CN211204917U - Aluminum ingot feeder - Google Patents

Abstract

An aluminum ingot feeder comprises a clamping device, a lifting mechanism, a fixing frame, a track and a feeding tower; a hydraulic platform is arranged below the clamping device, the lifting mechanism is connected with a power supply, and a switch is arranged on the lifting mechanism; a rotating device, a connecting shaft and a supporting plate are arranged below the connecting rod, the connecting rod is connected with the rotating device through the connecting shaft, the rotating device is hinged with the supporting plate, a track is arranged on the fixing frame, the lifting mechanism is arranged on the track and is arranged on the track in a sliding mode, and a feeding tower is arranged below the track; the utility model discloses alleviateed workman's intensity of labour greatly, changed original artifical transport mode into the machine transport, reduced the workman cost, improved intensity of automation greatly, the operation of being convenient for.

Description

Aluminum ingot feeder

Technical Field

The utility model belongs to the technical field of the feeder technique and specifically relates to an aluminium ingot feeder is related to.

Background

Most batch feeders in the current market still use a single batch feeder skip car feeding mode, when the single batch feeder in the prior art is used for feeding aluminum ingots, huge physical labor is needed, workers are needed to disassemble a whole stack of aluminum ingots and carry the aluminum ingots into the skip car, one skip car needs to carry about 200 plus 400 kilograms of materials, the feeding times are different every hour, if the single batch feeder is a large-scale furnace, the feeding times are more, and when the aluminum ingots are fed, the aluminum ingots are directly fed from the upper part of a batch feeding tower, the height drop is larger, the aluminum ingots can hit the wall or the bottom of the furnace body in the batch feeding process, and the inner wall of the furnace is easily damaged; when the batch feeder is maintained or maintained, the centralized furnace can only suspend feeding and melting, and the maintenance time is too long, which can cause great influence on the production of the whole workshop.

Therefore, there is a need to provide a new technical solution to overcome the above-mentioned drawbacks.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an aluminium ingot feeder that can effectively solve above-mentioned technical problem.

In order to achieve the purpose of the utility model, the following technical proposal is adopted:

an aluminum ingot feeder comprises a clamping device, a lifting mechanism, a fixing frame, a track and a feeding tower; a hydraulic platform is arranged below the clamping device, and the clamping device comprises a connecting rod, a first linkage mechanism, a rotating device, a connecting shaft, a supporting plate, a testing device, a second linkage mechanism, a top plate, a third linkage mechanism, a jacking device and a supporting frame; the device comprises two connecting rods, a testing device, a supporting frame, a jacking device, a lifting mechanism and a lifting mechanism, wherein the two connecting rods are arranged in a bilateral symmetry manner, a first linkage mechanism in the bilateral symmetry manner is arranged between the connecting rods, the first linkage mechanism is hinged with the connecting rods, the first linkage mechanism is arranged in a crossed manner, the testing device is arranged below the first linkage mechanism, the testing device is abutted against the lower part of the first linkage mechanism, the testing device is abutted against the supporting frame, a travel switch is arranged below the testing device, the second linkage mechanism is hinged with the upper part of the first linkage mechanism, the top plate is hinged with the supporting frame, the second linkage mechanism is hinged with the third linkage mechanism, the third linkage mechanism is hinged with the jacking device, the jacking device is buckled on the supporting frame, the lifting mechanism is fixedly arranged above the jacking device and is fixedly connected with the jacking device, the lifting mechanism is connected with a power supply, and a switch is arranged on the lifting mechanism; the feeding device is characterized in that a rotating device, a connecting shaft and a supporting plate are arranged below the connecting rod, the connecting rod is connected with the rotating device through the connecting shaft, the rotating device is hinged with the supporting plate, a track is arranged on the fixing frame, the lifting mechanism is arranged on the track and is arranged on the track in a sliding mode, and a feeding tower is arranged below the track.

Preferably, the lifting mechanism is an electric hoist.

Preferably, a feeding tower turnover cover is arranged on the feeding tower.

Preferably, the support frame is provided with fixing blocks at two sides of the first linkage mechanism.

