CN217552773U - Pore-forming device for graphite material - Google Patents

Abstract

The utility model discloses a pore-forming device for graphite material, which comprises a frame, be equipped with perforating device and anchor clamps in the frame, it is equipped with a plurality of moulds to press from both sides on the anchor clamps, be provided with the dust absorption subassembly in the frame, be connected through the drive assembly transmission between the output source of dust absorption subassembly and perforating device, still be provided with the absorption subassembly with dust absorption subassembly looks adaptation in the frame. The utility model discloses can absorb the dust that the in-process that punches produced, avoid the dust to cause the pollution to operational environment, need not the manual work and clear up, need not to set up independent dust collecting equipment in addition simultaneously and absorb the dust, reduce the running cost of device, guarantee the economic benefits of producer.

Description

Pore-forming device for graphite material

Technical Field

The utility model relates to a graphite material processing technology field especially relates to a pore-forming device for graphite material.

Background

One of the main uses of graphite is in the production of refractory materials including refractory bricks, crucibles, continuous casting powders, casting cores, molds, detergents and refractory materials.

Graphite material need use the pore-forming device to punch on graphite material man-hour adding, the in-process of punching can produce a large amount of graphite dust, nevertheless do not have the function of absorbing the dust on the pore-forming device now, lead to the dust to scatter easily on the workstation, cause the pollution to operational environment, still need the staff to clear up after processing, the practicality of pore-forming device has been restricted, some producers can adopt independent dust collecting equipment to handle the dust that the pore-forming in-process produced, but this can increase production input and processing cost, indirect reduction the economic benefits of producer, so, need design a pore-forming device for graphite material to solve above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing a pore-forming device for graphite materials.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a pore-forming device for graphite material, includes the frame, be equipped with perforating device and anchor clamps in the frame, it has a plurality of moulds to press from both sides the dress on the anchor clamps, be provided with dust absorption component in the frame, be connected through the transmission of drive assembly between dust absorption component and the output source of perforating device, still be provided with the absorption subassembly with dust absorption component looks adaptation in the frame.

As a preferred technical scheme of the utility model, the dust absorption subassembly includes mounting box, lead screw, movable plate, hollow utricule, each trachea and check valve, mounting box fixed connection is on perforating device's casing, the one end of lead screw is rotated the assembly and is in the inner face of mounting box, and the other end extends to the outside of mounting box, the movable plate screw thread cup joints on the lead screw, the one side of hollow utricule bonds in the inner face of mounting box, and the another side bonds in the side of movable plate, each tracheal one end all communicates each other with hollow utricule, each the check valve is installed respectively on each trachea.

As a preferred technical scheme of the utility model, drive assembly includes each synchronizing wheel and drive belt, one of them the synchronizing wheel is fixed to be cup jointed on perforating device's output source, another the synchronizing wheel cover is established and is located the outside one end of mounting box at the lead screw, the drive belt cover is established on each synchronizing wheel.

As a preferred technical scheme of the utility model, the absorption assembly includes each suction box and a plurality of dust absorption hole, each the equal fixed connection of suction box is in the frame, and communicates each other through the pipeline between each suction box, each the dust absorption hole is seted up respectively at the side that each suction box is close to each other, one of them the suction box communicates each other with the one end that hollow utricule was kept away from to one of them trachea.

As a preferred technical scheme of the utility model, the mounting box all is the rectangle structure with the cross-section of movable plate, and laminates each other between the inner face of mounting box and the side of movable plate.

As an optimal technical scheme of the utility model, each all be provided with anti-skidding line in the outer periphery of synchronizing wheel and the outer fringe of drive belt.

The utility model discloses a set up dust absorption assembly, transmission assembly and absorption assembly, at dust absorption assembly, transmission assembly and absorption assembly's synergism is down, a plurality of suction holes on two suction box can be internal to the graphite dust that the in-process that punches produced suction hollow bag, the staff only needs to be connected the trachea of discharge dust with a dust collecting container, can absorb the dust that the in-process that punches produced, avoid the dust to cause the pollution to operational environment, need not the manual work to clear up, need not to set up independent dust collecting equipment in addition simultaneously and absorb the dust, the running cost of device is reduced, guarantee the economic benefits of producer.

