CN116533413A - Carbon fiber composite material solidification equipment - Google Patents

Abstract

The invention discloses carbon fiber composite material curing and forming equipment, which relates to the technical field of carbon fiber processing, wherein a carbon fiber winding assembly comprises a supporting base, a plurality of winding grooves are formed in the winding grooves, a winding disc is arranged in the winding grooves, a baffle is fixedly arranged on the side wall of the winding disc, a lifting assembly I is fixedly arranged at the top of the supporting base, a supporting rod I is fixedly arranged at the top of the lifting assembly I, and a winding rod I is arranged on an upper bearing of the supporting rod I; the top of the supporting base is fixedly provided with a lifting assembly II, the top of the lifting assembly II is fixedly provided with a supporting rod II, and a bearing on the supporting rod II is provided with a winding rod II; the lifting assembly III is fixedly arranged at the top of the supporting base, the supporting rod III is fixedly arranged at the top of the lifting assembly III, the rolling rod III is arranged on the bearing on the supporting rod III, and the movement state of the corresponding carbon fiber strip is controlled by controlling whether the rolling disc moves or not, so that the shape of the subsequent carbon fiber product can be controlled.

Description

Carbon fiber composite material solidification equipment

Technical Field

The invention relates to the technical field of carbon fiber processing, in particular to carbon fiber composite material curing and forming equipment.

Background

The carbon fiber is high-strength high-modulus fiber with carbon content more than 90%, high-temperature resistant living chemical fiber is first, acrylic fiber and viscose fiber are used as raw materials, the raw materials are oxidized and carbonized at high temperature, the carbon fiber technology in China is developed very rapidly in recent two decades, the manufacturing technology and the forming of the carbon fiber composite material become an independent and frontier modern engineering technology, along with the continuous accumulation of use experience, the carbon fiber composite material is promoted and applied in a larger range, therefore, the development main stream of the modern carbon fiber composite material is formed by further improving the performance of the carbon fiber composite material and reducing the cost, the efficient, energy-saving and low-cost forming and manufacturing technology is an important aspect of the low cost of the composite material, the most of the processing of the carbon fiber material is finished by manual paste forming method at present, no special equipment is needed, the processing mode is low in efficiency, the processing requirement of the carbon fiber cannot be met, the shape requirement of the carbon fiber product is gradually increased, the equipment cannot meet the requirements of the current carbon fiber composite material, and the carbon fiber is a necessary to be manufactured by the curing equipment.

Disclosure of Invention

The invention aims to provide carbon fiber composite material curing and forming equipment so as to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: the carbon fiber composite material curing and forming equipment comprises a carbon fiber winding assembly, a resin coating assembly and a curing assembly, wherein the carbon fiber winding assembly is used for winding a carbon fiber strip straight and sequentially;

the resin coating component is used for coating the carbon fiber strip with resin;

the curing assembly is used for sequentially winding the carbon fiber strips coated with the resin on the core mold.

According to the technical scheme, the carbon fiber winding assembly comprises supporting bases, a winding barrel is arranged between the supporting bases, a plurality of winding grooves are formed in the winding barrel, a winding disc is arranged in the winding grooves, and a baffle is fixedly installed on the side wall of the winding disc.

According to the technical scheme, the lifting assembly I is fixedly arranged at the top of the supporting base, the supporting rod I is fixedly arranged at the top of the lifting assembly I, and the rolling rod I is arranged on the supporting rod I through a bearing;

the top of the supporting base is fixedly provided with a lifting assembly II, the top of the lifting assembly II is fixedly provided with a supporting rod II, and a bearing on the supporting rod II is provided with a winding rod II;

the top of the supporting base is fixedly provided with a lifting assembly III, the top of the lifting assembly III is fixedly provided with a supporting rod III, and a bearing on the supporting rod III is provided with a winding rod III.

