CN116952732A - Glass production is with many testing arrangement - Google Patents

Abstract

The invention discloses a plurality of testing devices for glass production, wherein a first fixing plate is provided with a vertical limiting component and an anti-impact hardness component respectively, the vertical limiting component is arranged at the lower end of the anti-impact hardness component, a bottom plate is provided with a compression hardness testing piece, the compression hardness testing piece is arranged at the lower end of the vertical limiting component, a second fixing plate is provided with a testing driving component, and one end of the testing driving component is movably connected with the vertical limiting component. The invention belongs to the technical field of glass testing, and particularly relates to a plurality of testing devices for glass production, which can perform impact resistance detection on toughened glass with different forces, realize the impact resistance detection on the toughened glass, and simulate the anti-falling capability detection of the toughened glass in the installation and use process when the toughened glass is placed at different angles.

Description

Glass production is with many testing arrangement

Technical Field

The invention belongs to the technical field of glass testing, and particularly relates to a plurality of testing devices for glass production.

Background

The toughened glass belongs to safety glass, is prestressed glass, and is characterized in that in order to improve the strength of the glass, a chemical or physical method is generally used for forming compressive stress on the surface of the glass, and the surface stress is counteracted when the glass bears external force, so that the bearing capacity is improved, the wind pressure resistance, summer-cold resistance, impact resistance and the like of the glass are enhanced, and the strength of the toughened glass needs to be detected after the toughened glass is produced, but the conventional toughened glass anti-impact detection device has some defects:

A. the existing toughened glass anti-collision detection device needs to be manually adjusted in height, so that labor force is increased, and working efficiency is reduced;

B. the existing toughened glass anti-collision detection device does not have the steel ball test of different quality for the toughened glass continuously, and needs to be replaced manually, so that labor force is increased, and time is wasted;

C. in the existing toughened glass anti-impact detection device, only anti-impact detection can be performed on toughened stripping, and pressure resistance detection cannot be performed on toughened glass at the same time;

D. in the existing toughened glass anti-collision detection device, the detection of the anti-falling capability of the toughened glass in the installation and use process at different placement angles cannot be simulated.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides a plurality of testing devices for glass production, which can perform impact resistance detection on toughened glass with different forces, realize the impact resistance detection on the toughened glass, and simulate the anti-falling capability detection of the toughened glass in the installation and use process when the toughened glass is placed at different angles.

The technical scheme adopted by the invention is as follows: the utility model provides a glass production is with many testing arrangement, includes the bottom plate, install backup pad one on the bottom plate, install fixed plate one on the backup pad one, be connected with backup pad two on the fixed plate one, be connected with fixed plate two on the backup pad two, install perpendicular spacing subassembly and anti striking hardness subassembly on the fixed plate one respectively, perpendicular spacing subassembly is located the lower extreme of anti striking hardness subassembly, be equipped with compressive hardness test piece on the bottom plate, compressive hardness test piece locates perpendicular spacing subassembly's lower extreme, and anti striking hardness subassembly can carry out striking formula test to glass, and compressive hardness test piece can carry out extrusion formula test to glass, and perpendicular spacing subassembly can adjust the position of glass that is tested, is convenient for carry out anti striking, compressive resistance to glass and simulate the test of beating of glass after the different angle installations, fixed plate two are installed test drive assembly, test drive assembly's one end and perpendicular spacing subassembly swing joint;

the test driving assembly comprises a fixed block, the fixed block is arranged on a second fixed plate, a limiting shaft is arranged in the fixed block, a driving rod is movably arranged on the limiting shaft, a first clamping groove and a second clamping groove are arranged in the driving rod, the first clamping groove is arranged at the middle position of the driving rod, the second clamping groove is arranged at the end part of the driving rod, a first sliding block is movably connected in the first clamping groove, a second sliding block is movably connected in the second clamping groove, a swing rod is movably connected on the side wall of the first sliding block, a second supporting seat is connected on the side wall of the second fixed plate, a second motor is arranged on the second supporting seat, and an output shaft of the second motor is connected with the other end of the swing rod;

the second motor drives the swing rod to rotate, the first slider is driven to do annular motion when the swing rod rotates, the first slider can repeatedly slide along the first clamping groove when moving, the first clamping groove pushes the driving rod to swing up and down, the driving rod drives the second clamping groove at the end to swing up and down to do fan-shaped motion, and the second clamping groove drives the second slider to swing up and down.

