CN218345351U - Glass fiber wire drawing cooling forming device - Google Patents

Abstract

The utility model relates to a glass fiber silk production technical field provides a glass fiber wire drawing cooling forming device, including melting case and wire drawing case, the lower extreme exit of melting case is connected with the wire drawing case, and wire drawing case below is connected with the water-cooling case, and the water-cooling incasement portion is connected with the cellosilk through the connecting rod and turns to the subassembly, and the right side wall upper end of water-cooling case is connected with air cooling mechanism. The utility model discloses a set up the water-cooling tank and set up in the water-cooling tank and turn to the subassembly, alright make the glass fiber silk of producing stretch into the water solution of water-cooling tank in and carry out the water-cooling to make its rapid cooling, thereby make the production efficiency of glass fiber silk improve, through set up forced air cooling mechanism in water-cooling tank one side, can cool off the glass fiber silk once more through forced air cooling mechanism, on the other hand can weather the moisture on glass fiber silk surface, so that the glass fiber silk can directly get into down one process. Through above-mentioned technical scheme, the problem that cooling rate is slow among the prior art has been solved.

Description

Glass fiber wire drawing cooling forming device

Technical Field

The utility model relates to a glass fiber silk production technical field, it is specific, relate to a glass fiber wire drawing cooling forming device.

Background

The glass fiber is an inorganic non-metallic material with excellent performance, has the advantages of good insulativity, strong heat resistance, good corrosion resistance and high mechanical strength, is prepared by adding specific metal oxide mineral raw materials into natural minerals taking silicon dioxide as a main raw material, uniformly mixing, melting at high temperature, flowing out molten glass liquid through a nozzle, drafting under the action of high-speed drawing force, rapidly cooling and solidifying to form superfine continuous fibers.

The glass fiber needs to be cooled after being drawn at high temperature, but the glass fiber is naturally cooled at present, and the cooling speed is low, so that the processing efficiency of the glass fiber can be reduced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a glass fiber wire drawing cooling forming device has solved the slow problem of cooling rate among the correlation technique.

The technical scheme of the utility model as follows:

the utility model provides a glass fiber wire drawing cooling forming device, includes melting case and wire drawing case, the lower extreme exit of melting case is connected with the wire drawing case, wire drawing case below is connected with the water-cooling case, the water-cooling incasement portion is connected with the cellosilk through the connecting rod and turns to the subassembly, the right side wall upper end of water-cooling case is connected with forced air cooling mechanism.

In a preferred scheme, the steering assembly comprises an annular ring which is obliquely arranged, and threading holes are uniformly formed in the annular ring.

In a preferable scheme, a protective pad is bonded on the annular ring at the inner side of the threading hole.

In a preferred scheme, the height of the steering assembly is lower than the installation height of the air cooling mechanism.

In a preferred scheme, the heat exchange assembly is installed at the bottom of the water cooling tank and comprises a heat exchange tube and a heat conduction plate, the heat exchange tube is fixedly installed at the bottom of the water cooling tank, and the heat conduction plate is uniformly connected to the outer side of the heat exchange tube.

In a preferred scheme, the bottom of the water cooling tank is provided with an air cooler, an outlet of the air cooler is connected with a first air pipe, the tail end of the first air pipe extends into the water cooling tank and is connected with one end of a heat exchange pipe, and the other end of the heat exchange pipe is connected with a second air pipe.

In a preferred scheme, air-cooling mechanism includes circle sleeve and play tuber pipe, circle sleeve fixed mounting is in the right side wall upper end of water-cooling box, the inside fixed mounting of circle sleeve has the play tuber pipe, evenly seted up the exhaust vent on the play tuber pipe, the left end that goes out the tuber pipe is connected with the second tuber pipe.

In a preferred scheme, supporting rollers are arranged at the left end and the right end of the inner side wall of the circular sleeve respectively, and the supporting rollers are installed on the inner wall of the circular sleeve through mounting racks.

In a preferable scheme, the upper end of the left side wall of the water cooling tank is provided with a water inlet, and the lower end of the left side wall of the water cooling tank is provided with a water outlet.

In a preferable scheme, a box door is rotatably installed on the front side of the water cooling box, and a sealing rubber strip is bonded at the connecting part of the box door and the side wall of the water cooling box.

The utility model discloses a theory of operation and beneficial effect do:

1. the utility model discloses a set up the water-cooling tank and set up in the water-cooling tank and turn to the subassembly, alright make the glass fiber silk of producing stretch into the water solution of water-cooling tank in and carry out the water-cooling to make its rapid cooling, thereby make the production efficiency of glass fiber silk improve.

2. Through setting up forced air cooling mechanism in water-cooling tank one side, can cool off glass fiber silk once more through forced air cooling mechanism, on the other hand can be weathered the moisture on glass fiber silk surface to glass fiber silk can directly get into next process.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of the external three-dimensional structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic view of the steering assembly of the present invention;

fig. 4 is a schematic structural view of the air cooling mechanism of the present invention.

