CN112265291A - Carbon fiber tube reelpipe fashioned device suitable for different diameters different wall thickness - Google Patents

Abstract

The invention relates to the field related to new materials, and discloses a device suitable for forming carbon fiber tube reelpipes with different diameters and different wall thicknesses, which comprises a main box body, wherein a feeding cavity is communicated from left to right in the main box body, a carbon fiber storage cavity is communicated with the upper side of the feeding cavity, a conveyor belt cavity is communicated with the lower side of the feeding cavity, a tube core pressing wheel cavity is communicated with the upper side of the feeding cavity, a shearing and cutting knife sliding cavity is communicated with the upper side of the feeding cavity, a half gear cavity is communicated with the left side of the shearing and cutting knife sliding cavity, the carbon fiber reelpipe is automatically cut off during forming, the step of cutting carbon fibers before reeling is omitted, the reeling efficiency is greatly improved, meanwhile, the cutting length of the carbon fiber can be changed, the thickness of the reelpipe is changed, the applicability of the device is ensured, the tube core pressing wheel is automatically clamped, so that the device is suitable for reeling processes of tube cores, the carbon fiber reel pipe is more compact in molding, and the molding quality of the carbon fiber reel pipe is greatly improved.

Description

Carbon fiber tube reelpipe fashioned device suitable for different diameters different wall thickness

Technical Field

The invention relates to the field of new materials, in particular to a device suitable for forming carbon fiber pipe reelpipes with different diameters and different wall thicknesses.

Background

One of the present new material of carbon fiber data, indicate the carbon content at the friction wheel cavity high strength high modulus fibre more than 90%, carbon fiber pipe, it is that adopting carbon-fibre composite to immerse phenethyl rare base polyester resin in advance and form through heating curing pultrusion (twine and warp), present carbon fiber pipe coil pipe former, need cut into appointed length with the carbon fiber earlier before the operation, two boards that reuse relative movement roll up the carbon fiber to the tube core on, make the reelpipe efficiency not high like this, if need produce the carbon fiber pipe of different wall thicknesses, need tailor carbon fiber length again.

Disclosure of Invention

The invention aims to provide a device suitable for carbon fiber tube coil forming with different diameters and different wall thicknesses, which can overcome the defects in the prior art and improve the practicability of equipment.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a device suitable for forming carbon fiber pipe reelpipes with different diameters and different wall thicknesses, which comprises a main box body, wherein a feeding cavity is arranged in the main box body in a left-right through way, a carbon fiber storage cavity is communicated and arranged at the upper side of the feeding cavity, a conveying belt cavity is communicated and arranged at the lower side of the feeding cavity, a pipe core pressing wheel cavity is communicated and arranged at the upper side of the feeding cavity, a shear knife sliding cavity is communicated and arranged at the upper side of the feeding cavity, a half gear cavity is communicated and arranged at the left side of the shear knife sliding cavity, a synchronous transmission cavity is arranged at the front side of the conveying belt cavity, a sliding bevel gear cavity is arranged at the front side of the synchronous transmission cavity, a driving belt wheel cavity positioned at the front side of the synchronous transmission cavity is arranged at the right side of the sliding bevel gear cavity, a motor is arranged at the front side of the driving belt wheel cavity, the rear end surface of the motor is fixedly connected with a left conveying wheel, the rear end wall of the sliding bevel gear cavity is connected with a rotating wheel shaft which extends backwards and penetrates through the synchronous transmission cavity and the conveying belt cavity to the rear end wall of the conveying belt cavity and extends forwards into the sliding bevel gear cavity in a rotating and matching manner, the front end wall of the conveying belt cavity is connected with a right conveying wheel shaft which extends backwards and penetrates through the conveying belt cavity to the rear end wall of the conveying belt cavity in a rotating and matching manner, the right conveying wheel shaft is fixedly connected with a right driving wheel positioned in the conveying belt cavity, the left conveying wheel shaft is fixedly connected with a left conveying wheel positioned in the conveying belt cavity, a conveying belt is connected between the left conveying wheel and the right driving wheel in a power matching manner, the rotating wheel shaft is fixedly connected with a rotating wheel positioned in the conveying belt cavity, the rotating wheel shaft is also fixedly connected with a synchronous driven belt wheel positioned in the synchronous transmission cavity, and the left conveying wheel shaft is also fixedly connected with a synchronous driving belt wheel, the synchronous driving belt wheel and the synchronous driven belt wheel are connected with a synchronous belt in a power fit mode, the tail end of the front side of the rotating wheel shaft is fixedly connected with a bevel gear, and the left conveying wheel shaft is further fixedly connected with a driving belt wheel located in the cavity of the driving belt wheel.