Further, the vertical limiting component comprises limiting plates, two groups of limiting plates are arranged on the upper wall of a fixed plate I and are oppositely arranged, limiting grooves are arranged between the two groups of limiting plates, a first sliding groove is arranged on the limiting plates close to the driving rod, a second sliding groove is arranged on the other group of limiting plates, the first sliding groove and the second sliding groove are oppositely arranged, the first sliding groove and the second sliding groove are all in through connection with the limiting grooves, the first sliding groove is in a straight line arrangement, the middle track of the second sliding groove is in a V-shaped structure, two side lengths of the two side of the V-shaped structure are equal, the outer corners of the V-shaped track at the second sliding groove are in an arc shape, the other tracks of the second sliding groove are in a straight line and are in through arrangement with the first sliding groove, a test push plate is movably clamped in the limiting grooves, one end of the test push plate is arranged on the outer side of the limiting plates, the anti-collision test board is connected, the other end of the test push board is movably clamped in the limit groove, one side wall of the other end of the test push board is connected with the plug-in unit, the plug-in unit is movably clamped in the second chute, the plug-in unit is of a cylindrical structure, the plug-in unit is matched with the outer corner of the V-shaped track at the second chute, when the plug-in unit moves to the outer corner of the V-shaped track at the second chute along the second chute, the plug-in unit is just clamped in the outer corner of the V-shaped track, the arrangement of the outer corner prevents the plug-in unit from continuously moving, the plug-in unit and the arrangement of the second chute limit the movement of the test push board, so that the test push board can move along the track of the second chute, the second slider is provided with a connecting shaft, the connecting shaft penetrates through the first chute and is movably connected with the other side wall of the test push board, and the plug-in unit is arranged at the end part of the driving rod, the connecting shaft is arranged on the driving rod, and the distance between the circle center of the connecting shaft and the circle center of the plug-in unit is the same as the side length of the two V-shaped track of the chute;

if the driving rod is arranged in the vertical state at first, the anti-collision test board is positively arranged at the upper end of the limiting board, the anti-collision test board is in the highest state, the second sliding block drives the connecting shaft to move downwards along the first sliding groove along with the downward movement of the driving rod, the connecting shaft drives the test push board to move along the limiting groove, the test push board drives the plug-in unit to move along the upper section linear track of the second sliding groove, and at the moment, the tracks of the second sliding groove and the first sliding groove are the same and are in the linear state, so that the test push board is in the vertical downward movement state, and the height of the anti-collision test board is reduced; when the plug-in is moved to one side of the V-shaped track of the second chute, the plug-in moves to the V-shaped corner along one side of the V-shaped track of the second chute along with the continued downward movement of the test push plate, one end of the test push plate is driven to move towards the outer corner, meanwhile, as the first chute is arranged in a straight line, the connecting shaft moves in a straight line, under the dual functions of the connecting shaft and the plug-in, the test push plate moves downward along the limit groove and simultaneously rotates anticlockwise by taking the plug-in as a rotating shaft, the test push plate drives the anti-impact test plate to rotate anticlockwise to the outer side of the limit plate, the glass on the test push plate rotates from a horizontal state to a vertical state, when the plug-in is clamped at the outer corner of the V-shaped track of the second chute, the outer corner limits the movement of the plug-in, but the connecting shaft continues to move, the test push plate is driven to rotate by taking the plug-in as the rotating shaft, the glass on the test push plate rotates from the vertical state to a downward inclined state, after the connecting shaft moves to the position of the first chute opposite to the linear track of the lower section of the second chute, when the connecting shaft drives the test push plate to move again, the test push plate drives the insert to move along the other side of the V-shaped track of the second chute, and as the test push plate moves downwards, the insert moves along the other side of the V-shaped track of the second chute, and drives one end of the test push plate to move away from the outer corner, meanwhile, the connecting shaft moves linearly, under the double functions of the connecting shaft and the insert, the test push plate moves downwards along the limit groove and simultaneously rotates anticlockwise by taking the insert as a rotating shaft, glass on the test push plate rotates from a vertical state to a horizontal state, the anti-impact test plate is reversely arranged at the lower end of the limit plate, the connecting shaft drives the test push plate to move along the first chute, the test push plate drives the plug-in unit to move along the linear track of the lower section of the second chute, and at the moment, the tracks of the second chute and the first chute are the same and are all in a linear state, so that the test push plate is in a vertical downward movement state until glass on the anti-impact test plate is extruded on the anti-compression hardness test piece, and the pressure between the glass and the anti-compression hardness test piece is increased along with the continuous downward movement of the test push plate, so that the anti-compression hardness test is realized.

As the invention, preferably, the anti-collision hardness component comprises a connecting rod, the lower end of the connecting rod is arranged on the upper wall of a first fixed plate, the upper end of the connecting rod is connected with a connecting plate, the outer side wall of the connecting plate is connected with a first supporting seat, a first motor is arranged on the first supporting seat, the first motor is a motor with two positive and negative rotations, the bottom wall of the connecting plate is movably provided with driving rollers, the driving rollers are provided with a plurality of groups, the driving rollers are uniformly arranged on the bottom wall of the connecting plate at equal intervals, each group of driving rollers is provided with gears, the gears on each group of driving rollers have the same size, the gears are arranged on the outer side wall of the connecting plate, the gears on two adjacent groups of driving rollers are in meshed connection, and the output shaft end of the first motor is connected with the driving roller at the outermost side;

the motor works to drive the driving rollers at the outermost side to rotate, the driving rollers at the outermost side drive gears to rotate, and the gears drive the gears meshed with the driving gears to rotate, so that the technical effect of simultaneous rotation of multiple groups of driving rollers is achieved.