In the figure: 1. a melting box; 2. a wire drawing box; 3. a water cooling tank; 31. a connecting rod; 32. a water inlet; 33. a water outlet; 34. a box door; 4. an air cooling mechanism; 41. a circular sleeve; 42. an air outlet pipe; 43. an air outlet; 44. a support roller; 5. a steering assembly; 51. an annular ring; 52. threading holes; 53. a protective pad; 6. an air cooler; 61. a first air duct; 62. a second air duct; 7. a heat exchange assembly; 71. a heat exchange pipe; 72. a heat conducting plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive work, are related to the scope of the present invention.

Examples

As shown in fig. 1-4, a glass fiber drawing cooling forming device comprises a melting box 1 and a drawing box 2, wherein the outlet at the lower end of the melting box 1 is connected with the drawing box 2, the lower part of the drawing box 2 is connected with a water cooling box 3, the interior of the water cooling box 3 is connected with a fiber turning component 5 through a connecting rod 31, the upper end of the right side wall of the water cooling box 3 is connected with an air cooling mechanism 4, raw materials in the melting box 1 enter the drawing box 2, glass fibers can be produced through the drawing box 2, the produced glass fibers enter the water cooling box 3 and bypass the turning component 5, the glass fibers can extend into water solution in the water cooling box 3 to be cooled by water, so that the glass fibers can be rapidly cooled, then enter the air cooling mechanism 4, the glass fibers can be cooled by air, moisture on the surfaces of the glass fibers can be dried by blowing, and the glass fibers can be dried after being cooled.

Referring to fig. 3, in a preferred embodiment, the steering assembly 5 includes an annular ring 51 disposed obliquely, threading holes 52 are uniformly formed in the annular ring 51, the glass fiber thread bypasses the threading holes 52 in the annular ring 51, so that the glass fiber thread can extend into the aqueous solution, and a protective pad 53 is bonded on the annular ring 51 at the inner side of the threading holes 52, so that the glass fiber thread can be protected when contacting the threading holes 52, and surface abrasion of the glass fiber thread caused when contacting the threading holes 52 can be avoided.

Referring to fig. 2, in a preferred embodiment, the height of the steering assembly 5 is lower than the installation height of the air cooling mechanism 4, so that the glass fiber yarns can extend into the aqueous solution in the water cooling tank 3 and can not enter the aqueous solution in the water cooling tank 3 into the air cooling mechanism 4.

Referring to fig. 2, in a preferred embodiment, a heat exchange assembly 7 is installed at the bottom of the water cooling tank 3, the heat exchange assembly 7 includes a heat exchange tube 71 and a heat conducting plate 72, the heat exchange tube 71 is fixedly installed at the bottom of the water cooling tank 3, the heat conducting plate 72 is uniformly connected to the outer side of the heat exchange tube 71, an air cooler 6 is installed at the bottom of the water cooling tank 3, an outlet of the air cooler 6 is connected with a first air duct 61, the end of the first air duct 61 extends into the water cooling tank 3 and is connected to one end of the heat exchange tube 71, the other end of the heat exchange tube 71 is connected with a second air duct 62, when cooling the aqueous solution in the water cooling tank 3, cold air can be generated by the air cooler 6 and conveyed into the heat exchange tube 71 through the first air duct 61, the temperature of the surfaces of the heat exchange tube 71 and the heat conducting plate 72 can be reduced, so as to cool the aqueous solution, so that the aqueous solution can maintain a lower temperature, so that the aqueous solution cools the glass fiber filaments.

Referring to fig. 2 and 4, in a preferred embodiment, the air cooling mechanism 4 includes a circular sleeve 41 and an air outlet pipe 42, the circular sleeve 41 is fixedly installed at the upper end of the right side wall of the water cooling tank 3, the air outlet pipe 42 is fixedly installed inside the circular sleeve 41, air outlet holes 43 are uniformly formed in the air outlet pipe 42, the left end of the air outlet pipe 42 is connected with a second air pipe 62, the glass fiber filaments are cooled by water and then enter a cavity between the circular sleeve 41 and the air outlet pipe 42, cold air can be conveyed into the air outlet pipe 42 through the second air pipe 62, and the cold air in the air outlet pipe 42 is sprayed out through the air outlet holes 43, so that the glass fiber filaments entering the circular sleeve 41 can be cooled by air, on one hand, the glass fiber filaments are cooled again, and on the other hand, moisture on the surface of the glass fiber filaments can be dried.

Referring to fig. 4, in a preferred embodiment, the support rollers 44 are respectively disposed at the left and right ends of the inner sidewall of the circular sleeve 41, the support rollers 44 are mounted on the inner wall of the circular sleeve 41 through mounting brackets, and the glass fiber filaments can be kept parallel in the circular sleeve 41 by the support rollers 44 and cannot be intertwined with each other.

