CN117741195A - Duplex position detection device - Google Patents

Abstract

The application discloses duplex position detection device relates to circuit board detection technical field. The application comprises the following steps: the device comprises a frame body, wherein the frame body is provided with two areas to be detected and two detection areas, two driving frames are vertically and slidably arranged on the frame body, a connecting assembly is arranged on the driving frames and used for installing a detection template, two pushing plates are slidably arranged on the frame body, and the two pushing plates are respectively positioned in the two areas to be detected; and the transmission mechanism is arranged on the frame body. This application makes the push plate propelling movement on the left to A detection zone through actuating mechanism, can accomplish the material loading in another detection zone at the in-process that detects to save time, not only this can make on two drive frames can install the detection template of different models through coupling assembling, thereby can carry out circuit detection to the PCB template of two kinds of different models simultaneously, further improved work efficiency.

Description

Duplex position detection device

Technical Field

The application relates to the technical field of circuit board detection, in particular to a double-station detection device.

Background

Cell phone FCT (functional test) detection devices play a vital role in the field of electronic device manufacturing. These devices are used to detect the circuit connections and functionality of a cell phone circuit board (PCB board) to ensure that its quality and performance meet standard requirements. However, the existing double-station detection device needs to place the PCB in the area to be detected in the detection process, and then moves the detected PCB onto the conveyor belt after the detection is completed, the whole detection process has a certain retention time when the PCB is moved, and the existing detection device can only detect the PCB with the same model, and when other PCBs are detected, the corresponding detection templates need to be replaced for batch detection, so that the problems of low detection efficiency and time waste are caused.

Disclosure of Invention

The purpose of the present application is: in order to solve the above-mentioned problems, the present application provides a dual-station detection device.

The application specifically adopts the following technical scheme for realizing the purposes:

a duplex position detection apparatus, comprising:

the device comprises a frame body, wherein the frame body is provided with two areas to be detected and two detection areas, two driving frames are vertically and slidably arranged on the frame body, a connecting assembly is arranged on the driving frames and used for installing a detection template, two pushing plates are slidably arranged on the frame body, and the two pushing plates are respectively positioned in the two areas to be detected;

the transmission mechanism is arranged on the frame body and is used for conveying the PCB to be detected to the two areas to be detected;

the transmission mechanism is arranged on the frame body and acts on the two driving frames, one driving frame moves to the detection area through the transmission mechanism, and the other driving frame moves in a direction away from the detection area;

the driving mechanism is arranged on the driving frame and is used for driving the pushing plate to move;

the blanking mechanism is arranged on the frame body and is used for receiving the PCB sliding from the detection area;

wherein, a plurality of locating boxes are placed on the transmission mechanism, and the PCB board is placed in the locating boxes.

Further, the transmission mechanism comprises a transmission rod rotatably mounted on the frame body, the free ends of the transmission rod are hinged with linkage rods, the free ends of the two linkage rods are respectively hinged to the two driving frames, and the frame body is provided with a power piece for driving the transmission rod to rotate.

Further, the power piece is including rotating the rolling disc of installing on the support body, construct on the rolling disc and have the eccentric column, install on the support body the drive rolling disc pivoted motor, transfer line one side mid-mounting has rocking bar, the movable groove has been seted up along its length direction on the rocking bar, the eccentric column slip is tangent in the movable groove.

Further, the driving mechanism comprises a convex plate which is constructed on one side of the driving frame, a hinge rod is hinged on the convex plate, a connecting plate is constructed at the top of the pushing plate, and the free ends of the two hinge rods are respectively hinged on the two connecting plates.

Further, the transmission mechanism comprises two first conveyor belt components symmetrically arranged on the frame body, a separation plate is constructed on the frame body, the conveying tail ends of the two first conveyor belt components are respectively contacted with one side of the separation plate, a limit baffle is constructed on one side of the pushing plate, and the length of the pushing plate is consistent with that of the positioning box.

Further, the blanking mechanism comprises a second conveyor belt assembly arranged on the frame body, a splicing groove is formed in one side of the length direction of the positioning box in a penetrating mode, a guide inserting plate for being inserted into the splicing groove is arranged at the position of the frame body detection area, and two guide inclined planes are symmetrically formed in one side of the guide inserting plate.

