CN107167389B

CN107167389B - Winding detection equipment for carbon fiber composite core

Info

Publication number: CN107167389B
Application number: CN201710421565.0A
Authority: CN
Inventors: 汪传斌; 孙湛; 田崇军; 蒋国庆
Original assignee: Far East Cable Co Ltd; New Far East Cable Co Ltd; Far East Composite Technology Co Ltd
Current assignee: Far East Cable Co Ltd; New Far East Cable Co Ltd; Far East Composite Technology Co Ltd
Priority date: 2017-06-06
Filing date: 2017-06-06
Publication date: 2023-06-02
Anticipated expiration: 2037-06-06
Also published as: CN107167389A

Abstract

The invention discloses a carbon fiber composite core winding detection device, which comprises a swing arm type passive pay-off rack, a swing arm type take-up and pay-off rack, a driving device, a crawler type rice recording device and a multi-section winding detection machine; the swing arm type passive pay-off rack, the swing arm type take-up and pay-off rack, the crawler-type rice recording device and the multi-section type winding detector are sequentially arranged; the driving device drives the swing arm type wire collecting and arranging frame to rotate; the core rod to be detected, which is wound on the swing arm type passive pay-off rack, is wound on the swing arm type take-up and pay-off rack sequentially through the crawler-type rice recording device and the multi-section winding detector. The invention has smart structure, realizes the core rod detection by winding the defects of the amplified core rod, has the advantages of multi-angle winding detection, high detection precision, accurate winding amplitude adjustment, recording of the number of meters and capability of rewinding the detected core rod into a disc, and greatly improves the working efficiency.

Description

Winding detection equipment for carbon fiber composite core

Technical Field

The invention relates to a carbon fiber composite core winding detection device.

Background

The winding performance is an important performance of the carbon fiber composite core, in the production of enterprises, the composite core rod detects the winding performance of the whole disc through winding, and the winding detection equipment used by the enterprises can not detect the composite core rod at a plurality of angles, so that the detection structure is inaccurate, and the winding amplitude can not be adjusted. Therefore, it is necessary to design a carbon fiber composite core winding detection device with adjustable winding amplitude at multiple angles.

Disclosure of Invention

The invention aims to provide a carbon fiber composite core winding detection device with adjustable winding amplitude and multiple angles.

The technical scheme for realizing the purpose of the invention is as follows: a winding detection device for a carbon fiber composite core comprises a swing arm type passive pay-off rack, a swing arm type take-up and pay-off rack, a driving device, a crawler type rice recording device and a multi-section winding detection machine; the swing arm type passive pay-off rack, the swing arm type take-up and pay-off rack, the crawler-type rice recording device and the multi-section type winding detector are sequentially arranged; the driving device drives the swing arm type wire collecting and arranging frame to rotate; the core rod to be detected, which is wound on the swing arm type passive pay-off rack, is wound on the swing arm type take-up and pay-off rack sequentially through the crawler-type rice recording device and the multi-section winding detector.

The multi-section type winding detection machine comprises a frame and a winding detection mechanism; a plurality of frames are arranged on the stand side by side; the winding detection mechanisms are arranged in parallel; the winding detection mechanism comprises a transverse track and a longitudinal track; the transverse track is arranged right in front of the center of the longitudinal track; each winding detection mechanism turns over different angles along the same central line, and the transverse track of each winding detection mechanism is fixed on the inner walls of two sides of one frame; and each frame is provided with a longitudinal rail for fixing the bending detection mechanism, wherein the longitudinal rail corresponds to the overturning angle of the bending detection mechanism arranged on the frame.

