CN116773370A

CN116773370A - Flexible glass strength test equipment

Info

Publication number: CN116773370A
Application number: CN202310845132.3A
Authority: CN
Inventors: 尹爀俊; 欧阳春炜; 李述蕾; 王强
Original assignee: Saide Semiconductor Co ltd
Current assignee: Saide Semiconductor Co ltd
Priority date: 2023-07-11
Filing date: 2023-07-11
Publication date: 2023-09-19
Anticipated expiration: 2043-07-11
Also published as: CN116773370B

Abstract

The invention belongs to the field of strength testing of flexible glass, and particularly relates to flexible glass strength testing equipment. The invention integrates the equipment for vertically carrying out the steel ball impact test on the flexible glass, the equipment for laterally carrying out the steel ball impact test on the flexible glass and the equipment for carrying out the shock resistance test on the flexible glass connection, effectively reduces the number of the whole equipment for carrying out the steel ball impact test on the flexible glass and the shock resistance test on the flexible glass connection, and reduces the equipment cost.

Description

Flexible glass strength test equipment

Technical Field

The invention belongs to the field of strength test of flexible glass, and particularly relates to strength test equipment of flexible glass.

Background

The flexible glass is a bendable flexible glass, and is applied to various occasions such as solar panels, glasses or mobile phones due to being bendable.

After the flexible glass is produced, the flexible glass needs to be subjected to strength test, wherein the strength test contents comprise: and performing impact test and flexible glass connection impact resistance test on the glass by utilizing the free falling body of the steel ball.

In the impact test of the glass by utilizing the free falling bodies of the steel balls, the flexible glass can be impacted in various states, the normal direction of the impact point of the fallen steel balls is not necessarily vertical upwards, so that the steel balls can fly sideways after impacting the glass, and the small balls are required to be picked back for the next test, so that the test efficiency is lower. In addition, the normal direction of the point on the glass where the steel ball is piled does not necessarily need to be vertically upwards, and the requirement of impacting the glass from the side exists, and the current steel ball impacting equipment cannot meet the requirement and needs additional equipment to assist in the process.

In the shock resistance test of flexible glass connection, special equipment different from steel ball impact test is needed to be used for completion, and during experiments, one end of the glass piece needs to be fixed, and the other end of the glass piece is used for carrying out impact pulling on glass through impact pulling force generated by high-pressure air, so that the whole test equipment is more, and the test cost is higher.

The invention designs a flexible glass strength testing device which solves the problems.

Disclosure of Invention

In order to solve the defects in the prior art, the invention discloses flexible glass strength testing equipment which is realized by adopting the following technical scheme.

The flexible glass strength testing equipment comprises a base, an upright post, a sliding seat, a supporting plate, a cross beam, a pressing wheel A, a pressing wheel B, a winding wheel, a spiral spring B and a pull rope, wherein the sliding seat vertically slides on the upright post, and a structure for locking the sliding seat is arranged between the sliding seat and the upright post; the upper end and the lower end of the sliding seat are respectively provided with a cross beam and a supporting plate for placing a steel ball or a glass piece at the tail end of the pull rope; the supporting plate is provided with a falling hole for the steel ball or glass piece to pass downwards; a pinch roller A which vertically guides the pull rope from the winding wheel on the upright post downwards and a pinch roller B which presses the pull rope to the pinch roller A are arranged on the cross beam, and a structure which presses the pull rope to the pinch roller A is arranged between the pinch roller B and the cross beam; the cross beam is provided with a structure which enables the retraction length of the stay rope to be equal to the distance between the supporting plate and the base for placing the glass piece or the base by driving the pinch roller A to rotate when the sliding seat moves vertically and a structure which buffers the stay rope when the stay rope is pulled by accident; a spiral spring B which enables the winding wheel to wind the stay cord is matched between the winding wheel and the wheel shaft D where the winding wheel is positioned; the supporting plate is provided with a switch for the falling hole and a structure for preventing the stay rope in a loose state between the cross beam and the supporting plate from being knotted.

As a further improvement of the technology, two sliding grooves A on the sliding seat are horizontally slid, are matched with limiting grooves which are vertically and uniformly distributed on the upright post, are connected with lock rods through connecting rods A, are provided with two springs A which reset the lock rods in one-to-one correspondence, and are provided with pull rings.