Further, the connecting assembly comprises a rotating rod rotatably mounted on the driving frame, a plurality of mounting plates are arranged on the outer periphery side of the rotating rod, mounting grooves are formed in the bottoms of the mounting plates and used for mounting the detection templates, and locking pieces are mounted on the driving frame and used for limiting the rotation of the driving frame.

Further, the locking piece is including installing sleeve on the drive frame, telescopic one end slip runs through has the locating lever, a plurality of constant head tanks that supply the locating lever to insert to establish are seted up to the circular array of dwang periphery side, the quantity of constant head tank is unanimous with the mounting panel quantity of installing on the dwang, the locating lever is located one side construction in the sleeve has the limiting plate, the limiting plate with install conflict spring between the sleeve.

Further, the free end of the linkage rod is hinged with a connecting frame, the driving frame is vertically and slidably arranged on the connecting frame, and an adjusting piece for driving the driving frame to vertically move is arranged on the connecting frame.

Further, the adjusting piece includes vertical and rotation and installs adjusting screw on the link, threaded sleeve is equipped with the screw thread piece on the adjusting screw, swing joint has the actuating lever on the screw thread piece, the free end of actuating lever articulates on the link, the drive slot has been seted up along its length direction on the actuating lever, be constructed on the drive frame with the tangent pole of drive slot slip.

The beneficial effects of this application are as follows:

this application makes the push plate propelling movement on the left to A detection zone through actuating mechanism, can accomplish the material loading in another detection zone at the in-process that detects to save time, not only this can make on two drive frames can install the detection template of different models through coupling assembling, thereby can carry out circuit detection to the PCB template of two kinds of different models simultaneously, further improved work efficiency.

Drawings

FIG. 1 is a schematic perspective view of the present application;

FIG. 2 is a schematic view of another view of FIG. 1 of the present application;

FIG. 3 is an exploded view of a portion of the construction of the present application;

FIG. 4 is an exploded view of yet another portion of the construction of the present application;

FIG. 5 is a schematic view of the present application from another perspective of FIG. 4;

FIG. 6 is a schematic diagram of the power member structure of the present application;

FIG. 7 is an enlarged view of the structure of FIG. 1A of the present application;

FIG. 8 is an enlarged view of the structure of FIG. 4B of the present application;

reference numerals: 1. a frame body; 2. a positioning box; 3. a drive rack; 4. a connection assembly; 401. a rotating lever; 402. a mounting plate; 403. a mounting groove; 5. a locking member; 501. a sleeve; 502. a positioning rod; 503. a limiting plate; 504. a contact spring; 505. a positioning groove; 6. a transmission mechanism; 601. a first conveyor belt assembly; 602. a partition plate; 603. a limit baffle; 7. a transmission mechanism; 701. a transmission rod; 702. a linkage rod; 8. a pushing plate; 9. a driving mechanism; 901. a convex plate; 902. a hinge rod; 903. a connecting plate; 10. a blanking mechanism; 1001. a second conveyor belt assembly; 1002. a plug-in groove; 1003. a guide plugboard; 1004. a guide slope; 11. a power member; 1101. a rotating disc; 1102. an eccentric column; 1103. swinging the rod; 1104. a movable groove; 12. a connecting frame; 13. an adjusting member; 1301. adjusting a screw; 1302. a screw block; 1303. a driving rod; 1304. a driving groove; 1305. a post.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

As shown in fig. 1 to 8, a dual-station detection device according to an embodiment of the present application includes:

the device comprises a frame body 1, wherein the frame body 1 is provided with two areas to be detected and two detection areas, two driving frames 3 are vertically and slidably arranged on the frame body 1, specifically, guide rods are arranged on the driving frames 3, the guide rods are rectangular, the number of the preferred guide rods can be multiple, so that stability in moving is improved, a connecting component 4 is arranged on the driving frames 3 and used for installing a detection template, two pushing plates 8 are slidably arranged on the frame body 1, and the two pushing plates 8 are respectively positioned in the two areas to be detected;

the transmission mechanism 6 is arranged on the frame body 1 and is used for conveying the PCB to be detected to the two areas to be detected;

the transmission mechanism 7 is arranged on the frame body 1 and acts on the two driving frames 3, one driving frame 3 moves to the detection area through the transmission mechanism 7, and the other driving frame 3 moves in a direction away from the detection area;