The transverse track comprises a first transverse slide bar, a second transverse slide bar and a transverse threaded slide bar which are arranged in parallel; the first transverse slide bar and the second transverse slide bar are fixedly connected with two side walls of the frame of the rack; the transverse threaded slide bar is arranged between the first transverse slide bar and the second transverse slide bar; the left side of the transverse threaded sliding rod is rotationally connected with the left side wall of the frame; the right side of the transverse threaded sliding rod penetrates through the right side wall of the frame and is rotationally connected with the right side wall of the frame; the right side surface of the transverse threaded sliding rod is fixedly provided with a first rotating disc; the longitudinal track comprises a first longitudinal slide bar, a second longitudinal slide bar and a longitudinal threaded slide bar which are arranged in parallel; the first longitudinal slide bar and the second longitudinal slide bar are fixedly connected with two ends of a supporting bracket of the frame; the longitudinal threaded slide bar is arranged between the first longitudinal slide bar and the second longitudinal slide bar; one end of the longitudinal threaded slide bar is rotationally connected with one end of the support bracket; the other end of the longitudinal threaded sliding rod penetrates through the other end of the supporting bracket and is rotationally connected with the supporting bracket; one end of the longitudinal threaded sliding rod penetrating through the supporting bracket is provided with a motor driving mechanism; the winding detection mechanism further comprises a first sliding block, a second sliding block, a third sliding block, a guide wheel and a pinch roller; the first sliding block and the second sliding block are arranged on the transverse track and are symmetrical along the middle part of the transverse track; the first sliding block and the second sliding block are in sliding connection with the first transverse sliding rod and the second transverse sliding rod; the first sliding block and the second sliding block are in threaded connection with the transverse threaded sliding rod; the upper right corner of one end surface of the first sliding block and the upper left corner of one end surface of the second sliding block are provided with bearings; the guide wheels are provided with two guide wheels and are respectively arranged on bearings of the first sliding block and the second sliding block; the third sliding block is arranged on the longitudinal track and is in sliding connection with the first longitudinal sliding rod and the second longitudinal sliding rod, and the third sliding block is in threaded connection with the longitudinal threaded sliding rod; a bearing is arranged in the middle of one end face of the third sliding block; the pinch roller is arranged on a bearing of the third sliding block, and the pinch roller and the two guide wheels are on the same plane.

The motor driving mechanism comprises a shell, a reduction gear set, a servo motor and a second rotating disc; the shell is fixed on the end face of the frame; the speed reduction gear set is arranged in the shell, and the output end of the speed reduction gear set is fixedly connected with the longitudinal threaded slide rod; the servo motor is arranged on one side of the shell, and an output shaft of the servo motor is fixedly connected with the input end of the reduction gear set; the second rotating disc is arranged on the other side of the shell, and is provided with a linkage rod fixedly connected with the other input end of the reduction gear set.

Bearings are arranged at the left lower corner of one end face of the first sliding block and the right lower corner of one end face of the second sliding block; the winding detection mechanism further comprises an auxiliary guide wheel; the two auxiliary guide wheels are respectively arranged on bearings at the lower left corner of one end face of the first sliding block and the lower right corner of one end face of the second sliding block; wheel grooves are formed in the outer circumferential surfaces of the auxiliary guide wheel, the guide wheel and the pinch roller.

The support bracket comprises a fixed plate; the two fixing plates are symmetrically fixed on two sides of the support bracket; one end of the fixed plate is fixedly connected with the first transverse sliding rod and the second transverse sliding rod, and one end of the fixed plate is rotationally connected with the transverse threaded sliding rod.

The device also comprises a guide bracket; the wire support is provided with two wire supports, and the two wire supports are respectively arranged between the swing arm type passive pay-off rack and the crawler-type rice recording device and between the multi-section type winding detector and the swing arm type take-up rack.

By adopting the technical scheme, the invention has the following beneficial effects: (1) The invention has smart structure, realizes the core rod detection by winding the defects of the amplified core rod, has the advantages of multi-angle winding detection, high detection precision, accurate winding amplitude adjustment, recording of the number of meters and capability of rewinding the detected core rod into a disc, and greatly improves the working efficiency.