The driving rollers are provided with a plurality of groups of partition boards, the partition boards are arranged on the driving rollers at intervals, connecting ropes are wound between the side walls of the connecting plates and the partition boards and between the partition boards and the partition boards, winding modes of the connecting ropes on the two adjacent groups of driving rollers are opposite, and the sagging ends of the connecting ropes are connected with test balls; when the motor I rotates, the driving roller is driven to rotate, the connecting rope falls off from the driving roller, the test ball falls down rapidly under the action of gravity, the glass fixed on the impact test board is impacted, meanwhile, the speed of the motor I rotates is greater than the falling speed of the test ball, and the influence of the connecting rope on the impact force of the test ball is reduced.

As a preferred mode of the invention, the upper wall of the anti-collision test board is provided with two groups of baffles, the two groups of baffles are vertically arranged on two adjacent sides of the anti-collision test board, the inner side walls of the two groups of baffles are respectively provided with a rubber cushion layer, the upper wall of the anti-collision test board is provided with two groups of clamping assemblies, the two groups of clamping assemblies are vertically arranged, and the clamping assemblies and the baffles are respectively oppositely arranged;

the glass to be tested is arranged between the baffle and the clamping assembly, the clamping assembly clamps and fixes the glass, and the clamped glass upper wall protrudes out of the baffle and the clamping assembly is arranged.

Further, the clamping assembly comprises a hydraulic rod, the hydraulic rod is fixedly arranged on the anti-collision test plate, the movable end of the hydraulic rod is connected with a pushing plate, a connecting piece is connected to the pushing plate, an extrusion plate is arranged on the connecting piece, and a rubber cushion layer is arranged on the inner side wall of the extrusion plate; the setting of rubber bed course can protect and fix glass.

Preferably, a pressure sensor is arranged in the compressive hardness test piece, and the working principle of the electronic scale is similar, when the glass vertically and downwards pushes against the upper wall of the compressive hardness test piece, the force of pushing the glass against the upper wall of the compressive hardness test piece is increased along with the downward movement of the anti-impact test plate, so that the compressive test of the glass is realized.

Preferably, a controller is arranged in the bottom plate, and the controller is electrically connected with the pressure sensor, the motor I, the motor II and the hydraulic rod.

The bottom wall of the compression hardness testing piece is provided with a base plate, the base plate is arranged on the bottom plate, the upper wall of the base plate is connected with the bottom wall of the compression hardness testing piece, the number or the height of the cushion blocks can be adjusted according to the difference of testing pressure, and then the adjustment of the height of the compression hardness testing piece is realized, so that the technical effect of testing different pressures on glass is realized.

Further, a protective cover is movably connected to the outer side of the bottom plate; in the testing process, the outer side wall of the bottom plate is provided with a guardrail; when the anti-falling test of the glass with different angles after the simulation installation is needed, the anti-impact test plate rotates to the installation angle to be tested under the action of the test push plate, and after the clamping assembly is used for clamping in a loosening mode, the glass falls on the bottom plate to be tested.

After the structure is adopted, the invention has the following beneficial effects:

(1) The anti-impact hardness component can perform impact type test on glass, and meanwhile, the vertical limiting component can adjust the height between the anti-impact test board and the test ball, so that impact detection with different forces is realized.

(2) The compressive hardness test piece can perform an extrusion test on glass.

(2) The vertical limiting component can adjust the azimuth of the tested glass, and is convenient for detecting the anti-falling capability of the simulated toughened glass in installation and use at different placing angles.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

FIG. 1 is a schematic diagram of a multiple test apparatus for glass production according to the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a front view of a multiple test apparatus for glass production according to the present invention;

FIG. 4 is a rear view of a multiple test apparatus for glass production according to the present invention;

fig. 5 is a schematic structural diagram of a multiple test apparatus for glass production according to the present invention.

In the drawings: 1. the device comprises a bottom plate, 2, a first supporting plate, 3, a first fixing plate, 4, a second supporting plate, 5, a second fixing plate, 6, a vertical limiting component, 7, an impact resistant hardness component, 8, an impact resistant hardness test piece, 9, a test driving component, 10, a fixed block, 11, a limiting shaft, 12, a driving rod, 13, a clamping groove I, 14, a clamping groove II, 15, a sliding block I, 16, a sliding block II, 17, a swinging rod, 18, a second supporting seat, 19, a second motor, 20, a limiting plate, 21, a limiting groove, 22, a sliding groove I, 23, a sliding groove II, 24, an outer corner, 25, a test push plate, 26, an impact resistant test plate, 27, an insert, 28, a connecting shaft, 29, a connecting rod, 30, a connecting plate, 31, a first supporting seat, 32, a motor I, 33, a driving roller, 34, a gear, 35, a partition plate, 36, a connecting rope, 37, a test ball, 38, a baffle, 39, a rubber cushion, 40, a clamping component, 41, a hydraulic rod, 42, a pushing plate, 43, a connecting piece, 44, a pressing plate, 45 and 45.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention; all other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It is noted that relational terms such as first and second, and the like are 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. Moreover, 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.

