CN210795777U - Carbon nanotube collecting device - Google Patents

Abstract

The utility model relates to a carbon nanotube collecting device, which is used for collecting carbon nanotubes on a liner; the method comprises the following steps: a base; the clamp is arranged on the base and used for clamping the gasket; the scraping plate is arranged above the clamp; the scraping plate comprises a main body part and a scraping edge, and the scraping edge is arranged at one end of the main body part; the sucking assembly is arranged above the clamp; the absorption component and the scraper plate are arranged at intervals relatively, and the absorption component is used for absorbing the carbon nano tubes on the liner; when collecting the carbon nanotube of liner, the scraper blade is actuated so that the scraping edge is close to the liner, and the suction plate is actuated so as to be close to the liner on the anchor clamps, and the scraping edge scrapes the carbon nanotube on the liner, so that carbon nanotube and liner separation, the absorption subassembly absorb and are scraped the carbon nanotube who has shelled by the scraper blade, absorb the carbon nanotube through adopting the absorption subassembly, and collect carbon nanotube through adopting the scraper blade is supplementary to be absorbed the subassembly, and easy operation, convenience effectively reduce artifical low in labor strength and improve collection efficiency.

Description

Carbon nanotube collecting device

Technical Field

The utility model relates to a nano-material production technical field especially relates to a carbon nanotube collection device.

Background

The carbon nano tube is a tubular object formed by coaxially winding single-layer carbon atoms or sleeving single-layer graphite cylinders along coaxial layers as a one-dimensional nano material, has light weight and perfect connection of a hexagonal structure, and has many abnormal mechanical, electrical and chemical properties. In recent years, as carbon nanotubes and nanomaterials are studied deeply, their broad application prospects are continuously revealed, for example, the electrical properties of the carbon nanotubes and nanomaterials are utilized for field emission electron sources, nano field effect transistors, hydrogen storage materials, high-strength fibers and the like.

The preparation method of carbon nanotubes is mainly Chemical Vapor Deposition (CVD), including microwave plasma CVD, radio frequency plasma CVD, hot wire CVD, etc. Carbon nanotube quality is light, electric conductivity, heat conductivity and certain viscidity, and in traditional art, to the collection of the carbon nanotube of growing on the silicon chip substrate, adopt the manual mode of scraping to collect carbon nanotube usually in traditional art, and artifical intensity of labour is high, collects inefficiency.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide a carbon nanotube collecting device, which is simple and convenient to operate, and can effectively reduce the labor intensity and improve the collecting efficiency, in order to solve the problems of the conventional techniques.

A carbon nanotube collecting device is used for collecting carbon nanotubes on a liner; the method comprises the following steps:

a base;

the clamp is arranged on the base and used for clamping the gasket;

the scraping plate is arranged above the clamp; the scraping plate comprises a main body part and a scraping edge, and the scraping edge is arranged at one end of the main body part;

the sucking assembly is arranged above the clamp; the suction assembly and the scraper are oppositely arranged at intervals, and the suction assembly is used for sucking the carbon nano tubes on the liner;

when the carbon nanotubes on the mat are collected, the scraper is actuated to make the scraping edge close to the mat, and the suction plate is actuated to close to the mat on the jig.

When the carbon nano tube collecting device collects the carbon nano tubes, the scraping plate is driven to enable the scraping edge to be close to the gasket, and the suction assembly is actuated to be close to the gasket on the clamp; scrape the sword and scrape the carbon nanotube who shells on the liner to make carbon nanotube and liner separation, absorb the subassembly and absorb the carbon nanotube of being scraped and being shelled by the scraper blade, absorb the subassembly through adopting and absorb the carbon nanotube, and collect carbon nanotube through adopting the scraper blade is supplementary to be absorb the subassembly, easy operation, convenience effectively reduce artifical low in labor strength and improve collection efficiency.

In one embodiment, the suction assembly comprises a suction plate and a suction pipe connected with the suction plate, the suction plate is arranged opposite to the scraper at a distance, and the suction plate is provided with a suction cavity and a suction opening communicated with the suction cavity; the air suction pipe is communicated with the air suction cavity and is used for being respectively connected with an external negative pressure device and a collection chamber.

In one embodiment, the suction opening is arranged at one end of the suction plate, and the suction opening is a strip-shaped opening.

In one embodiment, the surface of the scraping blade, the inner wall of the suction opening, the inner wall of the suction cavity and the inner wall of the suction pipe are coated with anti-sticking layers.