(2) The multi-section type winding detector can detect at multiple angles, can adjust the winding amplitude, and is convenient to operate.

(3) The bending detection mechanism also comprises an auxiliary guide wheel for positioning the core rod, so that the core rod is prevented from sliding out during bending detection, and the bending detection is more stable.

(4) The motor driving mechanism of the invention ensures that the winding amplitude is more convenient and accurate.

(5) The support bracket of the invention comprises the fixing plate, so that the transverse guide rail is better fixed.

(6) The guide bracket provided by the invention has good supporting and guiding functions in the detection process.

Drawings

In order that the invention may be more readily understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings, in which

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic structural diagram of a bending detection mechanism according to the present invention.

The reference numerals in the drawings are:

the device comprises a swing arm type passive pay-off rack 1, a swing arm type pay-off rack 2, a driving device, a crawler type rice recording device 3, a multi-section type winding detector 4, a guide bracket 5, a rack 4-1, a frame 4-1-1, a support bracket 4-1-2, a fixed plate 4-1-2-1, a winding detection mechanism 4-2, a transverse track 4-2-1, a first transverse slide bar 4-2-1-1, a second transverse slide bar 4-2-1-2, a transverse thread slide bar 4-2-1-3, a first rotating disc 4-2-1-3-1, a longitudinal track 4-2-2-2, a first longitudinal slide bar 4-2-1, a second longitudinal slide bar 4-2-2-2, a longitudinal thread slide bar 4-2-2-3, a motor driving mechanism 4-2-3-1, a shell 4-2-3-1-1, a speed reduction gear set 4-2-3-1-2, a servo motor 4-2-3-1-2-3, a second rotating disc 4-2-2-3, a second rotating disc 4-2-3, a guide wheel 4-2-6 and a guide wheel 4-8-4-6.

Detailed Description

Example 1

Referring to fig. 1 and 2, the winding detection device for the carbon fiber composite core winding of the embodiment comprises a swing arm type passive pay-off rack 1, a swing arm type take-up and pay-off rack 2, a driving device, a crawler type rice recording device 3 and a multi-section winding detection machine 4.

The swing arm type passive pay-off rack 1, the swing arm type take-up and pay-off rack 2, the crawler-type rice recording device 3 and the multi-section type winding detector 4 are sequentially arranged. The driving device drives the swing arm type wire collecting and arranging frame 2 to rotate. The core rod to be detected, which is wound on the swing arm type passive pay-off rack 1, is wound on the swing arm type pay-off rack 2 through the crawler-type rice recording device 3 and the multi-section type winding detector 4 in sequence. A guide bracket 5 is also included. The two wire supports are arranged and are respectively arranged between the swing arm type passive pay-off rack 1 and the crawler-type rice recording device 3 and between the multi-section type winding detector 4 and the swing arm type take-up and pay-off rack 2.

The multi-section type bending detection machine 4 comprises a frame 4-1 and a bending detection mechanism 4-2. The frame 4-1 is provided with a plurality of frames 4-1-1 side by side. The winding detection mechanism 4-2 is provided in plurality in parallel. The curl detection mechanism 4-2 includes a transverse track 4-2-1 and a longitudinal track 4-2-2. The transverse rail 4-2-1 is arranged right in front of the center of the longitudinal rail 4-2-2. Each of the curl detection mechanisms 4-2 is flipped by a different angle along the same center line, and the lateral rails 4-2-1 of each of the curl detection mechanisms 4-2 are fixed to the inner walls on both sides of one of the frames 4-1-1. Each frame 4-1-1 is provided with a support bracket 4-1-2 corresponding to the turning angle of the curl detection mechanism 4-2 mounted on the frame 4-1-1 to fix a longitudinal rail 4-2-2 of the curl detection mechanism 4-2. The support bracket 4-1-2 includes a fixing plate 4-1-2-1. The fixing plates 4-1-2-1 are provided with two fixing plates and are symmetrically fixed on two sides of the supporting bracket 4-1-2. One end of the fixed plate 4-1-2-1 is fixedly connected with the first transverse sliding rod 4-2-1-1 and the second transverse sliding rod 4-2-1-2, and one end of the fixed plate 4-1-2-1 is rotatably connected with the transverse threaded sliding rod 4-2-1-3.

