CN220782115U - Automatic stainless steel antiskid forging device of feed - Google Patents

Abstract

The utility model discloses an automatic-feeding stainless steel anti-skid forging device which comprises a storage bin, wherein a bin door is connected to one side wall of the storage bin through a hinge, a covering net is arranged at the top of the storage bin, a conveyor belt is arranged in the storage bin, a motor is arranged at the power input end of the conveyor belt, a gate is arranged at the discharge hole of the storage bin, a forging table underframe is arranged on one side of the storage bin, an electric push rod is fixed on four walls inside the forging table underframe, forging support frames are arranged on two sides of the top surface of the forging table underframe, a telescopic cylinder is arranged in the middle of the top end of the forging support frame, and a connecting block is arranged at the telescopic part of the telescopic cylinder. The beneficial effects are that: through carving anti-skid threads on forging concave table, increase material and the frictional force of forging concave table makes it be difficult for taking place the skew to through electric putter and push pedal that resets after beating at every turn, can both push back forging material forging point position, make it keep forging point position, increased the forging success rate.

Description

Automatic stainless steel antiskid forging device of feed

Technical Field

The utility model relates to the technical field of stainless steel forging, in particular to an automatic-feeding stainless steel anti-skid forging device.

Background

The stainless steel is short for stainless acid-resistant steel, is a weak corrosion medium resistant to air, steam, water and the like or a steel grade with stainless property, and the forging is a processing method for applying pressure to a metal blank by using forging machinery to enable the metal blank to be plastically deformed so as to obtain a forging piece with certain mechanical property and certain shape and size, the defect of cast loosening and the like generated in the smelting process of the metal can be eliminated by forging, the microstructure is optimized, and meanwhile, the mechanical property of the forging piece is generally superior to that of a casting piece made of the same material due to the fact that a complete metal streamline is preserved. Important parts with high load and severe working conditions in related machines are usually forged pieces except for plates, profiles or welded parts which are relatively simple in shape and can be rolled.

The current stainless steel forging device is in forging process, often can take place that the material slides on forging platform after undergoing the beating, makes follow-up forging point skew lead to forging success rate lower, and current stainless steel forging device can't carry out automatic feed after forging is accomplished, need the manual work to remove the material from the feed bin to forge the platform and forge, has not only reduced forging efficiency, has still increased the cost of labor.

Disclosure of Invention

First, the technical problem to be solved

The utility model aims to solve the technical problem of providing a stainless steel anti-skid forging device which is detachable, easy to assemble and capable of automatically feeding.

(II) technical scheme

The utility model is realized by the following technical scheme: the utility model provides an automatic-feeding stainless steel anti-skid forging device which comprises a bin, wherein a bin door is connected to one side wall of the bin through a hinge, a covering net is arranged at the top of the bin, a conveyor belt is arranged in the bin, a motor is arranged at the power input end of the conveyor belt, a gate is arranged at the discharge hole of the bin, a forging table underframe is arranged on one side of the bin, an electric push rod is fixed on four walls inside the forging table underframe, a forging support frame is arranged on two sides of the top surface of the forging table underframe, a telescopic cylinder is arranged in the middle of the top end of the forging support frame, a connecting block is arranged at the telescopic part of the telescopic cylinder, a forging hammer is arranged at one end of the connecting block, a forging concave table is embedded in the middle of the top surface of the forging table underframe, a reset push plate is connected to the telescopic part of the electric push rod, a discharge rail is connected between the conveyor belt and the forging concave table, and a vibration floor pad is adhered on the bottom layer of the forging table underframe.

Further, the motor is in bolted connection with the storage bin, and the conveyor belt is in rotary connection with the storage bin.

Through adopting above-mentioned technical scheme, through the motor drives the conveyer belt rotates, makes it can normally work to make the conveyer belt can be stably fixed on the feed bin at the during operation.

Further, the gate is hinged with the bin, and the covering net is connected with the bin through bolts.

Through adopting above-mentioned technical scheme, through the gate control feed bin ration ejection of compact at every turn, through cover the net prevents debris entering feed bin in ejection of compact in-process.

Further, the forging table underframe is connected with the electric push rod through bolts, and the electric push rod is connected with the reset push plate through bolts.

Through adopting above-mentioned technical scheme, through electric putter control reset the push pedal pushes away the material of skew to appointed forging point position.

Further, the forging table underframe is connected with the forging support frame through bolts, and the forging support frame is connected with the telescopic cylinder through bolts.

Through adopting above-mentioned technical scheme, make forge the platform chassis with forge the support frame and connect steadily, make flexible cylinder with flexible platform chassis is connected steadily, prevents to take place the skew in forging process.

