CN212362735U - Drying equipment with expansibility for manufacturing glass fiber sleeve - Google Patents

Abstract

The utility model discloses a drying equipment is used in glass fiber sleeve manufacturing with expansibility, including two sleeves that are located the box, the left and right sides lateral wall of box all has an electrical heating board through a supporting shoe fixed mounting, both sides outer wall fixed mounting has air pump, motor respectively around the box, and the intercommunication has intake pipe and outlet duct between air pump and the box, fixed mounting has a connecting pipe, two branch pipes and a plurality of spring in the box. Has the advantages that: the sleeve can intermittently bear a rotating acting force by the cooperation of the motor, the rotating shaft and the driving roller, so that the outer wall of the sleeve can be contacted with the electric heating plate in multiple directions, and the drying effect of the sleeve is improved; simultaneously, the air pump, the air inlet pipe, the air outlet pipe, the connecting pipe, the branch pipe and the drying pipe are matched to enable the blown air flow to pass through the inner wall of the sleeve pipe, so that direct drying operation is carried out on the inner wall of the sleeve pipe, and the drying efficiency is further improved.

Description

Drying equipment with expansibility for manufacturing glass fiber sleeve

Technical Field

The utility model relates to a sleeve pipe stoving technical field especially relates to a drying equipment is used in glass fiber sleeve pipe manufacturing with expansibility.

Background

The glass fiber pipe is a sleeve pipe with expansibility, which is formed by impregnating glass fiber yarns with resin, curing the impregnated glass fiber yarns in a photoelectric and thermal integrated high-speed polymerization device and then drawing, pultrusion, and the sleeve pipe needs to be dried by drying equipment in the production process.

But current stoving setting only places the sleeve pipe in having the box in the heating function, and the air in sleeve pipe itself and the box all is in quiescent condition all the time, wholly has the problem that the stoving speed is slow and inefficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem in the background art, and providing a drying equipment with expansibility for manufacturing glass fiber sleeve.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a drying device with expansibility for manufacturing a glass fiber sleeve comprises two sleeves positioned in a box body, the left side wall and the right side wall of the box body are both fixedly provided with an electric heating plate through a supporting block, the outer walls of the front side and the rear side of the box body are respectively and fixedly provided with an air pump and a motor, an air inlet pipe and an air outlet pipe are communicated between the air pump and the box body, a connecting pipe, two branch pipes and a plurality of springs are fixedly arranged in the box body, the connecting pipe is communicated with the air outlet pipe and the two branch pipes at the same time, a plurality of springs positioned at the same side are fixedly provided with a drying pipe together, the drying pipes are positioned in the corresponding sleeve pipes and are communicated with the corresponding branch pipes through hoses, the driving end of the motor is fixedly provided with a rotating shaft, and one end of the rotating shaft penetrates through the box body and is eccentrically and fixedly sleeved with the driving roller, and the rubber block is fixedly adhered to the farthest end of the driving roller far away from the rotating shaft.

In the drying equipment for manufacturing the expandable glass fiber sleeve, the two electric heating plates are arc-shaped side surfaces at the sides close to each other, and arc-shaped heat-conducting rubber is fixedly adhered to the arc-shaped side surfaces.

In foretell a glass fiber sleeve pipe drying equipment for manufacturing with expansibility, fixed mounting has two support frames in the box, two all seted up one on the support frame is close to sheathed tube one side and supported the groove and a plurality of spread groove, and the spread groove all is linked together with supporting the groove.

In the drying apparatus for manufacturing glass fiber sleeves with expansibility, the length of the driving roller is less than that of the sleeve, and the driving roller is located between the connecting pipe and the support frame.

In the drying apparatus for manufacturing an expandable glass fiber sleeve, the box body and the supporting block are both made of materials with small thermal conductivity coefficients.

Compared with the prior art, the utility model discloses the advantage lies in:

1: the direct stoving heating effect to corresponding sleeve pipe of heat that the electrical heating board during operation produced utilizes the cooperation of motor, pivot and driving roller to make the sleeve pipe can receive a pivoted effort intermittently to make sheathed tube outer wall can be diversified take place to contact with the electrical heating board, improve sheathed tube stoving effect.