Compared with the prior art, the utility model discloses following beneficial effect has: the labor intensity of workers is greatly reduced, the original manual carrying mode is changed into machine carrying, the cost of the workers is reduced, the automation intensity is greatly improved, and the operation is convenient.

Drawings

FIG. 1 is a schematic view of the working state of the aluminum ingot feeder of the present invention,

FIG. 2 is a schematic structural view of a gripping device in the aluminum ingot feeder shown in FIG. 1,

figure 3 is a first angular view of the internal structure of the gripping device of figure 2,

fig. 4 is a second angle schematic view of the internal structure of the grasping device shown in fig. 2.

Wherein, 1, the clamping device; 11 a connecting rod; 12 a first linkage mechanism; 13 a rotating device; 14 connecting the shafts; 15 a support plate; 16 a test platform; 17 a second linkage mechanism; 18 a top plate; 19 a third linkage mechanism; 10 jacking means; 101, fixing blocks; 102 a support frame; 2. a lifting mechanism; 3. a fixed mount; 4. a track; 5. turning over a cover of the feeding tower; 6. a feeding tower.

Detailed Description

The aluminum ingot feeding machine of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1-4 show an aluminum ingot feeder of the present invention, which comprises a clamping device 1, a lifting mechanism 2, a fixing frame 3, a track 4, and a feeding tower 6; a hydraulic platform (not shown) is arranged below the clamping device 1, so that the aluminum ingot can be conveyed to a specified height conveniently, and the clamping device 1 clamps the aluminum ingot; the clamping device 1 comprises a connecting rod 11, a first linkage mechanism 12, a rotating device 13, a connecting shaft 14, a supporting plate 15, a testing device 16, a second linkage mechanism 17, a top plate 18, a third linkage mechanism 19, a jacking device 10 and a supporting frame 102; the two connecting rods 11 are arranged in a bilateral symmetry manner, first linkage mechanisms 12 in the bilateral symmetry manner are arranged between the connecting rods 11 on the left side and the right side, the first linkage mechanisms 12 are hinged to the connecting rods 11, the first linkage mechanisms 12 on the left side and the right side are arranged in a crossed manner, a testing device 16 is arranged below the first linkage mechanisms 12, the testing device 16 abuts against the lower portion of the first linkage mechanisms 12, the testing device 16 can fix the lifting mechanism 2, the testing device 16 abuts against the supporting frame 102, the supporting frame 102 supports the testing device 16, and a travel switch (not shown) is arranged below the testing device 16, so that the lower portion can be conveniently detected; a second linkage mechanism 17 is hinged above the first linkage mechanism 12, a top plate 18 is hinged above the second linkage mechanism 17, the top plate 18 abuts against a support frame 102, and the support frame 102 plays a limiting role on the top plate 18; the second linkage mechanism 17 is hinged to a third linkage mechanism 19, the third linkage mechanism 19 is hinged to the jacking device 10, the jacking device 10 is fastened to a support frame 102, the support frame 102 plays a limiting role in the jacking device 10, a lifting mechanism 2 is fixedly mounted above the jacking device 10 and is fixedly connected with the jacking device, so that the lifting mechanism 2 can drive the clamping device 1 to move, the lifting mechanism 2 is connected with a power supply (not shown) to provide electric energy for the clamping device, and a switch is arranged on the lifting mechanism 2 to control the opening and closing of the lifting mechanism 2; a rotating device 13, a connecting shaft 14 and a supporting plate 15 are arranged below the connecting rod 11, the connecting rod 11 is connected with the rotating device 13 through the connecting shaft 14, the rotating device 13 is hinged with the supporting plate 15, the supporting plate 15 can rotate under the action of the rotating device 13, a track 4 is arranged on the fixed frame 3, the lifting mechanism 2 is arranged on the track 4, and the lifting mechanism 2 is arranged on the track 4 in a sliding manner, so that the lifting mechanism 2 can move on the track 4; and a feeding tower 6 is arranged below the track 4.

The lifting mechanism 2 is an electric hoist.