On the basis of the technical scheme, a pressing wheel shaft which extends backwards and penetrates through the feeding cavity into the rear end wall of the feeding cavity is connected in a rotationally matched manner in the front end wall of the feeding cavity, the pressing wheel shaft is positioned on the upper side of the right conveying wheel shaft, a pressing wheel positioned in the feeding cavity is fixedly connected to the pressing wheel shaft and positioned on the upper side of the conveying belt, a carbon fiber rotating shaft which extends backwards and penetrates through the carbon fiber storage cavity into the rear end wall of the carbon fiber storage cavity is connected in a rotationally matched manner in the front end wall of the carbon fiber storage cavity, a knob cavity positioned on the left side of the tube core pressing wheel cavity is arranged in the main box body, a knob which extends leftwards to the outside and rightwards to the knob cavity is connected in a threaded manner in the left end wall of the knob cavity in a matched manner, and a knob seat which, the rear end face of the knob seat is fixedly connected with a knob pull rope, the front side and the rear side of the tube core pressing wheel cavity are communicated with a sliding block cavity which is symmetrical front and back, the left side of the sliding block cavity is communicated with a sliding block connecting rod cavity, the sliding block connecting rod cavity is positioned on the upper side of the sliding bevel gear cavity, a sliding block is connected in the sliding block cavity in a sliding fit mode, and the left end face of the sliding block on the front side is fixedly connected with a connecting rod which is connected with the sliding block connecting rod cavity in a.

On the basis of the technical scheme, a sliding end face tooth cavity is arranged on the upper side of the sliding block connecting rod cavity, a torsion spring cavity is arranged on the upper side of the sliding end face tooth cavity, the upper end wall of the sliding bevel gear cavity is connected with a rotary spline shaft sleeve which extends downwards and extends into the sliding bevel gear cavity upwards, the upper end wall of the sliding block connecting rod cavity is connected with a spline shaft sleeve which extends downwards and extends into the sliding end face tooth cavity upwards, a transmission shaft through cavity is formed in the fixed shaft sleeve in a vertically through mode, the upper end wall of the sliding end face tooth cavity is connected with a spline shaft sleeve which extends upwards and extends into the torsion spring cavity downwards, a transmission shaft cavity with a downward opening is formed in the spline shaft sleeve, and the rotary spline shaft sleeve is internally connected with a spline shaft which extends upwards and penetrates through the sliding block connecting rod cavity, Lead to the chamber on the transmission shaft and slip terminal surface tooth chamber extremely the transmission shaft intracavity and with transmission shaft chamber spline fit connection downwardly extending transmission shaft in the slip bevel gear intracavity, on the transmission shaft intracavity wall fixedly connected with the clutch blocks of the outer disc butt of transmission shaft, the integral key shaft sheathe in end with fixedly connected with torsional spring between the torsional spring chamber upper end wall.

On the basis of the technical scheme, the transmission shaft is in spline fit connection with a shaft sleeve positioned in the sliding bevel gear cavity, the tail end of the upper side of the shaft sleeve is in rotary connection with a shaft sleeve seat, a transmission shaft through cavity is vertically communicated in the shaft sleeve seat, the transmission shaft penetrates through the transmission shaft through cavity, a shaft sleeve seat spring is fixedly connected between the upper end surface of the shaft sleeve seat and the upper end wall of the sliding bevel gear cavity, the tail end of the lower side of the shaft sleeve is fixedly connected with a helical gear capable of being meshed with the bevel gear, the slider at the front side is in rotary fit connection with a tube core pressing wheel shaft which extends backwards, penetrates through the tube core pressing wheel cavity to the slider at the rear side and is in rotary fit connection with the slider at the rear side, the tube core pressing wheel shaft is fixedly connected with a tube core pressing wheel positioned in the tube core pressing wheel cavity, and the, fixedly connected with slip terminal surface tooth on the one-way bearing, fixedly connected with is located on the transmission shaft slip terminal surface tooth intracavity and can with slip terminal surface tooth meshing's terminal surface tooth, one-way bearing down the terminal surface with fixedly connected with one-way bearing spring between the end wall under the slip terminal surface tooth chamber, terminal surface fixedly connected with magnetism slider stay cord under the one-way bearing.

On the basis of the technical scheme, a cutting knife which extends downwards into the feeding cavity is connected in a sliding fit manner in the cutting knife sliding cavity, a cutting knife spring is fixedly connected between the upper end surface of the cutting knife and the upper end wall of the cutting knife sliding cavity, a magnet is fixedly connected in the right end surface of the cutting knife, a magnetic slider cavity is communicated and arranged on the right side of the cutting knife sliding cavity, a magnetic slider corresponding to the magnet is connected in the magnetic slider cavity in a sliding fit manner, a magnetic slider spring is fixedly connected between the right end surface of the magnetic slider and the right end wall of the magnetic slider cavity, the other end of a magnetic slider pull rope is fixedly connected with the left end surface of the magnetic slider, a conical friction wheel cavity is arranged on the rear side of the transmission pulley cavity, a friction wheel cavity is communicated and arranged on the right side of the conical friction wheel cavity, and a transmission bevel gear cavity is arranged on, the right side of the transmission bevel gear cavity is provided with a pinion cavity, the pinion cavity is located at the front side of the half gear cavity, the rear end wall of the pinion cavity is connected with a half gear shaft which extends backwards into the half gear cavity forwards into the pinion cavity, the rear end of the half gear shaft is fixedly connected with a half gear meshed with the cutting knife, the front end of the half gear shaft is fixedly connected with a pinion, the front end wall of the right front end of the friction wheel cavity is connected with a friction wheel shaft which extends towards the right front side and towards the left rear side in the transmission bevel gear cavity.

