CN219767533U - Feeding mechanism for magnesium ingot cutting equipment - Google Patents

Abstract

The utility model discloses a feeding mechanism for magnesium ingot cutting equipment, which comprises a machine body, wherein a clamping assembly and a driving assembly are arranged in the machine body, the machine body is provided with a feeding channel and a discharging channel, the feeding channel and the discharging channel are distributed in a vertical state, the outer end face of the feeding channel is provided with a through notch, a port of the discharging channel is arranged in an arc shape, the arc of the port coincides with the center of a cutting roller of the cutting equipment, the clamping assembly is arranged in the middle of the feeding channel and is used for clamping and fixing magnesium ingots placed in a queuing state in the feeding channel, and the driving assembly is arranged at the joint of the discharging channel and the feeding channel and is used for transporting the magnesium ingots to be cut in the feeding channel. The automatic clamping and fixing in the magnesium ingot feeding process and the automatic continuous feeding in the cutting process can be realized, the stub bar can not be generated, the feeding efficiency can be improved, and the processing production cost is reduced.

Description

Feeding mechanism for magnesium ingot cutting equipment

Technical Field

The utility model relates to the technical field of magnesium ingot cutting auxiliary equipment, in particular to a feeding mechanism for magnesium ingot cutting equipment.

Background

The feeding mode of the current roller-type magnesium ingot cutting machine is that a pneumatic cylinder is acquired to prop against one end of a magnesium ingot through a hydraulic cylinder, and then the pneumatic cylinder continuously stretches out, so that the magnesium ingot props against a hob and is gradually cut. But in order to prevent the hydraulic cylinder from extending out of the end and extending out of the way too long to appear and hit the cutter phenomenon, will generally stop feeding when some magnesium ingot is left, the remaining small magnesium ingot stub bar falls by the blanking mouth, then the hydraulic cylinder resets, add new magnesium ingot manually, the stub bar needs to be collected one by one and then remelted into pieces to be processed again, not only has reduced the chip processing efficiency, but also has increased the production cost. To this end we propose a feed mechanism for a magnesium ingot chipping apparatus.

Disclosure of Invention

The utility model mainly aims to provide a feeding mechanism for magnesium ingot cutting equipment, which can effectively solve the problems in the background technology.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the utility model provides a feed mechanism for magnesium ingot cutting equipment, includes the organism, organism internally mounted has clamping assembly and drive assembly, the organism is equipped with a feed channel and a discharge channel, feed channel and discharge channel are vertical state and distribute, clamping assembly set up in the middle part of feed channel is used for with the place in the inside clamping of the magnesium ingot of queuing state of feed channel is fixed, drive assembly sets up in the junction of discharge channel and feed channel, is used for waiting to cut the transportation of magnesium ingot in the feed channel is inside.

Further, the clamping assembly comprises a pinch roller, the pinch roller upper end is connected with the ejector pin, ejector pin other end fixedly connected with sliding plate, the sliding plate upper end is connected with the deflection pole through the lug rotation, the deflection pole other end passes through axle fixedly connected with splint, splint symmetric distribution in inside the organism, and rotate with the organism through the axle and be connected, the sliding plate middle part is equipped with the guide bar, guide bar tip all is equipped with the spring with organism fixed connection, guide bar upper portion outside.

Further, the drive assembly includes the motor, motor lower extreme fixedly connected with motor cabinet, motor cabinet one end and organism fixed connection, the output axle head of motor is connected with band pulley drive mechanism, band pulley drive mechanism's power take off end has the drive roller through the coupling joint, the winding of drive roller outside has the track, a plurality of dog is evenly installed to the outer terminal surface of track, the track inboard is equipped with the backing roll, drive roller and backing roll all rotate with the organism and are connected.

Further, a plurality of groups of rollers are arranged in the discharging channel, and the rollers are rotatably connected with the machine body through shafts.

Further, the outer end face of the feeding channel is provided with a through notch, the port of the discharging channel is arranged in an arc shape, and the arc of the port coincides with the circle center of the cutting roller of the chip cutting device.

Further, the distance between two adjacent stoppers is larger than the horizontal width of the feed channel.

