CN214842893U - Synchronizing wheel installing support - Google Patents

Abstract

The utility model discloses a synchronizing wheel mounting bracket, which comprises an extension arm, a sliding component sliding on the extension arm and two rolling bearings arranged on the sliding component, wherein the two ends of the extension arm are respectively provided with a mounting shaft and a sliding rail, the sliding rail is provided with two parallel sliding chutes, a support rod is arranged between the two sliding chutes, and the sliding component is arranged on the sliding rail; the sliding assembly comprises sliding plates which are symmetrically arranged on two sides of the sliding rail, the two sliding plates are connected together through a connecting cylinder, the connecting cylinder penetrates through the sliding groove and is sleeved on the supporting rod, the sliding plates and the sliding rail are fixedly connected through movable screws, and a plurality of mounting holes for mounting the movable screws are formed in the sliding rail. The utility model is provided with symmetrical rotating bearings on the extension arm installed on the mobile woman, thereby realizing the synchronous rotation of the wheel body driven by the two bearings, reducing the distortion caused by the coaxiality and improving the measuring and calculating precision; and the height of the wheel body on the support is easy to adjust, so that the operation difficulty is reduced.

Description

Synchronizing wheel installing support

Technical Field

The utility model relates to a mounting bracket technical field, concretely relates to synchronizing wheel installing support.

Background

When a gypsum board is produced, the length of the gypsum board after a pressing plate needs to be measured, a synchronizing wheel is arranged on a movable roller, when the movable roller moves above the gypsum board, the synchronizing wheel rolls on the surface of the gypsum board, and a manufacturer calculates the length of the gypsum board by measuring the number of rolling circles of the synchronizing wheel. When the length is measured, the comparison wheel of one wheel body and the comparison wheel of the other wheel body can better measure the length of the gypsum board through the error of the two wheel bodies, so that the two wheel bodies need to be consistent in size and consistent in rotating speed.

The existing synchronizing wheel generally adopts a welding or casting integrated design, two wheel bodies are connected together through the same shaft rod, the pitch is changed if the existing synchronizing wheel is used for a long time, the use of the existing synchronizing wheel and the shaft rod is influenced, and errors are caused in measurement and calculation. In the production process, the final setting time of some gypsum boards is long, the height of the synchronizing wheel needs to be adjusted in order to prevent the synchronizing wheel from pressing the gypsum boards out of creases, but the existing synchronizing wheel mounting bracket is complex and heavy in structure, is not easy to adjust and is not beneficial to production.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a synchronizing wheel installing support to solve among the prior art coaxial installing support easy deformation, and the highly difficult technical problem who adjusts of synchronizing wheel.

In order to solve the above technical problem, the utility model particularly provides the following technical scheme:

the utility model provides a synchronizing wheel mounting bracket, which comprises an extension arm, a sliding component sliding on the extension arm, and two rolling bearings mounted on the sliding component, wherein mounting shafts and sliding rails are respectively mounted at two ends of the extension arm, the mounting shafts are sleeved on a movable groove, two parallel sliding grooves are arranged on the sliding rails, a supporting rod is arranged between the two sliding grooves, and the sliding component is mounted on the sliding rails;

the sliding assembly comprises sliding plates which are symmetrically arranged on two sides of the sliding rail, the two sliding plates are connected together through a connecting cylinder, the connecting cylinder penetrates through the sliding chute and is sleeved on the supporting rod, the shape of the sliding chute is matched with that of the connecting cylinder, the sliding plates are fixedly connected with the sliding rail through movable screws, and a plurality of mounting holes for mounting the movable screws are formed in the sliding rail;

the sliding plate is connected with a rotary bearing used for mounting the wheel body through an L-shaped connecting plate.

As a preferred scheme of the utility model, the support rod rotates on the slide rail; one end of the supporting rod is connected with the inner side of the sliding rail through a deep groove ball bearing, the other end of the supporting rod penetrates through the connecting cylinder and is installed at the tail end of the sliding rail, a rotating thread is arranged on the surface of the supporting rod, and a thread groove matched with the rotating thread is formed in the connecting cylinder.

As an optimized scheme of the utility model, the end of bracing piece is passed the sliding rail connection has the dwang.

