CN220411730U - Feeding mechanism for processing caster main body - Google Patents

Abstract

The utility model discloses a feeding mechanism for processing a caster body, which relates to the technical field of caster processing and comprises a lifting assembly and an adjusting assembly, wherein the lifting assembly comprises a shell, a driving motor, a driving sprocket, a chain belt, a driven sprocket I, a driven sprocket II, a driven sprocket III, a supporting plate, a supporting frame and rollers, the driving motor is arranged at the rear end of the shell, the output end of the driving motor penetrates through the rear end of the shell through a driving shaft to be connected with the driving sprocket, and the chain belt is connected to the outside of the driving sprocket. The feeding mechanism driving motor for processing the caster body drives the driving shaft and the driving sprocket to rotate, the driving sprocket drives the driven sprocket I, the driven sprocket II and the driven sprocket III which are also meshed with the chain belt to carry out meshing transmission, the caster body is lifted from a low position to a high position by means of supporting plates, and the cylinder works to push the caster body into a filling cylinder arranged nearby until the caster body reaches a proper height, so that the physical consumption is reduced, and the working efficiency is improved.

Description

Feeding mechanism for processing caster main body

Technical Field

The utility model relates to the technical field of caster machining, in particular to a feeding mechanism for caster body machining.

Background

The truckle is a supporting part which can be arranged at the bottom end of equipment or an object, and the main function of the truckle is to facilitate the movement of the equipment or the object, thereby saving manpower and having wide application.

The utility model of application number CN202122656791.1 discloses a feeding mechanism for processing a caster body. The utility model has the advantages of enabling the mechanism to be filled with a plurality of caster bodies at one time, reducing the working length of workers, increasing the working efficiency of the workers, preventing unqualified caster bodies from entering the next working procedure to influence the working process, and bringing a certain beneficial influence to the actual use. But the caster body to be processed needs to be automatically filled into the filling cylinder from the filling cylinder port at a high place, which increases physical effort.

Accordingly, in view of the above, research and improvement have been made on the conventional structure and the conventional disadvantages, and a feed mechanism for processing a caster body has been proposed.

Disclosure of Invention

The utility model aims to provide a feeding mechanism for processing a caster body, which aims to solve the problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a feed mechanism is used in truckle main part processing, includes hoisting assembly and adjusting part, hoisting assembly includes casing, driving motor, driving sprocket, chain belt, driven sprocket one, driven sprocket two, driven sprocket three, fagging, braced frame and gyro wheel, driving motor is installed to the rear end of casing, driving motor's output runs through the casing rear end through the drive shaft and is connected with driving sprocket, driving sprocket's external connection has chain belt, chain belt's inboard still is connected with driven sprocket one, driven sprocket two and driven sprocket three, chain belt's outside is provided with the fagging, the outside of casing is provided with the braced frame, the rotation of the front and back end below of casing is provided with the gyro wheel, adjusting part is placed in hoisting assembly's below.

Further, the lifting assemblies are arranged in two, and the two lifting assemblies are symmetrically distributed with respect to the vertical central axis of the adjusting assembly.

Further, the driving sprocket, the driven sprocket I, the driven sprocket II and the driven sprocket III are all meshed and connected with the chain belt, and the supporting plates are distributed at equal intervals along the periphery of the outer side of the chain belt.

Further, the adjusting component comprises a base, support legs and a forward and reverse rotation motor, the support legs are arranged on two sides of the bottom of the base, and the forward and reverse rotation motor is arranged in the middle of the bottom end of the base.

Further, the adjusting assembly further comprises a gear, a first rack and a second rack, the output end of the forward and backward rotating motor is connected with the gear through a driving shaft, and the first rack and the second rack are meshed with the outer side of the gear respectively.

Further, the adjusting component further comprises a sliding block and a sliding groove, the sliding blocks are arranged on the right side of the bottom of the first rack and the left side of the bottom of the second rack, and the sliding groove is formed in the bottom of the base.

Further, the first rack and the second rack are parallel to each other, the support frame positioned on the left side is fixedly connected with the first rack, and the support frame positioned on the right side is fixedly connected with the second rack.

Further, the front end of base is provided with the carrier bar, the rear end top of carrier bar is provided with the cylinder.

The utility model provides a feeding mechanism for processing a caster body, which has the following beneficial effects:

1. according to the utility model, the driving motor drives the driving shaft and the driving sprocket to rotate, and the driving sprocket drives the driven sprocket I, the driven sprocket II and the driven sprocket III which are also meshed with the chain belt to carry out meshing transmission, so that the caster body is lifted from a low position to a high position by means of supporting plates, and the cylinder works to push the caster body into a filling cylinder arranged nearby until the caster body reaches a proper height, thereby reducing physical consumption and improving working efficiency.