As shown in fig. 1-5, a plurality of test devices for glass production comprise a bottom plate 1, wherein a first supporting plate 2 is arranged on the bottom plate 1, a first fixing plate 3 is arranged on the first supporting plate 2, a second supporting plate 4 is connected to the first fixing plate 3, a second fixing plate 5 is connected to the second supporting plate 4, a vertical limiting component 6 and an impact-resistant hardness component 7 are respectively arranged on the first fixing plate 3, the vertical limiting component 6 is arranged at the lower end of the impact-resistant hardness component 7, a compression-resistant hardness test piece 8 is arranged on the bottom plate 1, the compression-resistant hardness test piece 8 is arranged at the lower end of the vertical limiting component 6, the impact-resistant hardness component 7 can perform impact test on glass, the compression-resistant hardness test piece 8 can perform extrusion test on the glass, the vertical limiting component 6 can adjust the azimuth of the tested glass, the impact-resistant pressure-resistant and impact-resistant test on the glass after simulating different angles of the glass are conveniently performed on the glass, a test driving component 9 is arranged on the second fixing plate 5, and one end of the test driving component 9 is movably connected with the movable limiting component 6. The test driving assembly 9 comprises a fixed block 10, the fixed block 10 is arranged on a fixed plate II 5, a limiting shaft 11 is arranged in the fixed block 10, a driving rod 12 is movably arranged on the limiting shaft 11, a clamping groove I13 and a clamping groove II 14 are arranged in the driving rod 12, the clamping groove I13 is arranged at the middle position of the driving rod 12, the clamping groove II 14 is arranged at the end part of the driving rod 12, a sliding block I15 is movably connected in the clamping groove I13, a sliding block II 16 is movably connected in the clamping groove II 14, a swing rod 17 is movably connected on the side wall of the sliding block I15, a supporting seat II 18 is connected on the side wall of the fixed plate II 5, a motor II 19 is arranged on the supporting seat II 18, and an output shaft of the motor II 19 is connected with the other end of the swing rod 17; the motor II 19 works to drive the swing rod 17 to rotate, the swing rod 17 drives the first slider 15 to do annular motion when rotating, the first slider 15 can repeatedly slide along the first clamping groove 13 when moving, the driving rod 12 is pushed to swing up and down through the first clamping groove 13, the driving rod 12 drives the second clamping groove 14 at the end to swing up and down to do fan-shaped motion, and the second clamping groove 14 drives the second slider 16 to swing up and down.

The vertical limiting component 6 comprises limiting plates 20, wherein the limiting plates 20 are provided with two groups, the two groups of limiting plates 20 are respectively arranged on the upper wall of a first fixed plate 3 and are oppositely arranged, limiting grooves 21 are arranged between the two groups of limiting plates 20, a first sliding groove 22 is arranged on the limiting plate 20 close to the driving rod 12, the other group of limiting plates 20 are provided with a second sliding groove 23, the positions of the first sliding groove 22 and the second sliding groove 23 are oppositely arranged, the first sliding groove 22 and the second sliding groove 23 are in through connection with the limiting grooves 21, the first sliding groove 22 is in linear arrangement, the middle track of the second sliding groove 23 is in a V-shaped structure, the two side lengths of the V-shaped track at the second sliding groove 23 are equal, the outer corners 24 of the V-shaped track at the second sliding groove 23 are in arc arrangement, the rest tracks of the second sliding groove 23 are in straight lines and are in through arrangement with the first sliding groove 22, the limiting groove 21 is movably clamped with a test push plate 25, one end of the test push plate 25 is arranged on the outer side of the limiting plate 20 and is connected with an anti-collision test plate 26, the other end of the test push plate 25 is movably clamped in the limiting groove 21, one side wall of the other end of the test push plate 25 is connected with an insert 27, the insert 27 is movably clamped in the sliding groove II 23, the insert 27 is of a cylindrical structure, the insert 27 is matched with an outer corner 24 of a V-shaped track at the sliding groove II 23, when the insert 27 moves to the outer corner 24 of the V-shaped track at the sliding groove II 23 along the sliding groove II 23, the insert 27 is just clamped in the outer corner 24 of the V-shaped track, the arrangement of the outer corner 24 prevents the continued movement of the insert 27, the insert 27 and the arrangement of the sliding groove II 23 limit the movement of the test push plate 25, so that the test push plate 25 can move along the track of the sliding groove II 23, the second slider 16 is provided with a connecting shaft 28, the connecting shaft 28 penetrates through the first chute 22 and is movably connected with the other side wall of the test push plate 25, the plug-in 27 is arranged at the end part of the driving rod 12, the connecting shaft 28 is arranged on the driving rod 12, and the distance between the circle center of the connecting shaft 28 and the circle center of the plug-in 27 is the same as the side length of the 23V-shaped track of the second chute;

