CN111504630A - Compression permanent deformation test device for automobile glass guide groove - Google Patents

Abstract

The invention discloses an automobile glass guide groove compression permanent deformation test device, which belongs to the technical field of automobile part detection and comprises an installation frame, an experiment fixing component, a lifting component and a mobile experiment component, wherein the experiment fixing component is arranged on the installation frame, the lifting component is arranged at one end of the installation frame, the mobile experiment component comprises a support frame, a compression experiment piece, a mobile experiment piece and two side edge experiment pieces, the compression experiment piece is vertically arranged at the top of the support frame, the mobile experiment piece is arranged at the top of the support frame, and the two side edge experiment pieces are symmetrically arranged on the installation frame. According to the invention, the fixed gear is driven to rotate by the work of the fixed motor, the two fixed toothed plates are driven to move on the side wall of the fixed groove by the rotation of the fixed gear, the two fixed toothed plates move to drive the two movable fixed plates to move relatively, the position of the experiment fixed plate on the mounting plate is fixed, and the position of the experiment fixed plate is prevented from being shifted in the processing process, so that the subsequent experiment is influenced.

Description

Compression permanent deformation test device for automobile glass guide groove

Technical Field

The invention relates to the technical field of automobile part detection, in particular to an automobile glass guide groove compression permanent deformation test device.

Background

The glass guide groove guide rail of the automobile door is arranged between the inner door plate and the outer door plate and is fixed on the inner door plate. The glass guide groove guide rail is a mechanism for guiding and protecting the door glass, which is formed by the glass guide groove guide rail and a door frame, is an important component of an automobile window lifting system, and plays an important role in guiding, supporting and limiting the stable lifting of a window. The glass guide groove plays a role in guiding glass to stably and smoothly slide in the vehicle door sheet metal guide rail. The automobile door structure is divided into: the automobile door comprises four types of upper section type automobile doors, composite type automobile doors, integral type automobile doors and frameless automobile doors. The glass guide grooves are also divided into four types according to different vehicle door structures; the corresponding glass run channel section of upper segment formula door is less, often can appear going up and down abnormal sound and switch door vibration sound, adopts the clamping force that increases the glass run channel lip limit to solve above-mentioned problem usually, but the increase of clamping force can lead to going up and down shake, go up and down the difficult, low temperature rise side effect such as not going.

However, the prior device has the following problems in use: first, when testing the glass guide slot, can not fix being used for the laboratory plate, lead to the skew to take place in the position of the in-process laboratory plate of processing to influence subsequent experiment, the second can not carry out comprehensive experiment to the glass guide slot, leads to not all of experiment.

Disclosure of Invention

The invention aims to solve the technical problem that the position of an experimental plate is deviated in the processing process and the comprehensive experiment on a glass guide groove cannot be carried out due to the fact that the experimental plate cannot be fixed in the prior art.

In order to solve the technical problems, the invention provides the following technical scheme: a compression permanent deformation test device for an automobile glass guide groove comprises a mounting rack, an experiment fixing component, a lifting component and a movable experiment component, the mounting rack is vertically arranged, the experiment fixing component is arranged on the mounting rack and is in sliding fit with the mounting rack, the experiment fixing component is provided with an experiment fixing plate which is horizontally arranged, the lifting component is arranged at one end of the mounting rack, the output end of the lifting assembly is in sliding fit with the mounting rack, the mobile experiment assembly comprises a support frame, a compression experiment piece, a mobile experiment piece and two side edge experiment pieces, the support frame is vertically arranged at the side of the mounting frame, the compression experimental piece is vertically arranged at the top of the support frame, the movable experimental part is arranged at the top of the supporting frame, the side experimental parts are symmetrically arranged on the mounting frame, and the side experimental parts are in sliding fit with the experiment fixing plate.