As a further improvement of the technology, sliding blocks are arranged at two ends of the wheel shaft B where the pressing wheel B is located, the sliding blocks slide in a sliding groove B on the inner wall of the cross beam, and a spring B which radially supports and presses the pressing wheel B towards the pressing wheel A along the horizontal direction is arranged in the sliding groove B.

As a further improvement of the technology, a belt wheel A is arranged on a wheel shaft A where the pinch roller A is positioned, the belt wheel A is in transmission connection with a belt wheel mechanism on the beam through a synchronous belt, a gear B is arranged on a wheel shaft C where the belt wheel mechanism is positioned, the gear A on the beam of the gear B is meshed, and the gear A is meshed with a rack A on the upright post.

As a further improvement of the technology, the belt wheel mechanism comprises a belt wheel B, a screw sleeve, a ring sleeve, a volute spring A, a clamping block A and a clamping block B, wherein the belt wheel B which is in rotary fit with the rotating shaft A and is in transmission connection with the belt wheel A through a synchronous belt is axially and slidably matched with the screw sleeve which is in threaded fit with the rotating shaft A, and the clamping block B on the end surface of the screw sleeve is matched with the clamping block A on the rotating shaft A; the inner wall of the screw sleeve is axially matched with a ring sleeve in a sliding way, and a vortex spring A is matched between the ring sleeve and the rotating shaft A.

As a further improvement of the technology, two guide blocks A are symmetrically arranged on the screw sleeve, and the two guide blocks A respectively slide in two guide grooves A on the inner wall of the belt wheel B; two guide blocks B are symmetrically arranged on the ring sleeve, and the two guide blocks B respectively slide in two guide grooves B on the inner wall of the screw sleeve.

As a further improvement of the present technology, the diameter ratio of the pulley B to the pulley a is 1:1, a step of; the transmission ratio of the gear A to the gear B is 1:1, a step of; the radius ratio of the gear A to the pinch roller B is 1:1, ensuring that the vertical movement distance of the sliding seat is equal to the retraction length of the pinch roller B to the pull rope.

As a further improvement of the technology, a guide ring which prevents the stay ropes from piling and knotting on the support plate and has an inverted conical inner wall is arranged on the support plate; the winding wheel is installed in the lower extreme of stand, and installs the stay cord horizontal guide to the guide wheel of pinch roller B of future winding wheel in the stand.

As a further improvement of the technology, a baffle A for opening and closing a falling hole is horizontally moved in a guide rail A at the lower end of the supporting plate, two baffle B are synchronously slid in opposite directions or back to back along the direction parallel to the movement of the baffle on two guide rails B which are fixed on the supporting plate and positioned between the supporting plate and the cross beam, and one baffle B is connected with the baffle A through a connecting rod B; steel wool matched with the pull ropes is densely distributed on the inner walls of the round grooves used for allowing the pull ropes to pass through.

As a further improvement of the technology, a pair of racks B are arranged on each baffle B; two racks B on the same side of the two baffles B are meshed with gears C arranged on corresponding side guide rails B.

Compared with the traditional flexible glass strength testing equipment, the device integrates the equipment for vertically carrying out the steel ball impact test on the flexible glass, the equipment for laterally carrying out the steel ball impact test on the flexible glass and the equipment for carrying out the impact test on the flexible glass connection, so that the number of the whole equipment for carrying out the steel ball impact test on the flexible glass and the impact test on the flexible glass connection is effectively reduced, and the equipment cost is reduced.

According to the invention, through the stay cord with the corresponding length, the steel ball can be pulled back for repeated testing after the steel ball and the glass are impacted and side-flown while the steel ball is prevented from interfering with the glass after falling freely, and the testing efficiency of the steel ball vertically impacting the glass is improved.

According to the invention, the pull rope can drive the steel ball to perform lateral impact test on the flexible glass on the base through the pull rope swinging point provided by the round groove on the supporting plate, and the height of the pull rope swinging point is adjustable, so that the impact direction, lateral speed and strength of the steel ball on the glass are effectively enriched.

According to the invention, after the falling height of the steel ball is adjusted, the pull rope is ensured to have enough length, and meanwhile, the stressed part of the pull rope is only arranged on the pull rope part between the pinch roller A and the pinch roller B and the base, but not the whole pull rope is stressed, so that the integral stress frequency of the pull rope is reduced, and the pull rope part between the pinch roller A and the pinch roller B and the base can be pulled out of the winding wheel to pull the steel ball when the pull rope is damaged and fails due to repeated stress, thereby improving the replacement efficiency of the pull rope.