if the driving rod 12 is arranged in the vertical state at first, the anti-impact test plate 26 is positively arranged at the upper end of the limiting plate 20, the anti-impact test plate 26 is in the highest state, the second slider 16 moves downwards along with the driving rod 12, the connecting shaft 28 is driven to move downwards along the first chute 22, the connecting shaft 28 drives the test push plate 25 to move along the limiting groove 21, the test push plate 25 drives the plug-in unit 27 to move along the upper section linear track of the second chute 23, and at the moment, the tracks of the second chute 23 and the first chute 22 are the same and are in the linear state, so that the test push plate 25 is in the vertical downwards moving state, and the height of the anti-impact test plate 26 is reduced; until the insert 27 moves to one side of the V-shaped track of the second chute 23, as the test push plate 25 moves down, the insert 27 moves to the V-shaped corner along one side of the V-shaped track of the second chute 23, driving one end of the test push plate 25 to move towards the outer corner 24, meanwhile, as the first chute 22 is arranged linearly, the connecting shaft 28 moves linearly, under the dual functions of the connecting shaft 28 and the insert 27, the test push plate 25 moves down along the limit groove 21 and rotates anticlockwise by taking the insert 27 as a rotation shaft, the test push plate 25 drives the anti-collision test plate 26 to rotate anticlockwise to the outer side of the limit plate 20, the glass on the test push plate 25 rotates from a horizontal state to a vertical state, when the insert 27 is clamped at the outer corner 24 of the V-shaped track of the second chute 23, the outer corner 24 limits the movement of the insert 27, but the connecting shaft 28 continues to move, the connecting shaft 28 drives the test push plate 25 to rotate by taking the insert 27 as a rotating shaft, the glass on the test push plate 25 rotates from a vertical state to a downward inclined state until the connecting shaft 28 moves to the position of the first chute 22 opposite to the linear track of the lower section of the second chute 23, when the test push plate 25 is driven to move again along with the connecting shaft 28, the test push plate 25 drives the insert 27 to continuously move along the other side of the V-shaped track of the second chute 23, the insert 27 moves along the other side of the V-shaped track of the second chute 23 along with the continuous downward movement of the test push plate 25, one end of the test push plate 25 is driven to move in a direction away from the outer corner 24, meanwhile, the connecting shaft 28 moves linearly due to the linear arrangement of the first chute 22, the test push plate 25 moves downwards along the limit groove 21 and simultaneously rotates anticlockwise by taking the insert 27 as the rotating shaft under the dual functions of the connecting shaft 28 and the insert 27, the glass on the test push plate 25 rotates from a vertical state to a horizontal state, the anti-impact test plate 26 is reversely arranged at the lower end of the limiting plate 20, the connecting shaft 28 drives the test push plate 25 to move continuously along the first chute 22, the test push plate 25 drives the plug-in unit 27 to move along the lower section linear track of the second chute 23, at the moment, the tracks of the second chute 23 and the first chute 22 are the same, and are in a linear state, so the test push plate 25 is in a vertically downward moving state until the glass on the anti-impact test plate 26 is extruded on the anti-compression hardness test piece 8, and the pressure between the glass and the anti-compression hardness test piece 8 is increased along with the continuous downward movement of the test push plate 25, so that the anti-compression hardness test is realized.

The anti-collision hardness assembly 7 comprises a connecting rod 29, the lower end of the connecting rod 29 is arranged on the upper wall of a first fixing plate 3, the upper end of the connecting rod 29 is connected with a connecting plate 30, the outer side wall of the first connecting plate 30 is connected with a first supporting seat 31, the first supporting seat 31 is provided with a first motor 32, the first motor 32 is a positive and negative rotating motor, the bottom wall of the connecting plate 30 is movably provided with a driving roller 33, the driving roller 33 is provided with a plurality of groups, the driving rollers 33 are uniformly arranged on the bottom wall of the connecting plate 30 at equal intervals, each group of driving rollers 33 is provided with a gear 34, the gears 34 on each group of driving rollers 33 have the same size, the gears 34 are arranged on the outer side wall of the connecting plate 30, the gears 34 on two adjacent groups of driving rollers 33 are in meshed connection, the output shaft end of the first motor 32 is connected with the driving roller 33 on the outermost side, the driving roller 33 is provided with a plurality of groups of separating plates 35, the side walls of the connecting plate 30 are arranged on the driving rollers 35 at intervals, and between the separating plates 35 and 35 are wound with connecting ropes 36, the driving rollers 36 are connected with the driving rollers 33 in opposite winding ways, and the connecting ends of the driving rollers 33 are connected with one another through the connecting balls 37 in opposite winding mode; when the motor I32 rotates, the driving roller 33 is driven to rotate, the connecting rope 36 falls off from the driving roller 33, the test ball 37 falls down rapidly under the action of gravity to impact against the glass fixed on the impact test board 26, and meanwhile, the rotating speed of the motor I32 is higher than the falling speed of the test ball 37, so that the influence of the connecting rope 36 on the impact force of the test ball 37 is reduced; the first motor 32 works to drive the outermost driving roller 33 to rotate, the outermost driving roller 33 drives the gear 34 to rotate, and the gear 34 drives the gear 34 meshed with the gear 34 to rotate, so that the technical effect of simultaneous rotation of multiple groups of driving rollers 33 is achieved.