The utility model has the following beneficial effects:

1) According to the scheme provided by the utility model, magnesium ingots to be processed are sequentially castellated in a feeding channel of a machine body, a motor is started, the motor operates to drive a driving roller to rotate through a belt pulley transmission mechanism, the driving roller drives a caterpillar band to circularly rotate in a discharging channel, magnesium ingots at the lowest layer drop to the discharging channel from the feeding channel and drop to the upper end of the caterpillar band, along with the rotation of the caterpillar band, the magnesium ingots drop between two adjacent check blocks and are pushed to an outlet of the discharging channel by a rear check block to be transported, in the magnesium ingot transportation process, the upper ends of the magnesium ingots are contacted with a compression roller and push the compression roller upwards, the compression roller pushes a push rod to enable a sliding plate to move upwards along a guide rod and drive deflection rods connected with two sides to rotate, the deflection rods drive clamping plates to simultaneously rotate inwards, so that the clamping plates clamp magnesium ingots at the upper layer of the magnesium ingots, the position of the upper layer of the magnesium ingots is temporarily fixed, when the magnesium ingots at the discharging channel are conveyed to be separated from the compression roller, the clamping plates are reset under the elastic action of a spring, the clamping force is not provided, and the magnesium ingots at the upper layer drop under the action of gravity force, and the feeding of the magnesium ingots drop to the upper layer and are repeatedly arranged to the channel to the end of the magnesium ingots, and are sequentially connected with the magnesium ingots at the end of the discharge channel, and the magnesium ingots are continuously conveyed by the conveyor.

Drawings

FIG. 1 is a schematic view of the overall structure of a feed mechanism for magnesium ingot chipping equipment according to the present utility model;

FIG. 2 is a top view of a feed mechanism for a magnesium ingot chipping apparatus of the present utility model;

FIG. 3 is a schematic view of the structure of section A in FIG. 2;

FIG. 4 is a schematic view of the internal structure of a feed mechanism for magnesium ingot chipping equipment according to the present utility model;

FIG. 5 is a side view of a feed mechanism for a magnesium ingot chipping apparatus of the present utility model;

FIG. 6 is a schematic view of the structure of section B in FIG. 4;

fig. 7 is a schematic structural view of the section C in fig. 4.

In the figure: 1. a body; 101. a feed channel; 102. a discharge channel; 201. a pinch roller; 202. a push rod; 203. a sliding plate; 204. a deflection lever; 205. a clamping plate; 206. a guide rod; 207. a spring; 301. a motor; 302. a motor base; 303. a belt wheel transmission mechanism; 304. a driving roller; 305. a track; 306. a stop block; 307. a support roller; 4. and a roller.

Detailed Description

The present utility model will be further described with reference to the following detailed description, wherein the drawings are for illustrative purposes only and are presented as schematic drawings, rather than physical drawings, and are not to be construed as limiting the utility model, and wherein certain components of the drawings are omitted, enlarged or reduced in order to better illustrate the detailed description of the present utility model, and are not representative of the actual product dimensions.

Example 1

As shown in fig. 1-7, a feeding mechanism for magnesium ingot cutting equipment comprises a machine body 1, wherein a clamping assembly and a driving assembly are installed in the machine body 1, the machine body 1 is provided with a feeding channel 101 and a discharging channel 102, the feeding channel 101 and the discharging channel 102 are distributed in a vertical state, the clamping assembly is arranged in the middle of the feeding channel 101 and used for clamping and fixing magnesium ingots placed in the feeding channel 101 in a queuing state, and the driving assembly is arranged at the joint of the discharging channel 102 and the feeding channel 101 and used for conveying magnesium ingots to be cut in the feeding channel 101.

The clamping assembly comprises a pinch roller 201, an ejector rod 202 is connected to the upper end of the pinch roller 201, a sliding plate 203 is fixedly connected to the other end of the ejector rod 202, a deflection rod 204 is rotatably connected to the upper end of the sliding plate 203 through a lifting lug, clamping plates 205 are fixedly connected to the other end of the deflection rod 204 through shafts, the clamping plates 205 are symmetrically distributed inside the machine body 1 and are rotatably connected with the machine body 1 through shafts, a guide rod 206 is arranged in the middle of the sliding plate 203, the end portions of the guide rod 206 are fixedly connected with the machine body 1, and springs 207 are arranged on the outer sides of the upper portions of the guide rods 206.

The driving assembly comprises a motor 301, the lower end of the motor 301 is fixedly connected with a motor base 302, one end of the motor base 302 is fixedly connected with the machine body 1, the output shaft end of the motor 301 is connected with a belt wheel transmission mechanism 303, the power output end of the belt wheel transmission mechanism 303 is connected with a driving roller 304 through a coupling, a crawler 305 is wound on the outer side of the driving roller 304, a plurality of stop blocks 306 are uniformly arranged on the outer end face of the crawler 305, a supporting roller 307 is arranged on the inner side of the crawler 305, and the driving roller 304 and the supporting roller 307 are both in rotary connection with the machine body 1.

The discharging channel 102 is internally provided with a plurality of groups of rollers 4, and the rollers 4 are rotatably connected with the machine body 1 through shafts.