In one embodiment, during the process of collecting the carbon nanotubes, the scraper and the suction plate move from the scraper to the direction of the suction plate along the radial direction of the liner, the scraper is attached to the liner, and the suction plate and the liner are kept at a preset distance.

In one embodiment, the scraper is in an inclined state relative to the clamp, and the suction plate is in an inclined state relative to the clamp; and the inclination direction of the suction plate is opposite to that of the scraper.

In one embodiment, the suction port is disposed opposite to the scraping edge, and a predetermined distance is maintained between the suction port and the scraping edge during the movement of the squeegee and the suction plate in the radial direction of the pad.

In one embodiment, the device further comprises a bracket, a horizontal driver arranged on the bracket, and a lifting driver arranged on the horizontal driver; the lifting driver is connected with the scraper and the suction plate, and the scraper and the suction plate are located between the lifting driver and the clamp.

In one embodiment, a piston rod of the lifting driver is connected with an adapter plate, the scraper is connected with a hanging rod, the hanging rod is connected with the adapter plate, the suction plate is connected with a suspender, and the suspender is connected with the adapter plate.

In one embodiment, the clamp comprises a clamping driver and at least two clamping jaws connected with the clamping driver, the clamping driver is arranged on the base, and the at least two clamping jaws are oppositely arranged; the clamping jaw comprises a telescopic rod and a stop block, one end of the telescopic rod is connected with the clamping driver, and the stop block is arranged at one end, far away from the clamping driver, of the telescopic rod.

In one embodiment, the scraping edge is located between two oppositely disposed stoppers when the carbon nanotubes are collected.

Drawings

Fig. 1 is a schematic structural view of a carbon nanotube collecting device according to a first embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a base and a clamp of the carbon nanotube collecting device shown in FIG. 1;

FIG. 3 is a schematic structural view of a scraper and a suction assembly in the carbon nanotube collecting device shown in FIG. 1;

fig. 4 is a schematic structural diagram of a carbon nanotube collecting device according to a second embodiment of the present invention.

The meaning of the reference symbols in the drawings is:

the carbon nanotube suction device comprises a gasket 100, a carbon nanotube 200, a base 10, a mounting hole 11, a clamp 20, a clamping driver 21, a clamping jaw 22, a telescopic rod 23, a stop block 24, a limiting groove 25, a supporting column 26, a convex button 27, a scraper 30, a main body part 31, a scraping edge 32, a hanging rod 33, a suction assembly 40, a suction plate 41, an air suction pipe 42, a suction cavity 43, a suction port 44, a hanging rod 45, a support 50, a horizontal driver 60, a lifting driver 70, a piston rod 71 and an adapter plate 72.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully below. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly on" another element, there are no intervening elements present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Referring to fig. 1 to 3, a carbon nanotube collecting device according to a first embodiment of the present invention is used for collecting carbon nanotubes 200 on a gasket 100, wherein the gasket 100 is a silicon wafer, and in this embodiment, the gasket 100 is a circular disc; the grown carbon nanotubes 200 are powdery, light in weight, and have a certain viscosity. The carbon nanotube collecting device includes a base 10, a clamp 20, a scraper 30 and a suction assembly 40. A clamp 20 is installed on the base 10, the clamp 20 being used to clamp the gasket 100; the scraper 30 is disposed above the jig 20, and the scraper 30 is used to scrape the carbon nanotubes 200 on the liner 100. The suction assembly 40 is disposed above the fixture 20, the suction assembly 40 is spaced from the scraper 30, and the suction assembly 40 is used for sucking the carbon nanotubes 200 on the surface of the mat 100.

Referring to fig. 1 and 2, in the present embodiment, the base 10 is a square plate; of course, in other embodiments, the base 10 may have other shapes. Be equipped with mounting hole 11 on the base 10, mounting hole 11 is a plurality of, and a plurality of mounting holes 11 set up along base 10's avris circumference interval respectively, and mounting hole 11 is used for with external stationary plane fixed connection.