The upper wall of the anti-collision test plate 26 is provided with two groups of baffles 38, the baffles 38 are vertically arranged on two adjacent sides of the anti-collision test plate 26, the inner side walls of the two groups of baffles 38 are respectively provided with a rubber cushion 39, the upper wall of the anti-collision test plate 26 is provided with a clamping assembly 40, the clamping assemblies 40 are vertically arranged, the clamping assemblies 40 and the baffles 38 are respectively oppositely arranged, the clamping assemblies 40 comprise hydraulic rods 41, the hydraulic rods 41 are fixedly arranged on the anti-collision test plate 26, the movable ends of the hydraulic rods 41 are connected with pushing plates 42, the pushing plates 42 are connected with connecting pieces 43, the connecting pieces 43 are provided with extrusion plates 44, and the inner side walls of the extrusion plates 44 are provided with the rubber cushion 39; the rubber cushion 39 is arranged to protect and fix the glass; the glass to be tested is arranged between the baffle 38 and the clamping assembly 40, the clamping assembly 40 clamps and fixes the glass, and the clamped glass upper wall protrudes out of the baffle 38 and the clamping assembly 40.

The pressure sensor is arranged in the compressive hardness test piece 8, and the working principle of the electronic scale is similar, when the glass vertically and downwards pushes against the upper wall of the compressive hardness test piece 8, the force of pushing the glass against the upper wall of the compressive hardness test piece 8 is increased along with the downward movement of the anti-collision test plate 26, so that the compressive test of the glass is realized; a controller is arranged in the bottom plate 1 and is electrically connected with the pressure sensor, the motor I32, the motor II 19 and the hydraulic rod 41; the bottom wall of the compression-resistant hardness test piece 8 is provided with a base plate 45, the base plate 45 is arranged on the bottom plate 1, the upper wall of the base plate 45 is connected with the bottom wall of the compression-resistant hardness test piece 8, the number or the height of cushion blocks can be adjusted according to different test pressures, the height of the compression-resistant hardness test piece 8 is adjusted, and the technical effects of different pressure tests on glass are realized conveniently; a protective cover is movably connected to the outer side of the bottom plate 1; in the testing process, the outer side wall of the bottom plate 1 is provided with guardrails; when the anti-falling test of the glass with different angles after the simulation installation is required, after the anti-impact test board 26 rotates to the installation angle to be tested under the action of the test push board 25, the clamping assembly 40 releases the clamping, and the glass falls on the bottom board 1 for testing.

The specific use is as follows:

in the testing process, the outer side wall of the bottom plate 1 is provided with guardrails for ensuring safety;

the impact resistance test was performed:

when the anti-collision test plate 26 is arranged in a downward inclined mode, then the glass is clamped between the baffle 38 and the clamping assembly 40, the clamping assembly 40 clamps and fixes the glass, the clamped glass upper wall protrudes out of the baffle 38 and the clamping assembly 40 is arranged, the motor II 19 works to drive the swing rod 17 to rotate, the swing rod 17 drives the slide block I15 to do annular motion when rotating, the slide block I15 can repeatedly slide along the clamping groove I13 when moving, the clamping groove I13 pushes the driving rod 12 to swing up and down, the driving rod 12 drives the clamping groove II 14 at the end to swing up and down to do fan-shaped motion, the clamping groove II 14 drives the slide block II 16 to swing up and down, the connecting shaft 28 is driven to move, the connecting shaft 28 drives the test push plate 25 to move, and after the test push plate 25 is brought to the right above the limiting plate 20, the glass on the test push plate 25 is in a positive horizontal state, and the test height is adjusted according to requirements;

the connecting shaft 28 drives the test push plate 25 to move along the first chute 22, the test push plate 25 drives the insert 27 to move along the upper section linear track of the second chute 23, and at the moment, the tracks of the second chute 23 and the first chute 22 are the same and are in a linear state, so that the test push plate 25 moves upwards in the vertical direction, and the distance from glass on the anti-collision test plate 26 to the test ball 37 is adjusted; after the distance is properly adjusted, the first motor 32 works to drive the outermost driving roller 33 to rotate, the outermost driving roller 33 drives the gear 34 to rotate, the gear 34 drives the gear 34 meshed with the outermost driving roller 33 to rotate, the technical effect of simultaneous rotation of a plurality of groups of driving rollers 33 is sequentially achieved, when the driving rollers 33 rotate, the connecting rope 36 falls off from the driving rollers 33, the test ball 37 rapidly falls under the action of gravity to resist the impact of glass fixed on the impact test board 26, then the first motor 32 reversely rotates and is brought to the driving rollers 33 to rotate, and the driving rollers 33 wind the connecting rope 36;

