KR100920754B1 - Manufacturing method and apparatus of the heat-resistant belt - Google Patents

Abstract

The present invention relates to a method and apparatus for producing a heat resistant belt; A first step of forming a skin material by extruding silicone rubber on a surface of a core material made of unburned fiber and a skin material coated with silicone rubber on an outer surface of the core material; After the first step is passed through a heat treatment unit, the second step of combining the non-combusted fiber forming a core material and the silicone rubber forming a skin material; is manufactured through.

The heat-resistant belt according to the present invention has the advantage that it can be used even in high-temperature environmental conditions by manufacturing by extrusion molding of high-strength and high-tear silicone rubber having excellent heat resistance to the aramid fiber, which is a non-combustible fiber, resistant to external impact, and excellent in mutual bonding. .

Heat Resistant, Belt, Aramid Fiber, Silicone Rubber

Description

Manufacturing method and apparatus of heat-resistant belt

The present invention relates to a method and apparatus for producing a heat resistant belt, and more particularly, to a method and apparatus for manufacturing a heat resistant belt having a structure that can be used even in a high temperature harsh use environment.

In general, a belt used for transmitting a driving force of a mechanical device is used to transfer a rotational movement of one shaft to another shaft by using a friction force by winding the belt around two pulleys connected to parallel axes.

Such belts are used in various applications such as electric belts, industrial belts, automobile belts, agricultural machinery belts, and the like, such as flat belts and V-belts.

By the way, the conventional belt is a structure in contact with the pulley and the like on a certain surface, in particular, the conventional V belt is in contact with the pulley and the left and right sides always cause friction.

Therefore, the friction is easily caused by the friction force and had a problem in that the weakness in terms of durability of the belt.

On the other hand, such a belt has a structure in which a rubber that provides elasticity and a fiber which is a core material for maintaining a constant strength is laminated in a multi-layered structure, and in particular, the core material is exposed to the outside on both sides thereof, which is continuous As the bond to rubber is gradually separated by friction, cracks are gradually generated and torn or cut, and there is a problem that it cannot be used for a long time in an extreme environment, for example, a chemical factory or a cold or a cold area.

Accordingly, the present invention has been made to solve these problems, the object of the present invention is to extrude the silicone rubber having excellent heat resistance and impact resistance to the outside of the fiber to the outside of the non-combustible fiber having excellent heat resistance without exposing the core material to the outside It is to provide a method and apparatus for producing a heat resistant belt to be produced.

Another object of the present invention is to manufacture a heat-resistant belt having excellent bonding strength between non-combustible fibers and silicone rubber by coating a varnish (excellent adhesive force) to the non-combustible fibers and then bonding them with silicone rubber without using a separate release agent. A method and apparatus are provided.

The present invention for achieving the above object relates to a method of manufacturing a heat resistant belt,

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Core material forming step of braiding aramid fibers or glass fibers and braiding them to form a core material; A varnish coating step of applying a varnish mixed with an adhesive to the surface of the core material; A skin material forming step of forming a skin material by extruding silicone rubber on the surface of the core material to which the varnish is coated with the adhesive; And a heat treatment step of coupling the core material and the skin material formed on the outside thereof through a heat treatment machine.

At this time, it is characterized in that it further comprises a post-vulcanization step of vulcanizing the heat-resistant belt discharged after passing through the heat treatment in an oven.

In addition, the present invention relates to an apparatus for manufacturing a heat resistant belt,

Heat-resistance by molding a skin material by supplying a reel for winding a core material made of unburned fiber, a rubber supply part for transferring silicone rubber to an extrusion molding part by a transfer screw, and extruding a silicone rubber on the surface of the core material supplied from the supply reel. An extrusion molding unit for manufacturing and discharging the belt, a heat treatment unit for heat-molding the heat-resistant belt discharged from the extrusion molding unit, and an oven for post-vulcanizing the heat-resistant belt heat-treated in the heat treatment machine.

At this time, the extrusion part, the body is formed in the hollow portion in the center, the inlet hole is formed in the front of the body supplied from the supply reel and the inlet hole formed in the rear of the body is formed on the surface of the core material It characterized in that it is composed of a discharge hole discharged from the heat-resistant belt of the state, and a funnel-shaped guide member which is provided in the hollow portion and the diameter decreases toward the discharge hole.

