CN220583756U - Sealing gasket durability test equipment - Google Patents

Abstract

The application discloses sealing gasket durability test equipment belongs to sealed technical field. The motor is characterized by mainly comprising a mounting plate, wherein one side of the mounting plate is provided with a third motor, and the other side of the mounting plate is provided with a second transmission shaft; the mounting groove is positioned on the other side of the second transmission shaft, a friction piece is arranged on the outer side of the mounting groove, a heat dissipation groove is formed in the friction piece, an auxiliary groove is formed in the outer side of the friction piece, and a positioning groove is formed in one side of the friction piece; the movable groove is positioned at the other side of the second transmission shaft, a spring is arranged in the movable groove, a push plate is arranged at the other side of the spring, a pull plate is arranged at the outer side of the push plate, a damping groove is arranged at the outer side of the pull plate, and a positioning head is arranged at the other side of the push plate; and the toggle groove is positioned at one side of the pull plate. The utility model provides a sealed durability test equipment that fills up reaches can replace second transmission shaft one side and sealed pad to rub, simultaneously through the spiro union of friction piece with the second transmission shaft, can be convenient for rub the piece and dismantle, is convenient for change the friction piece.

Description

Sealing gasket durability test equipment

Technical Field

The application relates to the technical field of sealing, in particular to sealing gasket durability test equipment.

Background

The sealing gasket is also called a sealing ring, is an annular sealing piece made of rubber, and when the sealing gasket is used on a food bottle, the sealing gasket is required to have the conditions of detection and experiment of simulation working conditions because the food in the food bottle is various, the environment is complex and the durability of the sealing ring is very tested.

The prior authorized China utility model bulletin number is: CN218823173U, publication date: 2023-04-07 discloses a durability detection device for production and processing of a food bottle sealing ring, which drives a threaded rod to rotate through the output end of a second motor, so that a T-shaped sliding block which is arranged on the threaded rod in a threaded manner is driven to move in a T-shaped sliding groove, and further drives a mounting plate to move, so that a second transmission shaft is enabled to approach a first transmission shaft until the sealing ring is clamped, and the output ends of the first motor and the second motor rotate to drive a first rotating shaft and a second rotating shaft to rotate, so that sliding friction is generated between the first rotating shaft and the surface of the sealing ring, and further the durability of the sealing ring is detected.

According to the scheme, the sealing gasket is sleeved outside the first rotating shaft, the first rotating shaft and the second rotating shaft are combined, the second rotating shaft rotates and rubs with the sealing gasket, the purpose of detecting the durability of the sealing gasket is achieved, but the sealing gasket is heated to melt in the process of long-time friction between the second rotating shaft and the sealing gasket, and then the sealing gasket is adhered to the second rotating shaft, and the adhered sealing gasket residues influence the subsequent detection of the second rotating shaft.

It is necessary to provide a gasket durability test apparatus to solve the above-described problems.

It should be noted that the above information disclosed in this background section is only for understanding the background of the present application concept and, therefore, it may contain information that does not constitute prior art.

Disclosure of Invention

Based on the above problems existing in the prior art, the problems to be solved by the present application are: the utility model provides a sealed durability test equipment that fills up, reaches to solve the sealed pad residue of adhesion and can influence the follow-up detection problem that carries out of second axis of rotation.

The technical scheme adopted for solving the technical problems is as follows: a gasket durability test apparatus comprising:

the mounting plate is provided with a third motor on one side and a second transmission shaft on the other side;

the mounting groove is positioned on the other side of the second transmission shaft, a friction piece is arranged on the outer side of the mounting groove, a heat dissipation groove is formed in the friction piece, an auxiliary groove is formed in the outer side of the friction piece, and a positioning groove is formed in one side of the friction piece;

the movable groove is positioned at the other side of the second transmission shaft, a spring is arranged in the movable groove, a push plate is arranged at the other side of the spring, a pull plate is arranged at the outer side of the push plate, a damping groove is arranged at the outer side of the pull plate, and a positioning head is arranged at the other side of the push plate;

the toggle groove is positioned on one side of the pull plate, a moving block is arranged in the toggle groove, a locking plate is arranged on one side of the moving block, and a toggle bar is arranged at the upper end of the locking plate.

Further, the mounting groove is arranged as an annular groove, the outer side of the mounting groove penetrates through the second transmission shaft, and the inner wall of the mounting groove is provided with external threads.

Further, the friction piece is arranged to be an annular structure with an L-shaped section, an inner thread is arranged on the inner wall of one side of the friction piece, and the friction piece is in threaded connection with the second transmission shaft.

