CN112518614A - Clamping mechanism for detecting cylindrical pulse capacitor and manufacturing process thereof - Google Patents

Abstract

The invention relates to the technical field of clamping equipment and discloses a clamping mechanism for detecting a cylindrical pulse capacitor; the clamping mechanism for detecting the cylindrical pulse capacitor comprises a fixing mechanism, a positioning and transporting mechanism, a damping mechanism, a mounting plate and a bottom plate, wherein the damping mechanism is positioned at the top of the bottom plate, the mounting plate is positioned at the top of the damping mechanism, the fixing mechanism and the positioning and transporting mechanism are both positioned at the top of the mounting plate, and the fixing mechanism is positioned at the front side of the positioning and transporting mechanism; the fixing mechanism comprises a fixing column, the top of the fixing column is fixedly connected with an installation box, and the inner cavity of the installation box is fixedly connected with a first motor.

Description

Clamping mechanism for detecting cylindrical pulse capacitor and manufacturing process thereof

Technical Field

The invention belongs to the technical field of clamping equipment, and particularly relates to a clamping mechanism for detecting a cylindrical pulse capacitor and a manufacturing process thereof.

Background

Two conductors in close proximity to each other with a non-conductive dielectric therebetween form a capacitor, which stores charge when a voltage is applied between the two plates of the capacitor. The capacitance of a capacitor, whose basic unit is farad (F), is numerically equal to the ratio of the amount of charge on one conductive plate to the voltage between the two plates, and is generally denoted by the letter C in the circuit diagram.

Pulse capacitor is before the incoming telegram leaves the factory, all need test its performance, when carrying out performance test to the cylinder type pulse capacitor that all has the electrical apparatus pin at both ends, because the particularity of its shape, need carry out the centre gripping to the electrical apparatus pin at both ends and fix, when current fixture pressed from both sides tightly this kind of cylinder type pulse capacitor, one: the pins of the electrical appliances at the two ends are unstable when clamped, so that the pins are disconnected during detection, and the detection result is inaccurate; II, secondly: when the cylindrical pulse capacitors with different sizes face, the clamping mechanism needs to be replaced for clamping, so that the workload is increased, and the working efficiency is reduced; thirdly, the method comprises the following steps: when the cylindrical pulse capacitor is clamped, auxiliary clamping needs to be performed manually, so that the manual workload is increased, and potential safety hazards are increased; therefore, improvements are now needed in view of the current situation.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides a clamping mechanism for detecting a cylindrical pulse capacitor and a manufacturing process thereof, which effectively solve the problems that the performance of the pulse capacitor needs to be tested before the pulse capacitor enters a field and leaves a factory, when the performance of the cylindrical pulse capacitor with electric appliance pins at two ends is tested, the electric appliance pins at two ends need to be clamped and fixed due to the particularity of the shape, and when the conventional clamping mechanism clamps the cylindrical pulse capacitor, the clamping mechanism comprises the following steps: the pins of the electrical appliances at the two ends are unstable when clamped, so that the pins are disconnected during detection, and the detection result is inaccurate; II, secondly: when the cylindrical pulse capacitors with different sizes face, the clamping mechanism needs to be replaced for clamping, so that the workload is increased, and the working efficiency is reduced; thirdly, the method comprises the following steps: when clamping cylindrical pulse capacitors, the manual work is needed to assist in clamping, so that the manual work load is increased, and the potential safety hazard is increased.

In order to achieve the purpose, the invention provides the following technical scheme: a clamping mechanism for detecting a cylindrical pulse capacitor comprises a fixing mechanism, a positioning and transporting mechanism, a damping mechanism, a mounting plate and a bottom plate, wherein the damping mechanism is positioned at the top of the bottom plate, the mounting plate is positioned at the top of the damping mechanism, the fixing mechanism and the positioning and transporting mechanism are both positioned at the top of the mounting plate, and the fixing mechanism is positioned at the front side of the positioning and transporting mechanism;