Further, the experiment fixing component comprises a fixed motor, a fixed gear, a mounting plate, two toothed plates and two movable fixing plates, the fixed motor is arranged at the bottom of the mounting frame, the output end of the fixed motor is vertically arranged upwards, the mounting frame is provided with fixing grooves, the fixing gears are arranged at the output ends of the fixed motors and are positioned in the fixing grooves, the two fixing toothed plates are symmetrically arranged in the fixing grooves and are in sliding fit with the side walls of the fixing grooves, the two fixing toothed plates are meshed with the fixing gears, the two movable fixing plates are symmetrically arranged on the two fixing toothed plates and are respectively in sliding fit with the top of the mounting frame, the mounting panel level sets up the top at the mounting bracket, experiment fixed plate level sets up at the top of mounting panel and is located between two removal fixed plates.

Furthermore, the lifting assembly comprises a lifting cylinder and a lifting plate, the lifting cylinder is arranged at the top of the mounting frame, the output end of the lifting cylinder is vertically arranged upwards, the output end of the lifting cylinder is in sliding fit with the mounting frame, and the lifting plate is horizontally arranged at the output end of the lifting cylinder.

Further, the compression experiment piece includes mount, compression board, two elevator motor, two lifter and two elevating gear, the vertical setting of mount is at the top of mounting bracket, two the vertical setting of lifter symmetry all with mount sliding fit at mount top and two lifters, every all be equipped with a plurality of tooth's socket on the lifter, two the elevator motor symmetry sets up the side that is located two lifters at the top of mount and two elevator motor, two elevating gear sets up respectively on two elevator motor's output, two elevating gear meshes with a plurality of tooth's socket on two lifters respectively, the compression board level sets up the bottom at two lifters.

Further, it is including rotating motor, rolling disc, carriage release lever, slide rail, slider and removal experiment board to remove the experiment piece, it sets up the top at the support frame to rotate the motor, the rolling disc sets up on the output that rotates the motor, the slide rail level sets up the top at the support frame, the slider sets up on the slide rail and slider and slide rail sliding fit, remove the experiment board setting on the slider and remove experiment board and slider fixed connection, the both ends of carriage release lever set up respectively on rolling disc and slider, the both ends of carriage release lever rotate with rolling disc and slider respectively and are connected.

Further, every the side experiment piece all includes slip table cylinder, lift cylinder and side experiment board, be equipped with the mounting groove on the support frame, the slip table cylinder sets up in the mounting groove, the lift cylinder sets up on the output of slip table cylinder and the vertical upwards setting of output of lift cylinder, side experiment board level sets up on the output of lift cylinder, side experiment board and experiment fixed plate sliding fit.

Furthermore, rubber pads are wrapped on the peripheral side walls of the experiment fixing plate.

Compared with the prior art, the invention has the beneficial effects that:

firstly, the experiment fixing assembly works to fix the experiment fixing plate during the experiment of the glass guide groove, the situation that the position of the experiment fixing plate is deviated to influence the subsequent experiment during the processing is prevented, after the glass guide groove is placed on the lifting assembly, the lifting assembly works to lift the glass guide groove upwards, the experiment piece moves to move the glass guide groove to the experiment fixing plate, the experiment is carried out on one end of the glass guide groove, the compression experiment piece works to compress the top of the glass guide groove, the experiment pieces on the two side edges work to carry out the experiment work on the side walls of the glass guide groove, the comprehensive experiment work on the glass guide groove is realized, and the accuracy of experiment data is improved.

Secondly, when the experiment fixing plate is fixed, the fixed motor works to drive the fixed gear to rotate, the fixed gear rotates to drive the two fixed toothed plates to move on the side wall of the fixed groove, the two fixed toothed plates move to drive the two movable fixing plates to move relatively, the position of the experiment fixing plate on the mounting plate is fixed, and the situation that the position of the experiment fixing plate is deviated in the processing process so as to influence subsequent experiments is prevented.

Thirdly, the two lifting motors work to drive the two lifting gears to rotate, the two lifting gears rotate to drive the tooth grooves on the two lifting rods to move so as to drive the two lifting rods to move on the fixing frame, the two lifting rods move to drive the compression plate to move, and the compression plate moves to compress the top of the glass guide groove.

Fourthly, the rotating motor works to drive the rotating disc to rotate, the rotating disc rotates to drive the moving rod to rotate, the moving rod rotates to drive the sliding block to move on the sliding rail, the sliding block moves to drive the movable experiment plate to move, the movable experiment plate moves to move the glass guide groove on the lifting plate to the experiment fixing plate, and experiment operation is conducted on the glass guide groove.

