CN117491132A - Cardboard resistance to compression testing arrangement is used in packing box production - Google Patents

Abstract

The invention relates to the technical field of compression resistance testing of packaging box paperboards, in particular to a paperboard compression resistance testing device for packaging box production, which comprises: base, support frame, roof and motor, high-efficient structure includes first threaded rod, the output shaft fixed connection of first threaded rod and motor, first threaded rod surface is through threaded connection has first swivel nut, first swivel nut lateral wall fixedly connected with head rod, head rod bottom fixedly connected with second connecting rod, second connecting rod bottom fixedly connected with pressure plate, base upper end fixedly connected with workstation, first threaded rod bottom fixedly connected with first gear, first gear has first bull stick through tooth meshing. The invention realizes that the test device can automatically perform compression test on the paperboard, and automatically drives the tested paperboard to move out of the space after the test is finished, thereby realizing the automation of the compression test of the paperboard and improving the practicability of the device.

Description

Cardboard resistance to compression testing arrangement is used in packing box production

Technical Field

The invention relates to the technical field of compression resistance testing of packaging box paperboards, in particular to a paperboard compression resistance testing device for packaging box production.

Background

The packing paper box is made of paper products and is used for packing various articles, the compressive strength of the paper box refers to the maximum load and deformation of the box body when dynamic pressure is uniformly applied by a pressure tester, the compressive strength of the paper box is divided into an effective value and a final value, and the paper board compressive testing device is used for testing the compressive property of the paper board.

In this regard, CN202221042594.9 discloses a paperboard compression testing device for packaging box production, which comprises an operation table, wherein a portal frame is fixedly installed on the operation table, an air cylinder is fixedly installed on the portal frame, a pressing plate is fixedly installed at the lower end of the air cylinder, a placing groove is formed in the operation table, a plurality of moving grooves are formed in the side wall of the placing groove, each moving groove is connected with a moving rod in a sliding manner, a control mechanism is installed on the operation table and matched with the moving rods, two containing grooves are formed in the lower end of the pressing plate, pressing blocks are connected onto the two containing grooves in a sliding manner, an adjusting mechanism is installed on the pressing plate, and the adjusting mechanism is matched with the two pressing blocks.

When the existing device is used for testing the compression resistance of the paperboards, the paperboards cannot be automatically driven to carry out the compression resistance test, and the tested paperboards cannot be automatically recovered after the test is finished, so that the compression resistance test efficiency of the paperboards is affected.

Therefore, in order to solve the above problems, a device for testing the compression resistance of the paperboard for producing the packaging box is provided.

Disclosure of Invention

The invention aims to provide a paperboard compression test device for producing packaging boxes, which solves the problems that the paperboard compression test device for producing packaging boxes cannot automatically drive a paperboard to perform compression test in the compression test of the paperboard provided in the background art, and the tested paperboard cannot be automatically recovered after the test is finished, so that the compression test efficiency of the paperboard is affected.

In order to achieve the above purpose, the present invention provides the following technical solutions: a paperboard compression testing device for packaging box production, comprising: the device comprises a base, a support frame, a top plate and a motor;

the efficient structure comprises a first threaded rod, the output shaft fixed connection of first threaded rod and motor, first threaded rod surface is through the first swivel nut of threaded connection, first swivel nut lateral wall fixedly connected with head rod, head rod bottom fixedly connected with second connecting rod, second connecting rod bottom fixedly connected with pressure plate, base upper end fixedly connected with workstation, first threaded rod bottom fixedly connected with first gear, first gear has first bull stick through tooth meshing, the one end that first gear was kept away from to first bull stick is inserted and is established inside the slot, the slot is seted up inside the support frame, and first bull stick can be at the inside rotation of slot, first bull stick surface is connected with the second bull stick through tooth meshing, the second bull stick surface is connected with the second gear through tooth meshing, the one end fixedly connected with second threaded rod of the second bull stick that the second gear kept away from, the second surface is through threaded connection second swivel nut lateral wall fixedly connected with first gear, the third connecting rod is kept away from to the second bull stick, the third connecting rod is connected with the connecting rod fixedly connected with fourth connecting rod, fifth connecting rod is provided with connecting rod, fifth connecting rod fixedly connected with connecting rod between the cardboard lateral wall.