Referring to fig. 2, the clamping device 20 includes a clamping driver 21 and at least two clamping jaws 22 connected to the clamping driver 21, wherein the at least two clamping jaws 22 are disposed opposite to each other, and the two clamping jaws 22 are used for clamping on two opposite sides of the pad 100; a clamping driver 21 is arranged on the base 10, the clamping driver 21 being adapted to drive at least two oppositely arranged clamping jaws 22 towards and away from each other, i.e. to drive the clamping jaws 22 to clamp or spread. In the present embodiment, the number of the clamping jaws 22 is four, four clamping jaws 22 are arranged opposite to each other in pairs, and the four clamping jaws 22 are uniformly clamped on the peripheral side of the pad 100 to improve the stability of clamping the pad 100. In the present embodiment, the clamp actuator 21 is a cylinder; in other embodiments, the clamping driver 21 may also be a driving mechanism composed of a motor and a lead screw, which is not limited herein.

Further, the clamping jaw 22 comprises a telescopic rod 23 and a stop block 24, one end of the telescopic rod 23 is connected with the clamping driver 21, the upper surface of the telescopic rod 23 is flush with the upper surface of the clamping driver 21, and the clamping driver 21 is used for driving the telescopic rod 23 to extend or shorten. The stop 24 is arranged at the end of the telescopic rod 23 remote from the clamping drive 21. The stopper 24 has a stopper groove 25 formed at an inner side thereof, and the stopper groove 25 is used to engage the gasket 100 to prevent the gasket 100 from moving up and down. Further, the spacing groove 25 is spaced apart from the expansion link 23 and the clamping driver 21 in the longitudinal direction, so that when the pad 100 is clamped, the pad 100 is spaced apart from the expansion link 23 and the clamping driver 21, thereby preventing the lower surface of the pad 100 from contacting the upper surface of the expansion link 23 and the upper surface of the clamping driver 21 and being worn.

In one embodiment, the telescopic rod 23 is further provided with a supporting column 26, the supporting column 26 is located between the stopper 24 and the clamping driver 21, and the supporting column 26 is used for supporting the pad 100, so as to effectively prevent the pad 100 from sagging, and ensure that the upper surface of the pad 100 is kept flat, so that the scraper 30 can better scrape the carbon nanotubes 200 on the pad 100 and the suction assembly 40 can better suck the carbon nanotubes 200 on the pad 100. In one embodiment, the protruding button 27 is disposed on the supporting column 26, and the surface of the protruding button 27 is a cambered surface, when the supporting column 26 supports the pad 100, the supporting column 26 contacts with the lower surface of the pad 100 through the protruding button 27, which effectively reduces the contact area with the pad 100, and effectively prevents the pad 100 from being worn when supporting the pad 100.

Referring to fig. 1 and 3, when the carbon nanotubes 200 on the mat 100 are collected, the scraper 30 is driven to be close to the mat 100 on the jig 20, and the carbon nanotubes 200 on the mat 100 are scraped by the scraper 30 to be separated from the mat 100, so that the carbon nanotubes 200 on the mat 100 can be more easily sucked by the suction assembly 40. In one embodiment, when the carbon nanotubes 200 on the mat 100 are collected, the scraper 30 is inclined with respect to the holder 20, so that the scraper 30 scrapes the carbon nanotubes 200 in an inclined state, thereby more easily scraping the carbon nanotubes 200. Specifically, the scraper 30 includes a main body 31 and a scraping edge 32, the main body 31 is a flat plate, the scraping edge 32 is disposed at one end of the main body 31, and the scraping edge 32 is used for scraping the carbon nanotube 200; further, the scraping edge 32 is in a strip shape, so that all the carbon nanotubes 200 on the same straight line of the liner 100 can be scraped simultaneously, and the working efficiency is effectively improved.

The suction assembly 40 comprises a suction plate 41 and a suction pipe 42 connected with the suction plate 41; the suction plate 41 is provided with a suction cavity 43 and a suction port 44 communicated with the suction cavity 43, the suction cavity 43 is arranged in the suction plate 41, the suction port 44 is arranged at one end of the suction plate 41, the suction port 44 is a strip-shaped port, the suction range is large, the carbon nanotubes 200 on the same straight line of the liner 100 can be sucked simultaneously, and the suction efficiency is effectively improved. In one embodiment, the suction plate 41 is inclined with respect to the jig 20 so that the carbon nanotubes 200 are more easily collected, and the direction of inclination of the suction plate 41 is opposite to the direction of inclination of the squeegee 30. Further, the suction plate 41 is an arc-shaped plate, so that the suction cavity 43 is an arc-shaped cavity, and one surface of the suction plate 41 facing the clamp 20 is a convex arc surface, so that the smoothness of the suction plate 41 relative to the liner 100 can be reduced, and the carbon nanotube 200 can be collected more easily. The air suction pipe 42 is connected with one end of the suction plate 41 far away from the suction port 44, the air suction pipe 42 is communicated with the air suction cavity 43, the air suction pipe 42 is a hose, and one end of the air suction pipe 42 far away from the suction plate 41 is used for being respectively connected with an external negative pressure device and a collection chamber.