a driving mechanism 9 mounted on the driving frame 3 for driving the pushing plate 8 to move; that is, the pushing plate 8 can be made to push the PCB to be inspected on the conveying mechanism 6 to the inspection area by the driving mechanism 9;

the blanking mechanism 10 is arranged on the frame body 1 and is used for receiving the PCB sliding from the detection area; specifically, after the PCB in the detection area is detected, the PCB to be detected is pushed to the detection area by the driving mechanism 9, and the detected PCB in the detection area moves to the blanking mechanism 10 due to extrusion of the PCB to be detected;

wherein, a plurality of positioning boxes 2 are placed on the transmission mechanism 6, the PCB board is placed in the positioning boxes 2, when in use, the PCB board is required to be placed in the positioning boxes 2, then the positioning boxes 2 are placed on the transmission mechanism 6, so that the PCB board is more stable when being transported, one pushing plate 8 is positioned in a corresponding detection area, the other pushing plate 8 is positioned in a corresponding detection area, then the two pushing plates 8 are moved by the transmission mechanism 7, the pushing plate 8 in the detection area can push the positioning boxes 2 on the transmission mechanism 6, thereby pushing the positioning boxes 2 to the detection area, and if the PCB board to be detected is positioned in the other detection area, the PCB board to be detected is detected in the process of moving the positioning boxes 2 to the detection area, for the convenience of understanding, as shown in figure 1, the left detection area and the detection area to be detected are called an A detection area and an A detection area, the right detection area and the detection area to be detected are called a B detection area and an B detection area, fig. 1 is in a working state, at this time, the PCB board on the A detection area is in detection, the left pushing board 8 is positioned in the A detection area, at this time, the PCB board on the B detection area is pushed to the PCB board to be detected on the detection area by the pushing board 8, at this time, the right driving frame 3 is enabled to move downwards through the transmission mechanism 7 until the right driving frame is in contact with the PCB board to be detected in the B detection area, at this time, the left driving frame 3 is enabled to move upwards for resetting, at this time, one of the PCB boards (comprising the positioning box 2) in the A detection area is enabled to be pushed to the A detection area through the driving mechanism 9, at this time, feeding of the other detection area can be completed in the detection process, therefore, time is saved, and the two driving frames 3 can be provided with detection templates of different types through the connecting component 4, so that circuit detection can be carried out on the PCB templates of two different types at the same time, and the working efficiency is further improved.

As shown in fig. 1, 4 and 6, in some embodiments, the transmission mechanism 7 includes a transmission rod 701 rotatably mounted on the frame 1, the free ends of the transmission rod 701 are hinged with a linkage rod 702, the free ends of the two linkage rods 702 are respectively hinged on the two driving frames 3, the frame 1 is provided with a power piece 11 for driving the transmission rod 701 to rotate, that is, the transmission rod 701 can be rotated by the power piece 11, when one end of the transmission rod 701 is close to the lower end, the other end of the transmission rod 701 is close to the upper end, so that the corresponding linkage rod 702 moves, when the linkage rod 702 moves, because one end of the transmission rod 702 is hinged on the driving rod 1303, the driving rod 1303 rotates to enable one driving frame 3 to move downwards and the other driving frame 3 moves upwards, so that one of the detection templates is located above the corresponding detection areas, the driving plate 8 can not be influenced to normally push the PCB board to be detected, the two driving frames 3 can be controlled to move upwards and downwards by the power piece 11, and excessive driving force is not required to drive the two driving frames 3 to move respectively.

As shown in fig. 1, 4 and 6, in some embodiments, the power member 11 includes a rotating disc 1101 rotatably mounted on the frame 1, an eccentric column 1102 is configured on the rotating disc 1101, a motor for driving the rotating disc 1101 to rotate is mounted on the frame 1, a rocking rod 1103 is mounted in a middle part of one side of the driving rod 701, a movable groove 1104 is formed on the rocking rod 1103 along a length direction of the rocking rod, the eccentric column 1102 is slidably tangent in the movable groove 1104, that is, the motor continuously rotates, so that the rotating disc 1101 continuously rotates, the rotating disc 1101 indirectly rotates the eccentric column 1102 configured on the rotating disc 1101, because the eccentric column 1102 is slidably tangent in the movable groove 1104, when the eccentric column 1102 rotates, the eccentric column 1102 moves in the movable groove 1104 and rotates along an axis thereof relative to the rocking rod 1103, so that the rocking rod 1103 is forced to reciprocate.