Preferably, the first stop lever is fixedly connected with the rear end of the first screw sleeve, the first stop lever is inserted into the first stop groove, and the first stop groove is formed in the support frame.

Preferably, the second bull stick lateral wall fixedly connected with stopper, the stopper is inserted and is established inside the second spacing groove, the second spacing groove is seted up inside the base.

Preferably, the second stop lever is fixedly connected with the side wall of the second screw sleeve, one end, far away from the second screw sleeve, of the second stop lever is inserted into the support frame, and the second stop lever can move in the support frame.

Preferably, the first movable block of limit splint lateral wall fixedly connected with, the one end that limit splint was kept away from to first movable block inserts and establishes in first inserting the intracavity portion, first inserting the intracavity portion of seting up in fifth connecting rod is inside, the one end fixedly connected with first spring that limit splint was kept away from to first movable block, the one end fixedly connected with at first movable block inner wall that first movable block was kept away from to first spring.

Preferably, the first sliding block is fixedly connected to the side wall of the first moving block, the first sliding block is inserted into the first sliding groove, and the first sliding groove is formed in the fifth connecting rod.

Preferably, the limit cavity has been seted up to the workstation inside, limit cavity inside has been inserted and has been equipped with packing box cardboard, limit cavity inside is provided with the rubber piece, the one end fixedly connected with second movable block that the packing box cardboard was kept away from to the rubber piece, the one end that the rubber piece was kept away from to the second movable block is inserted and is established at the second and insert the intracavity portion, the second is inserted the cavity and is seted up inside the workstation, the one end fixedly connected with second spring that the rubber piece was kept away from to the second movable block, the one end fixedly connected with that the second movable block was kept away from to the second spring is inserted the intracavity wall at the second.

Preferably, the rubber block is made of rubber, and one end of the rubber block, which is close to the paperboard of the packaging box, is provided with anti-skid patterns.

Preferably, the side wall of the second moving block is fixedly connected with a second sliding block, the second sliding block is inserted into a second sliding groove, and the second sliding groove is formed in the workbench.

Compared with the prior art, the invention has the beneficial effects that: when the compression test of the packing box paperboard is needed, firstly, placing the packing box paperboard in the container; the automatic test device comprises a first threaded rod, a second threaded rod, a first connecting rod, a second threaded rod, a third connecting rod, a fourth connecting rod, a fifth connecting rod, a limiting cavity, a pressure plate and a paper board.

Drawings

FIG. 1 is a schematic elevational cross-sectional view of the structure of the present invention;

FIG. 2 is a schematic cross-sectional view of a structural test according to the present invention;

FIG. 3 is an enlarged schematic view of the structure A in FIG. 2 according to the present invention;

FIG. 4 is an enlarged schematic view of the structure of FIG. 2B according to the present invention;

FIG. 5 is an enlarged schematic view of the structure of FIG. 2 at C in accordance with the present invention;

FIG. 6 is an enlarged schematic view of the structure of FIG. 1 at D in accordance with the present invention;

fig. 7 is an enlarged schematic view of the structure at E in fig. 2 according to the present invention.

In the figure: 1. a base; 21. a support frame; 22. a top plate; 23. a motor; 3. an efficient structure; 31. a first threaded rod; 32. a first screw sleeve; 33. a first connecting rod; 34. a second connecting rod; 35. a pressure plate; 36. a work table; 38. a first gear; 39. a first rotating lever; 41. a slot; 42. a second rotating rod; 43. a second gear; 44. a second threaded rod; 45. a second screw sleeve; 46. a third connecting rod; 47. a fourth connecting rod; 48. a fifth connecting rod; 49. limiting clamping plates; 51. packaging the paper board; 52. a first stop lever; 53. a first limit groove; 54. a second limit rod; 55. a first moving block; 56. a first insertion cavity; 57. a first spring; 58. a first slider; 59. a first chute; 61. a rubber block; 62. a second moving block; 63. a second insertion cavity; 64. a second spring; 65. a second slider; 66. a second chute; 67. a spacing cavity; 68. a limiting block; 69. and the second limit groove.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. 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.

