin using far infrared rays, characterized in that configured to give.

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