CN220242477U - Winding manufacturing device for carbon fiber composite pipe - Google Patents

Abstract

The utility model relates to a carbon fiber tube makes the field, especially, relate to a winding manufacturing installation of carbon fiber composite tube, including supplying carbon fiber prepreg winding mandrel, two rotating turret that one-to-one is located mandrel both ends department, connect in the bottom plate of two rotating turrets, locate the rotating turret and drive mandrel pivoted motor power, two rotating turrets are followed mandrel axis direction sliding connection in the bottom plate, the bottom plate is equipped with the mobile mechanism who drives two rotating turrets and remove, sliding connection has the work or material rest that drives the mandrel and keep away from between the two rotating turrets on the bottom plate, make prepreg winding accomplish the back on the mandrel, the work or material rest supports the mandrel, then two rotating turrets keep away from mutually, the work or material rest drives the mandrel and keeps away from between two rotating turrets, so that take off the mandrel and carry out subsequent solidification work.

Description

Winding manufacturing device for carbon fiber composite pipe

Technical Field

The present application relates to the field of carbon fiber tube manufacturing, and in particular, to a winding manufacturing apparatus for a carbon fiber composite tube.

Background

The carbon fiber composite tube has good electromagnetic shielding property, and can play a good role in protection. In order to manufacture the carbon fiber composite tube, a winding process is required, namely winding the carbon fiber prepreg onto a core mold coated with a release agent, wrapping a film on the outer layer after winding is completed, heating, removing the film after the carbon fiber prepreg is solidified, taking out the core mold, and then carrying out subsequent processing treatment to obtain the carbon fiber composite tube.

The prior art bulletin number CN218803980U is provided with a tooling for preparing the carbon fiber composite tube, the core mold is driven by a motor to rotate, so that the core mold is uniformly wound with carbon fiber prepreg, one end of the core mold is inserted into a groove of a connecting seat, and the other end of the core mold is directly connected with an output shaft of the motor.

In the above related art, when the carbon fiber is wound on the core mold, the core mold needs to be taken down for heating, and the distance between the connecting seats at the two ends of the core mold and the motor cannot be kept away from each other, so that the core mold is inconvenient to take down.

Disclosure of Invention

In order to facilitate the removal of the core mold for subsequent curing, the application provides a winding manufacturing device for a carbon fiber composite tube.

The winding manufacturing device of the carbon fiber composite tube adopts the following technical scheme:

the utility model provides a winding manufacturing installation of carbon fiber composite tube, includes that supply carbon fiber prepreg winding mandrel, one-to-one lie in two rotating turret of mandrel both ends department, connect in the bottom plate of two rotating turrets, locate the rotating turret and drive mandrel pivoted motor, two the rotating turret is along mandrel axis direction sliding connection in the bottom plate, and the bottom plate is equipped with the shifter who drives two rotating turrets and remove, and sliding connection has the work or material rest that drives the mandrel to keep away from between two rotating turrets on the bottom plate.

Through adopting above-mentioned technical scheme for after carbon fiber prepreg winding is accomplished, the work or material rest removes to the mandrel below and supports the mandrel, then two rotating frames keep away from mutually, make the work or material rest can drive the mandrel and remove, make the mandrel can be comparatively convenient take off and install.

Optionally, the moving mechanism comprises a bidirectional screw rod rotatably connected to the bottom plate, a guide rod fixedly connected to the bottom plate and penetrating through the two rotating frames, and a screw rod motor arranged on the bottom plate and driving the bidirectional screw rod to rotate.

By adopting the technical scheme, the two rotating frames can synchronously move to be close to or far away from each other, so that the two rotating frames can stably move.

Optionally, the rotating frame is fixedly connected with an end cylinder for inserting the end part of the core mould, the end cylinder is rotationally connected with a cylinder inner face gear, the end part of the core mould is fixedly connected with an end face gear which can be meshed with the cylinder inner face gear, and the output shaft of the power motor is coaxially and fixedly connected with the cylinder inner face gear.

By adopting the technical scheme, the core mold can be stably driven to rotate.

Optionally, the two ends of the core mold are detachably connected with a propping ring, and the propping ring can be propped against the end face of the core mold.

By adopting the technical scheme, the carbon fiber prepreg is not easy to wind to the position of the core mould beyond the supporting ring, and the face gear and the gear on the inner surface of the cylinder are not easy to bear larger pressure.

Optionally, an arc block is fixedly connected to the material rack, and the circumferential inner wall of the arc block is used for placing the supporting ring.

By adopting the technical scheme, the contact area between the arc block and the supporting ring is large, and the rolling condition is not easy to occur after the core mold is placed on the material rack.