Referring to fig. 1-7, an embodiment of the present invention is provided:

a paperboard compression testing device for packaging box production, comprising: the base 1, the support frame 21, the top plate 22 and the motor 23;

the efficient structure 3, the efficient structure 3 includes first threaded rod 31, the output shaft fixed connection of first threaded rod 31 and motor 23, first threaded rod 31 surface is through threaded connection first swivel nut 32, first swivel nut 32 lateral wall fixedly connected with head rod 33, head rod 33 bottom fixedly connected with second connecting rod 34, second connecting rod 34 bottom fixedly connected with pressure plate 35, base 1 upper end fixedly connected with workstation 36, first threaded rod 31 bottom fixedly connected with first gear 38, first gear 38 has first bull stick 39 through tooth meshing, first bull stick 39 is kept away from the one end of first gear 38 and is inserted in slot 41 inside, slot 41 sets up in support frame 21 inside, and first bull stick 39 can rotate in slot 41 inside, first bull stick 39 surface is connected with second bull stick 42 through tooth meshing, the one end fixedly connected with second threaded rod 44 that second bull stick 42 kept away from, second bull stick 44 surface is through threaded connection second swivel nut 45, second bull stick 45 lateral wall 45 fixedly connected with third connecting rod 46, fourth connecting rod 46 is connected with fourth connecting rod 47, fifth connecting rod 48 is fixedly connected with spacing cardboard 47 inside, fifth connecting rod 48 is connected with connecting rod 48 inside, fifth connecting rod 48 is connected with fifth connecting rod 47 inside the spacing cardboard 47.

Further, the first stop lever 52 is fixedly connected to the rear end of the first threaded sleeve 32, the first stop lever 52 is inserted into the first stop groove 53, the first stop groove 53 is formed in the support frame 21, through the design, under the action of threads, the first threaded sleeve 32 synchronously moves, and meanwhile, the first stop lever 52 synchronously moves in the first stop groove 53, so that the stop effect on the first threaded sleeve 32 is achieved, and the first threaded sleeve 32 is prevented from synchronously rotating along with the first threaded rod 31.

Further, the stopper 68 is fixedly connected with the side wall of the second rotating rod 42, the stopper 68 is inserted into the second limiting groove 69, the second limiting groove 69 is formed in the base 1, through the design, when the second rotating rod 42 rotates, the stopper 68 synchronously rotates in the second limiting groove 69, the second rotating rod 42 and the stopper 68 form a T-shaped structure, the limiting effect on the second rotating rod 42 is achieved, and the second rotating rod 42 rotates more stably in the base 1.

Further, the second stop lever 54 is fixedly connected with the side wall of the second threaded sleeve 45, one end, away from the second threaded sleeve 45, of the second stop lever 54 is inserted into the support frame 21, the second stop lever 54 can move inside the support frame 21, through the design, the second threaded sleeve 45 synchronously moves under the action of threads, at the moment, the second stop lever 54 synchronously moves inside the support frame 21, the limiting effect on the second stop lever 54 is achieved, and the problem that the second stop lever 54 synchronously rotates along with the second threaded rod 44 and cannot synchronously move is avoided.

Further, the first movable block 55 of limit splint 49 lateral wall fixedly connected with, the one end that limit splint 49 was kept away from to first movable block 55 inserts and establishes in first inserting cavity 56 inside, first inserting cavity 56 is seted up inside fifth connecting rod 48, the one end fixedly connected with first spring 57 that limit splint 49 was kept away from to first movable block 55, the one end fixedly connected with at first movable block 55 inner wall that first spring 57 kept away from first movable block 55, through this design, elastic deformation takes place for first spring 57, drive first movable block 55 and remove, make limit splint 49 carry out stable centre gripping to packing box cardboard 51, make it keep stable between two sets of limit splint 49.

Further, the first sliding block 58 is fixedly connected to the side wall of the first moving block 55, the first sliding block 58 is inserted into the first sliding groove 59, the first sliding groove 59 is formed in the fifth connecting rod 48, through the design, when the first moving block 55 moves, the first sliding block 58 synchronously moves in the first sliding groove 59, so that the limiting effect on the first moving block 55 is achieved, the movement of the first moving block 55 is more stable, and the stability of the device is improved.