The transverse track 4-2-1 comprises a first transverse slide bar 4-2-1-1, a second transverse slide bar 4-2-1-2 and a transverse threaded slide bar 4-2-1-3 arranged in parallel. The first transverse slide bar 4-2-1-1 and the second transverse slide bar 4-2-1-2 are fixedly connected with two side walls of the frame 4-1-1 of the stand 4-1. The transversal threaded slide bar 4-2-1-3 is arranged between the first transversal slide bar 4-2-1-1 and the second transversal slide bar 4-2-1-2. The left side of the transverse threaded slide bar 4-2-1-3 is rotatably connected with the left side wall of the frame 4-1-1. The right side of the transverse threaded sliding rod 4-2-1-3 penetrates through the right side wall of the frame 4-1-1 and is rotatably connected with the right side wall of the frame 4-1-1. The right side surface of the transverse threaded sliding rod 4-2-1-3 is fixedly provided with a first rotating disc 4-2-1-3-1. The longitudinal rail 4-2-2 comprises a first longitudinal slide bar 4-2-2-1, a second longitudinal slide bar 4-2-2-2 and a longitudinal threaded slide bar 4-2-2-3 arranged in parallel. The first longitudinal slide bar 4-2-2-1 and the second longitudinal slide bar 4-2-2 are fixedly connected with two ends of the support bracket 4-1-2 of the frame 4-1-1. The longitudinal threaded slide bar 4-2-2-3 is disposed between the first longitudinal slide bar 4-2-2-1 and the second longitudinal slide bar 4-2-2-2. One end of the longitudinal thread slide bar 4-2-2-3 is rotatably connected with one end of the support bracket 4-1-2. The other end of the longitudinal thread slide bar 4-2-2-3 penetrates through the other end of the support bracket 4-1-2 and is in rotary connection with the support bracket 4-1-2. One end of the longitudinal thread slide bar 4-2-2-3 penetrating through the support bracket 4-1-2 is provided with a motor driving mechanism 4-2-2-3-1. The motor driving mechanism 4-2-2-3-1 includes a housing 4-2-2-3-1-1, a reduction gear set 4-2-2-3-1-2, a servo motor 4-2-2-3-1-3, and a second rotary disk 4-2-2-3-1-4. The housing 4-2-2-3-1-1 is fixed to an end face of the frame 4-1-1. The reduction gear set 4-2-2-3-1-2 is arranged in the shell 4-2-2-3-1-1, and the output end of the reduction gear set 4-2-2-3-1-2 is fixedly connected with the longitudinal threaded slide rod 4-2-2-3. The servo motor 4-2-2-3-1-3 is arranged on one side of the shell 4-2-2-3-1-1, and an output shaft of the servo motor 4-2-2-3-1-3 is fixedly connected with an input end of the reduction gear set 4-2-2-3-1-2. The second rotating disc 4-2-2-3-1-4 is arranged on the other side of the shell 4-2-2-3-1-1, and is provided with a linkage rod fixedly connected with the other input end of the reduction gear set 4-2-2-3-1-2. The winding detection mechanism 4-2 further comprises a first sliding block 4-2-3, a second sliding block 4-2-4, a third sliding block 4-2-5, a guide wheel 4-2-6 and a pinch roller 4-2-7. The first slider 4-2-3 and the second slider 4-2-4 are provided on the lateral rail 4-2-1 and are symmetrical along the middle of the lateral rail 4-2-1. The first sliding block 4-2-3 and the second sliding block 4-2-4 are in sliding connection with the first transverse sliding rod 4-2-1-1 and the second transverse sliding rod 4-2-1-2. The first sliding block 4-2-3 and the second sliding block 4-2-4 are in threaded connection with the transverse threaded sliding rod 4-2-1-3. Bearings are arranged at the upper right corner of one end face of the first sliding block 4-2-3 and the upper left corner of one end face of the second sliding block 4-2-4. The guide wheels 4-2-6 are provided with two guide wheels and are respectively arranged on bearings of the first sliding block 4-2-3 and the second sliding block 4-2-4. The third sliding block 4-2-5 is arranged on the longitudinal track 4-2-2, the third sliding block 4-2-5 is in sliding connection with the first longitudinal sliding rod 4-2-2-1 and the second longitudinal sliding rod 4-2-2, and the third sliding block 4-2-5 is in threaded connection with the longitudinal threaded sliding rod 4-2-2-3. The middle part of one end face of the third sliding block 4-2-5 is provided with a bearing. The pinch roller 4-2-7 is arranged on a bearing of the third slider 4-2-5, and the pinch roller 4-2-7 and the two guide wheels 4-2-6 are both on the same plane. Bearings are arranged at the lower left corner of one end face of the first sliding block 4-2-3 and the lower right corner of one end face of the second sliding block 4-2-4. The curl detection mechanism 4-2 also includes a sub-guide roller 4-2-8. The two auxiliary guide wheels 4-2-8 are respectively arranged on bearings at the lower left corner of one end face of the first sliding block 4-2-3 and the lower right corner of one end face of the second sliding block 4-2-4; wheel grooves are formed in the outer circumferential surfaces of the auxiliary guide wheels 4-2-8, the guide wheels 4-2-6 and the pinch wheels 4-2-7.