Further, the friction piece is inside to be annular equidistance and is provided with multiunit heat dissipation groove, and the heat dissipation groove all sets up to vertical strip groove, and the friction piece is all run through to the inside and outside both sides of heat dissipation groove, and the friction piece outside is annular equidistance and is provided with multiunit auxiliary tank, and the auxiliary tank all sets up to horizontal strip groove.

Further, friction piece one side is annular equidistance and is provided with multiunit constant head tank, and the constant head tank all sets up to horizontal columnar groove.

Further, the movable groove is an annular groove with a rectangular section, the outer side of the movable groove penetrates through the second transmission shaft, and a spring is fixedly arranged in the movable groove.

Further, spring opposite side fixedly connected with push pedal, the push pedal sets up to annular structure, push pedal size and movable groove looks adaptation, push pedal outside fixed connection arm-tie, the arm-tie sets up to annular structure, arm-tie internal diameter size and second transmission shaft external diameter looks adaptation, the arm-tie outside transversely is provided with multiunit damping groove, the damping groove all sets up to the ring channel that the cross-section is semicircle, the push pedal opposite side corresponds the constant head tank and is provided with multiunit location head, the location head opposite side all sets up to horizontal columnar structure, the location head opposite side all runs through the movable groove and extends to in the constant head tank.

Further, stir the groove and set up to T type groove, stir the inside activity in groove and be provided with the piece that moves, move the piece and set up to T shape piece, move piece one side and run through and stir the groove, move piece one side fixedly connected with locking plate, the locking plate sets up to arc platelike structure, locking plate one side upper end integrated into one piece has and stir the strip, stir the strip and set up to semicircular arc strip for the cross-section.

Further, the other side of the second transmission shaft is provided with a locking groove corresponding to the locking plate, the locking groove is arranged into an arc-shaped groove, the size of the locking groove is matched with that of the locking plate, and inclined planes are arranged on two sides of the upper end of the locking groove.

The beneficial effects of this application are: the application provides a pair of sealed friction piece that sets up in pad durability test equipment can replace second transmission shaft one side to rub with sealed pad, simultaneously through the spiro union of friction piece with the second transmission shaft, can be convenient for the friction piece dismantle, be convenient for change the friction piece, conveniently follow-up detect, avoid the sealed pad residue of adhesion to influence the follow-up detection that carries out of second axis of rotation, and through the radiating groove that sets up, can be convenient for dispel the heat to the friction piece, reduce the degree that sealed pad was heated and melt.

Through the locating head cooperation constant head tank that sets up, can be convenient for to friction piece locking, avoid friction piece and second transmission shaft separation when rubbing with sealed pad, simultaneously through the arm-tie cooperation push pedal that sets up, can be convenient for separate locating head and constant head tank, be convenient for carry out the change of friction piece.

In addition to the objects, features, and advantages described above, there are other objects, features, and advantages of the present application. The present application will be described in further detail with reference to the drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute an undue limitation to the application. In the drawings:

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic cross-sectional view of a second drive shaft according to the present utility model;

FIG. 3 is a schematic view of the structure of the mounting groove of the present utility model;

FIG. 4 is a schematic view of the friction member of the present utility model;

FIG. 5 is an enlarged schematic view of the structure shown in FIG. 2A;

wherein, each reference sign in the figure:

the device comprises a mounting plate 1, a third motor 2, a second transmission shaft 3, a mounting groove 4, a friction piece 5, a heat dissipation groove 6, an auxiliary groove 7, a positioning groove 8, a movable groove 9, a spring 10, a push plate 11, a pull plate 12, a damping groove 13, a positioning head 14, a toggle groove 15, a moving block 16, a locking plate 17, a toggle bar 18 and a locking groove 19.

Detailed Description

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The present application will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

In order to make the present application solution better understood by those skilled in the art, the following description will be made in detail and with reference to the accompanying drawings in the embodiments of the present application, it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, shall fall within the scope of the present application.

As shown in fig. 1-5, the present application provides a gasket durability test apparatus comprising: the motor comprises a mounting plate 1, wherein one side of the mounting plate is provided with a third motor 2, and the other side of the mounting plate 1 is provided with a second transmission shaft 3; the installation groove 4 is positioned on the other side of the second transmission shaft 3, a friction piece 5 is arranged on the outer side of the installation groove 4, a heat dissipation groove 6 is formed in the friction piece 5, an auxiliary groove 7 is formed in the outer side of the friction piece 5, and a positioning groove 8 is formed in one side of the friction piece 5; the movable groove 9 is positioned at the other side of the second transmission shaft 3, a spring 10 is arranged in the movable groove 9, a push plate 11 is arranged at the other side of the spring 10, a pull plate 12 is arranged at the outer side of the push plate 11, a damping groove 13 is arranged at the outer side of the pull plate 12, and a positioning head 14 is arranged at the other side of the push plate 11; the toggle groove 15 is positioned on one side of the pull plate 12, a moving block 16 is arranged in the toggle groove 15, a locking plate 17 is arranged on one side of the moving block 16, and a toggle bar 18 is arranged at the upper end of the locking plate 17.

