CN216031716U - High-purity graphite carbon-point cutting drilling processing dust collector - Google Patents

Abstract

The utility model discloses a high-purity graphite carbon rod cutting, drilling and processing dust removal device, which comprises a sleeve; the limiting assembly is arranged above the sleeve and comprises a top cover, an air inlet pipe and an air outlet pipe; the dust removal device for cutting, drilling and processing the high-purity graphite carbon rod comprises a top cover, a sleeve, a movable plate, a traction rod, a limiting assembly and a dust removal device, wherein the movable plate is arranged below the sleeve, the top of the movable plate is provided with the traction rod, and the traction rod penetrates through the sleeve and is connected with the limiting assembly at the top of the sleeve; secondly, through the inside grafting extrusion stem at the top cap to set up the extrusion area in the bottom of extrusion stem, can improve the fixed stability of graphite carbon-point, secondly, can also laminate with the graphite carbon-point of different shapes, improve the suitability of device.

Description

High-purity graphite carbon-point cutting drilling processing dust collector

Technical Field

The utility model relates to the technical field of graphite carbon rod processing, in particular to a dust removal device for cutting, drilling and processing a high-purity graphite carbon rod.

Background

The carbon rod is a non-metal product, is used as a necessary consumable material in the production process of the carbon arc quartz crucible, is prepared by adding proper adhesive into carbon and graphite, extruding and molding the mixture, baking the mixture at 2200 ℃ and spinning the mixture into segments, and has the advantages of high temperature resistance, good conductivity and difficult fracture.

When the graphite carbon rod is processed, the graphite carbon rod is required to be cut, and a drilling device is required to be used for drilling the graphite carbon rod, so that a large amount of chips are generated.

At present, current graphite carbon-point drilling equipment is when using, directly drills to graphite carbon-point through the drill bit, and the in-process of drilling produces a large amount of pieces easily, and these pieces can follow the flow of air and enter into the air, lead to the environment a large amount of pollutions to appear, not only influence staff's healthy, still can't carry out effectual collection to the piece simultaneously, seriously influence drilling equipment's normal use, for this reason, we provide a high-purity graphite carbon-point cutting drilling processing dust collector

The information disclosed in this background section is only for enhancement of understanding of the general background of the utility model and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art already known to a person skilled in the art.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a high-purity graphite carbon rod cutting, drilling and processing dust removal device which can form air convection at a drilling position, so that the recovery and utilization of scraps are accelerated, and the recovery difficulty of materials is reduced.

Another object of the present invention is to: through the inside extrusion stem of pegging graft at the top cap to set up the extrusion band in the bottom of extrusion stem, not only can carry out one step carry on spacingly to the piece, can also improve the fixed stability of graphite carbon-point simultaneously, avoid it to take place to rock when drilling, secondly, can also laminate with graphite carbon-point of different shapes or size, improve the suitability of device.

In order to achieve the above object, the present invention provides a dust removing device for cutting, drilling and processing a high purity graphite carbon rod, comprising:

the top of the sleeve is provided with a groove for placing the graphite carbon rod, and the sleeve is cylindrical;

the limiting component is arranged above the sleeve and comprises a cylindrical top cover, and an air inlet pipe and an air outlet pipe which are arranged on two sides of the top cover; and

the movable plate is used for driving the limiting assembly to move up and down, the movable plate is installed below the sleeve, a traction rod is installed at the top of the movable plate, and the traction rod penetrates through the sleeve and is connected with the limiting assembly at the top of the sleeve through a bolt.

In one or more embodiments, a telescopic rod for moving the movable plate up and down is connected to the bottom of the movable plate, and the outer diameter of the movable plate is equal to that of the sleeve.

The telescopic rod is arranged at the bottom of the movable plate, the movable plate can be driven to move up and down, and the top of the movable plate is connected with the bottom of the limiting assembly through the traction rod, so that the limiting assembly can be driven to move up and down together in the moving process of the movable plate, and the limiting assembly covers the outer part of the graphite carbon rod to limit the graphite carbon rod.

In one or more embodiments, the length of the traction rod is greater than that of the sleeve, and the traction rod penetrates through a through hole formed in the inner wall of the movable plate.

Through setting up the through-hole in telescopic inside, make things convenient for the traction lever to move about its inside from top to bottom, secondly, through being greater than telescopic length with the length design of traction lever, can make to have certain clearance between spacing subassembly and the telescopic top, conveniently place the graphite carbon-point.