When the carbon nanotubes 200 on the mat 100 are collected, the jig 20 holds the mat 100 on which the carbon nanotubes 200 are grown, with the side of the mat 100 on which the carbon nanotubes 200 are grown facing upward; the squeegee 30 is actuated to bring the scraping edge 32 close to the pad 100 on the jig 20; the suction plate 41 is driven to be close to the mat on the jig 20, thereby bringing the suction port 44 of the suction plate 41 close to the carbon nanotube 200 on the mat 100, the suction port 44 being parallel to the mat 100; the suction plate 41 is spaced opposite to the scraper 30, and the suction port 44 is disposed opposite to the scraping blade 32, so that the scraping blade 32 scrapes the carbon nanotubes 200 and provides a pushing force for moving the carbon nanotubes 200 toward the suction assembly 40, thereby allowing the suction port 44 to more easily suck the carbon nanotubes 200; the scraper 30 scrapes the carbon nanotube 200 toward the suction plate 41 to separate the carbon nanotube 200 from the liner 100 and push the carbon nanotube 200 toward the suction port 44; and simultaneously starting an external negative pressure device connected with the air inlet pipe 42, generating certain negative pressure in the air suction pipe 42, the air suction cavity 43 and the vicinity of the suction port 44, separating the carbon nano tubes 200 growing on the gasket 100 from the gasket 100 after simultaneously receiving the thrust of the scraper 30 and the suction force of the suction port 44, and drifting to the collection chamber from the suction port 44, the air suction cavity 43 and the air suction pipe 42 along the air flow, wherein the direction indicated by an arrow in fig. 1 is the air flow direction.

In the process of collecting the carbon nanotubes 200, the scraper 30 and the suction plate 41 are moved in the radial direction of the mat 100 from the scraper 30 toward the suction plate 41, so that in the initial state, the suction plate 41 is positioned directly above the mat 100 and the scraper 30 is positioned above the side of the mat 100; and the scraper 30 is attached to the upper surface of the pad 100, and the suction plate 41 keeps a preset distance from the pad 100 along the vertical direction, that is, the suction plate 41 does not contact the carbon nanotubes 200 on the pad 100, so that the carbon nanotubes 200 on the pad 100 are effectively prevented from being scratched when the suction plate 41 moves horizontally, and the quality of the carbon nanotubes 200 is effectively ensured. During the radial movement of the scraper 30 and the suction plate 41 along the gasket 100, the suction port 44 and the scraping blade 32 maintain a predetermined distance therebetween, so that the scraping blade 32 can scrape the carbon nanotubes 200, and the suction port 44 can suck the carbon nanotubes 200.

Further, the length of the scraping blade 32 is smaller than the diameter of the pad 100, the width of the end of the suction plate 41 where the suction port 44 is provided is smaller than the diameter of the pad 100, and when the carbon nanotubes 200 are collected, the scraping blade 32 is located between the two oppositely arranged stoppers 24, and the end of the suction plate 41 where the suction port 44 is provided is located between the two oppositely arranged stoppers 24, so that the scraping blade 30 and the suction plate 41 can move smoothly in the radial direction of the pad 100, and the scraping blade 30 and the suction plate 41 are prevented from colliding against the stoppers 24 on both sides.

In one embodiment, since the carbon nanotubes 200 have conductivity, the scraper 30, the suction plate 41 and the suction pipe 42 are made of antistatic materials, such as acrylic, etc., that is, the scraper 30 is an antistatic scraper, the suction plate 41 is an antistatic plate, and the suction pipe 42 is an antistatic pipe, so that the carbon nanotube powder flying along with the air flow will not fly along the air flow directly due to the static sticking to the wall surface of the pipe during the floating process, and finally fly to the external collection chamber.