2. The forward and reverse rotation motor drives the driving shaft and the gear to rotate around the anticlockwise or clockwise direction, so that the rack I and the rack II meshed with the gear can horizontally move in opposite directions or opposite directions, the effect of adjusting the distance between the two lifting assemblies is achieved, and the two lifting assemblies have the capability of supporting and lifting caster bodies of different sizes when being combined for use.

Drawings

FIG. 1 is a schematic cross-sectional view of a housing of a feed mechanism for caster body machining according to the present utility model;

FIG. 2 is a schematic top view of a base of a feeding mechanism for caster body processing according to the present utility model;

fig. 3 is a schematic perspective view showing the appearance of a shell of a feeding mechanism for processing a caster body.

In the figure: 1. a lifting assembly; 101. a housing; 102. a driving motor; 103. a drive sprocket; 104. a chain belt; 105. a driven sprocket I; 106. a driven sprocket II; 107. driven sprocket III; 108. a supporting plate; 109. a support frame; 110. a roller; 2. an adjustment assembly; 201. a base; 202. a support leg; 203. a forward and reverse rotation motor; 204. a gear; 205. a first rack; 206. a second rack; 207. a slide block; 208. a chute; 3. a carrier bar; 4. and (3) a cylinder.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

As shown in fig. 1 and 3, a feeding mechanism for processing a caster body comprises a lifting assembly 1 and an adjusting assembly 2, the lifting assembly 1 comprises a shell 101, a driving motor 102, a driving sprocket 103, a chain belt 104, a driven sprocket I105, a driven sprocket II 106, a driven sprocket III 107, a supporting plate 108, a supporting frame 109 and a roller 110, the driving motor 102 is installed at the rear end of the shell 101, the driving sprocket 103 is connected with the rear end of the shell 101 through a driving shaft, the chain belt 104 is connected with the outer part of the driving sprocket 103, the inner side of the chain belt 104 is also connected with a driven sprocket I105, a driven sprocket II 106 and a driven sprocket III 107, the outer side of the chain belt 104 is provided with a supporting plate 108, the outer side of the shell 101 is provided with a supporting frame 109, the lower part of the front end and the rear end of the shell 101 is rotationally provided with a roller 110, the adjusting assembly 2 is placed below the lifting assembly 1, the lifting assembly 1 is provided with two lifting assemblies, the two lifting assemblies 1 are symmetrically distributed about the vertical central axis of the adjusting assembly 2, the driving sprocket 103, the driven sprocket I105, the driven sprocket II 106 and the driven sprocket III 107 are connected with the chain belt 104, the chain belt 104 is meshed with the chain belt 104, the chain belt 104 is provided with the bearing rod 3, the bearing rod is arranged at the outer side of the chain belt 104, and the bearing rod is provided with the bearing rod 3, and the bearing rod 3 is arranged at the same distance, and the bearing rod 3 is arranged.

The driving motor 102 drives the driving shaft and the driving sprocket 103 to rotate, the driving sprocket 103 drives the driven sprocket I105, the driven sprocket II 106 and the driven sprocket III 107 which are also meshed with the chain belt 104 to carry out meshing transmission, the caster body is lifted from a low position to a high position by means of the support of the supporting plate 108, the cylinder 4 works to push the caster body into a filling cylinder arranged nearby until the proper height is reached, the physical consumption is reduced, and the working efficiency is improved.

As shown in fig. 1 and 2, the adjusting assembly 2 comprises a base 201, a supporting leg 202 and a forward and reverse rotation motor 203, the supporting legs 202 are arranged on two sides of the bottom of the base 201, the forward and reverse rotation motor 203 is installed in the middle of the bottom end of the inside of the base 201, the adjusting assembly 2 further comprises a gear 204, a first rack 205 and a second rack 206, the output end of the forward and reverse rotation motor 203 is connected with the gear 204 through a driving shaft, the first rack 205 and the second rack 206 are meshed with the outer side of the gear 204 respectively, the adjusting assembly 2 further comprises a sliding block 207 and a sliding groove 208, the sliding blocks 207 are arranged on the right side of the bottom of the first rack 205 and the left side of the bottom of the second rack 206, the sliding groove 208 is formed in the bottom of the base 201, the first rack 205 and the second rack 206 are parallel to each other, the supporting frame 109 on the left side is fixedly connected with the first rack 205, and the supporting frame 109 on the right side is fixedly connected with the second rack 206.