2: the cooperation of utilizing air pump, intake pipe, outlet duct realizes that the hot-air in the box flows, makes the air current of blowing in pass through sheathed tube inner wall under the cooperation of connecting pipe, branch pipe and drying tube simultaneously to also carry out a direct stoving operation to sheathed tube inner wall.

Drawings

Fig. 1 is a schematic structural view of a drying apparatus for manufacturing glass fiber casing with expansibility according to the present invention;

fig. 2 is an enlarged schematic view of a portion a in fig. 1.

In the figure: the device comprises a box body 1, a driving roller 2, a rubber block 3, a supporting block 4, an electric heating plate 5, a supporting frame 6, a supporting groove 7, an air pump 8, a motor 9, a branch pipe 10, a spring 11, a drying pipe 12, a door body 13, a sleeve pipe 14, a connecting pipe 15 and a hose 16.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in 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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-2, the drying equipment for manufacturing the glass fiber sleeve with expansibility comprises two sleeves 14 positioned in a box body 1, wherein the left side wall and the right side wall of the box body 1 are fixedly provided with an electric heating plate 5 through a supporting block 4;

the following points are notable:

1. the two electric heating plates 5 are arc-shaped side surfaces at the sides close to each other, and arc-shaped heat-conducting rubber is fixedly stuck on the arc-shaped side surfaces; the arrangement of the heat conducting rubber can avoid direct contact between the rubber and the sleeve 14 by utilizing the elasticity of the rubber, and the heat generated by the operation of the electric heating plate 5 can be better conducted to the sleeve 14 by utilizing the excellent heat conductivity of the heat conducting rubber.

2. The electric heating plate 5 is a commercially available device, and the specific structure and operation principle thereof are the prior art and are not specifically described herein.

3. Two support frames 6 are fixedly installed in the box body 1, a support groove 7 and a plurality of connecting grooves are respectively formed in the side faces of one side, close to the sleeve 14, of the two support frames 6, and the connecting grooves are communicated with the support groove 7; the purpose of the connecting groove is to allow gas to pass through the supporting groove 7, and the supporting groove 7 is arranged so that one end of the sleeve 14 is positioned in the supporting groove 7 and has a limit to the end, so that the sleeve 14 can only rotate in the supporting groove and is not easy to move vertically and horizontally.

4. The upper end of the cabinet 1 is provided with a door 13, which is a common part of the existing cabinet 1 and will not be described in detail.

4. The box body 1, the supporting block 4 and the door body 13 are all made of materials with small heat conductivity coefficients, such as STP heat insulation materials, and the materials with small heat conductivity coefficients are adopted to reduce heat dissipation of heat in the box body 1 as far as possible.

An air pump 8 and a motor 9 are fixedly installed on the outer walls of the front side and the rear side of the box body 1 respectively, an air inlet pipe and an air outlet pipe are communicated between the air pump 8 and the box body 1, a connecting pipe 15, two branch pipes 10 and a plurality of springs 11 are fixedly installed in the box body 1, the connecting pipe 15 is communicated with the air outlet pipe and the two branch pipes 10 at the same time, a drying pipe 12 is fixedly installed on the springs 11 located on the same side together, the drying pipe 12 is located in a corresponding sleeve pipe 14, and the drying pipe 12 is communicated with the corresponding branch pipes 10 through hoses 16;

the following points are notable:

1. the air pump 8 can adopt a TC-750S air pump.

2. The motor 9 can be a common motor (a motor capable of rotating only in one direction) in daily life and production.

3. The drying duct 12 has a diameter equal to or smaller than the inner diameter of the casing 14.

4. The air inlet pipe and the air outlet pipe which are arranged on the air pump 8 are simultaneously communicated with the box body 1, so that the circulation of air in the box body 1 is realized.

5. In order to facilitate the installation of the casing 14, a baffle ring may be fixedly sleeved outside the drying duct 12, and the maximum diameter of the baffle ring is larger than the outer diameter of the casing 14, so that the baffle ring can generate a pressing effect on the casing after contacting with the baffle ring.

A rotating shaft is fixedly arranged at the driving end of the motor 9, and one end of the rotating shaft penetrates through the box body 1 and is eccentrically and fixedly sleeved with a driving roller 2;

the following points are notable:

1. the rubber block 3 is fixedly stuck at the farthest end of the driving roller 2 far away from the rotating shaft; the purpose that the rubber block 3 set up is in order to avoid driving roller 2 to rotate in-process direct and sleeve pipe 14 to take place to contact, utilize the elasticity that rubber block 3 has can make driving roller 2 rotate in-process and take place to contact with sleeve pipe 14 and produce a pivoted effect to it.