According to the invention, the tail ends of the part of pull ropes between the pinch roller A and the pinch roller B and the base are hooked with the hanging rings welded on the flexible glass to replace the steel balls, so that the glass piece freely falls from the supporting plate to perform the flexible glass connection impact resistance test, and the operation is convenient and quick.

The baffle A and the two baffles B in the invention can effectively prevent the pull rope from knotting due to accumulation, so that the pull rope can quickly fall along with the steel ball or the glass piece in the falling process of the steel ball or the glass piece.

The invention has simple structure and better use effect.

Drawings

Fig. 1 is a schematic diagram of two views of the present invention.

FIG. 2 is a schematic cross-sectional view of the invention mated with a pull cord and steel ball.

Fig. 3 is a schematic cross-sectional view of a locking structure on a slider from two perspectives.

Fig. 4 is a schematic cross-sectional view of a transverse structure.

Fig. 5 is a schematic cross-sectional view of a pulley mechanism from two perspectives.

Fig. 6 is a schematic cross-sectional view of the driving engagement of the baffle a with two baffles B.

Fig. 7 is a schematic top view in cross section of two baffles B mated with a pull cord.

Fig. 8 is a schematic view of the cooperation of the slide, the support plate and the cross beam.

Fig. 9 is a schematic view of a glass member.

Reference numerals in the figures: 1. a base; 2. a column; 3. a limit groove; 4. a slide; 5. a chute A; 6. a support plate; 7. a drop hole; 8. a guide ring; 9. a cross beam; 10. a chute B; 11. a lock lever; 12. a connecting rod A; 13. a pull ring; 14. a spring A; 15. a rack A; 16. pinch roller A; 17. an axle A; 18. pinch roller B; 19. an axle B; 20. a slide block; 21. a spring B; 22. a gear A; 23. a gear B; 24. an axle C; 25. a belt wheel A; 26. a synchronous belt; 27. a pulley mechanism; 28. a belt wheel B; 29. a guide groove A; 30. a screw sleeve; 31. a guide block A; 32. a guide groove B; 33. a ring sleeve; 34. a guide block B; 35. a vortex spring A; 36. a clamping block A; 37. a clamping block B; 38. a guide rail A; 39. a baffle A; 40. a connecting rod B; 41. a baffle B; 42. a circular groove; 43. steel wool; 44. a guide rail B; 45. a rack B; 46. a gear C; 47. a winding wheel; 48. an axle D; 49. a vortex spring B; 50. a guide wheel; 51. a pull rope; 52. a steel ball; 53. a glass member; 54. hanging rings.

Detailed Description

The drawings are schematic representations of the practice of the invention to facilitate understanding of the principles of operation of the structure. The specific product structure and the proportional size are determined according to the use environment and the conventional technology.

As shown in fig. 1 and 2, the device comprises a base 1, a stand column 2, a slide carriage 4, a supporting plate 6, a cross beam 9, a pinch roller A16, a pinch roller B18, a winding wheel 47, a spiral spring B49 and a pull rope 51, wherein as shown in fig. 3, the slide carriage 4 vertically slides on the stand column 2, and a structure for locking the slide carriage 4 is arranged between the slide carriage 4 and the stand column 2; as shown in fig. 1, 2 and 8, the upper end and the lower end of the sliding seat 4 are respectively provided with a cross beam 9 and a supporting plate 6 for placing a steel ball 52 or a glass piece 53 at the tail end of a pull rope 51; the supporting plate 6 is provided with a falling hole 7 for allowing the steel ball 52 or the glass piece 53 to pass downwards; as shown in fig. 2 and 4, a pinch roller a16 for guiding a pull rope 51 from a winding wheel 47 on a column 2 vertically downwards and a pinch roller B18 for pressing the pull rope 51 to the pinch roller a16 are installed on a cross beam 9, and a structure for pressing the pull rope 51 to the pinch roller a16 by the pinch roller B18 is arranged between the pinch roller B18 and the cross beam 9; as shown in fig. 1, 4 and 5, the cross beam 9 has a structure in which the draw-out length of the draw cord 51 is equal to the distance between the support plate 6 and the base 1 on which the glass piece 53 or the base is placed by driving the pinch roller a16 to rotate when the slider 4 moves vertically and a structure in which the draw cord 51 is buffered when the draw cord 51 is pulled unintentionally; as shown in fig. 2, a spiral spring B49 is fitted between the winding wheel 47 and the wheel axle D48 where the winding wheel 47 is located so that the winding wheel 47 winds the pull rope 51; as shown in fig. 2 and 6, the support plate 6 has a structure for opening and closing the drop hole 7 and preventing the rope 51 in a loose state between the cross member 9 and the support plate 6 from being knotted.