the fixing mechanism comprises a fixed column, an installation box is fixedly connected to the top of the fixed column, a first motor is fixedly connected to the inner cavity of the installation box, a bidirectional screw is rotatably connected to the inner cavity of the fixed column, the output end of the first motor is fixedly connected with the bidirectional screw, moving blocks which are symmetrically arranged up and down are in threaded connection with the outer wall of the bidirectional screw, clamping blocks are fixedly connected to the right sides of the two moving blocks, matching clamping grooves are formed in the viewing sides of the two clamping blocks, telescopic springs are fixedly connected to the viewing sides of the two matching clamping grooves, telescopic blocks are fixedly connected to the viewing sides of the two telescopic springs, and the two telescopic blocks are slidably connected to the inner cavities of the two;

the positioning and conveying mechanism comprises a mounting cross rod, the inner cavity of the mounting cross rod is rotatably connected with a screw rod, the top of the screw is provided with a limiting rod which is fixedly connected with the inner cavity of the mounting cross rod, the right side of the screw is fixedly connected with a second motor, and the outer wall of the screw rod is connected with a movable sliding block in a threaded manner, the top of the movable sliding block is fixedly connected with a telescopic sliding rod, the upper end and the lower end of the surface of the telescopic slide rod are fixedly connected with matching slide blocks, the right side of the top of the installation cross rod is fixedly connected with a support rod, the top of the supporting rod is fixedly connected with a top plate, the left side of the bottom of the top plate is fixedly connected with a sliding rod, the sliding rod is arc-shaped, the right end of the sliding rod is fixedly connected with the supporting rod, the two matched sliding blocks are respectively connected with the inner cavities of the sliding grooves formed in the limiting rod and the sliding rod in a sliding mode, and the front side of the matched sliding block at the upper end is fixedly connected with a clamping mechanism.

Preferably, clamping mechanism includes the fixed block, the installation cavity has been seted up to the fixed block inner chamber, the installation cavity inner chamber rotates through the damping pivot and is connected with the gear, the side all meshes "L" shape telescopic link around the gear, and two "L" shape telescopic links are located respectively the fixed block the side just with fixed block sliding connection about, the connecting block that fixed block front side fixedly connected with symmetry set up, two equal sliding connection of connecting block inner chamber have flexible post, and spacing spring has all been cup jointed to two flexible post outer ends, and just two flexible post back of the body ends all rotate and are connected with the connecting rod, and two connecting rods rotate with two "L" shape telescopic links respectively and connect, damping pivot bottom fixedly connected with knob, the knob is located the fixed block bottom.

Preferably, the equal fixedly connected with stopper in fixed block left and right sides, two connecting rods rotate with two stoppers respectively and are connected, fixed block front side fixedly connected with limiting plate, open the limiting plate front side and be equipped with "V" shape groove, two flexible posts looks the side and are the slant setting, stopper and two flexible posts are insulating bakelite material.

Preferably, damper includes four damping spring posts, damping spring post fixed connection respectively is in the bottom four corners department of mounting panel rotates between two damping spring posts about and is connected with the articulated connecting rod that sets up, fixedly connected with connecting spring between the connecting rod.

Preferably, the bottom plate bottom four corners department all fixedly connected with removes the gyro wheel, it all is provided with the brake to remove gyro wheel department, bottom plate top right side fixedly connected with push rod.

Preferably, the manufacturing process of the clamping mechanism for detecting the cylindrical pulse capacitor comprises the following steps:

s1, opening a hole and slotting: the end faces of the two clamping blocks after finish turning are perforated, the positions of the two perforations are required to be completely corresponding, the tolerance is +/-5 mm, the end face of the limiting plate after finish turning is grooved, the end faces of the two telescopic columns are obliquely turned, the inclination of the inclined planes of the two telescopic columns is required to be consistent with that of the groove of the end face of the limiting plate, and the tolerance is +/-2 degrees;

s2, mounting of a telescopic block: in step S1, welding a telescopic spring in the inner cavity of the hole formed by the two clamping blocks, welding a telescopic block at the end of the telescopic spring, testing the telescopic elasticity of the telescopic block, and installing a clamping mechanism after the elasticity is qualified;

