CN221395864U - Automatic tilting mechanism that carbon fiber yoke detected - Google Patents

Abstract

The utility model discloses an automatic turnover mechanism for carbon fiber fork arm detection, and relates to the technical field of automatic equipment. The utility model comprises a frame main body, wherein the frame main body comprises an uplink frame and a downlink frame which are fixedly connected, the uplink frame is provided with a connecting frame in a back-and-forth sliding way, a plurality of locking pieces for fixing one end of a fork arm are fixedly arranged on the connecting frame, the downlink frame is provided with a plurality of sockets which are in one-to-one correspondence with the locking pieces, the sockets are connected with the other end of the fork arm through bolts, the single end of a carbon fiber fork arm is respectively fixed with one of the other two ends, the carbon fiber fork arm can finish overturning movement by driving the connecting frame to slide back-and-forth, and the plurality of carbon fiber fork arms can be overturned simultaneously, so that the detection efficiency is improved.

Description

Automatic tilting mechanism that carbon fiber yoke detected

Technical Field

The utility model relates to the technical field of automatic equipment, in particular to an automatic overturning mechanism for carbon fiber fork arm detection.

Background

The fork arm is positioned at the front part in the bicycle structure, the upper end of the fork arm is connected with the handle bar part, the frame part is matched with the front pipe, the lower end of the fork arm is matched with the front shaft part to form a guiding system of the bicycle, and carbon fiber is an excellent material, so that the manufactured fork arm has good performance.

When the production of the carbon fiber fork arm is completed, the relevant detection flow is needed, the carbon fiber fork arm is usually lifted by factories at present, and then the relevant data is detected at each position through manual overturning.

Disclosure of Invention

The utility model aims to provide an automatic turnover mechanism for detecting carbon fiber fork arms, which aims to overcome the problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

The utility model provides an automatic tilting mechanism that carbon fiber yoke detected, includes the frame main part, the frame main part includes fixed connection's ascending frame and descending frame, ascending frame can be provided with the link around sliding, a plurality of retaining members that are used for fixed yoke one end have been set firmly on the link, a plurality of sockets with retaining member one-to-one are seted up to descending frame, socket and yoke's the other end bolt connection.

Further, the uplink frame is fixedly provided with a plurality of bearing parts, the bearing parts are slidably provided with driving parts and are provided with first racks fixedly connected with the driving parts, the connecting frame is fixedly provided with second racks, the first racks and the second racks are vertically distributed, and a linkage mechanism enabling the first racks and the second racks to slide synchronously is provided.

Still further, above-mentioned link gear is including rotating the drive shaft that sets up in ascending frame, one of them pot head of drive shaft is equipped with the first gear that is connected with first rack meshing, and another pot head is equipped with the second gear that is connected with the second rack meshing.

Further, the reinforcement is fixedly arranged on the uplink frame, and a sliding piece in sliding connection with the reinforcement is fixedly arranged on the connecting frame.

Further, the locking piece comprises a clamping piece and a positioning piece which are fixedly connected, and the clamping piece is arranged between the connecting frame and the positioning piece.

Further, the descending frame is detachably and fixedly provided with a bearing plate, and the socket is arranged on the bearing plate.

Compared with the prior art, the utility model has the beneficial effects that:

According to the utility model, the single end of the carbon fiber fork arm is respectively fixed with one of the other two ends, and the carbon fiber fork arm can finish overturning movement by driving the connecting frame to slide forwards and backwards, so that a plurality of carbon fiber fork arms can be overturned simultaneously, and the detection efficiency is improved.

In the second embodiment of the utility model, the socket plate for fixing the single end of the carbon fiber fork arm can be detached and replaced, the sizes of the sockets formed on different socket plates are different, and meanwhile, the size of the locking piece is larger than that of the standard carbon fiber fork arm on the existing market, and the socket plate with the socket with the corresponding size can be replaced to fix the carbon fiber fork arm with different sizes.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a rack body according to the present utility model.

Fig. 2 is an enlarged schematic view of the structure of the portion a in fig. 1 according to the present utility model.

Fig. 3 is a schematic diagram showing the overall structure of the frame body in the present utility model.

Fig. 4 is an enlarged schematic view of the B-section structure in fig. 3 according to the present utility model.