As shown in fig. 1 and 2, in some embodiments, the driving mechanism 9 includes a convex plate 901 configured on one side of the driving frame 3, hinge rods 902 are hinged on the convex plate 901, connecting plates 903 are configured on the top of the pushing plate 8, free ends of the two hinge rods 902 are respectively hinged on the two connecting plates 903, when the driving frame 3 moves upwards away from the corresponding detection area, the hinge rods 902 are driven to move at this time, because one end of the hinge rod 902 is hinged on the connecting plates 903, the corresponding pushing plate 8 is caused to move towards the detection area, so that a PCB board located in the area to be detected is pushed into the detection area, no additional driving force is needed, and thus the PCB board is pushed towards the detection area in the process of moving the driving frame 3 upwards, and the consistency of executing actions is improved.

As shown in fig. 1-3, 7 and 8, in some embodiments, the conveying mechanism 6 includes two first conveyor belt assemblies 601 symmetrically installed on the frame 1, the frame 1 is configured with a separation plate 602, the conveying ends of the two first conveyor belt assemblies 601 are respectively contacted with one side of the separation plate 602, as shown in fig. 1, that is, when the positioning box 2 is placed on the first conveyor belt assemblies 601, the positioning box 2 moves towards the direction of the separation plate 602, so that the plurality of positioning boxes 2 are sequentially attached together, the first conveyor belt assemblies 601 are an existing conveyor belt and a conveyor belt, the conveyor belt is installed between the two conveyor wheels, a motor for driving one of the conveyor wheels to rotate is installed on the frame 1, one side of the pushing plate 8 is configured with a limit baffle 603, that is, when the pushing plate 8 pushes the PCB board to be detected to the detection zone, the limit baffle 603 is contacted with the positioning box 2 on the conveyor belt, the positioning box 2 is prevented from contacting the separation plate 602 because the movement of the conveyor belt affects the movement of the conveyor belt to the separation plate 602, when the pushing plate 8 is not contacted with the detection zone 2, and when the pushing plate 8 is contacted with the separation plate 602 again, the pushing plate 8 is contacted with the detection zone 2, and the detection zone is moved to be contacted with the separation plate 2.

As shown in fig. 1-3, in some embodiments, the blanking mechanism 10 includes a second conveyor belt assembly 1001 installed on the frame 1, a plugging slot 1002 is formed through one side of the length direction of the positioning box 2, a guiding plug board 1003 for plugging the plugging slot 1002 is configured at the detection area of the frame 1, two guiding inclined planes 1004 are symmetrically configured at one side of the guiding plug board 1003, that is, when the pushing board 8 pushes the positioning box 2, the PCB board on the positioning box 2 will also move, the pushing board 8 pushes the PCB board on the positioning box 2 to move, thereby indirectly pushing the PCB board on the positioning box 2 to move, the positioning box 2 pushed by the pushing board 8 to the detection area will form a guiding plug board 1003 to be plugged in the plugging slot 1002, the guiding plug board 1003 can be plugged in the plugging slot 1002 better, the design of the plugging slot 1002 and the guiding plug board 1003 plays a guiding and limiting role, so that the detection template can accurately detect the detection on the PCB board.

As shown in fig. 1, 5 and 7, in some embodiments, the connection assembly 4 includes a rotating rod 401 rotatably mounted on the driving frame 3, a plurality of mounting plates 402 are configured on the outer circumference side of the rotating rod 401, mounting grooves 403 are formed in the bottoms of the mounting plates 402 and are used for mounting detection templates, locking pieces 5 are mounted on the driving frame 3 and are used for limiting the rotation of the driving frame 3, detection templates which often need to be detected in batches can be mounted in the mounting grooves 403, so that when the detection templates need to be replaced, the detection templates do not need to be detached, only the rotating rod 401 needs to be rotated, a plurality of detection templates indirectly rotate, and the rotation angle of the rotating rod 401 is limited through the locking pieces 5 after the rotation is finished, so that the detection templates can be replaced quickly, and the detection templates are more convenient to use.