The feeding tower 1 is provided with a feeding tower turnover cover 5, so that the feeding tower 1 is protected when not in use.

The support frame 102 is provided with fixing blocks 101 at two sides of the first linkage mechanism 12, and the fixing blocks 101 play a role in limiting the first linkage mechanism 12.

The working principle is as follows: firstly, placing an aluminum ingot on a conveyor belt, then conveying the aluminum ingot to a hydraulic platform below a batch feeder, then moving the aluminum ingot through the hydraulic platform so as to move to the position below a clamping device 1, at the moment, a travel switch on a test platform 16 detects the aluminum ingot below the test platform, so that a first linkage mechanism 12, a second linkage mechanism 17 and a third linkage mechanism 19 move, so that a top plate 18 and a jacking device 10 move upwards, so that a lifting mechanism 2 moves, so that a rotating device 13, a connecting shaft 14 and a supporting plate 15 below a connecting rod 11 work, so that the supporting plate 15 supports the aluminum ingot, then the lifting mechanism 2 enables the clamping device 1 to move upwards, then the clamping device moves horizontally to the position above a batch feeding tower 6 on a track 4, a batch feeding tower turnover cover 5 is opened, then the lifting mechanism 2 drives the clamping device 1 to move downwards until the aluminum ingot moves to the bottom of the batch feeding tower 6, and then, detecting a travel switch, so that the jacking device 10 moves downwards, the first linkage mechanism 12, the second linkage mechanism 17 and the third linkage mechanism 19 move, the rotating device 13, the connecting shaft 14 and the supporting plate 15 work, the supporting plate 15 rotates, the aluminum ingot is put down, and the feeding work is finished.

The above is only a specific application example of the present invention, and does not constitute any limitation to the protection scope of the present invention. All the technical solutions formed by equivalent transformation or equivalent replacement fall within the protection scope of the present invention.

Claims (4)

1. An aluminum ingot feeder comprises a clamping device, a lifting mechanism, a fixing frame, a track and a feeding tower; the method is characterized in that: a hydraulic platform is arranged below the clamping device, and the clamping device comprises a connecting rod, a first linkage mechanism, a rotating device, a connecting shaft, a supporting plate, a testing device, a second linkage mechanism, a top plate, a third linkage mechanism, a jacking device and a supporting frame; the device comprises two connecting rods, a testing device, a supporting frame, a jacking device, a lifting mechanism and a lifting mechanism, wherein the two connecting rods are arranged in a bilateral symmetry manner, a first linkage mechanism in the bilateral symmetry manner is arranged between the connecting rods, the first linkage mechanism is hinged with the connecting rods, the first linkage mechanism is arranged in a crossed manner, the testing device is arranged below the first linkage mechanism, the testing device is abutted against the lower part of the first linkage mechanism, the testing device is abutted against the supporting frame, a travel switch is arranged below the testing device, the second linkage mechanism is hinged with the upper part of the first linkage mechanism, the top plate is hinged with the supporting frame, the second linkage mechanism is hinged with the third linkage mechanism, the third linkage mechanism is hinged with the jacking device, the jacking device is buckled on the supporting frame, the lifting mechanism is fixedly arranged above the jacking device and is fixedly connected with the jacking device, the lifting mechanism is connected with a power supply, and a switch is arranged on the lifting mechanism; the feeding device is characterized in that a rotating device, a connecting shaft and a supporting plate are arranged below the connecting rod, the connecting rod is connected with the rotating device through the connecting shaft, the rotating device is hinged with the supporting plate, a track is arranged on the fixing frame, the lifting mechanism is arranged on the track and is arranged on the track in a sliding mode, and a feeding tower is arranged below the track.

2. An aluminum ingot feeder as set forth in claim 1, wherein: the lifting mechanism is an electric hoist.

3. An aluminum ingot feeder as set forth in claim 1, wherein: and a feeding tower turnover cover is arranged on the feeding tower.

4. An aluminum ingot feeder as set forth in claim 1, wherein: and fixed blocks are arranged on the support frame and positioned on two sides of the first linkage mechanism.

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