Fifthly, the output end of the lifting cylinder moves upwards to drive the side edge experiment plate to move to the position corresponding to the experiment fixed plate, the output end of the sliding table cylinder moves to drive the lifting cylinder to move so as to drive the side edge experiment plate to move to the position of the experiment fixed plate, the glass guide groove on the lifting plate moves to the position of the experiment fixed plate, and the side edge of the glass guide groove is subjected to experiment.

Drawings

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

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

FIG. 2 is a side view of the present invention;

FIG. 3 is a schematic perspective view of the experimental fixture assembly of the present invention;

FIG. 4 is a schematic perspective view of a mobile test piece according to the present invention;

FIG. 5 is a schematic perspective view of a compression test piece according to the present invention;

FIG. 6 is a partial perspective view of the present invention;

the reference numbers in the figures are:

mounting bracket 1, fixed slot 11, mounting groove 12, fixed subassembly 2 is fixed in the experiment, fixed motor 21, fixed gear 22, mounting panel 23, pinion rack 24, remove fixed plate 25, lifting subassembly 3, lifting cylinder 31, lifting board 32, remove experiment subassembly 4, support frame 41, compression experiment piece 42, mount 421, compression plate 422, elevator motor 423, lifter 424, lifting gear 425, tooth's socket 426, remove experiment piece 43, rotation motor 431, rolling disc 432, carriage release lever 433, slide rail 434, slider 435, remove experiment board 436, side experiment piece 44, slip table cylinder 441, lift cylinder 442, side experiment board 443, experiment fixed plate 5.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, are merely for convenience of description of the present invention, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

Referring to fig. 1 to 6, the invention provides an automobile glass run compression permanent deformation test device, which comprises a mounting frame 1, an experiment fixing component 2, a lifting component 3 and a mobile experiment component 4, wherein the mounting frame 1 is vertically arranged, the experiment fixing component 2 is arranged on the mounting frame 1, the experiment fixing component 2 is in sliding fit with the mounting frame 1, an experiment fixing plate 5 which is horizontally arranged is arranged on the experiment fixing component 2, the lifting component 3 is arranged at one end of the mounting frame 1, the output end of the lifting component 3 is in sliding fit with the mounting frame 1, the mobile experiment component 4 comprises a support frame 41, a compression experiment piece 42, a mobile experiment piece 43 and two side experiment pieces 44, the support frame 41 is vertically arranged at the side of the mounting frame 1, the compression experiment piece 42 is vertically arranged at the top of the support frame 41, the mobile experiment piece 43 is arranged at the top of the support frame 41, the two side experimental pieces 44 are symmetrically arranged on the mounting frame 1, and both the two side experimental pieces 44 are in sliding fit with the experimental fixing plate 5; when testing the glass guide slot, the required experiment fixed plate 5 of experiment is fixed in the work of experiment fixed subassembly 2, prevent in processing, thereby the skew takes place in the position of experiment fixed plate 5 and influences going on of subsequent experiment, put the glass guide slot on lifting subassembly 3 after, lifting subassembly 3 work upwards lifts the glass guide slot, remove experiment piece 43 work and remove the glass guide slot to experiment fixed plate 5, test the one end of glass guide slot, the top of glass guide slot is compressed in the work of compression experiment piece 42, the work of two side experiments piece 44 is tested the work and is carried out the experiment work to the lateral wall of glass guide slot.