On the basis of the technical scheme, the tail end of the front side of the friction wheel shaft is fixedly connected with a transmission bevel gear meshed with the pinion, the friction wheel is connected to the friction wheel shaft in a spline fit manner, the front end face of the friction wheel is fixedly connected with a friction wheel fixing block connected with the friction wheel shaft in a spline fit manner, the tail end of the front side of the friction wheel fixing block is connected with a fixing block seat in a rotating fit manner, a friction wheel shaft through cavity is arranged in the front and back of the fixing block seat in a penetrating manner, a friction wheel spring is fixedly connected between the front end face of the friction wheel shaft through cavity and the front end wall of the friction wheel cavity, the other end of the knob pull rope is fixedly connected with the front end face of the fixing block seat, a conical friction wheel shaft extending forwards into the transmission pulley cavity and backwards into the conical friction wheel cavity is connected in a rotating fit manner in, the transmission belt is connected between the driven belt wheel and the driving belt wheel in a power fit mode, the tail end of the rear side of the conical friction wheel shaft is fixedly connected with a conical friction wheel abutted against the friction wheel, and a resin adhesive brush is fixedly connected between the front end wall and the rear end wall of the feeding cavity.

The invention has the beneficial effects that: automatic cutting-off during carbon fiber reelpipe shaping, the step of cutting the carbon fiber before the reelpipe has been avoided, reelpipe efficiency has been improved greatly, and simultaneously, can change the carbon fiber and cut off length, make reelpipe thickness variable, the suitability of device has been guaranteed, tube core pinch roller self-holding makes the device be suitable for with the reelpipe technology of different diameter tube cores, and simultaneously, utilize the rotation wheel, the tube core pinch roller, left transfer gear presss from both sides tight tube core from three direction, make the shaping of carbon fiber reelpipe tighter, carbon fiber pipe shaping quality has been improved greatly.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic overall structure diagram of an apparatus for forming carbon fiber tubes with different diameters and different wall thicknesses according to the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is a schematic view of a portion of B-B of FIG. 2;

FIG. 4 is a schematic view of a portion of C-C of FIG. 1;

fig. 5 is an enlarged schematic view of fig. 3 at D.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Combine fig. 1-5 a fashioned device of carbon fiber tube reelpipe suitable for different diameter different wall thicknesses, including the main tank body 10, it is equipped with material conveying chamber 32 to link up about in the main tank body 10, material conveying chamber 32 upside intercommunication is equipped with carbon fiber storage chamber 17, material conveying chamber 32 downside intercommunication is equipped with conveyer belt chamber 28, material conveying chamber 32 upside intercommunication is equipped with tube core pressure roller chamber 33, material conveying chamber 32 upside intercommunication is equipped with tailor sword slip chamber 12, tailor sword slip chamber 12 left side intercommunication is equipped with half gear chamber 37, conveyer belt chamber 28 front side is equipped with synchronous drive chamber 87, synchronous drive chamber 87 front side is equipped with slide bevel gear chamber 47, slide bevel gear chamber 47 right side is equipped with the drive belt wheel chamber 45 that is located synchronous drive chamber 87 front side, drive belt wheel chamber 45 front side is equipped with motor 44, motor 44 rear end face fixedly connected with extends backward and runs through drive belt chamber 45, The synchronous transmission cavity 87 and the left transmission wheel shaft 27 from the transmission belt cavity 28 to the rear end wall of the transmission belt cavity 28, the rear end wall of the sliding bevel gear cavity 47 is connected with a rotating wheel shaft 29 which extends backwards, penetrates through the synchronous transmission cavity 87 and the transmission belt cavity 28, extends forwards and extends into the sliding bevel gear cavity 47 from the rear end wall of the transmission belt cavity 28 in a rotating and matching manner, the front end wall of the transmission belt cavity 28 is connected with a right transmission wheel shaft 22 which extends backwards, penetrates through the transmission belt cavity 28, to the rear end wall of the transmission belt cavity 28 in a rotating and matching manner, the right transmission wheel shaft 22 is fixedly connected with a right transmission wheel 23 positioned in the transmission belt cavity 28, the left transmission wheel shaft 27 is fixedly connected with a left transmission wheel 26 positioned in the transmission belt cavity 28, a transmission belt 24 is connected between the left transmission wheel 26 and the right transmission wheel 23 in a power matching manner, and the rotating wheel shaft 29 is fixedly connected with a rotating wheel 30 positioned in the transmission belt cavity 28, the rotating wheel shaft 29 is further fixedly connected with a synchronous driven wheel 49 positioned in the synchronous transmission cavity 87, the left transmission wheel shaft 27 is further fixedly connected with a synchronous driving wheel 41 positioned in the synchronous transmission cavity 87, a synchronous belt 46 is connected between the synchronous driving wheel 41 and the synchronous driven wheel 49 in a power fit manner, the tail end of the front side of the rotating wheel shaft 29 is fixedly connected with a bevel gear 48, and the left transmission wheel shaft 27 is further fixedly connected with a driving wheel 43 positioned in the transmission wheel cavity 45.