Further, the telescopic cylinder is connected with the connecting block through bolts, and the connecting block is connected with the forging hammer through bolts.

Through adopting above-mentioned technical scheme, make the connecting block forging hammer with connect between the flexible cylinder stably, prevent that it from shaking the skew in forging process.

Further, the forging concave table is connected with the discharging rail through bolts.

By adopting the technical scheme, the material sent out by the conveyor belt is sent to the forging concave table through the discharging rail.

(III) beneficial effects

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

1. in order to solve the problem that the existing stainless steel forging device often causes that materials slide on a forging table after being beaten, so that the subsequent forging points deviate to cause unsatisfactory forging results, the utility model comprises the steps of engraving anti-skid threads on a forging concave table, increasing the friction force between the materials and the forging concave table to ensure that the materials are not easy to deviate, pushing the forging materials back to the forging points after each beating by an electric push rod and a reset push plate, and keeping the forging materials at the forging points, thereby improving the forging success rate;

2. in order to solve the problems that the existing stainless steel forging device cannot automatically feed after forging is finished, and materials are required to be manually moved from a storage bin to a forging table for forging, the forging efficiency is reduced, and the labor cost is increased.

Drawings

FIG. 1 is a schematic view of an automatic feed stainless steel slip resistant forging apparatus according to the present utility model;

FIG. 2 is a front cross-sectional view of an automatic feed stainless steel slip resistant forging apparatus of the present utility model.

The reference numerals are explained as follows:

1. a storage bin; 2. a bin gate 2; 3. a conveyor belt; 4. a gate; 5. a forging table underframe; 6. forging a supporting frame; 7. a telescopic cylinder; 8. a connecting block; 9. forging a hammer; 10. resetting the push plate; 11. a discharge rail; 12. an anti-skid thread; 13. a motor; 14. forging a concave table; 15. an electric push rod; 16. shock-absorbing ground mat.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

As shown in fig. 1-2, the stainless steel anti-skid forging device capable of automatically feeding comprises a bin 1, a bin door 2 is connected to one side wall of the bin 1 through a hinge, a covering net 17 is arranged at the top of the bin 1 to prevent sundries from entering the bin 1 in the feeding process, a conveyor belt 3 is arranged in the bin 1 to convey materials in the bin 1, a motor 13 is arranged at a power input end of the conveyor belt 3 to provide power for the conveyor belt 3, a gate 4 is arranged at a discharge hole of the bin 1 to control the discharge amount of each feeding of the conveyor belt 3, a forging table underframe 5 is arranged at one side of the bin 1 and used for fixing a forging support frame 6, a forging concave table 14 and the forging device, an electric push rod 15 is fixed on four walls inside the forging table underframe 5, the novel forging table comprises a forging table chassis 5, a forging support frame 6 is arranged on two sides of the top surface of the forging table chassis 5, a telescopic cylinder 7 is arranged at the middle of the top end of the forging support frame 6 and is used for pulling up or falling down a connecting block 8, the connecting block 8 is arranged at the telescopic part of the telescopic cylinder 7, a forging hammer 9 is arranged at one end of the connecting block 8 and is used for forging materials, a forging concave table 14 is embedded in the middle of the top surface of the forging table chassis 5, a reset push plate 10 is connected with the telescopic part of an electric push rod 15 and is used for pushing the deviated materials to a forging point, a discharging rail 11 is connected between a conveying belt 3 and the forging concave table 14 and is used for conveying the materials from the conveying belt 3 to the forging concave table 14, and a slow vibration ground pad 16 is bonded at the bottom layer of the forging table chassis 5 and used for slowing down vibration generated by forging.

As shown in fig. 1-2, in this embodiment, the motor 13 is in bolted connection with the bin 1, the conveyor belt 3 is rotationally connected with the bin 1, the conveyor belt 3 is driven by the motor 13, so that the conveyor belt 3 can work normally, the gate 4 is hinged with the bin 1, so that the gate 4 can switch and control the material to be sent out, the cover net 17 is in bolted connection with the bin 1, the forging platform underframe 5 is in bolted connection with the electric push rod 15, the electric push rod 15 is fixed inside the forging platform underframe, the electric push rod 15 is in bolted connection with the reset push plate 10, so that the reset push plate 10 can be pushed out of the forging platform underframe 5 or retracted into the forging platform underframe 5, the forging platform underframe 5 is in bolted connection with the forging support frame 6, so that the forging device is firmly fixed on the forging support frame 6 and in bolted connection with the telescopic cylinder 7, the telescopic cylinder 7 is in bolted connection with the connecting block 8, the connecting block 8 is bolted connection with the forging hammer 9 through the telescopic cylinder 7, so that the connecting block 8 can drive the forging hammer 9 to complete forging, the forging concave table 14 is in bolted connection with the discharging rail 11, and the material can be transported to the concave table 14 stably through the discharging rail 11.