the distance between the anti-impact test plate 26 and the test ball 37 can be adjusted, so that the purpose of multiple groups of impact tests with different gravities can be realized;

when the compression test is carried out:

firstly, according to different testing pressures, the number or the height of the cushion blocks can be adjusted, so that the height of the compression-resistant hardness test piece 8 can be adjusted, and the technical effects of testing different pressures on glass can be realized conveniently;

then on the basis of the anti-collision test, the connecting shaft 28 drives the test push plate 25 to move upwards along the first chute 22, the test push plate 25 continues to move upwards in the vertical direction until the anti-collision test plate 26 is in the highest state, when the second slider 16 moves downwards along with the driving rod 12, the connecting shaft 28 drives the connecting shaft 28 to move downwards along the first chute 22, the connecting shaft 28 drives the test push plate 25 to move along the limit groove 21, the test push plate 25 drives the insert 27 to move along the upper section linear track of the second chute 23, and at the moment, the tracks of the second chute 23 and the first chute 22 are the same and are all in a linear state, so that the test push plate 25 is in the vertical downward movement state, and the height of the anti-collision test plate 26 is reduced; when the insert 27 moves to one side of the V-shaped track of the second chute 23, along with the continued downward movement of the test push plate 25, the insert 27 moves to the V-shaped outer corner 24 along one side of the V-shaped track of the second chute 23, so that one end of the test push plate 25 is driven to move towards the outer corner 24, meanwhile, as the first chute 22 is arranged linearly, the connecting shaft 28 moves linearly, under the dual functions of the connecting shaft 28 and the insert 27, the test push plate 25 moves downward along the limit groove 21 and simultaneously rotates anticlockwise by taking the insert 27 as a rotating shaft, the test push plate 25 drives the anti-collision test plate 26 to rotate anticlockwise to the outer side of the limit plate 20, the glass on the test push plate 25 rotates from a horizontal state to a vertical state, when the insert 27 is clamped at the outer corner 24 of the V-shaped track of the second chute 23, the outer corner 24 limits the movement of the insert 27, but the connecting shaft 28 continues to move, the connecting shaft 28 drives the test push plate 25 to rotate by taking the insert 27 as a rotating shaft, the glass on the test push plate 25 rotates from a vertical state to a downward inclined state until the connecting shaft 28 moves to the position of the first chute 22 opposite to the linear track of the lower section of the second chute 23, when the test push plate 25 is driven to move again along with the connecting shaft 28, the test push plate 25 drives the insert 27 to continuously move along the other side of the V-shaped track of the second chute 23, the insert 27 moves along the other side of the V-shaped track of the second chute 23 along with the continuous downward movement of the test push plate 25, one end of the test push plate 25 is driven to move in a direction away from the outer corner 24, meanwhile, the connecting shaft 28 moves linearly due to the linear arrangement of the first chute 22, the test push plate 25 moves downwards along the limit groove 21 and simultaneously rotates anticlockwise by taking the insert 27 as the rotating shaft under the dual functions of the connecting shaft 28 and the insert 27, the glass on the test push plate 25 rotates from a vertical state to a horizontal state, the anti-impact test plate 26 is reversely arranged at the lower end of the limiting plate 20, the connecting shaft 28 drives the test push plate 25 to move continuously along the first chute 22, the test push plate 25 drives the plug 27 to move along the lower section linear track of the second chute 23, at the moment, the tracks of the second chute 23 and the first chute 22 are the same, and are in a linear state, so the test push plate 25 is in a vertically downward moving state until the glass on the anti-impact test plate 26 is extruded on the anti-compression hardness test piece 8, the pressure between the glass and the anti-compression hardness test piece 8 is increased along with the continuous downward movement of the test push plate 25, and the pressure sensor records compression resistance data to realize the anti-compression hardness test;

according to different test pressures, the number or the height of the cushion blocks can be adjusted, so that the height of the compression-resistant hardness test piece 8 can be adjusted, and the technical effects of different pressure tests on glass can be realized conveniently;

when the anti-falling test of the glass with different angles after the installation is required to be simulated, after the anti-collision test plate 26 rotates to the installation angle to be tested under the action of the test push plate 25, the clamping assembly 40 releases the clamping, and the glass falls on the bottom plate 1 for testing; the tested glass is removed from the impact-resistant test plate 26.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present invention.