In one or more embodiments, a limiting cylinder is inserted into the center of the top cover, a disc-shaped extrusion plate is connected to the bottom of the limiting cylinder, and an anti-skid rubber pad is bonded to the bottom of the extrusion plate.

In one or more embodiments, the extrusion plate is connected with the inner top surface of the top cover through a spring, and the outer wall of the limiting cylinder is provided with blocking pieces at equal intervals.

In one or more embodiments, the bottom of the top cover is provided with a clamping groove, and the clamping groove and the groove formed in the top of the sleeve are in one-to-one correspondence from top to bottom.

In one or more embodiments, the limiting assembly further comprises a plurality of groups of extrusion rods inserted into the top cover and extrusion belts connected to the end portions of the extrusion rods, the extrusion rods are connected with the top cover through springs, and the plurality of groups of extrusion rods are distributed at equal intervals along the inner wall of the clamping groove.

In one or more embodiments, the end of the extrusion stem is "T" shaped and the extrusion band is wrapped around the end of the extrusion stem.

The end part of the extrusion rod is designed to be T-shaped, and the extrusion belt wraps the end part of the extrusion rod, so that the extrusion belt and the surface of the graphite carbon rod can be driven to extrude when the extrusion rod presses down.

In one or more embodiments, the two ends of the squeeze band are connected to the bottom of the top cap, respectively.

Compared with the prior art, the air inlet pipe and the air outlet pipe are respectively arranged on the two sides of the top cover, so that air convection can be formed at the drilling position, the recovery and the utilization of scraps are accelerated, and the recovery difficulty of materials is reduced;

secondly, the movable plate is arranged at the bottom of the sleeve, and the draw bar is arranged between the movable plate and the limiting assembly and can cover the drill hole of the graphite carbon rod, so that the position of the chips is limited, the chips are prevented from splashing everywhere, and the subsequent recovery is facilitated;

thirdly, through the inside extrusion stem of pegging graft at the top cap to set up the extrusion area in the bottom of extrusion stem, not only can carry out one step and carry on spacingly to the piece, can also improve the fixed stability of graphite carbon-point simultaneously, avoid it to take place to rock when drilling, secondly, can also laminate with graphite carbon-point of different shapes or size, improve the suitability of device.

Drawings

Fig. 1 is one of overall structural views according to an embodiment of the present invention.

Fig. 2 is a second overall structure diagram according to an embodiment of the present invention.

Fig. 3 is a block diagram of a spacing assembly in accordance with an embodiment of the present invention.

Fig. 4 is a partial sectional view of a top cover in accordance with an embodiment of the present invention.

Illustration of the drawings: 1. a sleeve; 2. a limiting component; 21. a top cover; 22. an air inlet pipe; 23. an exhaust pipe; 24. a limiting cylinder; 25. an extrusion stem; 26. extruding the belt; 3. a draw bar; 4. a movable plate.

Detailed Description

The following detailed description of the present invention is provided in conjunction with the accompanying drawings, but it should be understood that the scope of the present invention is not limited to the specific embodiments.

Throughout the specification and claims, unless explicitly stated otherwise, the word "comprise", or variations such as "comprises" or "comprising", will be understood to imply the inclusion of a stated element or component but not the exclusion of any other element or component.

Example one

As shown in fig. 1 to 3, a dust removing apparatus for cutting, drilling and processing a high purity graphite carbon rod according to an embodiment of the present invention includes:

the graphite carbon rod sleeve comprises a sleeve 1, wherein a groove for placing a graphite carbon rod is formed in the top of the sleeve 1, and the sleeve 1 is cylindrical;

the limiting component 2 is used for removing dust, the limiting component 2 is arranged above the sleeve 1, and the limiting component 2 comprises a cylindrical top cover 21, and an air inlet pipe 22 and an air outlet pipe 23 which are arranged on two sides of the top cover 21; and

the movable plate 4 is used for driving the limiting component 2 to move up and down, the movable plate 4 is installed below the sleeve 1, the traction rod 3 is installed at the top of the movable plate 4, and the traction rod 3 penetrates through the sleeve 1 and is connected with the limiting component 2 at the top of the sleeve 1 through a bolt.

As shown in fig. 2, the bottom of the movable plate 4 is connected with a telescopic rod for moving the movable plate to move up and down, and the outer diameter of the movable plate 4 is equal to the outer diameter of the sleeve 1.

The telescopic rod is arranged at the bottom of the movable plate 4, the movable plate 4 can be driven to move up and down, and the top of the movable plate 4 is connected with the bottom of the limiting component 2 through the traction rod 3, so that the limiting component 2 can be driven to move up and down together in the moving process of the movable plate 4, and the limiting component 2 is covered outside the graphite carbon rod to limit the graphite carbon rod.