s3, installing a clamping mechanism: respectively welding the two clamping blocks on the moving block to enable the two holes to be opposite, respectively installing the limiting plate and the two telescopic columns on the clamping mechanism to enable the inclined surfaces of the two telescopic columns and the end surface grooves of the limiting plate to form a rhombus, and welding the whole clamping mechanism on the surface of the matched sliding block at the positioning and conveying mechanism;

s4, positioning of a clamping mechanism: fixing the fixing mechanism on the top of the mounting plate, adjusting the position of the positioning and transporting mechanism, so that the inclined planes of the two telescopic columns and the diamond center point formed by the end face grooves of the limiting plate correspond to the opening center points on the two clamping blocks when the clamping mechanism moves to the leftmost end at the slide bar, and the tolerance is plus 5-8mm, thereby completing the manufacture of the whole clamping mechanism.

Compared with the prior art, the invention has the beneficial effects that: 1. according to the invention, the first motor is started to drive the bidirectional screw rod to rotate, so that the two moving blocks are driven to move relatively until the electric appliance pins at two ends of the cylindrical pulse capacitor enter the matching clamping groove and abut against the telescopic block, the telescopic springs at the telescopic block provide an opposite force to abut against the electric appliance pins, the first motor stops rotating, the electric appliance pins at two ends of the cylindrical pulse capacitor are abutted against by the telescopic block to complete clamping, the two electric appliance pins are abutted against the inside of the matching clamping groove, and the condition that the clamping is unstable to cause disconnection during detection and the detection result is inaccurate can be avoided;

2. according to the invention, the middle part of the cylindrical pulse capacitor to be detected is placed on the surface of the limiting plate, the knob is rotated to drive the gear to rotate, so that the two L-shaped telescopic rods are driven to expand outwards, and the two telescopic columns are driven to extrude inwards while the two L-shaped telescopic rods expand outwards, so that the cylindrical pulse capacitor is clamped, the cylindrical pulse capacitors with different sizes can be clamped, the workload is reduced, and the working efficiency is improved;

3. according to the invention, when clamping is carried out, only the cylindrical pulse capacitor at the clamping mechanism needs to be placed and clamped manually, and auxiliary clamping at the clamping mechanism is not needed manually, so that potential safety hazards are effectively reduced.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings:

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic cross-sectional view of the fastening mechanism of the present invention;

FIG. 3 is a schematic cross-sectional view of the positioning and transporting mechanism of the present invention;

FIG. 4 is a schematic cross-sectional view of the clamping mechanism of the present invention;

FIG. 5 is a schematic cross-sectional view of a clamping block of the present invention;

in the figure: 100. a fixing mechanism; 200. positioning a transport mechanism; 300. a damping mechanism; 400. mounting a plate; 500. a base plate; 600. moving the roller; 700. a clamping mechanism; 101. fixing a column; 102. installing a box; 103. a first motor; 104. a moving block; 105. a clamping block; 106. a bidirectional screw; 107. matching with the clamping groove; 108. a telescopic block; 109. a tension spring; 201. installing a cross bar; 202. a second motor; 203. a screw; 204. a limiting rod; 205. a slide bar; 206. a support bar; 207. a top plate; 208. a telescopic slide bar; 209. moving the slide block; 210. matching with the sliding block; 301. a shock absorbing spring post; 302. a connecting rod; 303. a connecting spring; 501. a push rod; 701. a fixed block; 702. a mounting cavity; 703. an L-shaped telescopic rod; 704. a connecting rod; 705. a limiting block; 706. a gear; 707. a limiting plate; 708. connecting blocks; 709. a telescopic column; 710. a limiting spring; 711. a knob.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a clamping mechanism for detecting a cylindrical pulse capacitor includes a fixing mechanism 100, a positioning and transporting mechanism 200, a damping mechanism 300, a mounting plate 400 and a bottom plate 500.