Fig. 5 is a schematic diagram of the overall structure of the linkage mechanism in the present utility model.

Reference numerals: 1. an uplink frame; 2. a downlink frame; 3. a connecting frame; 4. a locking member; 401. a clamping piece; 402. a positioning piece; 5. a socket; 6. a carrier; 7. a driving member; 8. a first rack; 9. a second rack; 10. a drive shaft; 11. a first gear; 12. a second gear; 13. a reinforcement; 14. a slider; 15. and a receiving plate.

Detailed Description

Specific embodiments of the present utility model will be described below with reference to the accompanying drawings. Numerous details are set forth in the following description in order to provide a thorough understanding of the present utility model, but it will be apparent to one skilled in the art that the present utility model may be practiced without these details.

As shown in fig. 1, an automatic turnover mechanism for detecting carbon fiber fork arms comprises a rack main body, wherein the rack main body comprises an uplink rack 1 and a downlink rack 2 which are fixedly connected, the uplink rack 1 and the downlink rack 2 are arranged in parallel, and two sides of the rack main body are fixed with square steel through welding, so that the uplink rack 1, the downlink rack 2 and the square steel form a shape of a Chinese character 'kou', and the stability of the rack main body is enhanced.

As shown in fig. 1-4, the up-going frame 1 can be provided with the connecting frame 3 in a sliding way, a plurality of locking pieces 4 for fixing one end of the fork arm are fixedly arranged on the connecting frame 3, the down-going frame 2 is provided with a plurality of sockets 5 corresponding to the locking pieces 4 one by one, the sockets 5 are connected with the other ends of the fork arms through bolts, when the carbon fiber fork arm is installed, one side of each of the two ends faces upwards, when the carbon fiber fork arm is fixed, one of the two ends is firstly inserted into the locking piece 4 upwards, then the independent end of the carbon fiber fork arm is aligned with the socket 5 to enable the fork arm to fall and insert, because the space length of the movable fork arm in the locking piece 4 is larger than the space length of the falling of the fork arm, and the socket 5 is in a circular table shape, the interface radius of the socket 5 is reduced from top to bottom, therefore, the carbon fiber fork arm can be erected between the up-going frame 1 and the down-going frame 2, and through forward or backward displacement of the motor driving connecting frame 3, the carbon fiber fork arm can be enabled to turn around the end connected with the socket 5 to be used as a pivot, and then a detector can manually turn over the fork arm, and the detector can turn over the carbon fiber fork arm, and the plurality of carbon fiber fork arms can be detected simultaneously, and the carbon fiber fork arm can be detected.

As shown in fig. 1-3, the ascending frame 1 is fixedly provided with a plurality of bearing pieces 6, the bearing pieces 6 are slidably provided with driving pieces 7, and are provided with first racks 8 fixedly connected with the driving pieces 7, the connecting frame 3 is fixedly provided with second racks 9, the first racks 8 are vertically distributed with the second racks 9, and are provided with a linkage mechanism for enabling the first racks 8 and the second racks 9 to slide synchronously, the driving pieces 7 slide on the bearing pieces 6 through motor driving, the driving pieces 7 can drive the first racks 8 to move together when sliding, the first racks 8 are horizontally distributed along the left and right, and the second racks 9 are longitudinally distributed along the front and the rear, so that the first racks 8 and the second racks 9 are vertically opposite, when the first racks 8 slide left and right, the second racks 9 can slide back and forth synchronously through the linkage mechanism, and the connecting frame 3 can be driven to slide back and forth, and the carbon fiber fork arms can be turned.

As shown in fig. 1, 3 and 5, specifically, the linkage mechanism includes a driving shaft 10 rotatably disposed on the uplink frame 1, one end of the driving shaft 10 is sleeved with a first gear 11 engaged with the first rack 8, and the other end is sleeved with a second gear 12 engaged with the second rack 9, so that the first rack 8 can drive the first gear 11 to rotate when sliding, and the first gear 11 can drive the driving shaft 10 and the second gear 12 to rotate, so that the second gear 12 can drive the second rack 9 to slide, and therefore, when the motor drives the driving member 7 to drive the first rack 8 to slide left and right, the second rack 9 can synchronously drive the connecting frame 3 to slide back and forth, so as to turn the carbon fiber fork arm.