As shown in fig. 1 and 2, the length of the traction rod 3 is greater than that of the sleeve 1, and the traction rod 3 passes through a through hole formed in the inner wall of the movable plate 4.

Through setting up the through-hole in sleeve 1's inside, make things convenient for traction lever 3 activity from top to bottom in its inside, secondly, through the length design with traction lever 3 for being greater than sleeve 1's length, can make and have certain clearance between spacing subassembly 2 and the top of sleeve 1, conveniently place the graphite carbon-point.

As shown in fig. 3, a limiting cylinder 24 is inserted into the center of the top cover 21, a disc-shaped extrusion plate is connected to the bottom of the limiting cylinder 24, and an anti-skid rubber pad is bonded to the bottom of the extrusion plate.

The extrusion plate is arranged at the bottom of the limiting cylinder 24, and the anti-skid rubber pad is bonded at the bottom of the extrusion plate, so that the graphite carbon rod can be extruded and fixed in the pressing process of the limiting component 2.

As shown in FIG. 3, the extrusion plate is connected with the inner top surface of the top cover 21 through a spring, and the outer wall of the limiting cylinder 24 is provided with a baffle at equal intervals.

Through passing through spring coupling between stripper plate and top cap 21 internal top face, make things convenient for the stripper plate to push down, push down on the surface of graphite carbon-point.

As shown in fig. 1, the bottom of the top cover 21 is provided with a slot, and the slot corresponds to the slot provided at the top of the sleeve 1.

The clamping grooves are formed in the bottom of the top cover 21 and correspond to the grooves formed in the top of the sleeve 1 one by one, and the upper surface and the lower surface of the graphite carbon rod are fixed conveniently.

When the outer wall of the graphite carbon rod needs to be drilled, firstly, the extension of the telescopic rod at the bottom of the movable plate 4 is controlled, the movable plate 4 drives the traction rod 3 on the movable plate to move upwards together, the top of the traction rod 3 is connected with the limiting component 2, the limiting component 2 can be driven to move upwards together in the process of moving upwards of the traction rod 3 to form the shape shown in fig. 1, then the graphite carbon rod is inserted between the sleeve 1 and the limiting component 2, the graphite carbon plate is clamped into the groove in the top of the sleeve 1, after the completion, the telescopic rod is controlled to drive the limiting component 2 to move downwards, the graphite carbon rod is covered outside the graphite carbon rod and is extruded and limited to form the shape shown in fig. 2, then, the drill bit penetrates through the limiting cylinder 24 to drill the graphite carbon rod below the limiting cylinder 24, and scraps generated by drilling are limited in the top cover 21.

When the end of the graphite carbon rod needs to be drilled, the limiting assembly 2 is separated from the traction rod 3 by using a tool, the graphite carbon rod is inserted into the sleeve 1, the limiting assembly 2 is connected with the traction rod 3, after the completion, the telescopic rod is controlled to drive the limiting assembly 2 to move downwards, so that the graphite carbon rod is covered at the end of the graphite carbon rod and is extruded and limited, the graphite carbon rod is formed as shown in figure 2, a drill bit penetrates through the limiting cylinder 24 and drills the graphite carbon rod below the limiting cylinder 24, chips generated by drilling are limited in the top cover 21, the chips are prevented from splashing everywhere, and subsequent recovery is facilitated.

When the material is retrieved, be connected the intake pipe 22 of top cap 21 one side with external air-blower, the blast pipe 23 of opposite side is connected with the air extractor for the piece of being restricted in top cap 21 inside is received, prevents that it from outwards splashing, thereby accelerates clastic recovery and is utilizing, reduces the recovery degree of difficulty of material.

Example two

As shown in fig. 3 to 4, the limiting component 2 further includes a plurality of sets of pressing rods 25 inserted into the top cover 21 and pressing belts 26 connected to the ends of the pressing rods 25, the pressing rods 25 are connected to the top cover 21 through springs, and the plurality of sets of pressing rods 25 are distributed at equal intervals along the inner wall of the slot.

As shown in fig. 4, the end of the pressing rod 25 is "T" shaped, and the pressing band 26 is wrapped around the end of the pressing rod 25.

The end part of the extrusion rod 25 is designed to be T-shaped, and the extrusion belt 26 wraps the end part of the extrusion rod 25, so that the extrusion belt 26 and the surface of the graphite carbon rod can be driven to extrude when the extrusion rod 25 is pressed downwards.

