CN222061271U - Automatic laying mechanism for reinforcing glass fiber of wind power generation deflector - Google Patents

Abstract

The utility model provides an automatic laying mechanism for reinforced glass fibers of a wind power generation dome, which relates to the technical field of automatic laying mechanisms. According to the utility model, under the action of the laying mechanism, firstly, the formed gel coat is placed in the groove, then, the glass fiber cloth is pulled to the surface of the gel coat, at the moment, the extrusion plate descends to fix the glass fiber cloth, the first sliding block drives the glass fiber cloth to be continuously laid on the surface of the gel coat, the glass fiber cloth can be laid flat by the roller, the glass fiber cloth can be automatically laid by the equipment, the laying work can be continuously and rapidly completed, the overall working efficiency is improved, the labor cost can be reduced, the stability and consistency of the product quality can be ensured, and the damage of workers to the body health of the glass fiber cloth can be reduced by reducing the contact with the glass fiber cloth.

Description

Automatic placement mechanism for reinforced glass fibers of wind power generation guide cover

Technical Field

The utility model relates to the technical field of automatic laying mechanisms, in particular to an automatic laying mechanism for reinforced glass fibers of a wind power generation dome.

Background

The automatic laying device is a technical device capable of realizing efficient and accurate material laying, is widely applied to the fields of composite material manufacturing, spinning, plastic processing and the like, is mainly used for automatically laying various materials on a die or other base materials according to a preset path and a preset shape, is efficient, accurate and flexible, and has important significance in improving the quality and the production efficiency of composite material products.

At present, in the manufacturing process of the wind power generation air guide sleeve, workers are required to manually lay glass fiber cloth on the surface of a gel coat, so that a large amount of time is consumed, the working efficiency is low, meanwhile, the uniformity and consistency of the glass fiber cloth are difficult to ensure by manual operation, the overall performance of the air guide sleeve is easily influenced, and the workers are easily cut and stabbed by the glass fiber cloth when contacting the glass fiber cloth.

Disclosure of utility model

The utility model aims to solve the problems that when the equipment is used, the working efficiency and the quality of a guide cover are reduced and workers are easy to be injured due to the fact that glass fiber cloth is required to be paved manually, so that the automatic paving mechanism for the reinforced glass fiber of the wind power generation guide cover is provided.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the automatic glass fiber reinforced laying mechanism of the wind power generation dome comprises a laying mechanism, wherein an air extraction mechanism is movably embedded in the inner surface wall of the laying mechanism;

The laying mechanism comprises a base, a support is fixedly arranged at the top of the base, two electric telescopic rods are fixedly arranged at the bottom of the inner wall of the support, extrusion plates are fixedly arranged at the telescopic ends of the electric telescopic rods, two guide rails are fixedly arranged at the top of the base, grooves are formed in the top of the base, first sliding blocks are movably sleeved on the outer surface walls of the guide rails, connecting plates are fixedly arranged on the opposite sides of the first sliding blocks, two round holes are formed in the tops of the connecting plates, sliding grooves are formed in the bottoms of the connecting plates, second sliding blocks are movably embedded in the inner surface walls of the sliding grooves, laser cutters are fixedly arranged at the bottoms of the second sliding blocks, and connecting rods are fixedly arranged on the opposite sides of the two first sliding blocks.

Preferably, the outer surface wall of the connecting rod is movably sleeved with a feeding cylinder, and the top of the connecting plate is fixedly provided with two cylinders.

Preferably, the output ends of the two cylinders are respectively provided with a piston rod, and the outer surface walls of the two piston rods are respectively movably inserted into the round holes.

Preferably, a mounting frame is fixedly arranged between the bottoms of the two piston rods, and a roller is movably inserted between the inner surface walls of the mounting frame.

Preferably, the air extraction mechanism comprises a sealing plate, a vacuum pump is fixedly arranged at the top of the sealing plate, and an air extraction pipe is fixedly communicated with the input end of the vacuum pump.

Preferably, the outer surface wall of the exhaust pipe is fixedly inserted into the sealing plate, and the output end of the vacuum pump is fixedly communicated with an exhaust pipe.

Preferably, the inner surface wall of the groove is movably embedded with the outer surface wall of the sealing plate.

Compared with the prior art, the utility model has the advantages and positive effects that,

1. According to the utility model, under the action of the laying mechanism, firstly, the formed gel coat is placed in the groove, then, the glass fiber cloth is pulled to the surface of the gel coat, at the moment, the extrusion plate descends to fix the glass fiber cloth, the first sliding block drives the glass fiber cloth to be continuously laid on the surface of the gel coat, the glass fiber cloth can be laid flat by the roller, the glass fiber cloth can be automatically laid by the equipment, the laying work can be continuously and rapidly completed, the overall working efficiency is improved, the labor cost can be reduced, the stability and consistency of the product quality can be ensured, and the damage of workers to the body health of the glass fiber cloth can be reduced by reducing the contact with the glass fiber cloth.