As an optimized scheme of the utility model, the side of L type connecting plate is installed through a plurality of rows of installation screw on the slide, the multirow the installation screw evenly sets up L type connecting plate with on the slide, L type connecting plate lower extreme through the antidetonation board with rolling bearing connects.

As a preferred scheme of the utility model, the antidetonation board includes fixed mounting and is in the first fagging of L type connecting plate lower extreme, first fagging has the second fagging through antidetonation spring coupling, the second fagging with rolling bearing fixed connection.

As a preferred scheme of the utility model, rolling bearing includes that vertical the installation is in first baffle on the second fagging, the centre of a circle of first baffle is connected with the second baffle through the axostylus axostyle, the axostylus axostyle transversely sets up first baffle with between the second baffle, install the sleeve through a plurality of rotary columns on the axostylus axostyle outer wall, the sleeve is in first baffle with rotate between the second baffle, the rotary column is in the sleeve with rotate between the axostylus axostyle.

Compared with the prior art, the utility model following beneficial effect has:

1. the symmetrical rotating bearings are arranged on the extension arm arranged on the movable woman, the wheel bodies are respectively arranged on the rotating bearings, so that the wheel bodies can synchronously rotate under the driving of the two bearings, the rotating shafts of the wheel bodies are not easily influenced with each other, the distortion caused by coaxiality is reduced, the distance can be better kept, and the measuring and calculating precision is improved;

2. the extension arm which is obliquely arranged is provided with the sliding plate through a screw, the rotating bearing is arranged on the sliding plate, the distance between the wheel body and the gypsum board is adjusted by moving the position of the screw, the height of the wheel body is easy to adjust, and the operation difficulty is reduced;

3. the two symmetrical sliding plates penetrate through the sliding rail arranged on the extension arm through the connecting cylinder, so that the symmetry is kept, and the structure is stable.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

Fig. 1 is a schematic structural view of a synchronizing wheel mounting bracket according to an embodiment of the present invention;

fig. 2 is a schematic view of a partial structure of a side surface of a synchronizing wheel mounting bracket according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a rotary bearing according to an embodiment of the present invention.

The reference numerals in the drawings denote the following, respectively:

1-an extension arm; 2-a sliding assembly; 3-a rotating bearing; 4, mounting a shaft; 5-a slide rail; 6-a chute; 7-a support bar; 8-mounting holes; 9-L-shaped connecting plates; 10-deep groove ball bearing; 11-turning the thread; 12-rotating rods; 13-mounting screws; 14-anti-seismic plates;

201-a slide plate; 202-a connecting cylinder; 203-moving screws; 301-a first baffle; 302-shaft rod; 303-a second baffle; 304-rotating column; 305-a sleeve; 1401-a first spreader; 1402-anti-seismic spring; 1403-second spreader.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1 to 3, the utility model provides a synchronizing wheel installing support, including extension arm 1 gliding sliding assembly 2 on the extension arm 1, and two are installed rolling bearing 3 on the sliding assembly 2, installation axle 4 and slide rail 5 are installed respectively to the both ends of extension arm 1, installation axle 4 cup joints on removing the woman, be provided with two parallel spouts 6 on the slide rail 5, two be provided with bracing piece 7 between the spout 6, sliding assembly 2 installs on the slide rail 5.

Installation axle 4 cup joints on removing the kun, and extension arm 1 slope sets up between removing kun and the gypsum board body, and the wheel body is installed on rolling bearing 3, when removing the kun removal, drives extension arm 1, sliding component 2 and rolling bearing 3 and removes, and the wheel body rolls on the gypsum board. The wheel bodies are respectively arranged on the two synchronous rotating bearings 3, so that the distortion caused by coaxiality can be reduced, the probability of mutual influence is reduced, and the service life of the device is prolonged.

Specifically, the sliding member 2 can slide on the inclined extension arm 1, when the sliding member 2 slides towards one end of the mounting shaft 4, the height of the sliding member 2 increases, the distance between the wheel body and the gypsum board increases, and when the sliding member 2 slides in the opposite direction, the height of the sliding member 2 decreases, and the distance between the wheel body and the gypsum board decreases.

The present invention shows a sliding assembly 2 having two embodiments.