As shown in fig. 2-4, the installation groove 4 is provided as an annular groove, the outer side of the installation groove 4 penetrates through the second transmission shaft 3, the inner wall of the installation groove 4 is provided with external threads, the friction piece 5 is provided as an annular structure with an L-shaped section, the inner wall of one side of the friction piece 5 is provided with internal threads, and the friction piece 5 is in threaded connection with the second transmission shaft 3. The friction piece 5 is inside to be annular equidistance and is provided with multiunit heat dissipation groove 6, and heat dissipation groove 6 all sets up to vertical strip groove, and the inside and outside both sides of heat dissipation groove 6 all run through friction piece 5, and the friction piece 5 outside is annular equidistance and is provided with multiunit auxiliary tank 7, and auxiliary tank 7 all sets up to horizontal strip groove. A plurality of groups of positioning grooves 8 are formed in one side of the friction piece 5 at equal intervals in an annular mode, and the positioning grooves 8 are all transverse columnar grooves.

Through the spiro union of friction piece 5 with second transmission shaft 3, can be convenient for carry out dismouting change to friction piece 5, conveniently carry out subsequent detection, simultaneously through the radiating groove 6 that sets up, can dispel the heat to friction piece 5, delay the speed of melting of sealed pad, and through the auxiliary tank 7 that sets up, can be convenient for rotate friction piece 5, improve and change the effect.

As shown in fig. 2-4, the movable groove 9 is an annular groove with a rectangular section, the outer side of the movable groove 9 penetrates through the second transmission shaft 3, and a spring 10 is fixedly arranged in the movable groove 9. The spring 10 opposite side fixedly connected with push pedal 11, push pedal 11 sets up to annular structure, push pedal 11 size and movable groove 9 looks adaptation, push pedal 11 outside fixed connection arm-tie 12, arm-tie 12 sets up to annular structure, arm-tie 12 internal diameter size and the external diameter looks adaptation of second transmission shaft 3, arm-tie 12 outside transversely is provided with multiunit damping groove 13, damping groove 13 all sets up to the ring channel that the cross-section is semicircle, push pedal 11 opposite side corresponds constant head 8 and is provided with multiunit positioning head 14, positioning head 14 all sets up to horizontal columnar structure, the positioning head 14 opposite side all runs through movable groove 9 and extends to in the constant head 8.

Through the spring 10 that sets up, can be convenient for extrude push pedal 11, in the positioning head 14 card of being convenient for goes into constant head tank 8, locks friction member 5, simultaneously through the arm-tie 12 of setting, can be convenient for drive push pedal 11 and remove, through the damping groove 13 of setting, can avoid appearing the hand when removing arm-tie 12 and slide.

As shown in fig. 5, the toggle slot 15 is set as a T-shaped slot, a moving block 16 is movably disposed in the toggle slot 15, the moving block 16 is set as a T-shaped block, one side of the moving block 16 penetrates through the toggle slot 15, one side of the moving block 16 is fixedly connected with a locking plate 17, the locking plate 17 is set as an arc plate-shaped structure, a toggle bar 18 is integrally formed at the upper end of one side of the locking plate 17, and the toggle bar 18 is set as an arc bar with a semicircular section. The other side of the second transmission shaft 3 is provided with a locking groove 19 corresponding to the locking plate 17, the locking groove 19 is an arc-shaped groove, the size of the locking groove 19 is matched with that of the locking plate 17, and two sides of the upper end of the locking groove 19 are provided with inclined planes.

The toggle grooves 15 arranged in the T shape are matched with the moving blocks 16, so that the locking plate 17 and the pulling plate 12 can be prevented from being separated, and the pulling plate 12 can be conveniently fixed through the matching of the locking plate 17 and the locking grooves 19.

When the friction piece 5 is replaced, the pull plate 12 is pulled to one side, the pull plate 12 drives the positioning head 14 to transversely move along the movable groove 9 through the push plate 11, when the locking plate 17 is aligned with the locking groove 19, the positioning head 14 is separated from the positioning groove 8, the positioning head 14 does not limit the friction piece 5 any more, the locking plate 17 is pushed downwards, the locking plate 17 is clamped into the locking groove 19, the pull plate 12 is locked, the friction piece 5 is rotated, the friction piece 5 is enabled to move to the other side until the friction piece 5 is separated from the second transmission shaft 3 through the action of the internal and external threads of the mounting groove 4, one side of the new friction piece 5 is clamped on the mounting groove 4 and rotated, when the friction piece 5 completely enters the mounting groove 4, the replacement is completed, the positioning groove 8 is aligned with the positioning head 14, the locking plate 17 is pulled upwards, the locking plate 17 is not limited to the pull plate 12, the spring 10 pushes the push plate 11 to move through self elastic force, and the positioning head 14 is clamped into the positioning groove 8, and the friction piece 5 is locked.