2. According to the utility model, resin can be injected into the groove after the glass fiber cloth is paved under the action of the air extraction mechanism, vacuum is formed in the groove through the vacuum pump, and the resin is infiltrated into the glass fiber cloth through vacuum negative pressure, so that the strength of the air guide sleeve can be improved, the process flow can be reduced, and the rapid forming of the air guide sleeve part can be realized.

Drawings

FIG. 1 is a perspective view of a front view structure of a wind power generation dome reinforced glass fiber automatic laying mechanism according to the present utility model;

FIG. 2 is a split cross-sectional view of a laying mechanism in a wind power generation dome reinforced glass fiber automatic laying mechanism;

FIG. 3 is a sectional exploded view of part of a laying mechanism in the automatic laying mechanism of reinforced glass fiber for a wind power generation dome;

FIG. 4 is a perspective exploded view of a part of a laying mechanism in the wind power generation dome reinforced glass fiber automatic laying mechanism;

fig. 5 is a top perspective view of an air extraction mechanism in the wind power generation dome reinforced glass fiber automatic laying mechanism according to the present utility model.

Legend description:

1. a laying mechanism; 101. a base; 102. a bracket; 103. an electric telescopic rod; 104. an extrusion plate; 105. a guide rail; 106. a groove; 107. a first slider; 108. a connecting plate; 109. a round hole; 110. a chute; 111. a second slider; 112. a laser cutter; 113. a connecting rod; 114. a feeding cylinder; 115. a cylinder; 116. a piston rod; 117. a mounting frame; 118. a roller; 2. an air extraction mechanism; 201. a sealing plate; 202. a vacuum pump; 203. an exhaust pipe; 204. and an exhaust pipe.

Detailed Description

In order that the above objects, features and advantages of the utility model will be more clearly understood, a further description of the utility model will be rendered by reference to the appended drawings and examples. It should be noted that, without conflict, the embodiments of the present utility model and features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model, but the present utility model may be practiced otherwise than as described herein, and therefore the present utility model is not limited to the specific embodiments of the disclosure that follow.

1, As shown in fig. 1-5, the utility model provides an automatic laying mechanism for reinforced glass fiber of a wind power generation dome, which comprises a laying mechanism 1, wherein an air extraction mechanism 2 is movably embedded in the inner surface wall of the laying mechanism 1;

The laying mechanism 1 comprises a base 101, a support 102 is fixedly arranged at the top of the base 101, two electric telescopic rods 103 are fixedly arranged at the bottom of the inner wall of the support 102, a pressing plate 104 is fixedly arranged at the telescopic ends of the two electric telescopic rods 103, two guide rails 105 are fixedly arranged at the top of the base 101, a groove 106 is formed in the top of the base 101, first sliding blocks 107 are movably sleeved on the outer surface walls of the two guide rails 105, connecting plates 108 are fixedly arranged at opposite sides of the two first sliding blocks 107, two round holes 109 are formed in the top of the connecting plates 108, sliding grooves 110 are formed in the bottoms of the connecting plates 108, second sliding blocks 111 are movably embedded in the inner surface walls of the sliding grooves 110, laser cutters 112 are fixedly arranged at the bottoms of the second sliding blocks 111, connecting rods 113 are fixedly arranged at opposite sides of the two first sliding blocks 107, a feeding cylinder 114 is movably sleeved on the outer surface walls of the connecting rods 113, two air cylinders 115 are fixedly arranged at the tops of the connecting plates 108, piston rods 116 are movably inserted in the inner parts of the round holes 109, and a roller 118 is fixedly arranged between the bottoms of the two piston rods 116.

The effect that its whole embodiment 1 reaches is, put the gel coat in recess 106 at first, again with fine cloth of glass to gel coat surface one side, electric telescopic handle 103 can drive stripper plate 104 and descend this moment, make fine cloth one end fixed in position of glass, first slider 107 can drive last feed cylinder 114 rotary motion afterwards, make the fine cloth of glass on surface spread gradually on gel coat surface, cylinder 115 can make mounting bracket 117 descend through piston rod 116 simultaneously, and under the effect of first slider 107, cylinder 118 rolls on fine cloth of glass and advances, with fine cloth tiling on gel coat surface, reduce manual operation not only can reduce artificial error, guarantee the stability of kuppe quality, still can reduce the time of laying, second slider 111 can drive laser cutter 112 and remove the cutting fine cloth of glass after the laying is accomplished, need not the manual cutting and improved work efficiency.

In embodiment 2, as shown in fig. 2-5, the air extraction mechanism 2 comprises a sealing plate 201, a vacuum pump 202 is fixedly installed at the top of the sealing plate 201, an air extraction pipe 203 is fixedly connected to the input end of the vacuum pump 202, the outer surface wall of the air extraction pipe 203 is fixedly inserted into the sealing plate 201, an exhaust pipe 204 is fixedly connected to the output end of the vacuum pump 202, and the inner surface wall of the groove 106 is movably embedded with the outer surface wall of the sealing plate 201.