The specific implementation process of this embodiment is as follows: when forging work is carried out, cover screen 17 at feed bin 1 top and bin gate 2 of feed bin 1 side are closed, prevent debris entering feed bin from influencing forging work, start motor 13, make conveyer belt 3 get into work, conveyer belt 3 sends out the material, control the ejection of compact volume through gate 4, ensure that conveyer belt 3 only sends out the required material volume of forging at every turn, after the material is sent out feed bin 1 by conveyer belt 3, send the material to forging concave table 14 through ejection of compact rail 11, simultaneously conveyer belt 3 pauses the transport to the material, after the material got into forging concave table 14, electric putter 15 will reset push pedal 10 from forging table chassis 5 release, and by reset push pedal 10 with the material propelling movement to appointed forging position, after the completion of propelling movement work, electric putter 15 will reset push pedal 10 back in the forging table chassis 5 again, prevent reset push pedal 10, cause equipment damage, after the material reaches appointed forging position, telescopic cylinder 7 just can start connecting block 8 and drive forging hammer 9 and carry out to the material, increase the frictional force between material and the forging hammer 14 through anti-skidding screw thread 12, prevent it from carrying out slip, and after electric putter 9 stops the electric putter 9 to carry out the operation again, it is carried out the automatic stop to the forging operation after the forging 15, can be accomplished, the completion of carrying out the automatic operation to reset to the material at the forging 15 again, after the time of carrying out stable operation is reset 15, after the electric putter 9 is reset, and reset operation is carried out the material is finished, and reset is carried out, and is finished, after the automatic is finished, and is carried out, and is finished, and is carried and is finished.

The above examples are merely illustrative of the preferred embodiments of the present utility model and are not intended to limit the spirit and scope of the present utility model. Various modifications and improvements of the technical scheme of the present utility model will fall within the protection scope of the present utility model without departing from the design concept of the present utility model, and the technical content of the present utility model is fully described in the claims.

Claims (7)

1. An automatic stainless steel antiskid forging device of feed, its characterized in that: including feed bin (1), there is bin gate (2) through hinged joint on feed bin (1) lateral wall, feed bin (1) top is provided with covers net (17), install conveyer belt (3) in feed bin (1), the power input of conveyer belt (3) is provided with motor (13), feed bin (1) discharge gate department is provided with gate (4), feed bin (1) one side is provided with and forges platform chassis (5), forge inside four walls of platform chassis (5) and be fixed with electric putter (15), forge platform chassis (5) top surface both sides and be provided with forge support frame (6), forge support frame (6) top mid-mounting and have telescopic cylinder (7), connecting block (8) are installed to telescopic part of telescopic cylinder (7), connecting block (8) one end is provided with forges hammer (9), forge platform chassis (5) top surface middle part is embedded to have concave table (14), electric putter (15) telescopic part is connected with reset push pedal (10), conveyer belt (3) with forge between concave table (14) and be connected with between concave table (11) and shake-down pad (16) and shake pad (16).

2. An automatic feed stainless steel slip resistant forging apparatus as recited in claim 1, wherein: the motor (13) is connected with the bin (1) through bolts, and the conveyor belt (3) is connected with the bin (1) in a rotating mode.

3. An automatic feed stainless steel slip resistant forging apparatus as recited in claim 1, wherein: the gate (4) is hinged with the bin (1), and the covering net (17) is connected with the bin (1) through bolts.

4. An automatic feed stainless steel slip resistant forging apparatus as recited in claim 1, wherein: the forging table underframe (5) is connected with the electric push rod (15) through bolts, and the electric push rod (15) is connected with the reset push plate (10) through bolts.

5. An automatic feed stainless steel slip resistant forging apparatus as recited in claim 1, wherein: the forging table underframe (5) is connected with the forging support frame (6) through bolts, and the forging support frame (6) is connected with the telescopic cylinder (7) through bolts.

6. An automatic feed stainless steel slip resistant forging apparatus as recited in claim 1, wherein: the telescopic cylinder (7) is connected with the connecting block (8) through bolts, and the connecting block (8) is connected with the forging hammer (9) through bolts.

7. An automatic feed stainless steel slip resistant forging apparatus as recited in claim 1, wherein: the forging concave table (14) is connected with the discharging rail (11) through bolts.