In addition, in one embodiment, a pressing wheel shaft 20 extending backwards and penetrating through the feeding cavity 32 to the rear end wall of the feeding cavity 32 is connected in a rotationally matched manner to the front end wall of the feeding cavity 32, the pressing wheel shaft 20 is positioned on the upper side of the right conveying wheel shaft 22, a pressing wheel 21 positioned in the feeding cavity 32 is fixedly connected to the pressing wheel shaft 20, the pressing wheel 21 is positioned on the upper side of the conveying belt 24, a carbon fiber rotating shaft 19 extending backwards and penetrating through the carbon fiber storage cavity 17 to the rear end wall of the carbon fiber storage cavity 17 is connected in a rotationally matched manner to the front end wall of the carbon fiber storage cavity 17, a knob cavity 34 positioned on the left side of the tube core pressing wheel cavity 33 is arranged in the main box body 10, a knob 35 extending leftwards and rightwards to the outside is connected in a rotationally matched manner to the left end wall of the knob cavity 34, a knob seat 18 connected with the knob cavity 34 in a sliding fit manner is connected to, the rear end face of the knob seat 18 is fixedly connected with a knob pull rope 36, the front side and the rear side of the tube core pressing wheel cavity 33 are communicated with a sliding block cavity 53 which is symmetrical front and rear, the left side of the sliding block cavity 53 is communicated with a sliding block connecting rod cavity 54, the sliding block connecting rod cavity 54 is located on the upper side of the sliding bevel gear cavity 47, a sliding block 88 is connected in the sliding block cavity 53 in a sliding fit mode, and the left end face of the sliding block 88 is fixedly connected with a connecting rod 82 which is connected with the sliding block connecting rod cavity 54 in a sliding fit mode.

In addition, in an embodiment, the upper side of the sliding block link cavity 54 is provided with a sliding end face tooth cavity 85, the upper side of the sliding end face tooth cavity 85 is provided with a torsion spring cavity 63, the upper end wall of the sliding bevel gear cavity 47 is connected with a rotating spline shaft sleeve 60 which extends downwards into the sliding bevel gear cavity 47 and extends upwards into the sliding block link cavity 54, the upper end wall of the sliding block link cavity 54 is connected with a fixed shaft sleeve 83 which extends downwards into the sliding block link cavity 54 and extends upwards into the sliding end face tooth cavity 85 in a rotating fit manner, the fixed shaft sleeve 83 is internally provided with an upper transmission shaft through cavity 81 in a vertical through manner, the upper end wall of the sliding end face tooth cavity 85 is connected with a spline shaft sleeve 51 which extends upwards into the torsion spring cavity 63 and extends downwards into the sliding end face tooth cavity 85 in a rotating fit manner, the spline shaft sleeve 51 is internally provided with a transmission shaft cavity 62 with a downward opening, spline fit connection has upwards to extend and runs through in the rotation spline axle sleeve 60 slider connecting rod chamber 54 lead to the chamber 81 on the transmission shaft and slide end face tooth chamber 85 extremely in the transmission shaft chamber 62 and with 62 spline fit connection downwardly extending in the transmission shaft chamber 52 in the slip bevel gear chamber 47, fixedly connected with on the transmission shaft chamber 62 inner wall with the clutch blocks 61 of the outer disc butt of transmission shaft 52, spline axle sleeve 51 up end with fixedly connected with torsional spring 50 between the torsional spring chamber 63 upper end wall.

In addition, in one embodiment, a shaft sleeve 56 located in the sliding bevel gear cavity 47 is connected to the transmission shaft 52 in a spline fit manner, a shaft sleeve seat 55 is rotatably connected to an upper end of the shaft sleeve 56, a transmission shaft through cavity 58 is vertically penetrated through the shaft sleeve seat 55, the transmission shaft 52 penetrates through the transmission shaft through cavity 58, a shaft sleeve seat spring 59 is fixedly connected between an upper end surface of the shaft sleeve seat 55 and an upper end wall of the sliding bevel gear cavity 47, a bevel gear 57 capable of being engaged with the bevel gear 48 is fixedly connected to a lower end of the shaft sleeve 56, a tube core pressing wheel shaft 31 which extends backwards through the tube core pressing wheel cavity 33 to a rear side of the slide block 88 and is rotatably connected with the rear side of the slide block 88 is rotatably connected to the front side of the slide block 88 in a fit manner, a tube core pressing wheel 89 located in the tube core pressing wheel cavity 33 is fixedly connected to the tube core pressing wheel shaft, spline fit connection has and is located on the fixed axle sleeve 83 one-way bearing 80 in the slip terminal surface tooth chamber 85, fixedly connected with slip terminal surface tooth 86 on the one-way bearing 80, fixedly connected with is located on the transmission shaft 52 in the slip terminal surface tooth chamber 85 and can with the terminal surface tooth 79 of slip terminal surface tooth 86 meshing, terminal surface under the one-way bearing 80 with fixedly connected with one-way bearing spring 84 between the terminal wall under the slip terminal surface tooth chamber 85, terminal surface fixed connection has magnetism slider stay cord 15 under the one-way bearing 80.