Drawings

Fig. 1 is a schematic structural diagram of a pore-forming device for graphite material according to the present invention;

fig. 2 is a schematic structural view of a fixture and a plurality of molds in a pore-forming device for graphite material according to the present invention;

fig. 3 is a schematic structural diagram of a mold in a pore-forming device for graphite material according to the present invention;

fig. 4 is a schematic structural view of a dust suction assembly in a pore-forming device for graphite materials according to the present invention.

In the figure: 10 machine frames, 20 perforating devices, 30 clamps, 40 moulds, 401 cylinders, 402 cylinder covers, 403 through holes, 50 dust collection assemblies, 501 installation boxes, 502 lead screws, 503 moving plates, 504 hollow capsules, 505 air pipes, 506 one-way valves, 60 transmission assemblies, 601 synchronizing wheels, 602 transmission belts, 70 absorption assemblies, 701 dust collection boxes and 702 dust collection holes.

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.

Referring to fig. 1-4, a pore-forming device for graphite materials includes a frame 10, a perforating device 20 and a fixture 30 are mounted on the frame 10, a specific working principle of the perforating device 20 is mature prior art and is not an innovative part of the present technical solution, which is not shown in the figures and is not described herein too much, a plurality of molds 40 are mounted on the fixture 30, a dust collection assembly 50 is disposed on the frame 10, the dust collection assembly 50 is in transmission connection with an output source of the perforating device 20 through a transmission assembly 60, and an absorption assembly 70 adapted to the dust collection assembly 50 is further disposed on the frame 10.

Referring to fig. 1 to 4, the dust collection assembly 50 includes a mounting box 501, a lead screw 502, a moving plate 503, a hollow bag 504, air pipes 505, and check valves 506, the mounting box 501 is fixedly connected to a housing of the perforating device 20, one end of the lead screw 502 is rotatably mounted on an inner surface of the mounting box 501, the other end extends to an outside of the mounting box 501, the moving plate 503 is sleeved on the lead screw 502 by a screw thread, one surface of the hollow bag 504 is bonded on the inner surface of the mounting box 501, the other surface is bonded on a side surface of the moving plate 503, one end of each air pipe 505 is communicated with the hollow bag 504, each check valve 506 is mounted on each air pipe 505, a flow limiting direction of each check valve 506 is opposite, and the arrangement is convenient for the hollow bag 504 to absorb dust generated in a perforating process.

Referring to fig. 1 to 4, the transmission assembly 60 includes synchronizing wheels 601 and a transmission belt 602, one of the synchronizing wheels 601 is fixedly sleeved on an output source of the perforating device 2, the other synchronizing wheel 601 is sleeved on one end of the screw rod 502 located outside the mounting box 501, the transmission belt 602 is sleeved on each synchronizing wheel 601, and by arranging the transmission assembly 60, dust is not required to be absorbed by a separate dust absorption device, so that the operation cost of the device is reduced.

Referring to fig. 1 to 4, the absorption assembly 70 includes each dust box 701 and a plurality of dust suction holes 702, each dust box 701 is fixedly connected to the frame 10, and the dust boxes 701 are communicated with each other through a pipeline, each dust suction hole 702 is respectively opened on a side surface of each dust box 701 close to each other, one of the dust boxes 701 is communicated with one end of one of the air pipes 505 far from the hollow bag 504.

Referring to fig. 1 to 4, the cross sections of the mounting box 501 and the moving plate 503 are both rectangular structures, and the inner surface of the mounting box 501 and the side surface of the moving plate 503 are attached to each other, so that the moving plate 503 can be prevented from rotating by the screw 502 when being driven to rotate, and the moving plate 503 can only do linear reciprocating movement.