In addition, a heater is installed on the inner side or the outer side of the extrusion part, and the extrusion part is characterized in that the vacuum pump is connected.

As described above, the heat-resistant belt according to the present invention is manufactured by extruding high-strength and high-tear silicone rubber having excellent heat resistance, strong external shock, and high bonding strength to aramid fibers and glass fibers, which are non-combustible fibers, and thus have a high temperature. There is an advantage that can be used even under the conditions (for example, conditions of continuous use temperature -30 ℃ ~ 200 ℃).

In addition, even if the heat-resistant belt to be manufactured is made of a circular cross-section and fastened to the pulley, etc., it is possible to solve the problem of wearing only a specific part, etc., which has the advantage of longer life.

In addition, the heat-resistant belt of the present invention has the advantage that it is easy to use because it can be cut to a certain length as necessary to tie both ends to each other, or simply used by using a clip.

Hereinafter, with reference to the accompanying drawings for the manufacturing method and apparatus of the heat-resistant belt according to the present invention will be understood by the embodiments described in detail.

At this time, Figure 1 is a view showing for explaining the structure of the heat-resistant belt according to the invention, Figure 2 is a block diagram of a manufacturing apparatus for manufacturing a heat-resistant belt according to the present invention, Figure 3 is a heat-resistant belt according to the present invention Figure 4 is an enlarged view of an extrusion molded part for manufacturing, Figure 4 is a flow chart of the manufacturing process of the heat-resistant belt according to the present invention.

According to Figure 1, the heat-resistant belt 100 according to the present invention is provided in the center of the core material 110 and the outer surface of the core material 110 made of non-combustible fiber functioning as a core material (heart) In order to block the external exposure of the unburned fiber, the cross section is made of a skin material 120 made of silicone rubber and has a circular cross section.

In this case, the non-combustible fiber is made of aramid fibers or glass fibers extracted from asbestos having excellent heat resistance, cold resistance, abrasion resistance and chemical resistance.

On the other hand, the aramid fibers can be classified into two types, para- and meta-based, based on the chemical structural formula, of which the liquid crystal polymer is a para-based, the chemical structure that has been successfully commercialized is polypara-phenylene terephthalamide. The polymer was successfully developed by DuPont in the US in 1972 and marketed under the trade name `` KEVLAR ''.

The skin material 120 provided on the outside of the core material 110 made of such non-combustible fiber is formed by extruding and coating a high-strength high-tear silicone rubber on its surface in order to withstand heat generation and strong impact.

Therefore, the heat-resistant belt 100 according to the present invention is suitable for products requiring a continuous use temperature condition of -30 ℃ ~ 200 ℃ by the characteristics of the silicone rubber.

On the other hand, the non-burned fiber and the silicone rubber is a varnish (VARNISH) 130 is mixed with an adhesive to the non-burned fiber in order to promote the bonding between the non-burned fiber and the silicone rubber without using a separate release agent, etc. Coating.

In this case, the varnish 130 is a paint generally used for forming a film, and is often referred to as a varnish. In particular, the varnish 130 is classified into a volatile varnish obtained by dissolving a resin in a volatile solvent such as alcohol, and an oily varnish to which dry oil such as voile oil or polymer oil is added. The oily varnish also varies in performance and use depending on the type of resin, the mixing ratio of oil and resin, and the like.

By coating the varnish 130 mixed with such an adhesive on the non-combustible fiber, when the silicon rubber is subsequently heated to a high temperature and extruded in a molten state, a chemical reaction with the silicon causes an increase in bonding strength.

On the other hand, the non-combustible fibers can be braided using a group of fibers in a double yarn at 1000 denier (Denier) using a 12-weight braid, the process of coating a varnish (VARNISH) on the surface of the unburned fibers In the non-combustible fiber surface is not evenly coated has a disadvantage that the adhesive strength with the silicone rubber is reduced.

Therefore, in order to improve adhesion, the non-combustible fiber is braided by using a 16-knit braid with a group of the fibers in 1500 deniers in two twisted yarns to widen the braided surface to the varnish 130 on the surface of the unburned fiber. To impregnate the well.

At this time, the denier (Denier) is a term commonly used in nylon or synthetic fibers, among the most basic and general term representing the fineness of the yarn (yarn), the length of a strand of yarn 9,000m (= 9km) is a unit attached to the measured g. For example, 70, 80, 100 denier, 9,000m of fibers are 70g, 80g, 100g, which means that the higher the number is the finer the fineness.