The foregoing description is only of the preferred embodiments of the present application and is not intended to limit the same, but rather, various modifications and variations may be made by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (9)

1. A gasket durability test apparatus, comprising:

the motor comprises a mounting plate (1), wherein one side of the mounting plate is provided with a third motor (2), and the other side of the mounting plate (1) is provided with a second transmission shaft (3);

the mounting groove (4) is positioned at the other side of the second transmission shaft (3), a friction piece (5) is arranged at the outer side of the mounting groove (4), a heat dissipation groove (6) is formed in the friction piece (5), an auxiliary groove (7) is formed in the outer side of the friction piece (5), and a positioning groove (8) is formed in one side of the friction piece (5);

the movable groove (9) is positioned at the other side of the second transmission shaft (3), a spring (10) is arranged in the movable groove (9), a push plate (11) is arranged at the other side of the spring (10), a pull plate (12) is arranged at the outer side of the push plate (11), a damping groove (13) is arranged at the outer side of the pull plate (12), and a positioning head (14) is arranged at the other side of the push plate (11);

toggle groove (15) is located pulling plate (12) one side, toggle groove (15) inside is provided with moves piece (16), move piece (16) one side and be provided with locking plate (17), locking plate (17) upper end is provided with toggle strip (18).

2. The gasket durability test apparatus according to claim 1, wherein: the mounting groove (4) is arranged to be an annular groove, the outer side of the mounting groove (4) penetrates through the second transmission shaft (3), and the inner wall of the mounting groove (4) is provided with external threads.

3. The gasket durability test apparatus according to claim 2, wherein: the friction piece (5) is of an annular structure with an L-shaped section, an inner thread is arranged on the inner wall of one side of the friction piece (5), and the friction piece (5) is in threaded connection with the second transmission shaft (3).

4. A gasket durability testing apparatus according to claim 3, wherein: the friction piece (5) is inside to be annular equidistance and is provided with multiunit radiating groove (6), radiating groove (6) all set up to vertical strip groove, radiating groove (6) inside and outside both sides all run through friction piece (5), friction piece (5) outside is annular equidistance and is provided with multiunit auxiliary tank (7), auxiliary tank (7) all set up to horizontal strip groove.

5. The gasket durability test apparatus according to claim 1, wherein: the friction piece (5) one side is annular equidistance and is provided with multiunit constant head tank (8), constant head tank (8) all set up to horizontal columnar groove.

6. The gasket durability test apparatus according to claim 1, wherein: the movable groove (9) is an annular groove with a rectangular cross section, the outer side of the movable groove (9) penetrates through the second transmission shaft (3), and the spring (10) is fixedly arranged in the movable groove (9).

7. The gasket durability test apparatus according to claim 6, wherein: the spring (10) opposite side fixedly connected with push pedal (11), push pedal (11) set up to annular structure, push pedal (11) size with movable groove (9) looks adaptation, push pedal (11) outside fixed connection arm-tie (12), arm-tie (12) set up to annular structure, arm-tie (12) internal diameter size with second transmission shaft (3) external diameter looks adaptation, arm-tie (12) outside transversely is provided with multiunit damping groove (13), damping groove (13) all set up to the ring channel that the cross-section is semicircle, push pedal (11) opposite side corresponds constant head (8) are provided with multiunit positioning head (14), positioning head (14) all set up to horizontal columnar structure, positioning head (14) opposite side all runs through movable groove (9) and extends to in constant head (8).

8. The gasket durability test apparatus according to claim 1, wherein: toggle groove (15) set up to T type groove, toggle groove (15) inside activity is provided with move piece (16), move piece (16) and set up to T shape piece, move piece (16) one side and run through toggle groove (15), move piece (16) one side fixedly connected with locking plate (17), locking plate (17) set up to arc platelike structure, locking plate (17) one side upper end integrated into one piece has toggle strip (18), toggle strip (18) set up to the arc strip that the cross-section is semicircle.

9. The gasket durability test apparatus of claim 8, wherein: the other side of the second transmission shaft (3) is provided with a locking groove (19) corresponding to the locking plate (17), the locking groove (19) is an arc-shaped groove, the size of the locking groove (19) is matched with that of the locking plate (17), and inclined planes are arranged on two sides of the upper end of the locking groove (19).