The experimental fixing assembly 2 comprises a fixed motor 21, a fixed gear 22, a mounting plate 23, two toothed plates 24 and two movable fixing plates 25, the fixed motor 21 is arranged at the bottom of the mounting rack 1, the output end of the fixed motor 21 is vertically arranged upwards, the mounting rack 1 is provided with fixing grooves 11, the fixing gear 22 is arranged at the output end of the fixing motor 21 and the fixing gear 22 is positioned in the fixing groove 11, two fixing tooth plates 24 are symmetrically arranged in the fixing groove 11 and two fixing tooth plates 24 are both in sliding fit with the side wall of the fixing groove 11, two fixing tooth plates 24 are both meshed with the fixing gear 22, two moving fixing plates 25 are symmetrically arranged on the two fixing tooth plates 24 and two moving fixing plates 25 are respectively in sliding fit with the top of the mounting rack 1, the mounting plate 23 is horizontally arranged at the top of the mounting frame 1, and the experiment fixing plate 5 is horizontally arranged at the top of the mounting plate 23 and is positioned between the two movable fixing plates 25; when fixing experiment fixed plate 5, fixed motor 21 work drives fixed gear 22 and rotates, and fixed gear 22 rotates and drives two fixed tooth plates 24 and remove on fixed slot 11 lateral wall, and two fixed tooth plates 24 remove and drive two removal fixed plates 25 relative movement, fix the position of experiment fixed plate 5 on mounting panel 23, prevent to test the position of fixed plate 5 and take place the skew at the in-process of processing to influence subsequent experiment.

The lifting assembly 3 comprises a lifting cylinder 31 and a lifting plate 32, the lifting cylinder 31 is arranged at the top of the mounting frame 1, the output end of the lifting cylinder 31 is vertically arranged upwards, the output end of the lifting cylinder 31 is in sliding fit with the mounting frame 1, and the lifting plate 32 is horizontally arranged at the output end of the lifting cylinder 31; after the glass guide groove is placed on the lifting plate 32, the output end of the lifting cylinder 31 moves upwards to drive the lifting plate 32 to move upwards, the lifting plate 32 moves upwards to drive the glass guide groove to move, the glass guide groove is moved to the side of the experiment fixing plate 5, and the experiment on the glass guide groove is facilitated.

The compression experimental part 42 comprises a fixed frame 421, a compression plate 422, two lifting motors 423, two lifting rods 424 and two lifting gears 425, wherein the fixed frame 421 is vertically arranged at the top of the mounting frame 1, the two lifting rods 424 are symmetrically and vertically arranged at the top of the fixed frame 421, the two lifting rods 424 are in sliding fit with the fixed frame 421, each lifting rod 424 is provided with a plurality of tooth sockets 426, the two lifting motors 423 are symmetrically arranged at the top of the fixed frame 421, the two lifting motors 423 are located beside the two lifting rods 424, the two lifting gears 425 are respectively arranged at the output ends of the two lifting motors 423, the two lifting gears 425 are respectively engaged with the tooth sockets 426 on the two lifting rods 424, and the compression plate 422 is horizontally arranged at the bottoms of the two lifting rods 424; two elevating motor 423 work and drive two elevating gear 425 and rotate, thereby two elevating gear 425 rotate and drive a plurality of tooth's socket 426 on two lifter 424 and remove and drive two lifter 424 and move on mount 421, and two lifter 424 remove and drive compression plate 422 and remove, and compression plate 422 removes and carries out the compression operation to the top of glass guide slot.

The movable experiment piece 43 comprises a rotating motor 431, a rotating disc 432, a moving rod 433, a sliding rail 434, a sliding block 435 and a movable experiment board 436, wherein the rotating motor 431 is arranged at the top of the support frame 41, the rotating disc 432 is arranged at the output end of the rotating motor 431, the sliding rail 434 is horizontally arranged at the top of the support frame 41, the sliding block 435 is arranged on the sliding rail 434, the sliding block 435 is in sliding fit with the sliding rail 434, the movable experiment board 436 is arranged on the sliding block 435, the movable experiment board 436 is fixedly connected with the sliding block 435, two ends of the moving rod 433 are respectively arranged on the rotating disc 432 and the sliding block 435, and two ends of the moving rod 433 are respectively in rotating connection with the rotating disc 432 and the sliding block 435; the rotating motor 431 works to drive the rotating disc 432 to rotate, the rotating disc 432 rotates to drive the moving rod 433 to rotate, the moving rod 433 rotates to drive the sliding block 435 to move on the sliding rail 434, the sliding block 435 moves to drive the movable experiment plate 436 to move, the movable experiment plate 436 moves to move the glass guide groove on the lifting plate 32 to the experiment fixing plate 5, and experiment operation is conducted on the glass guide groove.