According to the technical scheme, the resin coating assembly comprises a coating box, a first heightening rod and a second heightening rod are fixedly arranged at the top edge of the coating box, a first coating rod is arranged on a top bearing of the first heightening rod, and a second coating rod is arranged on a top bearing of the second heightening rod.

According to the technical scheme, the resin coating assembly further comprises a liquid feeding assembly arranged between the first heightening rod and the second heightening rod, the liquid feeding assembly comprises a driving disc arranged on the side wall of the coating box, a motor is arranged on the inner wall of the driving disc, the output end of the motor is fixedly connected with the clamping holes, and the clamping holes are formed in the middle of the side walls of the two ends of the coating cylinder.

According to the technical scheme, the liquid tanks are uniformly arranged on the surface of the cylinder wall of the coating cylinder, and the liquid holes are uniformly arranged in the liquid tanks.

According to the technical scheme, the bottom of the coating cylinder is provided with the liquid inlet, the liquid suction pipe is arranged at the liquid inlet, the electromagnetic valve is arranged at the position, close to the liquid inlet, in the liquid suction pipe, and the pump is arranged in the liquid suction pipe.

According to the technical scheme, the curing assembly comprises a metal frame, a curing bin is fixedly arranged on the metal frame, and a core mold is arranged in the curing bin.

Compared with the prior art, the invention has the following beneficial effects: according to the invention, the carbon fiber winding assembly is arranged, and the movement state of the corresponding carbon fiber strip is controlled by controlling whether the winding disc moves or not, so that the shape of the subsequent carbon fiber product can be controlled.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

FIG. 1 is a schematic view of the overall front cross-sectional structure of the present invention;

FIG. 2 is a schematic side view of the apparatus of the present invention;

FIG. 3 is a schematic view of a split-winding drum of the present invention;

FIG. 4 is a schematic view of a winding disc of the present invention;

FIG. 5 is an enlarged schematic view of area A of FIG. 1 in accordance with the present invention;

FIG. 6 is an enlarged schematic view of area B of FIG. 2 in accordance with the present invention;

FIG. 7 is a schematic view of a resin coated assembly of the present invention;

FIG. 8 is a schematic view of a liquid feeding assembly of the present invention;

FIG. 9 is an enlarged schematic view of region C of FIG. 2 in accordance with the present invention;

FIG. 10 is a schematic view of a curing assembly of the present invention;

FIG. 11 is an enlarged schematic view of area D of FIG. 1 in accordance with the present invention;

FIG. 12 is an enlarged schematic view of area E of FIG. 11 in accordance with the present invention;

in the figure: 1. a carbon fiber winding assembly; 11. a support base;

12. a lifting assembly I; 121. a first winding rod; 122. a first support rod;

13. lifting assembly II; 131. a second winding rod; 132. a second support rod;

14. lifting assembly III; 141. a winding rod III; 142. a third support rod;

15. a winding barrel is divided; 151. a winding groove; 152. a winding disc; 153. a baffle; 154. a turning hole; 155. a power supply assembly;

2. a resin coating assembly; 21. a coating box; 22. coating a first rod; 23. coating a second rod; 25. heightening a first rod; 26. heightening a second rod;

24. a liquid feeding component; 241. a drive plate; 242. a coating cylinder; 243. a clamping hole; 244. a liquid tank; 245. a liquid hole; 246. a liquid suction pipe; 247. an electromagnetic valve; 248. a liquid inlet hole;

3. curing the assembly; 31. a metal frame; 32. a curing bin; 33. a core mold; 34. correcting the column; 35. a ferrule; 36. a correction plate; 37. a main motor; 38. a horizontal sliding rail;

4. a main drain pipe; 41. a lower calandria; 42. an auxiliary calandria; 43. a collection tank; 44. and a lower row of holes.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-12, the present invention provides the following technical solutions: the utility model provides a carbon fiber composite material solidification equipment, includes carbon fiber winding subassembly 1, resin coating subassembly 2 and solidification subassembly 3, and carbon fiber winding subassembly 1 is used for being directed to the carbon fiber strip and winds in proper order, and resin coating subassembly 2 is used for being full of resin with the carbon fiber strip coating, and solidification subassembly 3 is used for being wound on mandrel 33 with the carbon fiber strip that is coated with resin in proper order, forms complete carbon fiber finished product after the multilayer is convoluteed.