The operation is as follows, the forward and reverse rotation motor 203 drives the driving shaft and the gear 204 to rotate around the anticlockwise or clockwise direction, so that the rack I205 and the rack II 206 meshed with the gear 204 can horizontally move towards the opposite or opposite directions, the effect of adjusting the interval between the two lifting assemblies 1 is achieved, and the two lifting assemblies 1 have the capability of supporting and lifting caster bodies of different sizes when being combined for use.

In summary, when the feeding mechanism for processing the caster body is used, firstly, the adjusting component 2 is moved to the vicinity of a filling cylinder or a conveyor belt which needs to be matched with feeding, then the forward and reverse rotation motor 203 is controlled to work according to the size of the caster body to be processed, the driving shaft and the gear 204 are driven to rotate around the anticlockwise or clockwise direction by the forward and reverse rotation motor 203, so that the rack I205 and the rack II 206 meshed with the gear 204 horizontally move in opposite directions or opposite directions until the distance between the supporting plates 108 in the two lifting components 1 is proper, then the driving motor 102 is started, meanwhile, a worker can supplement the caster body to the two supporting plates 108 from the lower position, the driving sprocket 103 which rotates along with the driving shaft drives the chain belt 104 to carry out meshing transmission, the chain belt 104 drives the driven sprocket I105, the driven sprocket II 106 and the driven sprocket III 107 to carry out meshing transmission, the caster body supported by the two supporting plates 108 is lifted from the lower position to the upper position until the cylinder 4 supported by the supporting rod 3 reaches the proper height, the caster body is pushed into the filling cylinder or the conveyor belt which is arranged nearby, the supplementing difficulty is reduced, the labor cost during feeding period is reduced, the first sliding cost of the rack I and the rack II is correspondingly increased, and the sliding cost of the sliding of the two racks 206 is guaranteed during the sliding operation of the sliding of the two groups of the sliding blocks 204 is respectively, and the sliding between the two groups of the sliding blocks 206 is guaranteed.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (8)

1. The utility model provides a feed mechanism is used in truckle main part processing, includes hoisting assembly (1) and adjusting part (2), a serial communication port, hoisting assembly (1) includes casing (101), driving motor (102), driving sprocket (103), chain belt (104), driven sprocket one (105), driven sprocket two (106), driven sprocket three (107), fagging (108), braced frame (109) and gyro wheel (110), driving motor (102) are installed to the rear end of casing (101), the output of driving motor (102) runs through casing (101) rear end through the drive shaft and is connected with driving sprocket (103), the outside of driving sprocket (103) is connected with chain belt (104), the inboard of chain belt (104) still is connected with driven sprocket one (105), driven sprocket two (106) and driven sprocket three (107), the outside of chain belt (104) is provided with fagging (108), the outside of casing (101) is provided with braced frame (109), the rotation of the front and back end below of casing (101) is provided with gyro wheel (110), adjusting part (2) are placed in the below of hoisting assembly (1).

2. The feeding mechanism for machining the caster body according to claim 1, wherein two lifting assemblies (1) are provided, and the two lifting assemblies (1) are symmetrically distributed about a vertical central axis of the adjusting assembly (2).

3. The feeding mechanism for processing the caster body according to claim 1, wherein the driving sprocket (103), the driven sprocket one (105), the driven sprocket two (106) and the driven sprocket three (107) are all engaged with the chain belt (104), and the stay plates (108) are equidistantly distributed along the outer circumference of the chain belt (104).

4. The feeding mechanism for caster body processing according to claim 1, wherein the adjusting assembly (2) comprises a base (201), supporting legs (202) and a forward and reverse motor (203), the supporting legs (202) are arranged on two sides of the bottom of the base (201), and the forward and reverse motor (203) is installed in the middle of the bottom end of the base (201).

5. The feeding mechanism for caster body processing according to claim 4, wherein the adjusting assembly (2) further comprises a gear (204), a first rack (205) and a second rack (206), wherein the output end of the forward and reverse rotation motor (203) is connected with the gear (204) through a driving shaft, and the first rack (205) and the second rack (206) are respectively meshed with the outer side of the gear (204).

6. The feeding mechanism for machining the caster body according to claim 5, wherein the adjusting assembly (2) further comprises a sliding block (207) and a sliding groove (208), the sliding block (207) is arranged on the right side of the bottom of the first rack (205) and the left side of the bottom of the second rack (206), and the sliding groove (208) is formed in the bottom of the base (201).

7. The feeding mechanism for caster body processing according to claim 6, wherein the first rack (205) and the second rack (206) are parallel to each other, the support frame (109) on the left side is fixedly connected to the first rack (205), and the support frame (109) on the right side is fixedly connected to the second rack (206).

8. The feeding mechanism for caster body processing according to claim 4, wherein a carrier rod (3) is provided at a front end of the base (201), and a cylinder (4) is provided above a rear end of the carrier rod (3).