Referring to fig. 1, the damping mechanism 300 is located on the top of the bottom plate 500, the mounting plate 400 is located on the top of the damping mechanism 300, the fixing mechanism 100 and the positioning and transporting mechanism 200 are located on the top of the mounting plate 400, and the fixing mechanism 100 is located on the front side of the positioning and transporting mechanism 200.

Referring to fig. 1-2, the fixing mechanism 100 includes a fixing column 101, an installation box 102 is fixedly connected to the top of the fixing column 101, a first motor 103 is fixedly connected to an inner cavity of the installation box 102, a bidirectional screw 106 is rotatably connected to an inner cavity of the fixing column 101, an output end of the first motor 103 is fixedly connected to the bidirectional screw 106, moving blocks 104 which are symmetrically arranged up and down are in threaded connection with outer walls of the bidirectional screw 106, clamping blocks 105 are fixedly connected to right sides of the two moving blocks 104, matching clamping grooves 107 are formed in viewing sides of the two clamping blocks 105, telescopic springs 109 are fixedly connected to viewing sides of the two matching clamping grooves 107, telescopic blocks 108 are fixedly connected to viewing sides of the two telescopic springs 109, and the two telescopic blocks 108 are slidably connected to inner cavities of;

the first motor 103 is started to drive the bidirectional screw 106 to rotate, so that the two moving blocks 104 are driven to move relatively until the pins of the electric appliances at the two ends of the cylindrical pulse capacitor enter the matching clamping groove 107 and abut against the telescopic block 108, the telescopic spring 109 at the telescopic block 108 provides an opposite force to abut against the pins of the electric appliances, the first motor 103 stops rotating, the pins of the electric appliances at the two ends of the cylindrical pulse capacitor are abutted against the telescopic block 108, and clamping is completed.

Referring to fig. 1-4, the positioning and transporting mechanism 200 includes a mounting cross bar 201, a screw 203 rotatably connected to an inner cavity of the mounting cross bar 201, a limiting rod 204 disposed on a top of the screw 203, the limiting rod 204 fixedly connected to the inner cavity of the mounting cross bar 201, a second motor 202 fixedly connected to a right side of the screw 203, and the outer wall of the screw 203 is connected with a movable sliding block 209 by screw thread, the top of the movable sliding block 209 is fixedly connected with a telescopic sliding rod 208, the upper and lower ends of the surface of the telescopic sliding rod 208 are fixedly connected with a matching sliding block 210, the right side of the top of the installation cross bar 201 is fixedly connected with a supporting rod 206, the top of the supporting rod 206 is fixedly connected with a top plate 207, the left side of the bottom of the top plate 207 is fixedly connected with a sliding, the right end of the sliding rod 205 is fixedly connected with the supporting rod 206, the two matching sliding blocks 210 are respectively connected with the inner cavities of the sliding chutes formed at the limiting rod 204 and the sliding rod 205 in a sliding manner, and the front sides of the matching sliding blocks 210 at the upper ends are fixedly connected with a clamping mechanism 700; the clamping mechanism 700 comprises a fixed block 701, an inner cavity of the fixed block 701 is provided with an installation cavity 702, the inner cavity of the installation cavity 702 is rotatably connected with a gear 706 through a damping rotating shaft, the front side and the rear side of the gear 706 are respectively engaged with an L-shaped telescopic rod 703, the two L-shaped telescopic rods 703 are respectively positioned at the left side and the right side of the fixed block 701 and are slidably connected with the fixed block 701, the front side of the fixed block 701 is fixedly connected with symmetrically arranged connecting blocks 708, the inner cavities of the two connecting blocks 708 are respectively slidably connected with telescopic columns 709, the outer ends of the two telescopic columns 709 are respectively sleeved with a limiting spring 710, the opposite back ends of the two telescopic columns 709 are respectively rotatably connected with connecting rods 704, the two connecting rods 704 are respectively rotatably connected with the two L-shaped; the left side and the right side of the fixed block 701 are fixedly connected with limit blocks 705, the two connecting rods 704 are respectively and rotatably connected with the two limit blocks 705, the front side of the fixed block 701 is fixedly connected with a limit plate 707, a V-shaped groove is formed in the front side of the limit plate 707, the visual sides of the two telescopic columns 709 are obliquely arranged, and the limit blocks 705 and the two telescopic columns 709 are made of insulating bakelite materials;