The carbon fiber winding assembly 1 comprises two supporting bases 11, one ends of the supporting bases 11 are connected with the resin coating assembly 2, the other ends of the supporting bases extend upwards, a winding dividing cylinder 15 is arranged between the two supporting bases 11, a power supply assembly 155 is arranged at the end of each supporting base 11, a plurality of winding grooves 151 are uniformly formed in the cylinder wall of each winding dividing cylinder 15, a winding disc 152 is arranged in each winding groove 151, friction layers are arranged on the disc surfaces of the winding discs 152, friction force between the winding discs 152 and carbon fiber strips is increased, rotating holes 154 are formed in the middle of the winding discs 152, the winding discs 152 can rotate in the winding grooves 151 through the rotating connection of the rotating holes 154 and the winding grooves 151, a baffle 153 is fixedly arranged on the side wall of each winding disc 152, each winding disc 152 is electrically connected with the power supply assembly 155, and the effect that the single winding disc 152 independently rotates can be achieved under the control of a curing system;

the lifting assembly I12, the lifting assembly II 13 and the lifting assembly III 14 are fixedly arranged at the top of the supporting base 11, the lifting assembly I12, the lifting assembly II 13 and the lifting assembly III 14 are equidistantly arranged, the supporting rod I122 is fixedly arranged at the top of the lifting assembly I12, the rolling rod I121 is arranged on the supporting rod I122 in a bearing manner, the supporting rod II 132 is fixedly arranged at the top of the lifting assembly II 13, the rolling rod II 131 is arranged on the supporting rod II 132 in a bearing manner, the supporting rod III 142 is fixedly arranged at the top of the lifting assembly III 14, the rolling rod III 141 is arranged on the supporting rod III 142 in a bearing manner, and when the carbon fiber strips are wound on the rolling rods I121, the rolling rods II 131 and the rolling rods III 141, friction layers are arranged on the rolling rods 121, the rolling rods II 131 and the rolling rods III 141 and can be rotated by the movement of the carbon fiber strips;

a power line is arranged in the support base 11 and is electrically connected with the lifting assembly I12, the lifting assembly II 13 and the lifting assembly III 14 in sequence, and the hidden power line improves the safety performance of the equipment;

the resin coating component 2 comprises a coating box 21, wherein the top of the coating box 21 is uncovered, a first heightening rod 25 and a second heightening rod 26 are fixedly arranged at the top edge of the coating box 21, a first coating rod 22 is arranged on a top bearing of the first heightening rod 25, a second coating rod 23 is arranged on a top bearing of the second heightening rod 26, and brushes (not shown in the figure) are detachably arranged on the rod surfaces of the first coating rod 22 and the second coating rod 23;

the resin coating component 2 further comprises a liquid feeding component 24 arranged between the first heightening rod 25 and the second heightening rod 26, the liquid feeding component 24 comprises a driving disc 241 arranged on the side wall of the coating box 21, a motor is arranged on the inner wall of the driving disc 241, the output end of the motor is fixedly connected with a clamping hole 243, the clamping hole 243 is arranged between the side walls of the two ends of the coating cylinder 242, liquid tanks 244 are uniformly arranged on the wall surface of the coating cylinder 242, liquid holes 245 are uniformly arranged in the liquid tanks 244, and the liquid holes 245 are used for providing an overflow passage for resin in the coating cylinder 242;

the bottom of the coating cylinder 242 is provided with a liquid inlet 248, a liquid suction pipe 246 is arranged at the liquid inlet 248, the liquid suction pipe 246 is telescopic, an electromagnetic valve 247 is arranged at the position, close to the liquid inlet 248, in the liquid suction pipe 246, and a pump is arranged in the liquid suction pipe 246 for pumping resin;