Optionally, a limiting ring groove for the arc block to enter is formed in the circumferential outer wall of the supporting ring.

By adopting the technical scheme, the mandrel is not easy to move along the axis direction of the mandrel after being positioned on the material rack.

Optionally, step surfaces are formed at two ends of the core mold, and the supporting ring is in threaded connection with the step surfaces.

By adopting the technical scheme, after the supporting ring is taken down, the solidified carbon fiber composite tube can be taken down from the core die more conveniently, and is not easy to be blocked by threads on the step surface.

Optionally, the work or material rest includes sliding connection in the slide of bottom plate, sliding connection in the slide and be close to or keep away from the crane of the mandrel that is located between two rotating frames, locates the slide and drives the lift cylinder that the crane removed.

By adopting the technical scheme, after the position of the core mould is fixed between the two rotating frames, the sliding seat can vertically move downwards so as to be smoothly far away from the core mould.

In summary, the present application includes at least one of the following beneficial effects:

1. the two rotating frames are far away from each other, so that the material rack can drive the core mold to move, and the core mold can be conveniently taken down and installed;

2. the mandrel is not easy to move randomly in the process of moving along with the material rack, so that the possibility that the mandrel falls off from the material rack is reduced.

Drawings

FIG. 1 is a schematic diagram of the main structure of the present application;

fig. 2 is a schematic view of an exploded view of one end of the mandrel removed from the end cylinder adjacent the power motor in the direction of the mandrel axis.

Reference numerals illustrate: 1. a core mold; 2. a rotating frame; 21. an arc block; 22. a limit ring groove; 23. a slide; 24. a lifting frame; 25. a lifting cylinder; 26. a step surface; 27. face gears; 3. a bottom plate; 31. a power motor; 32. a moving mechanism; 33. a material rack; 34. a bidirectional screw rod; 35. a guide rod; 36. a lead screw motor; 37. an end cylinder; 38. a gear on the inner surface of the cylinder; 39. and (5) abutting the ring.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses winding manufacturing installation of carbon fiber composite pipe, refer to fig. 1, including being horizontal bottom plate 3, bottom plate 3 upper surface sliding connection has two rotating turret 2, installs between two rotating turrets 2 and is horizontal mandrel 1, and mandrel 1 supplies carbon fiber prepreg to twine, and two rotating turrets 2 are close to or keep away from along mandrel 1 axis direction mutually. The upper surface of the bottom plate 3 is slidably connected with a material frame 33 along the horizontal radial direction of the core mold 1, and the material frame 33 is used for removing the core mold 1 after winding.

Referring to fig. 1, a base plate 3 is provided with a moving mechanism 32 for driving two rotating frames 2 to move, the moving mechanism 32 comprises a bidirectional screw rod 34 rotatably connected to the base plate 3, the length direction of the bidirectional screw rod 34 is consistent with the length direction of a mandrel 1, the screw thread directions at two sides of the center point of the bidirectional screw rod 34 are opposite, the two rotating frames 2 are positioned at equal distances on two sides of the center point of the bidirectional screw rod 34, the base plate 3 is fixedly connected with two guide rods 35, the length direction of the guide rods 35 is consistent with the length direction of the bidirectional screw rod 34, the bidirectional screw rod 34 is positioned between the two guide rods 35, the two guide rods 35 penetrate through the two rotating frames 2, the rotating frames 2 are slidably connected to the guide rods 35, and the base plate 3 is fixedly connected with a screw motor 36 with an output shaft which is coaxially and fixedly connected to one end of the bidirectional screw rod 34.

Referring to fig. 1 and 2, both ends of the core mold 1 are coaxially formed with step surfaces 26, the diameter of the step surfaces 26 is smaller than that of the core mold 1, both step surfaces 26 are coaxially screwed with an abutment ring 39, and the diameter of the abutment ring 39 is larger than that of the core mold 1. The upper end of the rotating frame 2 is fixedly connected with an end cylinder 37, the axial direction of the end cylinder 37 is the same as that of the core mold 1, the circumferential inner wall of the end cylinder 37 is slidably connected with the step surface 26, and the end surface of the end cylinder 37 can be abutted against the end surface of the abutting ring 39 to slide. The inner wall of the end cylinder 37 is coaxially and rotatably connected with a cylinder inner face gear 38, the end face of the core mold 1 is coaxially and fixedly connected with an end face gear 27, the end face gear 27 can be meshed with the cylinder inner face gear 38, a rotating frame 2 is detachably connected with a power motor 31, and the output shaft of the power motor 31 is coaxially and fixedly connected with a similar cylinder inner face gear 38, so that the core mold 1 can rotate to wind carbon fiber prepreg.