Each side experiment piece 44 comprises a sliding table cylinder 441, a lifting cylinder 442 and a side experiment plate 443, wherein the supporting frame 41 is provided with a mounting groove 12, the sliding table cylinder 441 is arranged in the mounting groove 12, the lifting cylinder 442 is arranged at the output end of the sliding table cylinder 441, the output end of the lifting cylinder 442 is vertically arranged upwards, the side experiment plate 443 is horizontally arranged at the output end of the lifting cylinder 442, and the side experiment plate 443 is in sliding fit with the experiment fixing plate 5; the output end of the lifting cylinder 442 moves upwards to drive the side experiment plate 443 to move to the position corresponding to the experiment fixing plate 5, the output end of the sliding table cylinder 441 moves to drive the lifting cylinder 442 to move so as to drive the side experiment plate 443 to move to the position of the experiment fixing plate 5, and the glass guide groove on the lifting plate 32 moves to the position of the experiment fixing plate 5 to perform experiments on the side edge of the glass guide groove.

Rubber pads are wrapped on the peripheral side walls of the experiment fixing plate 5; the use of rubber pad is to the in-process of glass guide slot, prevents that long-time experiment from causing the damage to the glass guide slot, influences the complete of experiment.

The working principle of the invention is as follows: when the experiment fixing plate is used, when an experiment fixing plate 5 is fixed, a fixed motor 21 works to drive a fixed gear 22 to rotate, the fixed gear 22 rotates to drive two fixed toothed plates 24 to move on the side wall of a fixing groove 11, the two fixed toothed plates 24 move to drive two movable fixing plates 25 to move relatively, the position of the experiment fixing plate 5 on a mounting plate 23 is fixed, the position of the experiment fixing plate 5 on the processing process is prevented from being deviated, and subsequent experiments are influenced, after a glass guide groove is placed on a lifting plate 32, the output end of a lifting cylinder 31 moves upwards to drive the lifting plate 32 to move upwards, the lifting plate 32 moves upwards to drive the glass guide groove to move, the glass guide groove is moved to the side of the experiment fixing plate 5, the experiment on the glass guide groove is convenient, a rotating motor 431 works to drive a rotating disc 432 to rotate, the rotating disc 432 rotates to drive a moving rod 433 to, the movable rod 433 rotates to drive the sliding block 435 to move on the sliding rail 434, the sliding block 435 moves to drive the movable experiment board 436 to move, the movable experiment board 436 moves to move the glass guide groove on the lifting plate 32 to the experiment fixing plate 5, the experiment operation is performed on the glass guide groove, the output end of the lifting cylinder 442 moves upwards to drive the side experiment plate 443 to move to the position corresponding to the experiment fixing plate 5, the output end of the sliding table cylinder 441 moves to drive the lifting cylinder 442 to move so as to drive the side experiment plate 443 to move to the position of the experiment fixing plate 5, the glass guide groove on the lifting plate 32 moves to the position of the experiment fixing plate 5, the experiment is performed on the side edge of the glass guide groove, the two lifting motors 423 work to drive the two lifting gears 425 to rotate, the two lifting gears 425 rotate to drive the tooth grooves 426 on the two lifting rods 424 to move on the, the two lifting rods 424 move to drive the compression plate 422 to move, and the compression plate 422 moves to compress the top of the glass guide groove.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (7)

1. The automobile glass guide groove compression permanent deformation test device is characterized by comprising a mounting frame (1), an experiment fixing component (2), a lifting component (3) and a mobile experiment component (4), wherein the mounting frame (1) is vertically arranged, the experiment fixing component (2) is arranged on the mounting frame (1), the experiment fixing component (2) is in sliding fit with the mounting frame (1), an experiment fixing plate (5) horizontally arranged is arranged on the experiment fixing component (2), the lifting component (3) is arranged at one end of the mounting frame (1), the output end of the lifting component (3) is in sliding fit with the mounting frame (1), the mobile experiment component (4) comprises a support frame (41), a compression experiment piece (42), a mobile experiment piece (43) and two side experiment pieces (44), the support frame (41) is vertically arranged at the side of the mounting frame (1), the vertical setting of compression experiment piece (42) is at the top of support frame (41), remove experiment piece (43) and set up at the top of support frame (41), two side experiment piece (44) symmetry sets up on mounting bracket (1), two side experiment piece (44) all with experiment fixed plate (5) sliding fit.