the middle part of a cylindrical pulse capacitor to be detected is placed on the surface of the limiting plate 707, the knob 711 is rotated to drive the gear 706 to rotate, thereby driving the two L-shaped telescopic rods 703 to expand outwards, and while the two L-shaped telescopic rods 703 expand outwards, the two telescopic columns 709 are driven to extrude inwards, thereby clamping the cylindrical pulse capacitor, starting the second motor 202, driving the screw rod 203 to rotate, thereby driving the moving slider 209 to move leftwards, thereby, the telescopic sliding rod 208 connected with the moving slider 209 also moves leftwards, and while moving, along with the upward extension of the sliding rod 205, until moving to the fixing mechanism 100.

Referring to fig. 1, the damping mechanism 300 includes four damping spring posts 301, the damping spring posts 301 are respectively and fixedly connected to four corners of the bottom of the mounting plate 400, the left and right damping spring posts 301 are rotatably connected to each other by a connecting rod 302, and the connecting rod 302 is fixedly connected to a connecting spring 303;

four shock-absorbing spring posts 301 receive the vibrational force that mounting panel 400 top produced to compress, thereby drive connecting rod 302 contained angle and reduce, make connecting spring 303 compress, because connecting spring 303 and shock-absorbing spring post 301's resilience force offsets the vibrational force, carry out effective shock attenuation.

Referring to fig. 1, four corners of the bottom plate 500 are fixedly connected with movable rollers 600, the movable rollers 600 are provided with brakes, and the right side of the top of the bottom plate 500 is fixedly connected with a push rod 501;

the design of the movable roller 600 can facilitate the movement of the whole clamping mechanism, and reduce the labor force.

A manufacturing process of a clamping mechanism for detecting a cylindrical pulse capacitor comprises the following steps:

s1, opening a hole and slotting: the end faces of the two clamping blocks 105 after finish turning are holed, the positions of the two holes are required to be completely corresponding, the tolerance is +/-5 mm, the end face of the limiting plate 707 after finish turning is grooved, the end faces of the two telescopic columns 709 are obliquely turned, the inclination of the inclined faces of the two telescopic columns 709 is required to be consistent with the inclination of the end face groove of the limiting plate 707, and the tolerance is +/-2 degrees;

s2, mounting of a telescopic block: in step S1, welding the telescopic spring 109 to the inner cavity of the hole formed by the two clamping blocks 105, welding the telescopic block 108 to the end of the telescopic spring 109, testing the telescopic elasticity of the telescopic block 108, and installing the clamping mechanism after the test is qualified;

s3, installing a clamping mechanism: respectively welding the two clamping blocks 105 on the moving block 104 to enable the two opened holes to be opposite, respectively installing the limiting plate 707 and the two telescopic columns 709 on the clamping mechanism 700 to enable the inclined surfaces of the two telescopic columns 709 and the end surface grooves of the limiting plate 707 to form a rhombus, and welding the whole clamping mechanism 700 on the surface of the matching slide block 210 at the positioning and transporting mechanism 200;

s4, positioning of a clamping mechanism: fixing the fixing mechanism 100 on the top of the mounting plate 400, adjusting the position of the positioning and transporting mechanism 200, so that the inclined planes of the two telescopic columns 709 and the end face slot of the limiting plate 707 correspond to the diamond center points of the openings on the two clamping blocks 105 when the clamping mechanism 700 moves to the leftmost end at the sliding rod 205, and the tolerance is plus 5-8mm, thereby completing the manufacture of the whole clamping mechanism.

In this embodiment: the first motor 103 and the second motor 202 both adopt a forward and reverse rotating motor of 6D300GU-C type.