When the device is used, one end of a core rod to be inspected, which is placed on the swing arm type passive pay-off rack 1, is wound on the swing arm type pay-off rack 2 sequentially through the guide bracket 5, the crawler type rice recording device 3, the multi-section winding detection machine 4 and the other guide bracket 5, the driving device drives the swing arm type pay-off rack 2 to rotate to repeat the core rod into a disc, the core rod passes through a first auxiliary guide wheel 4-2-8, a first guide wheel 4-2-6, a pressing wheel 4-2-7, a second guide wheel 4-2-6 and a second auxiliary guide wheel 4-2-8 of the plurality of winding detection mechanisms 4-2, the pressing wheel 4-2-7 of the winding detection mechanism 4-2 and the two guide wheels 4-2-6 squeeze the core rod to bend the core rod, and the plurality of detection mechanisms 4-2 squeeze the core rod from different angles. The first rotating disc 4-2-1-3-1 is manually rotated to drive the transverse threaded sliding rod 4-2-1-3 to rotate, so that the guide wheel 4-2-6 on the first sliding block 4-2-3 and the guide wheel 4-2-6 on the second sliding block 4-2-4 synchronously move to two sides or move to the middle on the transverse track 4-2-1, and the motor driving mechanism 4-2-2-3-1 is used for driving the longitudinal threaded sliding rod 4-2-2-3 to rotate, so that the pinch roller 4-2-7 on the third sliding block 4-2-5 moves on the longitudinal track 4-2-2, and therefore the winding amplitude is adjusted.

While the foregoing is directed to embodiments of the present invention, other and further details of the invention may be had by the present invention, it should be understood that the foregoing description is merely illustrative of the present invention and that no limitations are intended to the scope of the invention, except insofar as modifications, equivalents, improvements or modifications are within the spirit and principles of the invention.