As shown in fig. 1, fig. 5 and fig. 8, in some embodiments, the locking piece 5 includes a sleeve 501 installed on the driving frame 3, one end of the sleeve 501 is slidably penetrated with a positioning rod 502, a plurality of positioning grooves 505 for inserting the positioning rod 502 are formed in a circular array on the outer periphery side of the rotating rod 401, the number of the positioning grooves 505 is consistent with that of the mounting plates 402 installed on the rotating rod 401, a limiting plate 503 is configured on one side of the positioning rod 502 located in the sleeve 501, an interference spring 504 is installed between the limiting plate 503 and the sleeve 501, when the detection template needs to be replaced, the positioning rod 502 is pulled at this time, so that the positioning rod 502 is separated from the corresponding positioning groove 505, then the rotating rod 401 is rotated, so that the corresponding detection template faces the detection area, then the positioning rod 502 is made to be interfered in the positioning groove 505 by loosening the characteristic of elastic deformation of the interference spring 504, thus the detection template is replaced quickly, the positioning rod 502 can be effectively prevented from being separated from the corresponding positioning groove 505 by the design of the interference spring 504, and the protection function is played.

As shown in fig. 1, 4 and 7, in some embodiments, the free end of the linkage rod 702 is hinged with a connecting frame 12, the driving frame 3 is vertically slidably mounted on the connecting frame 12, an adjusting member 13 for driving the driving frame 3 to move vertically is mounted on the connecting frame 12, and the detecting templates of different signals may have different heights for detecting the needle heads, so that the height of the driving frame 3 can be adjusted by the adjusting member 13 to adapt to different detecting heights, so that the device can be suitable for detecting PCB board circuits by different detecting templates, and the applicability is improved.

As shown in fig. 1, fig. 4 and fig. 7, in some embodiments, the adjusting element 13 includes an adjusting screw 1301 vertically and rotatably mounted on the connecting frame 12, a threaded block 1302 is sleeved on the adjusting screw 1301, a driving rod 1303 is movably connected to the threaded block 1302 and moves along the axial direction of the driving rod 1303, a free end of the driving rod 1303 is hinged on the connecting frame 12, a driving groove 1304 is formed on the driving rod 1303 along the length direction of the driving rod 1303, specifically, one end of the threaded block 1302 is configured with a rod body, a rod 1305 which is in sliding contact with the driving rod 1304 is formed on the driving frame 3, when the adjusting screw 1301 is rotated, the adjusting screw 1301 is limited by the driving rod 1303, so that the adjusting screw 1301 rotates to enable the threaded block 1302 to move in the vertical direction, and indirectly drive the rod 1303 to move along the axial direction of the driving rod, and force the driving rod 1303 to move along the driving rod 1304, and because one end of the driving rod 1303 is hinged on the connecting frame 12, and the driving rod 1303 rotates along the hinging point of the driving rod 1303, and the driving rod 1305 moves along the axial direction of the driving rod 1305, and thus the driving rod 1305 is not easy to move along the driving rod 1301, and the driving rod 1305 moves along the axial direction of the driving rod 1301, and moves along the driving rod 1305 in the vertical direction when the driving rod 1305 is in the vertical direction, and the driving rod 1305 moves along the axial direction, and when the driving rod 1305 moves along the driving rod, and when the driving rod 1305 and when the driving rod is better.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A duplex position detection apparatus, comprising:

the device comprises a frame body (1), wherein the frame body (1) is provided with two areas to be detected and two detection areas, two driving frames (3) are vertically and slidably arranged on the frame body (1), a connecting component (4) is arranged on each driving frame (3) and is used for installing a detection template, two pushing plates (8) are slidably arranged on the frame body (1), and the two pushing plates (8) are respectively positioned in the two areas to be detected;

the transmission mechanism (6) is arranged on the frame body (1) and is used for conveying the PCB to be detected to the two areas to be detected;

the transmission mechanism (7) is arranged on the frame body (1) and acts on the two driving frames (3), one driving frame (3) moves to the detection area through the transmission mechanism (7), and the other driving frame (3) moves in a direction away from the detection area;

a driving mechanism (9) mounted on the driving frame (3) for driving the pushing plate (8) to move;

the blanking mechanism (10) is arranged on the frame body (1) and is used for receiving the PCB sliding off from the detection area;

wherein, a plurality of locating boxes (2) are placed on the transmission mechanism (6), and the PCB board is placed in the locating boxes (2).