Referring to fig. 1, the material rack 33 includes a sliding seat 23 slidably connected to the bottom plate 3, and a cylinder can be fixed on the bottom plate 3 to drive the sliding seat 23 to move directionally (not shown in the figure), and when the weight of the wound carbon fiber composite tube is small, the sliding seat 23 can also be directly dragged to move. The upper surface of the sliding seat 23 is inserted in the vertical direction and is connected with a lifting frame 24 in a sliding manner, the lower part of the sliding seat 23 is detachably connected with a lifting cylinder 25, and a power rod of the lifting cylinder 25 is fixedly connected to the bottom of the lifting frame 24. Two arc blocks 21 are fixedly connected to the upper portion of the lifting frame 24 corresponding to the two supporting rings 39, limiting ring grooves 22 are coaxially formed in the circumferential outer walls of the supporting rings 39, and the arc blocks 21 can enter the limiting ring grooves 22, so that the core mold 1 can keep good stability when moving along with the movement of the sliding seat 23.

The winding manufacturing device of the carbon fiber composite tube of the embodiment of the application is implemented according to the following principle: the power motor 31 rotates the core mold 1 to wind the carbon fiber prepreg. After winding is completed, the core mold 1 stops rotating, the sliding seat 23 moves to the position where the arc blocks 21 are located right below the core mold 1, then the lifting cylinder 25 drives the lifting frame 24 to move upwards, so that the two arc blocks 21 enter the two limit ring grooves 22 in a one-to-one correspondence manner, then the screw motor 36 drives the bidirectional screw 34 to rotate, so that the two rotating frames 2 are far away, two ends of the core mold 1 are separated from the end cylinders 37, then the lifting frame 24 moves downwards and the sliding seat 23 moves, so that the core mold 1 moves to the side edge of the bottom plate 3 and can be sent to solidification by manpower or corresponding transportation equipment.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The utility model provides a winding manufacturing installation of carbon fiber composite pipe, includes supplies carbon fiber prepreg winding mandrel (1), two rotating turret (2) that one-to-one is located mandrel (1) both ends department, connects in bottom plate (3) of two rotating turret (2), locates rotating turret (2) and drives mandrel (1) pivoted power motor (31), its characterized in that: the two rotating frames (2) are connected to the bottom plate (3) in a sliding mode along the axis direction of the core mold (1), the bottom plate (3) is provided with a moving mechanism (32) for driving the two rotating frames (2) to move, and the bottom plate (3) is connected with a material rack (33) for driving the core mold (1) to be far away from between the two rotating frames (2) in a sliding mode.

2. The winding manufacturing device of a carbon fiber composite tube according to claim 1, wherein: the moving mechanism (32) comprises a bidirectional screw rod (34) rotatably connected to the bottom plate (3), a guide rod (35) fixedly connected to the bottom plate (3) and penetrating through the two rotating frames (2), and a screw rod motor (36) arranged on the bottom plate (3) and driving the bidirectional screw rod (34) to rotate.

3. The winding manufacturing device of a carbon fiber composite tube according to claim 1, wherein: the rotary frame (2) is fixedly connected with an end cylinder (37) for inserting the end part of the core mould (1), a cylinder inner face gear (38) is rotationally connected with the end cylinder (37), the end part of the core mould (1) is fixedly connected with an end face gear (27) which can be meshed with the cylinder inner face gear (38), and an output shaft of the power motor (31) is coaxially and fixedly connected with the cylinder inner face gear (38).

4. A winding manufacturing apparatus of a carbon fiber composite tube according to claim 3, wherein: two ends of the core mold (1) are detachably connected with a propping ring (39), and the propping ring (39) can be propped against the end face of the core mold (1).

5. The winding manufacturing device of a carbon fiber composite tube according to claim 4, wherein: an arc block (21) is fixedly connected to the material frame (33), and the circumferential inner wall of the arc block (21) is used for placing the supporting ring (39).

6. The winding manufacturing apparatus of a carbon fiber composite tube according to claim 5, wherein: the circumferential outer wall of the supporting ring (39) is provided with a limiting ring groove (22) for the arc block (21) to enter.

7. The winding manufacturing device of a carbon fiber composite tube according to claim 4, wherein: step surfaces (26) are formed at two ends of the core mold (1), and the supporting ring (39) is connected with the step surfaces (26) in a threaded mode.

8. The winding manufacturing device of a carbon fiber composite tube according to claim 1, wherein: the material rack (33) comprises a sliding seat (23) connected to the bottom plate (3) in a sliding manner, a lifting frame (24) connected to the sliding seat (23) in a sliding manner and close to or far away from the core mold (1) between the two rotating frames (2), and a lifting cylinder (25) arranged on the sliding seat (23) and driving the lifting frame (24) to move.