The working principle is as follows: when in use, in the first step, the middle part of a cylindrical pulse capacitor to be detected is placed on the surface of the limiting plate 707, the knob 711 is rotated to drive the gear 706 to rotate, thereby driving the two L-shaped telescopic rods 703 to expand outwards, and the two L-shaped telescopic rods 703 drive the two telescopic columns 709 to extrude inwards while expanding outwards, thereby clamping the cylindrical pulse capacitor, in the second step, the second motor 202 is started to drive the screw rod 203 to rotate, thereby driving the moving slider 209 to move leftwards, thereby the telescopic slide rod 208 connected with the moving slider 209 also moves leftwards, and moves simultaneously, the slide rod 205 extends upwards until moving to the fixing mechanism 100, in the third step, the first motor 103 is started to drive the bidirectional screw rod 106 to rotate, thereby driving the two moving blocks 104 to move relatively until the electric appliance pins at the two ends of the cylindrical pulse capacitor enter the matching clamping groove 107, and the telescopic spring 109 at the telescopic block 108 provides an opposite force to tightly support the pins of the electrical appliance, the first motor 103 stops rotating, the pins of the electrical appliance at two ends of the cylindrical pulse capacitor are tightly supported by the telescopic block 108 to complete clamping, and at the moment, detection is performed.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a cylinder type pulse capacitor detects uses fixture, includes fixed establishment (100), location conveying mechanism (200), damper (300), mounting panel (400) and bottom plate (500), its characterized in that: the shock absorption mechanism (300) is positioned on the top of the bottom plate (500), the mounting plate (400) is positioned on the top of the shock absorption mechanism (300), the fixing mechanism (100) and the positioning and transporting mechanism (200) are positioned on the top of the mounting plate (400), and the fixing mechanism (100) is positioned on the front side of the positioning and transporting mechanism (200);

the fixing mechanism (100) comprises a fixing column (101), the top of the fixing column (101) is fixedly connected with an installation box (102), a first motor (103) is fixedly connected with the inner cavity of the installation box (102), a bidirectional screw (106) is rotatably connected with the inner cavity of the fixed column (101), the output end of the first motor (103) is fixedly connected with the bidirectional screw (106), the bidirectional screw (106) is in threaded connection with moving blocks (104) which are symmetrically arranged up and down, clamping blocks (105) are fixedly connected to the right sides of the two moving blocks (104), matching clamping grooves (107) are formed in the viewing sides of the two clamping blocks (105), telescopic springs (109) are fixedly connected to the viewing sides of the two matching clamping grooves (107), telescopic blocks (108) are fixedly connected to the viewing sides of the two telescopic springs (109), and the two telescopic blocks (108) are slidably connected to inner cavities of the two matching clamping grooves (107);

the positioning and transporting mechanism (200) comprises an installation cross rod (201), a screw rod (203) is rotatably connected to the inner cavity of the installation cross rod (201), a limiting rod (204) is arranged at the top of the screw rod (203), the limiting rod (204) is fixedly connected to the inner cavity of the installation cross rod (201), a second motor (202) is fixedly connected to the right side of the screw rod (203), a movable sliding block (209) is connected to the outer wall of the screw rod (203) in a threaded manner, a telescopic sliding rod (208) is fixedly connected to the top of the movable sliding block (209), matching sliding blocks (210) are fixedly connected to the upper end and the lower end of the surface of the telescopic sliding rod (208), a supporting rod (206) is fixedly connected to the right side of the top of the installation cross rod (201), a top plate (207) is fixedly connected to the top of the supporting rod (206, the right end of the sliding rod (205) is fixedly connected with the supporting rod (206), the two matching sliding blocks (210) are respectively connected with the inner cavities of the sliding grooves formed in the limiting rod (204) and the sliding rod (205) in a sliding mode, and the front side of the matching sliding block (210) at the upper end is fixedly connected with a clamping mechanism (700).