Further, the limiting cavity 67 is formed in the workbench 36, the packing box paperboard 51 is inserted in the limiting cavity 67, the rubber block 61 is arranged in the limiting cavity 67, one end, away from the packing box paperboard 51, of the rubber block 61 is fixedly connected with the second moving block 62, one end, away from the rubber block 61, of the second moving block 62 is inserted into the second inserting cavity 63, the second inserting cavity 63 is formed in the workbench 36, one end, away from the rubber block 61, of the second moving block 62 is fixedly connected with the second spring 64, one end, away from the second moving block 62, of the second spring 64 is fixedly connected to the inner wall of the second inserting cavity 63, through the design, the second spring 64 is elastically deformed, the second moving block 62 is driven to move, and further the rubber block 61 is driven to synchronously move, so that two groups of rubber blocks 61 limit and clamp the packing box paperboard 51, and two ends of the packing box paperboard 51 are kept stable during compression test.

Further, the rubber block 61 is made of rubber, and the anti-skid patterns are formed in one end, close to the packing box paperboard 51, of the rubber block 61, and through the design, the rubber block 61 is made of rubber, so that friction force between the rubber block 61 and the packing box paperboard 51 is increased, and the packing box paperboard 51 is clamped by the rubber block 61 more stably.

Further, the second sliding block 65 is fixedly connected to the side wall of the second moving block 62, the second sliding block 65 is inserted into the second sliding groove 66, the second sliding groove 66 is formed in the workbench 36, through the design, when the second moving block 62 moves, the second sliding block 65 synchronously moves in the second sliding groove 66, so that the limiting effect on the second moving block 62 is achieved, the movement of the second sliding block is more stable, and the stability of the device is improved.

Working principle:

when the compression test of the paperboard of the packing case is required, the paperboard 51 of the packing case is firstly placed; the switch is then opened between the two groups of limit clamping plates 49, the motor 23 starts to work, the first threaded rod 31 is driven to rotate, under the action of threads, the first threaded rod 32 synchronously moves downwards, simultaneously the first limit rod 52 synchronously moves in the first limit groove 53, the limit effect on the first threaded rod 32 is realized, the first threaded rod 32 is prevented from synchronously rotating along with the first threaded rod 31, the first connecting rod 33 is driven to synchronously move downwards, then the second connecting rod 34 synchronously moves downwards, finally the pressure plate 35 is driven to synchronously move downwards, simultaneously, the first gear 38 and the first rotating rod 39 are driven to synchronously rotate under the action of tooth meshing on the surfaces of the first gear 38 and the second rotating rod 42, the second rotating rod 42 is driven to synchronously rotate under the action of tooth meshing on the surfaces of the first rotating rod 39 and the second rotating rod 42, when the second rotating rod 42 synchronously rotates, the limit block 68 synchronously rotates in the second limit groove 69, the limit effect on the second rotating rod 42 is realized, the second rotating rod 42 is enabled to rotate more stably in the base 1, the second rotating rod 42 is driven to synchronously rotate along with the second threaded rod 33, then the second rotating rod 45 is driven to synchronously move along with the second rotating rod 54, the second rotating rod 45 is driven to synchronously move along with the second rotating rod 54, and then the second rotating rod 54 is driven to synchronously move, and the second rotating rod 54 is prevented from synchronously moving along with the second rotating groove, the second rotating rod 54 is driven to synchronously, the second rotating rod is deformed, the second rotating rod is driven to synchronously, the second rotating rod is rotated and the second rotating, the second rotating rod is stably rotates is stably and the rotating, the first moving block 55 is driven to move, the limiting clamping plates 49 are used for stably clamping the packing box paper plates 51, the limiting clamping plates 49 are used for keeping the packing box paper plates 51 stable between the two groups of limiting clamping plates 49, the packing box paper plates 51 enter the limiting cavity 67, the pressure plate 35 moves downwards to perform compression resistance test on the paper plates, after the test is finished, the motor 23 rotates reversely, the first threaded rod 31 rotates synchronously, the first threaded sleeve 32 is driven to move upwards synchronously under the action of threads, the pressure plate 35 is driven to return to the original position finally, meanwhile, the limiting clamping plates 49 drive the packing box paper plates 51 to return to the original position under the reverse rotation action of the motor 23, and the compression resistance test for replacing another group of paper plates can be performed, so that the operation is finished;

it will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. A paperboard compression testing device for packaging box production, comprising: the device is characterized by comprising a base (1), a support frame (21), a top plate (22) and a motor (23);