In addition, in one embodiment, the cutting knife 11 extending downward into the feeding cavity 32 is connected in the cutting knife sliding cavity 12 in a sliding fit manner, a cutting knife spring 13 is fixedly connected between the upper end surface of the cutting knife 11 and the upper end wall of the cutting knife sliding cavity 12, a magnet 14 is fixedly connected in the right end surface of the cutting knife 11, a magnetic slider cavity 16 is arranged in the right side of the cutting knife sliding cavity 12 in a communicating manner, a magnetic slider 78 corresponding to the magnet 14 is connected in the magnetic slider cavity 16 in a sliding fit manner, a magnetic slider spring 39 is fixedly connected between the right end surface of the magnetic slider 78 and the right end wall of the magnetic slider cavity 16, the other end of the magnetic slider pull rope 15 is fixedly connected with the left end surface of the magnetic slider 78, a conical friction wheel cavity 74 is arranged at the rear side of the driving pulley cavity 45, and a friction wheel cavity 90 is arranged in the right side of the conical friction wheel cavity 74 in, the friction wheel chamber 90 right side front side is equipped with transmission bevel gear chamber 70, transmission bevel gear chamber 70 right side is equipped with pinion chamber 67, pinion chamber 67 is located half gear chamber 37 front side, the end wall normal running fit in pinion chamber 67 is connected and extends to backward extend to half gear chamber 37 is inside to extend to half gear 40 in the pinion chamber 67, the terminal fixedly connected with in half gear 40 rear side with cut out the half gear 38 of 11 meshings of cutter, the terminal fixedly connected with pinion 66 in half gear 40 front side, the end wall normal running fit in friction wheel chamber 90 right side front side is connected and extends to right front side the left rear side extends to the friction wheel axle 68 in friction wheel chamber 90.