Claims

1. A carbon fiber composite core winding detection device is characterized in that: comprises a swing arm type passive pay-off rack (1), a swing arm type take-up and pay-off rack (2), a driving device, a crawler type rice recording device (3) and a multi-section type winding detector (4); the swing arm type passive pay-off rack (1), the swing arm type pay-off rack (2), the crawler type rice recording device (3) and the multi-section type winding detection machine (4) are sequentially arranged; the driving device drives the swing arm type wire collecting and arranging frame (2) to rotate; the core rod to be detected, which is wound on the swing arm type passive pay-off rack (1), is wound on the swing arm type pay-off rack (2) through the crawler-type rice recording device (3) and the multi-section type winding detector (4) in sequence;

the multi-section type winding detection machine (4) comprises a frame (4-1) and a winding detection mechanism (4-2); a plurality of frames (4-1-1) are arranged on the stand (4-1) side by side; the winding detection mechanism (4-2) is provided with a plurality of winding detection mechanisms side by side; the winding detection mechanism (4-2) comprises a transverse track (4-2-1) and a longitudinal track (4-2-2); the transverse track (4-2-1) is arranged right in front of the center of the longitudinal track (4-2-2); the bending detection mechanisms (4-2) are turned over by different angles along the same central line, and the transverse tracks (4-2-1) of each bending detection mechanism (4-2) are fixed on the inner walls of two sides of one frame (4-1-1); the frame (4-1-1) is provided with a support bracket (4-1-2) corresponding to the overturning angle of the bending detection mechanism (4-2) arranged on the frame (4-1-1), and a longitudinal rail (4-2-2) of the bending detection mechanism (4-2) is fixed on the support bracket;

the transverse track (4-2-1) comprises a first transverse sliding rod (4-2-1-1), a second transverse sliding rod (4-2-1-2) and a transverse threaded sliding rod (4-2-1-3) which are arranged in parallel; the first transverse sliding rod (4-2-1-1) and the second transverse sliding rod (4-2-1-2) are fixedly connected with two side walls of the frame (4-1-1) of the stand (4-1); the transverse threaded sliding rod (4-2-1-3) is arranged between the first transverse sliding rod (4-2-1-1) and the second transverse sliding rod (4-2-1-2); the left side of the transverse threaded sliding rod (4-2-1-3) is rotationally connected with the left side wall of the frame (4-1-1); the right side of the transverse threaded sliding rod (4-2-1-3) penetrates through the right side wall of the frame (4-1-1) and is rotationally connected with the right side wall of the frame (4-1-1); the right side surface of the transverse threaded sliding rod (4-2-1-3) is fixedly provided with a first rotating disc (4-2-1-3-1); the longitudinal track (4-2-2) comprises a first longitudinal sliding rod (4-2-2-1), a second longitudinal sliding rod (4-2-2-2) and a longitudinal threaded sliding rod (4-2-2-3) which are arranged in parallel; the first longitudinal sliding rod (4-2-2-1) and the second longitudinal sliding rod (4-2-2) are fixedly connected with two ends of a supporting bracket (4-1-2) of the frame (4-1-1); the longitudinal threaded sliding rod (4-2-2-3) is arranged between the first longitudinal sliding rod (4-2-2-1) and the second longitudinal sliding rod (4-2-2-2); one end of the longitudinal threaded slide bar (4-2-2-3) is rotatably connected with one end of the support bracket (4-1-2); the other end of the longitudinal threaded sliding rod (4-2-2-3) penetrates through the other end of the supporting bracket (4-1-2) and is rotationally connected with the supporting bracket (4-1-2); one end of the longitudinal threaded sliding rod (4-2-2-3) penetrating through the supporting bracket (4-1-2) is provided with a motor driving mechanism (4-2-2-3-1); the winding detection mechanism (4-2) further comprises a first sliding block (4-2-3), a second sliding block (4-2-4), a third sliding block (4-2-5), a guide wheel (4-2-6) and a pinch roller (4-2-7); the first sliding block (4-2-3) and the second sliding block (4-2-4) are arranged on the transverse track (4-2-1) and are symmetrical along the middle part of the transverse track (4-2-1); the first sliding block (4-2-3) and the second sliding block (4-2-4) are in sliding connection with the first transverse sliding rod (4-2-1-1) and the second transverse sliding rod (4-2-1-2); the first sliding block (4-2-3) and the second sliding block (4-2-4) are in threaded connection with the transverse threaded sliding rod (4-2-1-3); the upper right corner of one end surface of the first sliding block (4-2-3) and the upper left corner of one end surface of the second sliding block (4-2-4) are provided with bearings; the guide wheels (4-2-6) are provided with two guide wheels and are respectively arranged on bearings of the first sliding block (4-2-3) and the second sliding block (4-2-4); the third sliding block (4-2-5) is arranged on the longitudinal track (4-2-2), the third sliding block (4-2-5) is in sliding connection with the first longitudinal sliding rod (4-2-2-1) and the second longitudinal sliding rod (4-2-2-2), and the third sliding block (4-2-5) is in threaded connection with the longitudinal threaded sliding rod (4-2-2-3); a bearing is arranged in the middle of one end face of the third sliding block (4-2-5); the pinch roller (4-2-7) is arranged on a bearing of the third sliding block (4-2-5), and the pinch roller (4-2-7) and the two guide wheels (4-2-6) are both on the same plane.