In addition, the term "plywood" means a yarn made by combining a few single yarns, and a two-ply yarn means a yarn made by twisting two strands of single yarn.

The fiber group of such non-combustible fibers can be selected according to the use environment and characteristics of the heat-resistant belt 100 to be produced, it is preferable to fit the outer diameter of the braided braided (two go, three go).

On the other hand, Figure 2 and Figure 3 is a block diagram of the extrusion molding device for producing a heat-resistant belt according to the present invention, the supply reel 210 and the silicone rubber 140, the core material 110 is made of unburned fibers are wound Heat-resistant belt 100 by molding the skin material 120 by extruding silicone rubber on the surface of the core material 110 made of a rubber supply unit 220 and a non-combusted fiber supplied from the supply reel 210 to transfer the heating. Extruded portion 230 for manufacturing and discharging), a heat treatment unit 240 for heat-molding the heat-resistant belt 100 discharged from the extruded portion 230 to a predetermined temperature, and through the heat treatment unit 240 The heat-resistant heat-resistant belt 100 is composed of an oven 250 for post-vulcanization.

At this time, at the rear end of the heat treatment machine 240, the core member 110, which is made of unburned fiber introduced from the supply reel 210, passes through the extruded part 230 in a tense state and at the same time the extrusion. A winding reel 260 is provided to wind the heat resistant belt 100 discharged from the molding unit 230 and discharged through the heat treatment machine 240.

On the other hand, the supply reel 210 is used in which the unburned fiber is wound in a multi-layer, the unburned fiber is a reel in which the varnish 130 mixed with an adhesive is coated on the non-burned fiber to be.

In addition, the rubber supply unit 220 is a device for smoothly transferring the soft silicone rubber 140 to the inlet of the extrusion molding unit 230 when continuously fed, the constant tube 222 and the tube 222 It consists of a transfer screw 224 to rotate about the central axis in the interior. In particular, the silicone rubber 140 is transferred to the extrusion molded part 230 by a transfer screw 224 while maintaining the softness of the dough state.

Next, the extrusion molded part 230 has an inlet hole 231a into which the core material 110 supplied from the supply reel 210 is introduced in front of the body 231 in which the hollow part 232 is formed at the center thereof. And, the rear of the body 231 is formed on the surface of the core material 110, the discharge hole 231b for discharging the heat-resistant belt 100 in the state in which the skin material 120 is molded.

At this time, the extrusion molded part 230 is provided with a funnel-shaped guide member 234 of which diameter decreases toward the discharge hole 231b in the hollow part 232 of the body 231 and the guide member 234 of The discharge hole 231b communicates with an end portion, and the upper portion of the body 231 communicates with an outlet of the rubber supply unit 220, and is forcibly melt-transferred by the rubber supply unit 220. Is discharged while wrapping the surface of the core material (110). On the other hand, in the extrusion process, the heater 236 is provided on the inside or the outside of the extrusion part 230 to smoothly mold and transport the silicone rubber 140 to heat the silicone rubber 140 to a constant temperature. Will let you.

In addition, a vacuum pump 270 is provided in the extrusion molding unit 230 to remove the air generated during the coating molding process of the silicone rubber 140 in the process of extrusion molding.

On the other hand, the heat-resistant belt 100 discharged to the discharge hole (231b) from the extrusion molding unit 230 is heat-treated because the skin 120 is not completely coupled to the core material 110 in a state of being simply coated. Bonding is promoted by the adhesive varnish 130 of the non-combustible resin constituting the core material 110 and the silicone rubber 140 constituting the skin material 120 is heated while passing through the group 240. At this time, the heat treatment unit 240 is divided into a plurality of heater areas of the heater 242, if necessary, the heat treatment, the heat treatment time takes a few minutes (sec) to about a few minutes (min). Of course, such a temperature and time conditions may naturally vary depending on the use of the heat-resistant belt 100 is manufactured.

In this way, the heat-resistant belt 100 discharged through the heat treatment unit 240 may be put into the oven 250 and subjected to a post-vulcanization process for about 2 to 3 hours at a temperature condition of about 180 ℃.

Hereinafter, the manufacturing process of the heat resistant belt according to the present invention will be described in detail with reference to FIGS. 1 to 4.