Referring to fig. 1 to 4, the outer circumference of each synchronizing wheel 601 and the outer edge of the driving belt 602 are provided with anti-slip threads, so that the stability of the operation of the device can be ensured.

The utility model discloses a concrete theory of operation as follows:

the utility model provides a pore-forming device is when the in-service use, perforating device 2 when operation, perforating device 2's output can drive lead screw 502 through two synchronizing wheels 601 and drive belt 602 and take place to rotate, because the cross-section of mounting box 501 and movable plate 503 all is the rectangle structure, and laminate each other between the inner face of mounting box 501 and the side of movable plate 503, so lead screw 502 can not drive movable plate 503 when rotating and take place to rotate, make movable plate 503 only can be along lead screw 502 do straight reciprocating motion in mounting box 501, movable plate 503 can be continuous extrudees hollow utricule 504 at the in-process that removes, because the current-limiting opposite direction of two check valves 506, one of them check valve 506 restriction air current can only get into in hollow utricule 504, another check valve 506 restriction air current can only flow from hollow utricule 504, so at 503 continuous extrusion hollow utricule 504 in-process, a plurality of suction holes 702 on two suction boxes 701 can inhale hollow utricules the graphite dust that the in-process produced in the hollow utricule 504, the staff is connected the trachea 505 of discharging the dust with a collection container, can be to the dust that produces in-process of punching, can carry out, the dust collection container that need not explain, this is the mature collection container, do not need too much, this, the existing technology is not too much, do not yet, it is not do.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. The pore-forming device for the graphite material comprises a frame (10), wherein a punching device (20) and a clamp (30) are assembled on the frame (10), a plurality of dies (40) are clamped on the clamp (30), and the pore-forming device is characterized in that a dust suction assembly (50) is arranged on the frame (10), the dust suction assembly (50) is in transmission connection with an output source of the punching device (20) through a transmission assembly (60), and an absorption assembly (70) matched with the dust suction assembly (50) is further arranged on the frame (10).

2. The pore-forming device for the graphite material as claimed in claim 1, wherein the dust collection assembly (50) comprises a mounting box (501), a lead screw (502), a moving plate (503), a hollow capsule (504), air pipes (505) and one-way valves (506), the mounting box (501) is fixedly connected to a shell of the perforating device (20), one end of the lead screw (502) is rotatably assembled on the inner surface of the mounting box (501), the other end of the lead screw extends to the outside of the mounting box (501), the moving plate (503) is in threaded connection with the lead screw (502), one surface of the hollow capsule (504) is bonded to the inner surface of the mounting box (501), the other surface of the hollow capsule is bonded to the side surface of the moving plate (503), one end of each air pipe (505) is communicated with the hollow capsule (504), and each one-way valve (506) is respectively installed on each air pipe (505).

3. The pore-forming device for the graphite material as claimed in claim 2, wherein the transmission assembly (60) comprises synchronous wheels (601) and a transmission belt (602), wherein one synchronous wheel (601) is fixedly sleeved on an output source of the perforating device (20), the other synchronous wheel (601) is sleeved on one end of the screw rod (502) located outside the mounting box (501), and the transmission belt (602) is sleeved on each synchronous wheel (601).

4. The pore-forming device for the graphite material as claimed in claim 1, wherein the absorption assembly (70) comprises each dust box (701) and a plurality of dust suction holes (702), each dust box (701) is fixedly connected to the frame (10), the dust boxes (701) are communicated with each other through a pipeline, each dust suction hole (702) is respectively formed in one side surface of each dust box (701) close to each other, and one of the dust boxes (701) is communicated with one end of one of the air pipes (505) far away from the hollow capsule body (504).

5. The pore-forming device for the graphite material as claimed in claim 2, wherein the mounting box (501) and the moving plate (503) are rectangular in cross section, and the inner surface of the mounting box (501) and the side surface of the moving plate (503) are attached to each other.

6. A pore-forming device for graphite material as claimed in claim 3, characterized in that the outer circumferential surface of each synchronizing wheel (601) and the outer edge of the transmission belt (602) are provided with anti-slip threads.

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