the curing assembly 3 comprises a metal frame 31, a curing bin 32 is fixedly arranged on the metal frame 31, a main motor 37 is arranged on one side of the curing bin 32, a main motor 37 body is arranged outside the curing bin 32, an output shaft of the main motor 37 penetrates through the side wall of the curing bin 32 and stretches into the curing bin 32, a core mold 33 is fixedly arranged on the output shaft, the core mold 33 is a detachable part, the core mold 33 is replaced by different specifications according to requirements, and carbon fiber strips are wound on the core mold 33 in multiple layers to form carbon fiber finished products;

a transverse sliding rail 38 is arranged on the metal frame 31, a plurality of correction columns 34 are slidably arranged on the transverse sliding rail 38, a ferrule 35 is fixedly arranged at the top of the correction columns 34, a correction plate 36 capable of deflecting at a small angle is arranged in the ferrule 35, and each correction column 34 can move independently;

the bottom of solidification storehouse 32 sets up down calandria 41, and the bottom of calandria 41 passes through three way valve pipeline connection owner calandria 4 and vice calandria 42, and vice calandria 42 passes through the connecting piece to be fixed and upwards extends on metal frame 31, and metal frame 31's top sets up collecting vat 43, sets up down row hole 44 in the collecting vat 43, and lower row hole 44 pipe connection stretches into solidification storehouse 32 in making the resin in the collecting vat 43 continuously be discharged from mandrel 33 top to mandrel 33 on.

The core mold 33 rotates in the same direction as the split winding drum 15, so that the carbon fiber strips on the split winding drum 15 move onto the core mold 33, and a carbon fiber product is formed according to the shape of the core mold 33.

In the first embodiment, as shown in fig. 2, the winding process of the carbon fiber strip is controlled by the winding of the carbon fiber winding assembly 1 to always maintain a proper tension;

as shown in fig. 5-6, the carbon fiber strip is wound from the winding drum 15 to the bottom of the winding rod two 131 via the top of the winding rod one 121 and then to the top of the winding rod three 141, the carbon fiber strip is wound into a triangle shape in the carbon fiber winding assembly 1, the tension of the carbon fiber strip is adjusted by controlling the lifting assembly one 12, the lifting assembly two 13 and the lifting assembly three 14, when the tension of the carbon fiber strip is reduced, the tension of the carbon fiber strip is increased in the first step by lifting the lifting assembly one 12, then driving the winding rod one 121 to be lifted, the tension of the carbon fiber strip is increased, the tension of the carbon fiber strip needs to be further increased, the height of the lifting assembly two 13 is reduced, then driving the height of the winding rod two 131, the tension of the carbon fiber strip needs to be further increased, the tension of the carbon fiber strip is increased in the third step by controlling the height of the lifting assembly three 14, then driving the height of the winding rod three 141, the tension of the carbon fiber strip is increased, and if the carbon fiber strip is shaped like, the carbon fiber product is formed in a defect condition that the carbon fiber strip is insufficient in the subsequent tension of the carbon fiber strip is maintained in the carbon fiber product by three different sequential modes.

In the second embodiment, as shown in fig. 3-5, a continuous carbon fiber strip is placed in a winding groove 151 until all or a matched number of winding grooves 151 are placed, and because the tensioning force of the carbon fiber strip is adapted, the single carbon fiber strip can be driven to move or pause through the movement of the winding disc 152, the winding disc 152 rotates to drive the carbon fiber strip to move towards the core mold 33, the winding disc 152 pauses, the carbon fiber strip does not move, whether the movement of the winding disc 152 is controlled, the movement state of the corresponding carbon fiber strip is controlled, the shape of a subsequent carbon fiber product can be controlled, the rotating distance of the winding disc 152 is long, the conveying area of the carbon fiber strip is large, and the thickness of a carbon fiber product area made of the corresponding carbon fiber strip conveyed through the winding groove 151 is inconsistent with that of other areas;

each winding slot 151 is responsible for one carbon fiber product forming area;

the baffle 153 effectively limits the offset distance of the carbon fiber strips and improves the molding quality of the carbon fiber products.