First, in order to manufacture the heat-resistant belt 100, the core material 110 is formed by braiding and then braiding aramid fibers or glass fibers, which are non-combustible fibers.

The core material 110 is applied to the varnish 130, the adhesive is mixed on the surface in order to promote the bonding force with the silicone rubber 140.

As such, the core material 110 coated with the adhesive varnish 130 is supplied from the supply reel 210 to pass through the inlet hole 231a and the outlet hole 231b of the extrusion molding unit 230, and the heat treatment unit 240. After passing through) to perform a preparatory step of fixing to the winding reel (260).

In this case, when the extrusion molding apparatus 200 is operated, the soft silicone rubber 140 is transferred to the extrusion molding unit 230 through the rubber supply unit 240, and then through the inlet hole 231a of the extrusion molding unit 230. While the silicone rubber 140 is coated on the outside of the core material 110 to be supplied, it is forcibly transferred to the discharge hole 231b of the extrusion part 230 and discharged. As described above, the soft silicone rubber 140 forcibly moved is guided through the guide member 234 to form the skin 120 while covering the surface of the core 110 while passing through the discharge hole 231b.

As described above, the heat-resistant belt 100 manufactured through the extrusion molding part 230 is not completely formed in the state in which the core material 110 and the skin material 120 are coupled to each other. Bonding is promoted by the adhesive varnish 130 and the non-combustible fibers constituting the) and the skin rubber 120 to maintain the shape of the heat-resistant belt 100 constant.

When the heat-resistant belt 100 completed as described above is to be used as a belt for power transmission, both ends of the heat-resistant belt 100 may be bundled together or combined by using a clip.

Although the preferred embodiment of the present invention has been described above, the scope of the present invention is not limited thereto, and the scope of the present invention extends to the scope of the present invention to be substantially equivalent to the embodiment of the present invention. Various modifications can be made by those skilled in the art without departing from the scope of the present invention.

The present invention relates to a method and apparatus for producing a heat resistant belt, and more particularly, to a method and apparatus for manufacturing a heat resistant belt having a structure that can be used even in a high temperature harsh use environment.

1 is a view showing for explaining the structure of the heat-resistant belt according to the invention,

Figure 2 is a block diagram of an extrusion molding apparatus for producing a heat-resistant belt according to the present invention,

3 is an enlarged view of an extruded part of an extrusion apparatus for manufacturing a heat resistant belt according to the present invention;

4 is a flowchart illustrating a manufacturing process of the heat resistant belt according to the present invention.

*** Explanation of symbols for main parts of drawing ***

100: heat-resistant belt 110: heartwood

120: skin 130: varnish

140: silicone rubber 200: extrusion molding apparatus

210: supply reel 220: rubber supply

230: extrusion molded part 260: winding reel

270 vacuum pump

Claims (7)

delete delete Core material forming step of braiding aramid fibers or glass fibers and braiding them to form a core material; A varnish coating step of applying a varnish mixed with an adhesive to the surface of the core material; A skin material forming step of forming a skin material by extruding silicone rubber on the surface of the core material to which the varnish is coated with the adhesive; And A heat treatment step of coupling the core material and the skin material formed on the outside thereof through a heat treatment machine; And And a post-vulcanization step of vulcanizing the heat-resistant belt discharged after the heat treatment into an oven. delete Supply reel to wind up the core material which consists of unburned fiber, A rubber supply part for transferring the silicone rubber to the extrusion molding part by a conveying screw; An extrusion molding part for manufacturing and discharging a heat-resistant belt by extruding silicone rubber on the surface of the core material supplied from the supply reel to mold the skin material; A heat treatment device for heating the heat-resistant belt discharged from the extrusion molding unit; It is configured to include an oven for post-vulcanizing the heat-resistant belt heat-treated in the heat treatment machine, Heater is installed inside or outside the extrusion molding unit, heat-resistant belt manufacturing apparatus, characterized in that the extrusion molding unit is connected to a vacuum pump. The method of claim 5, The extrusion molding unit, A body having a hollow portion formed in a central portion thereof, An inlet hole formed at the front of the body and into which the core material supplied from the supply reel flows; A discharge hole formed at the rear of the body to discharge the heat-resistant belt in a state where the skin material is formed on the surface of the core material; The heat-resistant belt manufacturing apparatus, characterized in that composed of a funnel-shaped guide member that is provided in the hollow portion is reduced in diameter toward the discharge hole. delete

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