As shown in fig. 1 and 3, two sliding grooves A5 on the sliding seat 4 are horizontally slid to be matched with the limiting grooves 3 which are vertically and uniformly distributed on the upright post 2, lock rods 11 connected through connecting rods a12 are arranged, two springs a14 which reset the lock rods 11 in a one-to-one correspondence manner are arranged, and pull rings 13 are arranged on the connecting rods a 12.

As shown in fig. 4 and 8, both ends of the axle B19 where the pinch roller B18 is located are provided with a slider 20, the slider 20 slides in a chute B10 on the inner wall of the cross beam 9, and a spring B21 for radially pressing the pinch roller B18 against the pinch roller a16 along the horizontal direction is installed in the chute B10.

As shown in fig. 4, a pulley a25 is mounted on an axle a17 where the pinch roller a16 is located, the pulley a25 is in transmission connection with a pulley mechanism 27 on the beam 9 through a synchronous belt 26, a gear B23 is mounted on an axle C24 where the pulley mechanism 27 is located, a gear a22 on the beam 9 of the gear B23 is meshed, and the gear a22 is meshed with a rack a15 on the upright 2.

As shown in fig. 4 and 5, the pulley mechanism 27 includes a pulley B28, a threaded sleeve 30, a ring sleeve 33, a spiral spring a35, a clamping block a36, and a clamping block B37, wherein the pulley B28 rotationally engaged with the rotating shaft a and in driving connection with the pulley a25 through the synchronous belt 26 is axially slidably engaged with the threaded sleeve 30 in threaded engagement with the rotating shaft a, and the clamping block B37 on the end surface of the threaded sleeve 30 is engaged with the clamping block a36 on the rotating shaft a; the inner wall of the screw sleeve 30 is axially and slidably matched with a ring sleeve 33, and a vortex spring A35 is matched between the ring sleeve 33 and the rotating shaft A.

As shown in fig. 5, two guide blocks a31 are symmetrically installed on the screw sleeve 30, and the two guide blocks a31 slide in two guide grooves a29 on the inner wall of the belt wheel B28 respectively; two guide blocks B34 are symmetrically arranged on the ring sleeve 33, and the two guide blocks B34 respectively slide in two guide grooves B32 on the inner wall of the screw sleeve 30.

As shown in fig. 4, the diameter ratio of the pulley B28 to the pulley a25 is 1:1, a step of; the gear ratio of the gear A22 to the gear B23 is 1:1, a step of; the radius ratio of gear a22 to puck B18 is 1:1, the distance of the vertical movement of the sliding seat 4 is ensured to be equal to the retraction length of the pinch roller B18 to the stay cord 51.

As shown in fig. 2, the support plate 6 is provided with a guide ring 8 which prevents the stay cord 51 from piling up and knotting on the support plate 6 and has an inverted conical inner wall; the winding wheel 47 is mounted in the lower end of the upright 2, and a pulling rope 51 of the future winding wheel 47 is mounted in the upright 2 to be horizontally guided to a guide wheel 50 of the pinch roller B18.

As shown in fig. 2 and 6, a baffle a39 for opening and closing the drop hole 7 is horizontally moved in a guide rail a38 at the lower end of the support plate 6, two baffle B41 are synchronously slid in opposite directions or opposite directions along a direction parallel to the baffle movement on two guide rails B44 fixed to the support plate 6 and positioned between the support plate 6 and the cross beam 9, and one baffle B41 is connected with the baffle a39 through a connecting rod B40; the inner walls of the circular grooves 42 for allowing the pull ropes 51 to pass through are densely provided with steel wool 43 matched with the pull ropes 51 on the two baffle plates B41.