2. The carbon fiber composite core winding detection apparatus as defined in claim 1, wherein: the motor driving mechanism (4-2-2-3-1) comprises a shell (4-2-2-3-1-1), a reduction gear set (4-2-2-3-1-2), a servo motor (4-2-2-3-1-3) and a second rotating disc (4-2-2-3-1-4); the shell (4-2-2-3-1-1) is fixed on the end face of the frame (4-1-1); the speed reduction gear set (4-2-2-3-1-2) is arranged in the shell (4-2-2-3-1-1), and the output end of the speed reduction gear set (4-2-2-3-1-2) is fixedly connected with the longitudinal threaded slide rod (4-2-2-3); the servo motor (4-2-2-3-1-3) is arranged on one side of the shell (4-2-2-3-1-1), and an output shaft of the servo motor (4-2-2-3-1-3) is fixedly connected with an input end of the reduction gear set (4-2-2-3-1-2); the second rotating disc (4-2-2-3-1-4) is arranged on the other side of the shell (4-2-2-3-1-1), and is provided with a linkage rod fixedly connected with the other input end of the reduction gear set (4-2-2-3-1-2).

3. The carbon fiber composite core winding detection apparatus as defined in claim 1, wherein: bearings are arranged at the lower left corner of one end face of the first sliding block (4-2-3) and the lower right corner of one end face of the second sliding block (4-2-4); the winding detection mechanism (4-2) further comprises an auxiliary guide wheel (4-2-8); the two auxiliary guide wheels (4-2-8) are arranged on bearings at the lower left corner of one end face of the first sliding block (4-2-3) and the lower right corner of one end face of the second sliding block (4-2-4) respectively; wheel grooves are formed in the outer circumferential surfaces of the auxiliary guide wheels (4-2-8), the guide wheels (4-2-6) and the pinch wheels (4-2-7).

4. The carbon fiber composite core winding detection apparatus as defined in claim 1, wherein: the support bracket (4-1-2) comprises a fixed plate (4-1-2-1); the two fixing plates (4-1-2-1) are symmetrically fixed on two sides of the supporting bracket (4-1-2); one end of the fixing plate (4-1-2-1) is fixedly connected with the first transverse sliding rod (4-2-1-1) and the second transverse sliding rod (4-2-1-2), and one end of the fixing plate (4-1-2-1) is rotatably connected with the transverse threaded sliding rod (4-2-1-3).

5. The carbon fiber composite core winding detection apparatus as defined in claim 1, wherein: also comprises a guide bracket (5); the guide brackets are arranged in two, and are respectively arranged between the swing arm type passive pay-off rack (1) and the crawler type rice recording device (3) and between the multi-section type winding detector (4) and the swing arm type winding and unwinding rack (2) side by side.