The effect that its whole embodiment 2 reaches is, and closing plate 201 can make relevant material be in sealed environment, and vacuum pump 202 starts the back, can be through exhaust tube 203 and blast pipe 204 with the inside air discharge of mechanism, makes the resin infiltrate in the fine cloth of glass with the vacuum negative pressure, improves the stability and the uniformity of kuppe quality, also can reduce the process flow, improves work efficiency and reduce cost.

Working principle: when a worker needs to lay glass fiber cloth, the worker only needs to put gel cloth in the groove 106 firstly, then pull the glass fiber cloth to the surface of the gel cloth, then start the two electric telescopic rods 103 to drive the two extrusion plates 104 to descend, so that one end of the glass fiber cloth is kept fixed, then the first sliding block 107 slides on the guide rail 105 to drive the glass fiber cloth on the surface of the upper charging barrel 114 to be gradually laid on the surface of the gel cloth, meanwhile, the cylinder 115 can drive the piston rod 116 to descend, the piston rod 116 can enable the mounting frame 117 to descend, the roller 118 is enabled to contact the glass fiber cloth and roll on the glass fiber cloth, the glass fiber cloth is tiled on the surface of the gel cloth, the laser cutter 112 starts to start after the glass fiber cloth is laid, the second sliding block 111 can slide in the sliding groove 110 to drive the laser cutter 112 to move and cut the glass fiber cloth, after the glass fiber cloth is laid, the worker can inject resin and auxiliary materials into the groove 106, and insert the sealing plate 201 into the groove 106, at the moment, the vacuum pump 202 starts to draw out internal air through the pipe 203, and discharge the exhaust pipe 204, thereby facilitating the resin to be immersed into the glass fiber cloth, and improving the quality of a diversion cover.

The present utility model is not limited to the above-mentioned embodiments, and any equivalent embodiments which can be changed or modified by the technical content disclosed above can be applied to other fields, but any simple modification, equivalent changes and modification made to the above-mentioned embodiments according to the technical substance of the present utility model without departing from the technical content of the present utility model still belong to the protection scope of the technical solution of the present utility model.

Claims (7)

1. The utility model provides a wind power generation kuppe reinforcing glass fiber automatic placement mechanism, includes placement mechanism (1), its characterized in that: an air exhaust mechanism (2) is movably embedded in the inner surface wall of the laying mechanism (1);

The laying mechanism (1) comprises a base (101), a support (102) is fixedly arranged at the top of the base (101), two electric telescopic rods (103) are fixedly arranged at the bottom of the inner wall of the support (102), extrusion plates (104) are fixedly arranged at telescopic ends of the electric telescopic rods (103), two guide rails (105) are fixedly arranged at the top of the base (101), grooves (106) are formed in the top of the base (101), first sliding blocks (107) are movably sleeved on the outer surface walls of the guide rails (105), two connecting plates (108) are fixedly arranged on opposite sides of the first sliding blocks (107), two round holes (109) are formed in the top of the connecting plates (108), sliding grooves (110) are formed in the bottoms of the connecting plates (108), second sliding blocks (111) are movably embedded in inner surface walls of the sliding grooves (110), laser cutters (112) are fixedly arranged at the bottoms of the second sliding blocks (111), and connecting rods (113) are fixedly arranged on opposite sides of the first sliding blocks (107).

2. The automatic placement mechanism for reinforced glass fibers of a wind power generation dome according to claim 1, wherein the automatic placement mechanism is characterized in that: the outer surface wall of the connecting rod (113) is movably sleeved with a feeding cylinder (114), and two cylinders (115) are fixedly arranged at the top of the connecting plate (108).

3. The automatic placement mechanism for reinforced glass fibers of wind power generation air guide sleeve as set forth in claim 2, wherein: the output ends of the two cylinders (115) are respectively provided with a piston rod (116), and the outer surface walls of the two piston rods (116) are respectively movably inserted into the round holes (109).

4. The automatic placement mechanism for reinforced glass fibers of a wind power generation dome according to claim 3, wherein the automatic placement mechanism is characterized in that: a mounting frame (117) is fixedly arranged between the bottoms of the two piston rods (116), and a roller (118) is movably inserted between the inner surface walls of the mounting frames (117).

5. The automatic placement mechanism for reinforced glass fibers of a wind power generation dome according to claim 1, wherein the automatic placement mechanism is characterized in that: the air extraction mechanism (2) comprises a sealing plate (201), a vacuum pump (202) is fixedly arranged at the top of the sealing plate (201), and an air extraction pipe (203) is fixedly communicated with the input end of the vacuum pump (202).

6. The automatic placement mechanism for reinforced glass fibers of a wind power generation dome according to claim 5, wherein the automatic placement mechanism is characterized in that: the outer surface wall of the exhaust pipe (203) is fixedly inserted into the sealing plate (201), and the output end of the vacuum pump (202) is fixedly communicated with an exhaust pipe (204).

7. The automatic placement mechanism for reinforced glass fibers of a wind power generation dome according to claim 5, wherein the automatic placement mechanism is characterized in that: the inner surface wall of the groove (106) is movably embedded with the outer surface wall of the sealing plate (201).