Example 1:

the sliding assembly 2 comprises sliding plates 201 symmetrically arranged on two sides of a sliding rail 5, the two sliding plates 201 are connected together through a connecting cylinder 202, the connecting cylinder 202 penetrates through a sliding groove 6 and is sleeved on a supporting rod 7, the shape of the sliding groove 6 is matched with that of the connecting cylinder 202, the sliding plates 201 are fixedly connected with the sliding rail 5 through a movable screw 203, a plurality of mounting holes 8 for mounting the movable screw 203 are formed in the sliding rail 5, and a thread groove matched with the movable screw 203 is formed in each mounting hole 8.

The sliding plate 201 is connected with the rotary bearing 3 for mounting the wheel body through an L-shaped connecting plate 9.

In this embodiment, the connecting cylinder 202 slides inside the sliding slot 6, slides on the outer wall of the supporting rod 7, and positions the sliding plate 201 by detaching the moving screw 203, and the two sliding plates 201 are connected together by the connecting cylinder 202 penetrating through the sliding rail 5, which is beneficial to maintaining symmetry and stable structure. When the device is used, the optimal distance between the wheel body and the gypsum board is measured in advance, the wheel body is prevented from extruding the gypsum board, and the position of the movable screw 203 is adjusted, so that the distance between the wheel body and the gypsum board is the optimal distance.

Example 2:

the supporting rod 7 rotates on the sliding rail 5; one end of the supporting rod 7 is connected with the inner part of the sliding rail 5 through the deep groove ball bearing 10, the other end of the supporting rod 7 penetrates through the connecting cylinder 202 and is installed at the tail end of the sliding rail 5, the surface of the supporting rod 7 is provided with a rotating thread 11, and a thread groove matched with the rotating thread 11 is formed in the connecting cylinder 202.

In this embodiment, the connecting cylinder 202 slides inside the sliding slot 6, the inner wall of the connecting cylinder 202 is in threaded connection with the outer wall of the supporting rod 7, and when the supporting rod 7 rotates, the connecting cylinder 202 slides inside the sliding slot 6 under the driving of the rotating thread 11. The optimal distance of wheel body and gypsum board is measured in advance when using, prevents that the wheel body from producing the extrusion to the gypsum board, and the bracing piece 7 is rotated again, adjusts the position of slide 201 for the distance between wheel body and the gypsum board at this moment is the optimal distance. Compared with a common structure, the sliding structure is simple to operate, does not need to disassemble any part, and saves time.

Preferably, the tail end of the supporting rod 7 penetrates through the sliding rail 5 to be connected with a rotating rod 12. When the wheel body height control device is used, the protruding rotating rod 12 is rotated, so that the wheel body height can be controlled, and the operation difficulty is reduced.

The height of the slide plate 201 raised above the extension arm 1 is limited, and if the height of the gypsum board changes significantly, it is necessary to correct the height by another lifting mechanism.

Therefore, in this embodiment, the side surface of the L-shaped connecting plate 9 is mounted on the sliding plate 201 through a plurality of rows of mounting screws 13, the plurality of rows of mounting screws 13 are uniformly arranged on the L-shaped connecting plate 9 and the sliding plate 201, and the lower end of the L-shaped connecting plate 9 is connected with the rotary bearing 3 through the anti-vibration plate 14. The mounting screws 13 can be detached, and when the height needs to be adjusted, the corresponding relation between the mounting screws 13 and the mounting holes is changed, so that the height of the wheel body can be changed.

In this embodiment, the wheel body is liable to collide with the protrusions on the gypsum board when rotating, and the generated vibration is liable to affect the service life of the components in the sliding structure and the lifting structure, so it is necessary to provide the anti-vibration plate 14 between the L-shaped connecting plate 9 and the rotary bearing 3, where the anti-vibration plate 14 includes a first supporting plate 1401 fixedly installed at the lower end of the L-shaped connecting plate 9, the first supporting plate 1401 is connected to a second supporting plate 1403 through an anti-vibration spring 1402, and the second supporting plate 1403 is fixedly connected to the rotary bearing 3.