In addition, in one embodiment, a transmission bevel gear 69 engaged with the pinion gear 66 is fixedly connected to the front end of the friction wheel shaft 68, a friction wheel 77 is connected to the friction wheel shaft 68 in a spline fit manner, a friction wheel fixing block 76 connected to the friction wheel shaft 68 in a spline fit manner is fixedly connected to the front end face of the friction wheel 77, a fixing block seat 75 is rotatably connected to the front end of the friction wheel fixing block 76 in a fit manner, a friction wheel through cavity 64 is formed in the fixing block seat 75 in a front-back penetrating manner, a friction wheel spring 65 is fixedly connected between the front end face of the friction wheel through cavity 64 and the front end wall of the friction wheel cavity 90, the other end of the knob pull rope 36 is fixedly connected to the front end face of the fixing block seat 75, a tapered friction wheel shaft 72 extending forwards into the transmission belt wheel cavity 45 and backwards into the tapered friction wheel cavity 74 is connected to the front end wall of, the tail end of the front side of the conical friction wheel shaft 72 is fixedly connected with a driven belt wheel 71, a transmission belt 42 is connected between the driven belt wheel 71 and the driving belt wheel 43 in a power fit mode, the tail end of the rear side of the conical friction wheel shaft 72 is fixedly connected with a conical friction wheel 73 abutted against the friction wheel 77, and a resin adhesive brush 25 is fixedly connected between the front end wall and the rear end wall of the feeding cavity 32.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-5, when the apparatus of the present invention is in an initial state, the half gear 38 is just engaged with the cropper 11, the left end surface of the magnetic slider 78 is attached to the left end wall of the magnetic slider cavity 16, the upper end surface of the slider 88 is attached to the upper end wall of the slider cavity 53, the die pressing wheel shaft 31 is located in the die pressing wheel cavity 33, the bevel gear 57 is engaged with the bevel gear 48, the sleeve seat spring 59 is in a compressed state, the end surface teeth 79 are engaged with the sliding end surface teeth 86, the magnetic slider pull rope 15 is in a tightened state, and the torsion spring 50 is in a loosened state; sequence of mechanical actions of the whole device: when the machine starts to work, a tube core is placed between the rotating wheel 30 and the left conveying wheel 26, the carbon fiber on the carbon fiber rotating shaft 19 is pressed on the conveying belt 24 by the pressing wheel 21, the left conveying wheel shaft 27 is driven to rotate by the starting motor 44, so that the conveying belt 24 is driven to rotate, and the carbon fiber is driven to move leftwards, the resin adhesive brush 25 brushes the resin adhesive on the carbon fiber, the synchronous driving wheel 41 is driven to rotate by the rotation of the left conveying wheel shaft 27, the synchronous driven wheel 49 is driven to rotate by the synchronous belt 46, so that the rotating wheel shaft 29 is driven to rotate, the bevel gear 48 is driven to rotate, so that the bevel gear 57 is driven to rotate, so that the transmission shaft 52 is driven to rotate, so that the connecting rod 82 is driven to move downwards, so that the sliding block 88 is driven, when the die pinch roller 89 moves to touch the die, the die pinch roller 89 stops moving downward, as the drive shaft 52 continues to rotate, the drive shaft 52 moves upwardly, which in turn moves the sleeve 56 upwardly, which in turn moves the bevel gear 57 upwardly out of engagement with the bevel gear 48, under the elastic force of the shaft sleeve seat spring 59, the tube core pressing wheel 89 presses the tube core, simultaneously, the transmission shaft 52 rotates to drive the spline shaft sleeve 51 to rotate, thereby causing the torsion spring 50 to be twisted, the one-way bearing 80, by the elastic force of the one-way bearing spring 84, causes the sliding face teeth 86 to temporarily mesh with the face teeth 79, since the one-way bearing 80 can rotate only in one direction, the sliding end face teeth 86 cannot be reversed, so that the end face teeth 79 cannot be reversed temporarily, so that the transmission shaft 52 cannot be reversed temporarily, and the spline housing 51 cannot be reversed temporarily by the torsion force of the torsion spring 50; at this time, one end of the carbon fiber is just adhered to the tube core, the left transfer wheel 26 and the rotary wheel 30 are continuously rotated to rotate the tube core, so that the carbon fiber is rolled up on the tube core, the tube core is pressed and compacted by the tube core pressing wheel shaft 31, meanwhile, the left transfer wheel shaft 27 rotates to drive the driving wheel 43 to rotate, the driven wheel 71 is driven to rotate by the transmission belt 42, so that the conical friction wheel shaft 72 rotates to drive the conical friction wheel 73 to rotate, so that the friction wheel 77 rotates to drive the friction wheel shaft 68 to rotate, so that the pinion 66 rotates to drive the half gear shaft 40 to rotate, so that the half gear 38 rotates to drive the cutter 11 to move downwards to touch the transmission belt 24, so as to cut off the carbon fiber, the cutter spring 13 is stretched, at this time, the magnet 14 moves to the left side of the magnetic slider 78 to repel the right side, so as to pull the, the one-way bearing 80 moves downwards to drive the sliding end face teeth 86 to move downwards to be disengaged from the end face teeth 79, so that the spline shaft sleeve 51 rotates reversely under the torsion action of the torsion spring 50 to drive the transmission shaft 52 to rotate reversely, the connecting rod 82 moves upwards to drive the tube core pressing wheel 89 to move upwards, and the formed carbon fiber tube can be taken down; meanwhile, the shaft sleeve seat 55 moves downwards under the action of the elastic force of the shaft sleeve seat spring 59, so that the shaft sleeve 56 moves downwards, and the transmission shaft 52 is driven to move downwards, the transmission shaft 52 moves downwards slowly due to the friction action of the friction block 61, when the slide block 88 moves upwards to restore the initial position, the bevel gear 57 moves downwards just to be meshed with the bevel gear 48, when the half gear 38 rotates to be disengaged with the cutter knife 11, the cutter knife 11 moves upwards to the initial position under the pulling of the cutter knife spring 13, the magnet 14 is far away from the magnetic slide block 78, so that the magnetic slide block pull rope 15 is loosened, so that the one-way bearing 80 moves upwards, and the sliding end face teeth 86 are driven to move upwards to be meshed with the end face teeth 79, the device restores the initial state, at the moment, a new pipe core is placed, the moving process is repeated, next pipe rolling is carried out, when the thickness of the pipe needs to be, the knob 35 is rotated, so that the knob 35 moves left and right, the knob pull rope 36 is pulled, the fixing block seat 75 moves up and down, the friction wheel 77 is driven to move up and down, the friction wheel 77 and the conical friction wheel 73 are abutted to different diameters, the rotating speed of the friction wheel 77 is changed, the descending speed of the shearing knife 11 is changed, the time from starting to cutting off carbon fibers is changed, the length of the carbon fibers is changed, and the thickness of the reel pipe of the carbon fiber pipe is changed.