2. The automotive glass run compression set test apparatus of claim 1, wherein: the experiment fixing assembly (2) comprises a fixing motor (21), a fixed gear (22), a mounting plate (23), two toothed plates (24) and two movable fixing plates (25), wherein the fixing motor (21) is arranged at the bottom of the mounting frame (1) and the output end of the fixing motor (21) is vertically and upwards arranged, a fixing groove (11) is formed in the mounting frame (1), the fixed gear (22) is arranged at the output end of the fixing motor (21) and the fixed gear (22) is positioned in the fixing groove (11), the two fixed toothed plates (24) are symmetrically arranged in the fixing groove (11) and the two fixed toothed plates (24) are in sliding fit with the side wall of the fixing groove (11), the two fixed toothed plates (24) are meshed with the fixed gear (22), the two movable fixing plates (25) are symmetrically arranged on the two fixed toothed plates (24) and the two movable fixing plates (25) are respectively in sliding fit with the top of the mounting frame (1), mounting panel (23) level setting is at the top of mounting bracket (1), experiment fixed plate (5) level setting just is located between two removal fixed plates (25) at the top of mounting panel (23).

3. The automotive glass run compression set test apparatus of claim 1, wherein: the lifting assembly (3) comprises a lifting cylinder (31) and a lifting plate (32), the lifting cylinder (31) is arranged at the top of the mounting frame (1) and the output end of the lifting cylinder (31) is vertically arranged upwards, the output end of the lifting cylinder (31) is in sliding fit with the mounting frame (1), and the lifting plate (32) is horizontally arranged at the output end of the lifting cylinder (31).

4. The automotive glass run compression set test apparatus of claim 1, wherein: the compression experiment piece (42) comprises a fixed frame (421), a compression plate (422), two lifting motors (423), two lifting rods (424) and two lifting gears (425), wherein the fixed frame (421) is vertically arranged at the top of the mounting frame (1), the two lifting rods (424) are symmetrically and vertically arranged at the top of the fixed frame (421), the two lifting rods (424) are in sliding fit with the fixed frame (421), each lifting rod (424) is provided with a plurality of tooth sockets (426), the two lifting motors (423) are symmetrically arranged at the top of the fixed frame (421), the two lifting motors (423) are positioned at the sides of the two lifting rods (424), the two lifting gears (425) are respectively arranged at the output ends of the two lifting motors (423), the two lifting gears (425) are respectively meshed with the tooth sockets (426) on the two lifting rods (424), the compression plate (422) is horizontally arranged at the bottom of the two lifting rods (424).

5. The automotive glass run compression set test apparatus of claim 1, wherein: the movable experimental part (43) comprises a rotary motor (431), a rotary disc (432), a movable rod (433), a sliding rail (434), a sliding block (435) and a movable experimental plate (436), the rotating motor (431) is arranged at the top of the supporting frame (41), the rotating disc (432) is arranged on the output end of the rotating motor (431), the sliding rail (434) is horizontally arranged at the top of the supporting frame (41), the sliding block (435) is arranged on the sliding rail (434) and the sliding block (435) is in sliding fit with the sliding rail (434), the movable experiment board (436) is arranged on the sliding block (435) and the movable experiment board (436) is fixedly connected with the sliding block (435), two ends of the moving rod (433) are respectively arranged on the rotating disc (432) and the sliding block (435), two ends of the moving rod (433) are respectively connected with the rotating disc (432) and the sliding block (435) in a rotating mode.

6. The automotive glass run compression set test apparatus of claim 1, wherein: every side experiment piece (44) all includes slip table cylinder (441), lift cylinder (442) and side experiment board (443), be equipped with mounting groove (12) on support frame (41), slip table cylinder (441) set up in mounting groove (12), lift cylinder (442) set up on the output of slip table cylinder (441) and the vertical upwards setting of output of lift cylinder (442), side experiment board (443) level sets up on the output of lift cylinder (442), side experiment board (443) and experiment fixed plate (5) sliding fit.

7. The automotive glass run compression set test apparatus of claim 1, wherein: rubber pads are wrapped on the peripheral side walls of the experiment fixing plate (5).

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