In this embodiment, in order to ensure the smoothness of the wheel rotation, the specific structure of the rotation bearing 3 is as follows: the rotating bearing 3 comprises a first baffle 301 vertically mounted on the second supporting plate 1403, the center of the first baffle 301 is connected with a second baffle 303 through a shaft 302, the shaft 302 is transversely arranged between the first baffle 301 and the second baffle 303, a sleeve 305 is mounted on the outer wall of the shaft 302 through a plurality of rotating columns 304, the sleeve 305 rotates between the first baffle 301 and the second baffle 303, and the rotating columns 304 rotate between the sleeve 305 and the shaft 302.

When the wheel body is used, the wheel body is arranged on the sleeve 305 and rotates along with the sleeve 305, and the two ends of the wheel body are limited by the baffle plates and are not prone to shifting.

The synchronous wheel mounting bracket of the embodiment can realize synchronous rotation of the synchronous wheel driven by two bearings, the rotating shafts of the synchronous wheel are not easy to influence each other, the distance can be better kept, and the measuring and calculating precision is improved; and the distance between the wheel body and the gypsum board is conveniently adjusted, and the operation difficulty is reduced.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims (6)

1. The synchronous wheel mounting bracket is characterized by comprising an extension arm (1), a sliding assembly (2) sliding on the extension arm (1) and two rotating bearings (3) mounted on the sliding assembly (2), wherein a mounting shaft (4) and a sliding rail (5) are respectively mounted at two ends of the extension arm (1), the mounting shaft (4) is sleeved on a moving groove, two parallel sliding grooves (6) are formed in the sliding rail (5), a supporting rod (7) is arranged between the two sliding grooves (6), and the sliding assembly (2) is mounted on the sliding rail (5);

the sliding assembly (2) comprises sliding plates (201) symmetrically arranged on two sides of the sliding rail (5), the two sliding plates (201) are connected together through a connecting cylinder (202), the connecting cylinder (202) penetrates through the sliding chute (6) and is sleeved on the supporting rod (7), the shape of the sliding chute (6) is matched with that of the connecting cylinder (202), the sliding plates (201) are fixedly connected with the sliding rail (5) through movable screws (203), and a plurality of mounting holes (8) for mounting the movable screws (203) are formed in the sliding rail (5);

the sliding plate (201) is connected with a rotary bearing (3) for mounting the wheel body through an L-shaped connecting plate (9).

2. A synchronizer wheel mounting bracket according to claim 1, characterized in that the support rod (7) rotates on the slide rail (5); one end of the supporting rod (7) is connected with the inner part of the sliding rail (5) through a deep groove ball bearing (10), the other end of the supporting rod (7) penetrates through the connecting cylinder (202) and is installed at the tail end of the sliding rail (5), the supporting rod (7) is provided with a rotating thread (11) on the surface, and a thread groove matched with the rotating thread (11) is formed in the connecting cylinder (202).

3. A synchronising wheel mounting bracket according to claim 2, characterised in that the end of the support rod (7) is connected to a turning rod (12) through the slide rail (5).

4. A synchronous wheel mounting bracket according to claim 3, characterized in that the side of the L-shaped connecting plate (9) is mounted on the sliding plate (201) through a plurality of rows of mounting screws (13), a plurality of rows of the mounting screws (13) are uniformly arranged on the L-shaped connecting plate (9) and the sliding plate (201), and the lower end of the L-shaped connecting plate (9) is connected with the rotary bearing (3) through a shock-proof plate (14).

5. A synchronous wheel mounting bracket according to claim 4, characterized in that the anti-vibration plate (14) comprises a first stay plate (1401) fixedly mounted at the lower end of the L-shaped connecting plate (9), the first stay plate (1401) is connected with a second stay plate (1403) through an anti-vibration spring (1402), and the second stay plate (1403) is fixedly connected with the rotary bearing (3).

6. A synchronizer wheel mounting bracket according to claim 5, characterized in that the rotary bearing (3) comprises a first baffle (301) vertically mounted on the second stay plate (1403), the center of the first baffle (301) is connected with a second baffle (303) through a shaft (302), the shaft (302) is transversely arranged between the first baffle (301) and the second baffle (303), a sleeve (305) is mounted on the outer wall of the shaft (302) through a plurality of rotary columns (304), the sleeve (305) rotates between the first baffle (301) and the second baffle (303), and the rotary columns (304) rotate between the sleeve (305) and the shaft (302).

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