As shown in fig. 6, a pair of racks B45 are mounted on both the baffle plates B41; two racks B45 on the same side of the two shutters B41 are engaged with gears C46 mounted on the corresponding side rails B44.

According to the invention, the rim of the pinch roller A16 matched with the pull rope 51 is rough, so that the rotation of the pinch roller A16 can drive the pull rope 51 to be effectively retracted and released.

The working flow of the invention is as follows: in the initial state, the sliding seat 4 is in the lowest limit state of the upright post 2, the supporting plate 6 is just on the base 1, the baffle A39 is in a closed state to the falling hole 7 on the supporting plate 6, the steel ball 52 at the tail end of the pull rope 51 is just on the baffle A39, the stretching part between the cross beam 9 and the supporting plate 6 is in a stretched state, the two baffles B41 are in a closed state, and the steel wool 43 in the circular groove 42 on the baffles B41 is in a clamping state to the pull rope 51. The spiral spring a35 is in a compressed state. The volute spring B49 in the belt wheel mechanism 27 is in a compressed state, the clamping block A36 circumferentially abuts against the clamping block B37, the threaded sleeve 30 is located at the limit position, close to the cross beam 9, in the belt wheel B28, and the annular sleeve 33 is located at the limit position, far away from the cross beam 9, in the threaded sleeve 30. Both lock bars 11 are inserted into the corresponding limit grooves 3 of the upright posts 2 to lock the sliding seat 4.

When the invention is used for testing the impact strength of the steel ball 52 on the flexible glass, the falling height of the initial steel ball 52 is adjusted according to the requirement of the light test of the flexible glass, the pull ring 13 is pulled to drive the two lock rods 11 to separate from the corresponding limit grooves 3 to unlock the sliding seat 4, the sliding seat 4 is pushed to move vertically upwards to the required height on the upright post 2, and meanwhile, the sliding seat 4 drives the supporting plate 6 and the cross beam 9 to synchronously move and communicate with each other. The support plate 6 moves the steel ball 52 to a desired height by the shutter a 39.

Meanwhile, the gear A22 drives the belt wheel B28 to rotate through the gear B23, the wheel shaft C24, the clamping block A36, the clamping block B37 and the threaded sleeve 30 under the drive of the rack A15, the belt wheel B28 drives the pinch roller A16 to rotate through the synchronous belt 26, the belt wheel A25 and the wheel shaft A17, the pinch roller downwards discharges the end part of the steel ball 52 of the pull rope 51 pressed by the pinch roller B18, the winding wheel 47 rotates under the pull rope 51 and further compresses the vortex spring A35, meanwhile, the pinch roller A16 rotates under the pull rope 51 pull of the pinch roller B18, and the downwards discharged pull rope 51 is piled on the two baffle plates B41.

When the steel balls 52 reach the required height, the length of the pull ropes 51 piled on the two baffle plates B41 is equal to the rising height of the steel balls 52, so that the steel balls 52 can effectively impact the flexible glass placed on the base 1 after falling, the splashing distance of the small balls after impact is not too large, the speed of pulling the small balls is increased, and the impact test efficiency is improved.

Next, a flexible glass requiring test strength is prevented on the base 1.

Then, the connecting rod B40 is pulled, the connecting rod B40 drives the baffle A39 to open the falling hole 7, meanwhile, the connecting rod B40 drives one baffle B41 to move, the baffle B41 connected with the connecting rod B40 drives the other baffle B41 to open through the rack B45 and the gear C46, and the opening speed of the two baffles B41 is faster than that of the baffle A39 to open the falling hole 7.

The pull ropes 51 piled up on the two baffles B41 fall into the guide ring 8 completely before the steel balls 52 fall, when the baffle A39 fully opens the falling holes 7, the steel balls 52 freely fall downwards, and the pull ropes 51 in the guide ring 8 do not have knotting phenomenon under the guidance of the conical surface and smoothly move downwards along with the steel balls 52.

The steel ball 52 will splash after striking the flexible glass on the base 1, and because the length of the pull rope 51 is substantially the same as the distance between the cross beam 9 and the base 1, the steel ball 52 can be quickly pulled back without splashing too far, the steel ball 52 is returned to above the support plate 6 through the drop hole 7 again and the baffle A39 is closed so that the steel ball 52 is located on the baffle A39, and meanwhile, the accumulated part of the pull rope 51 is sent to above the baffle B41 before the two baffles B41 are closed. The impact strength test of the steel ball 52 on the flexible glass is completed by repeating the above steps several times.