Claims (10)

1. The utility model provides a glass production is with many testing arrangement, includes the bottom plate, install backup pad one on the bottom plate, install fixed plate one on the backup pad one, be connected with backup pad two on the fixed plate one, be connected with fixed plate two on the backup pad two, its characterized in that, install perpendicular spacing subassembly and anti striking hardness subassembly on the fixed plate one respectively, perpendicular spacing subassembly locates the lower extreme of anti striking hardness subassembly, be equipped with compressive hardness test piece on the bottom plate, compressive hardness test piece locates the lower extreme of perpendicular spacing subassembly, test drive assembly is installed to fixed plate two, test drive assembly's one end and perpendicular spacing subassembly swing joint;

the test driving assembly comprises a fixing block, the fixing block is arranged on a second fixing plate, a limiting shaft is arranged in the fixing block, a driving rod is movably arranged on the limiting shaft, a first clamping groove and a second clamping groove are arranged in the driving rod, the first clamping groove is arranged at the middle position of the driving rod, the second clamping groove is arranged at the end part of the driving rod, a first sliding block is movably connected in the first clamping groove, a second sliding block is movably connected in the second clamping groove, a swing rod is movably connected on the side wall of the first sliding block, a second supporting seat is connected on the side wall of the second fixing plate, a second motor is arranged on the second supporting seat, and an output shaft of the second motor is connected with the other end of the swing rod.

2. The device for testing multiple items for glass production according to claim 1, wherein the vertical limiting component comprises limiting plates, the limiting plates are provided with two groups, the two groups of limiting plates are respectively arranged on the upper wall of the fixed plate and are oppositely arranged, limiting grooves are formed between the limiting plates, the limiting plates close to the driving rods are provided with first sliding grooves, the limiting plates are provided with second sliding grooves, the first sliding grooves and the second sliding grooves are oppositely arranged, the first sliding grooves and the second sliding grooves are respectively and fixedly connected with the limiting grooves, the first sliding grooves are linearly arranged, middle tracks of the second sliding grooves are of V-shaped structures, the middle tracks of the second sliding grooves are of equal length, the outer corners of the V-shaped tracks of the second sliding grooves are of circular arc shapes, the rest tracks of the second sliding grooves are of straight lines and are in through arrangement, a test push plate is movably clamped in the limiting grooves, one end of each test push plate is arranged on the outer side of the limiting plate, the other end of each test push plate is connected with an anti-collision test plate, the other end of each test push plate is movably clamped in the corresponding sliding groove, the other is in the corresponding to one side of the corresponding sliding groove, the corresponding to the second sliding groove is connected with the corresponding side of the corresponding sliding groove, the corresponding sliding groove is connected with the corresponding sliding groove, and the other is connected with the corresponding sliding groove is arranged at the end of the corresponding side of the corresponding sliding groove.

3. The device for testing multiple items for glass production according to claim 2, wherein the anti-collision hardness assembly comprises a connecting rod, the lower end of the connecting rod is arranged on the upper wall of a fixed plate I, the upper end of the connecting rod is connected with a connecting plate, the outer side wall of the connecting plate is connected with a supporting seat I, a motor I is arranged on the supporting seat I, the motor I is a reversible motor, the bottom wall of the connecting plate is movably provided with driving rollers, the driving rollers are provided with multiple groups, the multiple groups of driving rollers are uniformly arranged on the bottom wall of the connecting plate at equal intervals, gears are arranged on each group of driving rollers, the gears on each group of driving rollers are identical in size, the gears on the adjacent two groups of driving rollers are meshed and connected, and the output shaft ends of the motor I are connected with the driving rollers on the outermost side.

4. The device for testing a plurality of glass production lines according to claim 3, wherein the driving rollers are provided with a plurality of groups of partition boards, the partition boards are arranged on the driving rollers at intervals, connecting ropes are wound between the side walls of the connecting boards and the partition boards and between the partition boards and the partition boards, winding modes of the connecting ropes on the two adjacent groups of driving rollers are opposite, and the sagging ends of the connecting ropes are connected with test balls.

5. The device for testing multiple items for glass production according to claim 4, wherein the upper wall of the anti-impact test plate is provided with two baffle plates, the two baffle plates are vertically arranged on two adjacent sides of the anti-impact test plate, the inner side walls of the two baffle plates are respectively provided with a rubber cushion layer, the upper wall of the anti-impact test plate is provided with two clamping assemblies, the two clamping assemblies are vertically arranged, and the clamping assemblies and the baffle plates are respectively oppositely arranged.

6. The device for testing multiple items for glass production according to claim 5, wherein the clamping assembly comprises a hydraulic rod, the hydraulic rod is fixedly arranged on the anti-collision test plate, the movable end of the hydraulic rod is connected with a pushing plate, the pushing plate is connected with a connecting piece, the connecting rod is provided with a squeezing plate, and the inner side wall of the squeezing plate is provided with a rubber cushion layer.

7. The apparatus according to claim 6, wherein a pressure sensor is provided in the test piece for measuring compressive hardness.

8. The apparatus of claim 7, wherein a controller is disposed within the base plate, the controller being electrically connected to the pressure sensor, the first motor, the second motor, and the hydraulic lever.

9. The apparatus according to claim 8, wherein the bottom wall of the hardness tester is provided with a pad, the pad is disposed on the bottom plate, and the upper wall of the pad is connected to the bottom wall of the hardness tester.

10. The device for testing glass according to claim 9, wherein a protective cover is movably connected to the outer side of the bottom plate.