The invention has the beneficial effects that: automatic cutting-off during carbon fiber reelpipe shaping, the step of cutting the carbon fiber before the reelpipe has been avoided, reelpipe efficiency has been improved greatly, and simultaneously, can change the carbon fiber and cut off length, make reelpipe thickness variable, the suitability of device has been guaranteed, tube core pinch roller self-holding makes the device be suitable for with the reelpipe technology of different diameter tube cores, and simultaneously, utilize the rotation wheel, the tube core pinch roller, left transfer gear presss from both sides tight tube core from three direction, make the shaping of carbon fiber reelpipe tighter, carbon fiber pipe shaping quality has been improved greatly.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides a fashioned device of carbon fiber tube reelpipe suitable for different diameter different wall thicknesses, includes the main tank body, its characterized in that: it is equipped with the pay-off chamber to link up about in the main tank body, pay-off chamber upside intercommunication is equipped with carbon fiber storage chamber, pay-off chamber downside intercommunication is equipped with the conveyer belt chamber, pay-off chamber upside intercommunication is equipped with tube core pinch roller chamber, pay-off chamber upside intercommunication is equipped with cuts the cutter and slides the chamber, it is equipped with the half gear chamber to cut cutter slip chamber left side intercommunication, conveyer belt chamber front side is equipped with the synchronous transmission chamber, synchronous transmission chamber front side is equipped with the slip bevel gear chamber, slip bevel gear chamber right side is equipped with and is located the drive pulley chamber of synchronous transmission chamber front side, drive pulley chamber front side is equipped with the motor, motor rear end face fixedly connected with backward extension runs through the drive pulley chamber synchronous transmission chamber and conveyer belt chamber extremely the left conveying shaft in the conveyer belt chamber rear end wall, the cooperation of slip bevel gear chamber rear end wall is connected with backward extension runs through the synchronous transmission chamber and the conveyer belt chamber extremely the conveyer belt chamber A rotating wheel shaft extending forwards into the sliding bevel gear cavity from the rear end wall, a right transmitting wheel shaft extending backwards and penetrating through the transmitting belt cavity to the rear end wall of the transmitting belt cavity is connected in a rotating matching manner in the front end wall of the transmitting belt cavity, a right transmitting wheel positioned in the transmitting belt cavity is fixedly connected to the right transmitting wheel shaft, a left transmitting wheel positioned in the transmitting belt cavity is fixedly connected to the left transmitting wheel shaft, a transmitting belt is connected between the left transmitting wheel and the right transmitting wheel in a power matching manner, a rotating wheel positioned in the transmitting belt cavity is fixedly connected to the rotating wheel shaft, a synchronous driven belt wheel positioned in the synchronous transmitting cavity is also fixedly connected to the rotating wheel shaft, a synchronous driving belt wheel positioned in the synchronous transmitting cavity is also fixedly connected to the left transmitting wheel shaft, and a synchronous belt is connected between the synchronous driving belt wheel and the synchronous driven belt wheel in a power matching manner, the end of the front side of the rotating wheel shaft is fixedly connected with a bevel gear, and the left transmission wheel shaft is also fixedly connected with a driving belt wheel positioned in the driving belt wheel cavity.

2. The device for carbon fiber tube coiling forming of different diameters and different wall thicknesses as claimed in claim 1, wherein: a pressing wheel shaft which extends backwards and penetrates through the feeding cavity into the rear end wall of the feeding cavity is connected in a rotationally matched manner in the front end wall of the feeding cavity, the pressing wheel shaft is positioned on the upper side of the right conveying wheel shaft, a pressing wheel positioned in the feeding cavity is fixedly connected to the pressing wheel shaft, the pressing wheel is positioned on the upper side of the conveying belt, a carbon fiber rotating shaft which extends backwards and penetrates through the carbon fiber storage cavity into the rear end wall of the carbon fiber storage cavity is connected in a rotationally matched manner in the front end wall of the carbon fiber storage cavity, a knob cavity positioned on the left side of the tube core pressing wheel cavity is arranged in the main box body, a knob which extends leftwards to the outside and rightwards to the inside of the knob cavity is connected in a threaded manner in the left end wall of the knob cavity, a knob seat which is connected with the right end, the front side and the rear side of the tube core pressing wheel cavity are communicated with slider cavities which are symmetrical front and back, the left side of the slider cavity at the front side is communicated with a slider connecting rod cavity, the slider connecting rod cavity is positioned on the upper side of the sliding bevel gear cavity, a slider is connected in the slider cavity in a sliding fit manner, and the left end face of the slider at the front side is fixedly connected with a connecting rod which is connected with the slider connecting rod cavity in a sliding fit manner.