In the third embodiment, as shown in fig. 2 and 7-9, when the carbon fiber strip passes through the resin coating component 2, the carbon fiber strip passes through the first coating rod 22, the coating cylinder 242 and the top of the second coating rod 23 in sequence, dust on the carbon fiber strip is brushed away by the action of a brush when the carbon fiber strip passes through the first coating rod 22, and the resin coated on the carbon fiber strip is brushed evenly by the action of the brush when the carbon fiber strip passes through the top of the second coating rod 23;

the coating cylinder 242 rotates along with the operation of the motor, the two ends of the carbon fiber strips are provided with output kinetic energy, and the kinetic energy of the coating cylinder 242 can assist the movement of the carbon fiber strips, so that the stability of the movement of the carbon fiber strips is improved;

when the liquid suction pipe 246 rotates to face the coating box 21, the liquid suction pipe 246 stretches to be inserted into the resin in the coating box 21, at the moment, the resin is pumped into the coating box 21 by the operation of the pump, the electromagnetic valve 247 is opened during the operation of the pump, the rest time is closed, the resin in the coating barrel 242 is continuously pumped in by the liquid suction pipe 246, the resin in the coating barrel 242 which is fully loaded originally is discharged to the surface of the coating barrel 242 through the liquid holes 245, so that the surface of the carbon fiber strip is coated with a layer of resin, and the carbon fiber strip is coated with a layer of resin in advance, so that the curing rate of the carbon fiber strip on the core mold 33 is accelerated;

the extractor tube 246 is extended only during extraction and the rest of the time is at a minimum to avoid interfering with the rotation of the coating cylinder 242.

In the fourth embodiment, as shown in fig. 11 and 12, a single carbon fiber strip enters a ferrule 35, the ferrule 35 is divided into two areas by a correction plate 36, the cross-sectional area of one area is slightly larger, the cross-sectional area of one area is slightly smaller, and the carbon fiber strips required by a carbon fiber product are uniformly used in one type of area, so that the correction plate 36 is convenient to operate, and the type of area needs to be determined according to the specification of the carbon fiber strip;

the correction column 34 slides on the transverse sliding rail 38 to drive the carbon fiber strips to move to the corresponding core mould 33 area, so that the carbon fiber strips move to the area needing to be wound, the movement of the correction column 34 is controlled by the correction system, the correction system controls the correction column 34 according to the shape of the core mould 33, and the manufacture of carbon fiber products with different shapes can be completed by replacing the core mould 33.

In the fifth embodiment, as shown in fig. 1 and 10, the carbon fiber strip is wound on the mandrel 33, during the winding process, the resin is dropped into the curing bin 32, and is controlled by the three-way valve, a part of the resin enters the collecting tank 43 through the auxiliary drain pipe 42, and then drops onto the carbon fiber strip being wound from above the mandrel 33 through the lower drain hole 44, so as to continuously reinforce the carbon fiber strip, and then improve the curing rate of the carbon fiber product, another part of the resin enters the main drain pipe 4, and then enters the coating box 21 through the main drain pipe 4, and a one-way valve is arranged at the position of the main drain pipe 4 close to the coating box 21, so that the resin in the coating box 21 is prevented from flowing back into the main drain pipe 4, and the resin is recycled through the main drain pipe 4 and the auxiliary drain pipe 42, so that no unnecessary waste is caused.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, 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 carbon fiber composite material curing and forming equipment comprises a carbon fiber winding assembly (1), a resin coating assembly (2) and a curing assembly (3), and is characterized in that the carbon fiber winding assembly (1) is used for winding a carbon fiber strip straight and sequentially;

the resin coating component (2) is used for coating the carbon fiber strip with resin;

the curing assembly (3) is used for sequentially winding the carbon fiber strips coated with the resin on the core mold (33).