Referring to fig. 1-2, in a preferred embodiment, a water inlet 32 is formed in the upper end of the left side wall of the water cooling tank 3, so as to facilitate the injection of an aqueous solution into the water cooling tank 3, a water outlet 33 is formed in the lower end of the left side wall of the water cooling tank 3, so as to facilitate the discharge of the aqueous solution and facilitate the replacement of the aqueous solution in the water cooling tank 3, a tank door 34 is rotatably installed on the front side of the water cooling tank 3, so as to facilitate the glass fiber filaments to bypass the threading holes 52, and facilitate the inspection and maintenance of the components inside the water cooling tank 3, and a joint strip is bonded to the joint between the tank door 34 and the side wall of the water cooling tank 3, so that the water cooling tank 3 has good sealing performance when the tank door 34 is closed.

In this embodiment, during the specific use, draw the glass fiber silk of wire drawing case 2 production earlier in the water-cooling tank 3 to make glass fiber silk walk around through wires hole 52 on the annular ring 51, glass fiber silk alright enter into the aqueous solution of water-cooling tank 3 bottom this moment, alright carry out the water-cooling to glass fiber silk, and the heat exchange assemblies 7 of water-cooling tank 3 bottom can cool down aqueous solution, make aqueous solution keep lower temperature.

Then, the glass fiber yarns are fed into the air cooling mechanism 4 to enable the glass fiber yarns to bypass the supporting roller 44, so that the glass fiber yarns are kept parallel in the round sleeve 41 and cannot be intertwined with each other, at the moment, the second air pipe 62 conveys cold air into the air outlet pipe 42, the cold air in the air outlet pipe 42 is sprayed out through the air outlet hole 43, the glass fiber yarns entering the round sleeve 41 can be cooled by air, on one hand, the glass fiber yarns are cooled again, and on the other hand, moisture on the surfaces of the glass fiber yarns can be dried by air.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a glass fiber wire drawing cooling forming device, its characterized in that, includes melting case (1) and wire drawing case (2), the lower extreme exit of melting case (1) is connected with wire drawing case (2), wire drawing case (2) below is connected with water-cooling tank (3), water-cooling tank (3) inside is connected with cellosilk through connecting rod (31) and turns to subassembly (5), the right side wall upper end of water-cooling tank (3) is connected with forced air cooling mechanism (4).

2. A glass fiber drawing, cooling and forming device as claimed in claim 1, wherein the steering assembly (5) comprises an inclined annular ring (51), and threading holes (52) are uniformly formed on the annular ring (51).

3. A glass fiber drawing cooling forming device as claimed in claim 2, wherein a protective pad (53) is bonded on the annular ring (51) inside the threading hole (52).

4. A glass fiber drawing cooling forming device as claimed in claim 2, wherein the height of the steering component (5) is lower than the installation height of the air cooling mechanism (4).

5. A glass fiber drawing cooling forming device according to claim 1, wherein a heat exchange assembly (7) is installed at the bottom of the water cooling tank (3), the heat exchange assembly (7) comprises a heat exchange tube (71) and a heat conduction plate (72), the heat exchange tube (71) is fixedly installed at the bottom of the water cooling tank (3), and the heat conduction plate (72) is uniformly connected to the outer side of the heat exchange tube (71).

6. A glass fiber drawing, cooling and forming device according to claim 5, wherein an air cooler (6) is installed at the bottom of the water cooling tank (3), an outlet of the air cooler (6) is connected with a first air pipe (61), the tail end of the first air pipe (61) extends into the water cooling tank (3) and is connected with one end of a heat exchange pipe (71), and the other end of the heat exchange pipe (71) is connected with a second air pipe (62).

7. The glass fiber drawing, cooling and forming device according to claim 6, wherein the air cooling mechanism (4) comprises a round sleeve (41) and an air outlet pipe (42), the round sleeve (41) is fixedly installed at the upper end of the right side wall of the water cooling box (3), the air outlet pipe (42) is fixedly installed inside the round sleeve (41), air outlet holes (43) are uniformly formed in the air outlet pipe (42), and the left end of the air outlet pipe (42) is connected with the second air pipe (62).

8. A glass fiber drawing, cooling and forming device as claimed in claim 7, wherein supporting rollers (44) are respectively arranged at the left end and the right end of the inner side wall of the circular sleeve (41), and the supporting rollers (44) are mounted on the inner wall of the circular sleeve (41) through mounting racks.

9. A glass fiber drawing, cooling and forming device as claimed in claim 1, wherein the upper end of the left side wall of the water cooling tank (3) is provided with a water inlet (32), and the lower end of the left side wall of the water cooling tank (3) is provided with a water outlet (33).

10. A glass fiber drawing, cooling and forming device as claimed in claim 1, wherein a box door (34) is rotatably mounted at the front side of the water cooling box (3), and a sealing rubber strip is bonded at the connecting part of the box door (34) and the side wall of the water cooling box (3).

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