2. Double-station detection device according to claim 1, characterized in that the transmission mechanism (7) comprises a transmission rod (701) rotatably mounted on the frame body (1), the free ends of the transmission rod (701) are hinged with a linkage rod (702), the free ends of the two linkage rods (702) are respectively hinged on the two driving frames (3), and the frame body (1) is provided with a power piece (11) for driving the transmission rod (701) to rotate.

3. The double-station detection device according to claim 2, wherein the power piece (11) comprises a rotating disc (1101) rotatably mounted on the frame body (1), an eccentric column (1102) is constructed on the rotating disc (1101), a motor for driving the rotating disc (1101) to rotate is mounted on the frame body (1), a rocking rod (1103) is mounted in the middle of one side of the transmission rod (701), a movable groove (1104) is formed in the rocking rod (1103) along the length direction of the rocking rod, and the eccentric column (1102) is in sliding tangent with the movable groove (1104).

4. Double-station detection device according to claim 1, characterized in that the drive mechanism (9) comprises a lug plate (901) constructed on one side of the drive frame (3), on which lug plate (901) a hinge rod (902) is hinged, on top of the push plate (8) a connecting plate (903) is constructed, the free end of the hinge rod (902) being hinged on the connecting plate (903).

5. Double-station detection device according to claim 1, characterized in that the transmission mechanism (6) comprises two first conveyor belt assemblies (601) symmetrically arranged on the frame body (1), a separation plate (602) is constructed on the frame body (1), the conveying tail ends of the two first conveyor belt assemblies (601) are respectively contacted with one side of the separation plate (602), a limit baffle (603) is constructed on one side of the pushing plate (8), and the length of the pushing plate (8) is consistent with that of the positioning box (2).

6. The double-station detection device according to claim 1, wherein the blanking mechanism (10) comprises a second conveyor belt assembly (1001) mounted on the frame body (1), a plugging groove (1002) is formed in one side of the positioning box (2) in a penetrating manner in the length direction, a guide plug board (1003) for plugging the plugging groove (1002) is formed in the detection area of the frame body (1), and two guide inclined planes (1004) are symmetrically formed on one side of the guide plug board (1003).

7. Double-station detection device according to claim 1, characterized in that the connection assembly (4) comprises a rotating rod (401) rotatably mounted on the driving frame (3), a plurality of mounting plates (402) are arranged on the outer periphery side of the rotating rod (401), mounting grooves (403) are formed in the bottoms of the mounting plates (402) and are used for mounting detection templates, and locking pieces (5) are mounted on the driving frame (3) and are used for limiting the rotation of the driving frame (3).

8. The double-station detection device according to claim 7, wherein the locking piece (5) comprises a sleeve (501) installed on the driving frame (3), one end of the sleeve (501) is penetrated with a positioning rod (502) in a sliding manner, a plurality of positioning grooves (505) for inserting the positioning rod (502) are formed in a circular array on the outer periphery side of the rotating rod (401), the number of the positioning grooves (505) is consistent with that of mounting plates (402) installed on the rotating rod (401), a limiting plate (503) is constructed on one side, located in the sleeve (501), of the positioning rod (502), and an abutting spring (504) is installed between the limiting plate (503) and the sleeve (501).

9. Double-station detection device according to claim 2, characterized in that the free end of the linkage rod (702) is hinged with a connecting frame (12), the driving frame (3) is vertically and slidably arranged on the connecting frame (12), and an adjusting piece (13) for driving the driving frame (3) to vertically move is arranged on the connecting frame (12).

10. The double-station detection device according to claim 9, wherein the adjusting element (13) comprises an adjusting screw (1301) which is vertically and rotatably installed on the connecting frame (12), a threaded block (1302) is sleeved on the adjusting screw (1301) in a threaded mode, a driving rod (1303) is movably connected to the threaded block (1302), the free end of the driving rod (1303) is hinged to the connecting frame (12), a driving groove (1304) is formed in the driving rod (1303) along the length direction of the driving rod, and a post rod (1305) which is in sliding tangency with the driving groove (1305) is formed in the driving frame (3).