When the lateral impact strength test is required to be carried out on the glass on the base 1, the baffle A39 is firstly opened in an initial state, the two baffles B41 can be opened, the steel ball 52 is in a suspended state, then the height of the sliding seat 4 is regulated, after the height of the supporting plate 6 is regulated as required, the steel ball 52 is laterally swung to a certain height, and the flexible glass is placed on the base 1 in a laterally impacted state. Then, the hands are loosened, and the steel ball 52 swings to the flexible glass with the falling hole 7 as a swinging point under the action of dead weight and the traction of the pull rope 51 to finish the lateral impact strength test.

When it is necessary to perform an impact resistance test on the connection of the flexible glass, the pellet is removed from the string 51 in an initial state, and the glass piece 53 welded with the glass hook is hooked on the baffle a39 at the end of the string 51 and below the drop hole 7. Then, the base 1 is removed, the height of the glass piece 53 to be dropped is adjusted as required, after the height adjustment is finished, the baffle A39 and the baffle B41 are opened, the glass piece 53 is dropped in a free falling manner, and finally the impact strength test of the connection of the glass piece 53 is completed.

In summary, the beneficial effects of the invention are as follows: the invention integrates the equipment for vertically carrying out the steel ball 52 impact test on the flexible glass, the equipment for laterally carrying out the steel ball 52 impact test on the flexible glass and the equipment for carrying out the impact test on the flexible glass connection, effectively reduces the number of the whole equipment for carrying out the steel ball 52 impact test on the flexible glass and the impact test on the flexible glass connection, and reduces the equipment cost.

According to the invention, through the stay cord 51 with the corresponding length, the steel ball 52 can be pulled back for repeated testing after the steel ball 52 and the glass are impacted to fly sideways while the interference of the stay cord 51 to the steel ball 52 and the glass is avoided after the steel ball 52 falls freely, and the testing efficiency of the steel ball 52 vertically impacting the glass is improved.

According to the invention, the swinging point of the pull rope 51 provided by the round groove 42 on the supporting plate 6 can enable the pull rope 51 to drive the steel ball 52 to perform lateral impact test on flexible glass on the base 1, and the height of the swinging point of the pull rope 51 is adjustable, so that the impact direction, lateral speed and strength of the steel ball 52 on the glass are effectively enriched.

According to the invention, after the falling height of the steel ball 52 is adjusted, the enough length of the pull rope 51 can be ensured, the stressed part of the pull rope 51 is only arranged on the pull rope 51 part between the pinch roller A16 and the pinch roller B18 and the base 1, but not the whole pull rope 51 is stressed, the whole stress frequency of the pull rope 51 is reduced, and when the pull rope 51 part between the pinch roller A16 and the pinch roller B18 and the base 1 fails due to repeated stress damage, a new pull rope 51 can be pulled out from the winding wheel 47 to pull the steel ball 52, so that the replacement efficiency of the pull rope 51 is improved.

According to the invention, the tail ends of the part of the pull ropes 51 between the pinch roller A16 and the pinch roller B18 and the base 1 are hooked with the hanging rings 54 welded on the flexible glass to replace the steel balls 52, so that the glass piece 53 freely falls from the supporting plate 6 to perform the flexible glass connection impact resistance test, and the operation is convenient and quick.

The baffle A39 and the two baffles B41 can effectively prevent the stay cord 51 from knotting due to accumulation, so that the stay cord 51 falls along with the steel ball 52 or the glass piece 53 in the falling process of the steel ball 52 or the glass piece 53.

Claims

1. A flexible glass intensity test equipment, its characterized in that: the device comprises a base, a stand column, a slide seat, a supporting plate, a cross beam, a pinch roller A, a pinch roller B, a winding wheel, a spiral spring B and a pull rope, wherein the slide seat vertically slides on the stand column, and a structure for locking the slide seat is arranged between the slide seat and the stand column; the upper end and the lower end of the sliding seat are respectively provided with a cross beam and a supporting plate for placing a steel ball or a glass piece at the tail end of the pull rope; the supporting plate is provided with a falling hole for the steel ball or glass piece to pass downwards; a pinch roller A which vertically guides the pull rope from the winding wheel on the upright post downwards and a pinch roller B which presses the pull rope to the pinch roller A are arranged on the cross beam, and a structure which presses the pull rope to the pinch roller A is arranged between the pinch roller B and the cross beam; the cross beam is provided with a structure which enables the retraction length of the stay rope to be equal to the distance between the supporting plate and the base for placing the glass piece or the base by driving the pinch roller A to rotate when the sliding seat moves vertically and a structure which buffers the stay rope when the stay rope is pulled by accident; a spiral spring B which enables the winding wheel to wind the stay cord is matched between the winding wheel and the wheel shaft D where the winding wheel is positioned; the supporting plate is provided with a switch for the falling hole and a structure for preventing the stay rope in a loose state between the cross beam and the supporting plate from being knotted.