2. The driving roller 2 is eccentrically fixed on the rotating shaft, and can be in one-time contact with the two sleeves 14 in the process of one rotation to enable the two sleeves 14 to rotate, and when the two sleeves are separated, the sleeves 14 can still rotate at a certain angle under the inertia of the rotation of the sleeves 14.

3. The length of the driving roller 2 is less than that of the sleeve 14, and the driving roller 2 is positioned between the connecting pipe 15 and the support frame 6; the dimensioning here is such that the arrangement of the driving roller 2 is prevented from affecting the supporting frame 6.

Further, unless otherwise specifically stated or limited, the above-described fixed connection is to be understood in a broad sense, and may be, for example, welded, glued, or integrally formed as is conventional in the art.

The utility model discloses in, when needs dry the operation, take off the door body 13 and install corresponding electric heating board 5, support frame 6 and drying tube 12 with sleeve pipe 14 on (here installation operation is similar with the installation of remote controller battery, produces the extrusion to support frame 6 through drying tube 12 earlier, then go into support groove 7 with sleeve pipe 14's one end card in, remove the effort of applying to sleeve pipe 14 can).

Open electric heating plate 5 and motor 9 earlier, heat that 5 works on the electric heating plate produced heats sleeve pipe 14, and motor 9 works and drives driving roller 2 through the pivot and carry out eccentric rotation, but 2 eccentric rotations of driving roller apply a rotation effect to sleeve pipe 14 intermittently to make sleeve pipe 14's outer wall can diversified take place to contact with electric heating plate 5, improve sleeve pipe 14's stoving effect.

After a period of time, the air pump 8 is turned on, the air pump 8 works to enable the hot air in the box body 1 to flow, and in the flowing process, the air flow blown in is enabled to pass through the inner wall of the sleeve 14 through the matching of the air outlet pipe, the connecting pipe 15, the branch pipe 10 and the drying pipe 12, so that the direct drying operation is also carried out on the inner wall of the sleeve 14.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (5)

1. The drying equipment with expansibility for manufacturing the glass fiber sleeve comprises two sleeves (14) positioned in a box body (1), and is characterized in that the side walls of the left side and the right side of the box body (1) are fixedly provided with an electric heating plate (5) through a supporting block (4), the outer walls of the front side and the rear side of the box body (1) are respectively fixedly provided with an air pump (8) and a motor (9), an air inlet pipe and an air outlet pipe are communicated between the air pump (8) and the box body (1), a connecting pipe (15), two branch pipes (10) and a plurality of springs (11) are fixedly arranged in the box body (1), the connecting pipe (15) is simultaneously communicated with the air outlet pipe and the two branch pipes (10), a plurality of springs (11) positioned on the same side are jointly and fixedly provided with a drying pipe (12), and the drying pipe (12) is positioned in the corresponding sleeve (, and drying tube (12) with be linked together through hose (16) and corresponding branch pipe (10), the drive end fixed mounting of motor (9) has the pivot, and the one end of pivot runs through box (1) and eccentric fixed the having cup jointed driving roller (2), and driving roller (2) keep away from the farthest end fixed paste of pivot and have rubber block (3).

2. The drying apparatus for manufacturing glass fiber sleeve with expansibility as claimed in claim 1, wherein the two electric heating plates (5) are curved sides, and curved heat-conducting rubber is fixedly adhered to the curved sides.

3. The drying equipment with the expansibility for manufacturing the glass fiber sleeve is characterized in that two supporting frames (6) are fixedly installed in the box body (1), one side face, close to the sleeve (14), of each of the two supporting frames (6) is provided with a supporting groove (7) and a plurality of connecting grooves, and each connecting groove is communicated with the supporting groove (7).

4. The drying apparatus for manufacturing glass fiber sleeve with expansibility as recited in claim 1, wherein the length of the driving roller (2) is less than that of the sleeve (14), and the driving roller (2) is located between the connecting pipe (15) and the supporting frame (6).

5. The drying apparatus for manufacturing glass fiber casing with expansibility as recited in claim 1, wherein the box body (1) and the supporting block (4) are made of materials with low thermal conductivity.

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