2. The carbon fiber composite material curing molding device according to claim 1, wherein the carbon fiber winding assembly (1) comprises a supporting base (11), a sub-winding cylinder (15) is arranged between the supporting bases (11), a plurality of winding grooves (151) are formed in the sub-winding cylinder (15), a winding disc (152) is arranged in the winding grooves (151), and a baffle (153) is fixedly arranged on the side wall of the winding disc (152).

3. The carbon fiber composite material curing molding device according to claim 2, wherein a lifting assembly I (12) is fixedly installed at the top of the supporting base (11), a supporting rod I (122) is fixedly installed at the top of the lifting assembly I (12), and a rolling rod I (121) is installed on a bearing on the supporting rod I (122);

the top of the support base (11) is fixedly provided with a lifting assembly II (13), the top of the lifting assembly II (13) is fixedly provided with a support rod II (132), and a bearing on the support rod II (132) is provided with a winding rod II (131);

the top of the support base (11) is fixedly provided with a lifting assembly III (14), the top of the lifting assembly III (14) is fixedly provided with a support rod III (142), and a bearing on the support rod III (142) is provided with a winding rod III (141).

4. The carbon fiber composite material curing molding device according to claim 1, wherein the resin coating assembly (2) comprises a coating box (21), a first heightening rod (25) and a second heightening rod (26) are fixedly installed at the top edge of the coating box (21), a first coating rod (22) is installed on a top bearing of the first heightening rod (25), and a second coating rod (23) is installed on a top bearing of the second heightening rod (26).

5. The carbon fiber composite material curing molding device according to claim 4, wherein the resin coating component (2) further comprises a liquid feeding component (24) arranged between the first heightening rod (25) and the second heightening rod (26), the liquid feeding component (24) comprises a driving disc (241) arranged on the side wall of the coating box (21), a motor is arranged on the inner wall of the driving disc (241), the output end of the motor is fixedly connected with a clamping hole (243), and the clamping hole (243) is arranged in the middle of the side walls of two ends of the coating cylinder (242).

6. The curing and forming device for carbon fiber composite materials according to claim 5, wherein the surface of the wall of the coating cylinder (242) is uniformly provided with liquid tanks (244), and liquid holes (245) are uniformly arranged in the liquid tanks (244).

7. The carbon fiber composite material curing molding device according to claim 6, wherein a liquid inlet (248) is formed in the bottom of the coating cylinder (242), a liquid suction pipe (246) is arranged at the liquid inlet (248), an electromagnetic valve (247) is arranged at a position, close to the liquid inlet (248), in the liquid suction pipe (246), and a pump is arranged in the liquid suction pipe (246).

8. The carbon fiber composite material curing molding device according to claim 1, wherein the curing assembly (3) comprises a metal frame (31), a curing bin (32) is fixedly arranged on the metal frame (31), and a core mold (33) is arranged in the curing bin (32).

9. The carbon fiber composite material curing molding device according to claim 8, wherein a transverse sliding rail (38) is arranged on the metal frame (31), a plurality of correction columns (34) are slidably arranged on the transverse sliding rail (38), a ferrule (35) is fixedly arranged at the top of each correction column (34), and a correction plate (36) is arranged in each ferrule (35).

10. The carbon fiber composite material curing molding device according to claim 9, wherein a lower calandria (41) is arranged at the bottom of the curing bin (32), the bottom end of the lower calandria (41) is connected with a main calandria (4) and an auxiliary calandria (42) through a three-way valve pipeline, the auxiliary calandria (42) is fixed on the metal frame (31) through a connecting piece and extends upwards, a collecting groove (43) is arranged at the top of the metal frame (31), and a lower calandria hole (44) is arranged in the collecting groove (43).