the high-efficiency structure (3), the high-efficiency structure (3) comprises a first threaded rod (31), output shaft fixed connection of first threaded rod (31) and motor (23), first threaded rod (31) surface is through threaded connection first swivel nut (32), first swivel nut (32) lateral wall fixedly connected with head rod (33), head rod (33) bottom fixedly connected with second connecting rod (34), second connecting rod (34) bottom fixedly connected with pressure plate (35), base (1) upper end fixedly connected with workstation (36), first threaded rod (31) bottom fixedly connected with first gear (38), first gear (38) have first bull stick (39) through tooth meshing, the one end that first bull stick (39) kept away from first gear (38) is inserted in slot (41) inside, slot (41) are seted up inside support frame (21), and head rod (39) can rotate in slot (41) inside, first bull stick (39) surface is connected with second gear (42) through tooth meshing, second end (42) have second end fixed connection second gear (42) through tooth meshing of second threaded rod (42), the surface of the second threaded rod (44) is connected with a second threaded sleeve (45) through threads, the side wall of the second threaded sleeve (45) is fixedly connected with a third connecting rod (46), the side wall of the third connecting rod (46) is fixedly connected with a fourth connecting rod (47), the side wall of the fourth connecting rod (47) is fixedly connected with a fifth connecting rod (48), a limiting clamp plate (49) is arranged inside the fifth connecting rod (48), and a packing box paperboard (51) is clamped between the limiting clamp plates (49).

2. The paperboard compression testing device for packaging box production according to claim 1, wherein: the novel screw nut is characterized in that the rear end of the first screw sleeve (32) is fixedly connected with a first limiting rod (52), the first limiting rod (52) is inserted into a first limiting groove (53), and the first limiting groove (53) is formed in the supporting frame (21).

3. The paperboard compression testing device for packaging box production according to claim 1, wherein: the side wall of the second rotating rod (42) is fixedly connected with a limiting block (68), the limiting block (68) is inserted into a second limiting groove (69), and the second limiting groove (69) is formed in the base (1).

4. The paperboard compression testing device for packaging box production according to claim 1, wherein: the side wall of the second screw sleeve (45) is fixedly connected with a second limiting rod (54), one end, far away from the second screw sleeve (45), of the second limiting rod (54) is inserted into the supporting frame (21), and the second limiting rod (54) can move in the supporting frame (21).

5. The paperboard compression testing device for packaging box production according to claim 1, wherein: the utility model discloses a spacing splint, including spacing splint (49) lateral wall fixedly connected with first movable block (55), the one end that spacing splint (49) was kept away from to first movable block (55) is inserted and is established inside first chamber (56) of inserting, first chamber (56) of inserting is seted up inside fifth connecting rod (48), the one end fixedly connected with first spring (57) that spacing splint (49) was kept away from to first movable block (55), the one end fixedly connected with at first movable block (55) inner wall that first movable block (55) was kept away from to first spring (57).

6. The paperboard compression testing device for packaging box production according to claim 5, wherein: the side wall of the first moving block (55) is fixedly connected with a first sliding block (58), the first sliding block (58) is inserted into a first sliding groove (59), and the first sliding groove (59) is formed in a fifth connecting rod (48).

7. The paperboard compression testing device for packaging box production according to claim 1, wherein: spacing chamber (67) has been seted up to workstation (36) inside, spacing chamber (67) inside is inserted and is equipped with packing box cardboard (51), spacing chamber (67) inside is provided with rubber piece (61), one end fixedly connected with second movable block (62) that packing box cardboard (51) was kept away from to rubber piece (61), one end that rubber piece (61) was kept away from to second movable block (62) is inserted and is established in second insert chamber (63) inside, second insert chamber (63) are seted up inside workstation (36), one end fixedly connected with second spring (64) that rubber piece (61) was kept away from to second movable block (62), one end fixedly connected with at second insert chamber (63) inner wall that second movable block (62) was kept away from to second spring (64).

8. The paperboard compression testing device for packaging box production as recited in claim 7, wherein: the rubber block (61) is made of rubber, and one end of the rubber block (61) close to the packing box paperboard (51) is provided with anti-skid patterns.

9. The paperboard compression testing device for packaging box production as recited in claim 7, wherein: the side wall of the second moving block (62) is fixedly connected with a second sliding block (65), the second sliding block (65) is inserted into a second sliding groove (66), and the second sliding groove (66) is formed in the workbench (36).