The outer end face of the feeding channel 101 is provided with a through notch, the port of the discharging channel 102 is arranged in an arc shape, and the arc of the port coincides with the circle center of a cutting roller of the chip cutting device.

The distance between two adjacent stoppers 306 is larger than the horizontal width of the feed channel 101.

By adopting the technical scheme: the magnesium ingots to be processed are put into the feeding channel 101 of the machine body 1 to be castellated in sequence, the motor 301 is started, the motor 301 operates to drive the driving roller 304 to rotate through the belt pulley transmission mechanism 303, the driving roller 304 drives the caterpillar 305 to rotate in the discharging channel 102 in a circulating way, the magnesium ingots at the lowest layer drop into the discharging channel 102 from the feeding channel 101 and drop at the upper end of the caterpillar 305, along with the rotation of the caterpillar 305, the magnesium ingots drop between two adjacent stop blocks 306 and are pushed to the outlet of the discharging channel 102 by the stop blocks 306 at the rear side, in the magnesium ingot transportation process, the upper ends of the magnesium ingots are contacted with the pinch rollers 201 and push the pinch rollers 201 upwards, the pinch rollers 201 push the ejector rods 202 to enable the sliding plates 203 to move upwards along the guide rods 206 and drive the deflection rods 204 connected at two sides to rotate, the deflection rods 204 drive the clamping plates 205 to rotate inwards simultaneously, the magnesium ingots at the upper layer of the clamping plates 205 are enabled to be temporarily fixed, when the magnesium ingots at the upper layer of the discharging channel 102 are conveyed to the end of the magnesium ingots, the clamping plates 205 are separated from the upper end of the magnesium ingots under the action of the spring 207, the reset clamping plates 205 are not provided by the clamping plates at the upper end of the magnesium ingots and the upper layer 102, and the magnesium ingots are continuously dropped to the end of the magnesium ingots at the feeding channel 102 in the process.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a feed mechanism for magnesium ingot cutting equipment, includes organism (1), organism (1) internally mounted has clamping assembly and drive assembly, its characterized in that: the machine body (1) is provided with a feeding channel (101) and a discharging channel (102), the feeding channel (101) and the discharging channel (102) are distributed in a vertical state, the clamping assembly is arranged in the middle of the feeding channel (101) and used for clamping and fixing magnesium ingots placed in the feeding channel (101) in a queuing state, and the driving assembly is arranged at the joint of the discharging channel (102) and the feeding channel (101) and used for conveying the magnesium ingots to be cut in the feeding channel (101).

2. A feed mechanism for magnesium ingot chipping equipment as defined in claim 1 wherein: the clamping assembly comprises a pinch roller (201), the upper end of the pinch roller (201) is connected with a push rod (202), the other end of the push rod (202) is fixedly connected with a sliding plate (203), the upper end of the sliding plate (203) is rotationally connected with a deflection rod (204) through a lifting lug, the other end of the deflection rod (204) is fixedly connected with a clamping plate (205) through a shaft, the clamping plate (205) is symmetrically distributed in the machine body (1) and is rotationally connected with the machine body (1) through a shaft, the middle part of the sliding plate (203) is provided with a guide rod (206), the end part of the guide rod (206) is fixedly connected with the machine body (1), and the outer side of the upper part of the guide rod (206) is provided with a spring (207).

3. A feed mechanism for magnesium ingot chipping equipment as defined in claim 1 wherein: the driving assembly comprises a motor (301), the lower end of the motor (301) is fixedly connected with a motor base (302), one end of the motor base (302) is fixedly connected with a machine body (1), the output shaft end of the motor (301) is connected with a belt wheel transmission mechanism (303), the power output end of the belt wheel transmission mechanism (303) is connected with a driving roller (304) through a coupling, a crawler belt (305) is wound on the outer side of the driving roller (304), a plurality of stop blocks (306) are uniformly arranged on the outer end face of the crawler belt (305), a supporting roller (307) is arranged on the inner side of the crawler belt (305), and the driving roller (304) and the supporting roller (307) are rotationally connected with the machine body (1).

4. A feed mechanism for magnesium ingot chipping equipment as defined in claim 1 wherein: the inside of the discharging channel (102) is provided with a plurality of groups of rollers (4), and the rollers (4) are rotationally connected with the machine body (1) through shafts.

5. A feed mechanism for magnesium ingot chipping equipment as defined in claim 1 wherein: the outer end face of the feeding channel (101) is provided with a through notch, the port of the discharging channel (102) is arranged in an arc shape, and the arc of the port coincides with the circle center of the cutting roller of the chip cutting device.

6. A feed mechanism for magnesium ingot chipping equipment as in claim 3 wherein: the distance between two adjacent stoppers (306) is larger than the horizontal width of the feed channel (101).