2. The clamping mechanism for detecting the cylindrical pulse capacitor as claimed in claim 1, wherein: the clamping mechanism (700) comprises a fixed block (701), an installation cavity (702) is formed in the inner cavity of the fixed block (701), a gear (706) is rotatably connected to the inner cavity of the installation cavity (702) through a damping rotating shaft, L-shaped telescopic rods (703) are respectively meshed with the front side and the rear side of the gear (706), the two L-shaped telescopic rods (703) are respectively positioned on the left side and the right side of the fixed block (701) and are in sliding connection with the fixed block (701), symmetrically-arranged connecting blocks (708) are fixedly connected to the front side of the fixed block (701), telescopic columns (709) are respectively in sliding connection with the inner cavities of the two connecting blocks (708), limiting springs (710) are respectively sleeved at the outer ends of the two telescopic columns (709), connecting rods (704) are respectively and rotatably connected with the opposite back ends of the two telescopic columns (709), and the two connecting rods (704) are, the bottom of the damping rotating shaft is fixedly connected with a knob (711), and the knob (711) is located at the bottom of the fixing block (701).

3. The clamping mechanism for detecting the cylindrical pulse capacitor as claimed in any one of claims 1-2, wherein: the equal fixedly connected with stopper (705) in fixed block (701) left and right sides, two connecting rods (704) rotate with two stopper (705) respectively and are connected, fixed block (701) front side fixedly connected with limiting plate (707), limiting plate (707) front side is opened and is equipped with "V" shape groove, and two flexible post (709) looks the side and is the slant setting, stopper (705) and two flexible post (709) are insulating bakelite material.

4. The clamping mechanism for detecting the cylindrical pulse capacitor as claimed in claim 1, wherein: damper (300) include four shock attenuation spring post (301), shock attenuation spring post (301) fixed connection respectively are in the bottom four corners department of mounting panel (400) controls and rotates between two shock attenuation spring post (301) to be connected with articulated connecting rod (302) that set up, fixedly connected with connecting spring (303) between connecting rod (302).

5. The clamping mechanism for detecting the cylindrical pulse capacitor as claimed in claim 1, wherein: the equal fixedly connected with of bottom plate (500) bottom four corners department removes gyro wheel (600), remove gyro wheel (600) department and all be provided with the brake, bottom plate (500) top right side fixedly connected with push rod (501).

6. The manufacturing process of the clamping mechanism for detecting the cylindrical pulse capacitor as claimed in claim 1, is characterized in that: the method comprises the following steps:

s1, opening a hole and slotting: the end faces of the two clamping blocks (105) after finish turning are holed, the positions of the two holes are required to be completely corresponding, the tolerance is +/-5 mm, the end face of the limiting plate (707) after finish turning is grooved, the end faces of the two telescopic columns (709) are obliquely turned, the slope of the two telescopic columns (709) is required to be consistent with the slope of the groove of the end face of the limiting plate (707), and the tolerance is +/-2 degrees;

s2, mounting of a telescopic block: in step S1, welding an expansion spring (109) in the hole cavity formed by the two clamping blocks (105), welding an expansion block (108) at the end part of the expansion spring (109), testing the expansion elasticity of the expansion block (108), and installing a clamping mechanism after the expansion elasticity is qualified;

s3, installing a clamping mechanism: respectively welding two clamping blocks (105) on a moving block (104) to enable the two holes to be opposite, respectively installing a limiting plate (707) and two telescopic columns (709) on a clamping mechanism (700) to enable inclined surfaces of the two telescopic columns (709) and end surfaces of the limiting plate (707) to form a diamond shape, and welding the whole clamping mechanism (700) on the surface of a matching sliding block (210) at a positioning and transporting mechanism (200);

s4, positioning of a clamping mechanism: fixing the fixing mechanism (100) on the top of the mounting plate (400), adjusting the position of the positioning and transporting mechanism (200), so that the inclined surfaces of the two telescopic columns (709) and the diamond center point formed by the end surface grooves of the limiting plate (707) correspond to the opening center points on the two clamping blocks (105) when the clamping mechanism (700) moves to the leftmost end at the sliding rod (205), and the tolerance is +/-5-8 mm, thereby completing the manufacture of the whole clamping mechanism.

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