As shown in fig. 3 and 4, the ascending frame 1 is fixedly provided with a reinforcement 13, the connecting frame 3 is fixedly provided with a sliding member 14 slidably connected with the reinforcement 13, in a specific embodiment, the reinforcement 13 and the sliding member 14 are provided with a plurality of groups, are arranged at intervals with the second rack 9, and are matched with the second rack 9 to be equidistantly distributed on the connecting frame 3, so that the self-weight force borne by the connecting frame 3 can be equally shared by a plurality of reinforcement 13 and the sliding member 14, and when the second rack 9 slides forwards and backwards, the sliding member 14 also synchronously moves forwards and backwards, so that the connecting frame 3 cannot be blocked due to overlarge stress of a certain second rack 9 when sliding.

As shown in fig. 1-4, the locking member 4 includes a locking member 401 and a positioning member 402 that are fixedly connected, the locking member 401 is disposed between the connecting frame 3 and the positioning member 402, a notch for inserting the carbon fiber fork arm is formed in the locking member 401, and the positioning member 402 surrounds the notch, so that the locking member 402 is only required to be moved into the positioning member 402 when the carbon fiber fork arm is fixed, so that the positioning member 402 limits the moving range thereof, and then the carbon fiber fork arm can be easily aligned to the notch on the positioning member 402 and inserted in the moving range.

As shown in fig. 1 and 3, the downlink frame 2 is detachably and fixedly provided with a receiving plate 15, the socket 5 is arranged on the receiving plate 15, the receiving plate 15 is locked and fixed on the downlink frame 2 through bolts, the size of the socket 5 on the receiving plate 15 can be arranged according to design, and the size of the notch on the clamping piece 401 is larger than the standard size of all the existing carbon fiber fork arms on the market, so that the clamping piece 401 can be inserted by the fork arms with different sizes.

The foregoing is merely illustrative of specific embodiments of the present utility model, but the design concept of the present utility model is not limited thereto, and any insubstantial modification of the present utility model by using the design concept shall fall within the scope of the present utility model.

Claims (6)

1. The utility model provides an automatic tilting mechanism that carbon fiber yoke detected, includes the frame main part, its characterized in that: the frame main part includes fixed connection's ascending frame (1) and descending frame (2), ascending frame (1) can be provided with link (3) with sliding back and forth, a plurality of retaining members (4) that are used for fixed yoke one end have been set firmly on link (3), a plurality of sockets (5) with retaining member (4) one-to-one are seted up to descending frame (2), socket (5) are connected with the other end bolt of yoke.

2. The automatic turnover mechanism for carbon fiber yoke detection according to claim 1, wherein: the uplink frame (1) is fixedly provided with a plurality of bearing pieces (6), the bearing pieces (6) are slidably provided with driving pieces (7) and are provided with first racks (8) fixedly connected with the driving pieces (7), the connecting frame (3) is fixedly provided with second racks (9), the first racks (8) are vertically distributed with the second racks (9), and a linkage mechanism enabling the first racks (8) and the second racks (9) to synchronously slide is provided.

3. The automatic turnover mechanism for carbon fiber yoke detection according to claim 2, wherein: the linkage mechanism comprises a driving shaft (10) which is rotatably arranged on the uplink frame (1), one end of the driving shaft (10) is sleeved with a first gear (11) which is meshed with the first rack (8), and the other end of the driving shaft is sleeved with a second gear (12) which is meshed with the second rack (9).

4. The automatic turnover mechanism for carbon fiber yoke detection according to claim 1, wherein: the reinforcing member (13) is fixedly arranged on the ascending frame (1), and the connecting frame (3) is fixedly provided with a sliding piece (14) which is in sliding connection with the reinforcing member (13).

5. The automatic turnover mechanism for carbon fiber yoke detection according to claim 1, wherein: the locking piece (4) comprises a clamping piece (401) and a positioning piece (402) which are fixedly connected, and the clamping piece (401) is arranged between the connecting frame (3) and the positioning piece (402).

6. The automatic turnover mechanism for carbon fiber yoke detection according to claim 1, wherein: the descending frame (2) is detachably and fixedly provided with a bearing plate (15), and the socket (5) is arranged on the bearing plate (15).