3. The device for carbon fiber tube coiling forming of different diameters and different wall thicknesses as claimed in claim 2, wherein: the slider connecting rod chamber upside is equipped with the slip terminal surface tooth chamber, slip terminal surface tooth chamber upside is equipped with the torsional spring chamber, the last end wall normal running fit in slip bevel gear chamber is connected and is extended downwards the slip bevel gear intracavity upwards extends to the rotation spline axle sleeve in slider connecting rod intracavity, the last end wall normal running fit in slider connecting rod chamber is connected and is extended downwards the slider connecting rod intracavity upwards extends to the fixed axle sleeve in slip terminal surface tooth intracavity, link up from top to bottom in the fixed axle sleeve and be equipped with the chamber that leads to on the transmission shaft, the last end wall normal running fit in end wall in slip terminal surface tooth chamber is connected with and upwards extends to the spline axle sleeve in the torsional spring chamber downwards extends to the slip terminal surface tooth intracavity, be equipped with the transmission shaft chamber that opens downwards in the spline axle sleeve, the spline fit in the rotation spline shaft, Lead to the chamber on the transmission shaft and slip terminal surface tooth chamber extremely the transmission shaft intracavity and with transmission shaft chamber spline fit connection downwardly extending transmission shaft in the slip bevel gear intracavity, on the transmission shaft intracavity wall fixedly connected with the clutch blocks of the outer disc butt of transmission shaft, the integral key shaft sheathe in end with fixedly connected with torsional spring between the torsional spring chamber upper end wall.

4. The device for carbon fiber tube coiling forming of different diameters and different wall thicknesses as claimed in claim 3, wherein: the transmission shaft is connected with a shaft sleeve positioned in the sliding bevel gear cavity in a spline fit manner, the tail end of the upper side of the shaft sleeve is rotatably connected with a shaft sleeve seat, a transmission shaft through cavity is arranged in the shaft sleeve seat in a vertically through manner, the transmission shaft penetrates through the transmission shaft through cavity, a shaft sleeve seat spring is fixedly connected between the upper end surface of the shaft sleeve seat and the upper end wall of the sliding bevel gear cavity, the tail end of the lower side of the shaft sleeve is fixedly connected with a helical gear capable of being meshed with the bevel gear, the slider at the front side is rotatably connected with a tube core pressing wheel shaft which extends backwards through the tube core pressing wheel cavity to the rear side and is rotatably connected with the slider at the rear side in a fit manner, the tube core pressing wheel shaft is fixedly connected with a tube core pressing wheel positioned in the tube core pressing wheel cavity, and the fixed, fixedly connected with slip terminal surface tooth on the one-way bearing, fixedly connected with is located on the transmission shaft slip terminal surface tooth intracavity and can with slip terminal surface tooth meshing's terminal surface tooth, one-way bearing down the terminal surface with fixedly connected with one-way bearing spring between the end wall under the slip terminal surface tooth chamber, terminal surface fixedly connected with magnetism slider stay cord under the one-way bearing.

5. The device for carbon fiber tube coiling forming of different diameters and different wall thicknesses as claimed in claim 2, wherein: the shearing knife sliding cavity is internally connected with a shearing knife which extends downwards into the feeding cavity in a sliding fit manner, a shearing knife spring is fixedly connected between the upper end surface of the shearing knife and the upper end wall of the shearing knife sliding cavity, a magnet is fixedly connected in the right end surface of the shearing knife, the right side of the shearing knife sliding cavity is communicated with a magnetic slider cavity, a magnetic slider corresponding to the magnet is connected in the magnetic slider cavity in a sliding fit manner, a magnetic slider spring is fixedly connected between the right end surface of the magnetic slider cavity and the right end wall of the magnetic slider cavity, the other end of a magnetic slider pull rope is fixedly connected with the left end surface of the magnetic slider, the rear side of the transmission belt wheel cavity is provided with a conical friction wheel cavity, the right side of the conical friction wheel cavity is communicated with a friction wheel cavity, the right front side of the friction wheel cavity is provided with a transmission bevel gear cavity, and the right side, the bevel gear comprises a half gear cavity, a half gear shaft, a cutting knife, a pinion, a friction wheel shaft, a friction wheel cavity, a right front side wall, a transmission bevel gear cavity, a left rear side wall, a friction wheel shaft and a cutting knife, wherein the half gear shaft extends backwards in the half gear.

6. The device for carbon fiber tube coiling forming of different diameters and different wall thicknesses as claimed in claim 5, wherein: the tail end of the front side of the friction wheel shaft is fixedly connected with a transmission bevel gear meshed with the pinion, the friction wheel is connected to the friction wheel shaft in a spline fit manner, the front end face of the friction wheel is fixedly connected with a friction wheel fixing block in a spline fit manner, the tail end of the front side of the friction wheel fixing block is connected with a fixing block seat in a rotating fit manner, a friction wheel shaft through cavity is arranged in the front and back of the fixing block seat in a penetrating manner, a friction wheel spring is fixedly connected between the front end face of the friction wheel shaft through cavity and the front end wall of the friction wheel cavity, the other end of the knob pull rope is fixedly connected with the front end face of the fixing block seat, a conical friction wheel shaft which extends forwards into the transmission wheel cavity and backwards into the conical friction wheel cavity is connected in a rotating fit manner in the front end wall of the, the transmission belt is connected between the driven belt wheel and the driving belt wheel in a power fit mode, the tail end of the rear side of the conical friction wheel shaft is fixedly connected with a conical friction wheel abutted against the friction wheel, and a resin adhesive brush is fixedly connected between the front end wall and the rear end wall of the feeding cavity.

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