2. A flexible glass strength testing apparatus according to claim 1, wherein: two sliding grooves A on the sliding seat are horizontally slid to be matched with limit grooves which are vertically and uniformly distributed on the upright post, lock rods connected through the connecting rods A are arranged in the two sliding grooves A, two springs A which reset the lock rods in one-to-one correspondence are arranged on the two sliding grooves A, and pull rings are arranged on the connecting rods A.

3. A flexible glass strength testing apparatus according to claim 1, wherein: the two ends of the wheel shaft B where the pressing wheel B is located are provided with sliding blocks, the sliding blocks slide in a sliding groove B on the inner wall of the cross beam, and a spring B which radially supports and presses the pressing wheel B towards the pressing wheel A along the horizontal direction is arranged in the sliding groove B.

4. A flexible glass strength testing apparatus according to claim 1, wherein: a pulley A is arranged on a wheel shaft A where the pinch roller A is located, the pulley A is in transmission connection with a pulley mechanism on the beam through a synchronous belt, a gear B is arranged on a wheel shaft C where the pulley mechanism is located, the gear A on the beam of the gear B is meshed, and the gear A is meshed with a rack A on the upright post.

5. A flexible glass strength testing apparatus according to claim 4, wherein: the belt wheel mechanism comprises a belt wheel B, a screw sleeve, a ring sleeve, a vortex spring A, a clamping block A and a clamping block B, wherein the belt wheel B which is in rotary fit with the rotating shaft A and is in transmission connection with the belt wheel A through a synchronous belt is axially and slidably matched with the screw sleeve which is in threaded fit with the rotating shaft A, and the clamping block B on the end face of the screw sleeve is matched with the clamping block A on the rotating shaft A; the inner wall of the screw sleeve is axially matched with a ring sleeve in a sliding way, and a vortex spring A is matched between the ring sleeve and the rotating shaft A.

6. A flexible glass strength testing apparatus according to claim 5, wherein: two guide blocks A are symmetrically arranged on the screw sleeve, and the two guide blocks A respectively slide in two guide grooves A on the inner wall of the belt wheel B; two guide blocks B are symmetrically arranged on the ring sleeve, and the two guide blocks B respectively slide in two guide grooves B on the inner wall of the screw sleeve.

7. A flexible glass strength testing apparatus according to claim 5, wherein: the diameter ratio of the belt wheel B to the belt wheel A is 1:1, a step of; the transmission ratio of the gear A to the gear B is 1:1, a step of; the radius ratio of the gear A to the pinch roller B is 1:1.

8. a flexible glass strength testing apparatus according to claim 1, wherein: the guide ring which prevents the stay ropes from piling and knotting on the support plate and has an inverted conical inner wall is arranged on the support plate; the winding wheel is installed in the lower extreme of stand, and installs the stay cord horizontal guide to the guide wheel of pinch roller B of future winding wheel in the stand.

9. A flexible glass strength testing apparatus according to claim 1, wherein: a baffle A for opening and closing a falling hole is horizontally moved in a guide rail A at the lower end of the supporting plate, two baffle B are synchronously slid in opposite directions or opposite directions along a direction parallel to the movement of the baffle on two guide rails B which are fixed on the supporting plate and positioned between the supporting plate and the cross beam, and one baffle B is connected with the baffle A through a connecting rod B; steel wool matched with the pull ropes is densely distributed on the inner walls of the round grooves used for allowing the pull ropes to pass through.

10. A flexible glass strength testing apparatus according to claim 9, wherein: a pair of racks B are arranged on the two baffles B; two racks B on the same side of the two baffles B are meshed with gears C arranged on corresponding side guide rails B.