As shown in fig. 4, both ends of the pressing band 26 are connected to the bottom of the top cover 21, respectively.

When spacing subassembly 2 pushes down, be located the extrusion stem 25 in the top cap 21 draw-in groove, under the effect of its top spring again, extrude downwards, because multiunit extrusion stem 25 equidistant distribution is in the below of top cap 21, and extrusion band 26 parcel is at the tip of extrusion stem 25, consequently when extrusion stem 25 shifts down, make the surface laminating of extrusion band 26 and graphite carbon-point, not only can carry out one step carry out spacingly to the piece (avoid the piece to fly out from the clearance between top cap 21 and the graphite carbon-point), can also improve the fixed stability of graphite carbon-point simultaneously, avoid it to take place to rock when drilling, secondly, can also laminate with the graphite carbon-point of different shapes or size, improve the suitability of device.

The foregoing descriptions of specific exemplary embodiments of the present invention have been presented for purposes of illustration and description. It is not intended to limit the utility model to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments were chosen and described in order to explain certain principles of the utility model and its practical application to enable one skilled in the art to make and use various exemplary embodiments of the utility model and various alternatives and modifications as are suited to the particular use contemplated. It is intended that the scope of the utility model be defined by the claims and their equivalents.

Claims (9)

1. The utility model provides a high-purity graphite carbon-point cutting drilling processing dust collector which characterized in that, this dust collector includes:

the graphite carbon rod sleeve comprises a sleeve (1), wherein a groove for placing a graphite carbon rod is formed in the top of the sleeve (1), and the sleeve (1) is cylindrical;

the dust removal device comprises a limiting component (2) for removing dust, wherein the limiting component (2) is arranged above a sleeve (1), and the limiting component (2) comprises a cylindrical top cover (21), and an air inlet pipe (22) and an air outlet pipe (23) which are arranged on two sides of the top cover (21); and

the movable plate (4) is used for driving the limiting component (2) to move up and down, the movable plate (4) is installed below the sleeve (1), the traction rod (3) is installed at the top of the movable plate (4), the traction rod (3) penetrates through the sleeve (1) and is connected with the limiting component (2) at the top of the sleeve (1) through a bolt.

2. The dust removing device for cutting, drilling and processing the high-purity graphite carbon rod as claimed in claim 1, wherein a telescopic rod for moving the movable plate (4) up and down is connected to the bottom of the movable plate (4), and the outer diameter of the movable plate (4) is equal to that of the sleeve (1).

3. The device for cutting, drilling, processing and dedusting the high-purity graphite carbon rod as claimed in claim 1, wherein the length of the traction rod (3) is greater than that of the sleeve (1), and the traction rod (3) penetrates through a through hole formed in the inner wall of the movable plate (4).

4. The dust removing device for cutting, drilling and processing of the high-purity graphite carbon rod as claimed in claim 1, wherein a limiting cylinder (24) is inserted into the center of the top cover (21), a disk-shaped extrusion plate is connected to the bottom of the limiting cylinder (24), and an anti-skid rubber pad is bonded to the bottom of the extrusion plate.

5. The dust removing device for cutting, drilling and processing the high-purity graphite carbon rod as claimed in claim 4, wherein the extrusion plate is connected with the inner top surface of the top cover (21) through a spring, and the outer wall of the limiting cylinder (24) is provided with baffle plates at equal intervals.

6. The device for cutting, drilling, processing and dedusting the high-purity graphite carbon rod as claimed in claim 1, wherein a clamping groove is formed in the bottom of the top cover (21), and the clamping groove and a groove formed in the top of the sleeve (1) are in one-to-one correspondence from top to bottom.

7. The cutting, drilling, processing and dust removing device for the high-purity graphite carbon rods as claimed in claim 6, wherein the limiting assembly (2) further comprises a plurality of groups of extrusion rods (25) inserted in the top cover (21) and extrusion belts (26) connected to the ends of the extrusion rods (25), the extrusion rods (25) are connected with the top cover (21) through springs, and the plurality of groups of extrusion rods (25) are distributed at equal intervals along the inner wall of the clamping groove.

8. The device for removing dust in cutting, drilling and processing of the high-purity graphite carbon rod as claimed in claim 7, wherein the end of the extrusion rod (25) is T-shaped, and the extrusion belt (26) wraps the end of the extrusion rod (25).

9. The high purity graphite carbon rod cutting, drilling, machining and dedusting device as claimed in claim 7, wherein both ends of the extrusion belt (26) are respectively connected with the bottom of the top cover (21).

Images