In one embodiment, since the carbon nanotubes 200 have a certain viscosity, an anti-sticking layer, such as polytetrafluoroethylene (Teflon or PTFE), is coated on the surface of the scraping blade 32, the inner wall of the suction opening 44, the inner wall of the suction cavity 43, the inner wall of the suction pipe 42, and the inner wall of the collection chamber connected to the suction pipe 42, so that the carbon nanotubes 200 can be effectively prevented from sticking to the surface of the scraping blade 32, the inner wall of the suction opening 44, the inner wall of the suction cavity 43, or the inner wall of the suction pipe 42. It should be noted that, since the grown carbon nanotubes 200 are powdery and light in weight, and will be drawn when they are stuck together, predetermined negative pressures are ensured in the suction port 44, the suction chamber 43 and the suction pipe 42, so as to prevent the carbon nanotubes 200 from blocking the suction port 44 of the suction chamber 43, the suction chamber 43 or the suction pipe 42.

In the carbon nanotube collecting device of the present invention, when the carbon nanotube 200 is collected, the scraper 30 is driven to make the scraping edge 32 close to the gasket 100, and the suction assembly 40 is actuated to close to the gasket 100 on the clamp 20; the scraping edge 32 scrapes the carbon nanotube 200 on the liner 100, so that the carbon nanotube 200 is separated from the liner 100, the absorption component 40 absorbs the carbon nanotube 200 scraped and stripped by the scraper 30, the absorption component 40 absorbs the carbon nanotube 200 by adopting, and the absorption component 40 collects the carbon nanotube 200 by adopting the scraper 30 to assist, so that the operation is simple and convenient, the labor intensity is effectively reduced, and the collection efficiency is improved.

Referring to fig. 4, a carbon nanotube collecting device according to a second embodiment of the present invention includes a base 10, a clamp 20, a scraper 30 and a suction assembly 40. The base 10, the jig 20, the squeegee 30, and the suction member 40 are the same as the base 10, the jig 20, the squeegee 30, and the suction member 40 in the first embodiment, respectively. The difference is that the carbon nanotube collecting apparatus further includes a support 50, a horizontal driver 60 provided on the support 50, and a lift driver 70 provided on the horizontal driver 60. The bracket 50 is U-shaped, and the bracket 50 is located at one side of the base 10. The elevation driver 70 is located above the squeegee 30 and the suction plate 41, that is, the squeegee 30 and the suction plate 41 are located between the elevation driver 70 and the jig 20, and the elevation driver 70 connects the squeegee 30 and the suction plate 41.

Further, the piston rod 71 of the elevating driver 70 is connected to an adapter plate 72, the scraper 30 is connected to a hanging rod 33, the hanging rod 33 is connected to the adapter plate 72, the suction plate 41 is connected to a boom 45, and the boom 45 is connected to the adapter plate 72.

The lifting driver 70 is used for driving the scraper 30 and the suction plate 41 to be far away from or close to the clamp 20 so as to enable the scraper 30 and the suction plate 41 to be close to or far away from the gasket 100 on the clamp 20, and the horizontal driver 60 is used for driving the lifting driver 70 to reciprocate along the horizontal direction so as to drive the scraper 30 and the suction plate 41 to move from one side of the gasket 100 to the other side of the gasket 100 along the radial direction of the gasket 100 so as to enable all carbon nanotubes on the gasket 100 to be collected; by arranging the horizontal driver 60 and the lifting driver 70, the scraper 30 and the suction plate 41 do not need to be manually actuated in the process of collecting the carbon nanotubes, so that the labor intensity of workers is further reduced, and the automation degree is improved.

In this embodiment, the horizontal driver 60 is a linear motor, and the elevation driver 70 is an air cylinder.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (11)

1. A carbon nanotube collecting device is used for collecting carbon nanotubes on a liner; it is characterized by comprising:

a base;

the clamp is arranged on the base and used for clamping the gasket;

the scraping plate is arranged above the clamp; the scraping plate comprises a main body part and a scraping edge, and the scraping edge is arranged at one end of the main body part;

the sucking assembly is arranged above the clamp; the suction assembly and the scraper are oppositely arranged at intervals, and the suction assembly is used for sucking the carbon nano tubes on the liner;

when the carbon nano tubes on the liner are collected, the scraper blade is actuated to enable the scraper blade to be close to the liner, and the suction assembly is actuated to be close to the liner on the clamp.

2. The carbon nanotube collecting device according to claim 1, wherein the suction assembly comprises a suction plate and a suction pipe connected to the suction plate, the suction plate is spaced from the scraper, and the suction plate has a suction chamber and a suction port communicating with the suction chamber; the air suction pipe is communicated with the air suction cavity and is used for being respectively connected with an external negative pressure device and a collection chamber.

3. The carbon nanotube collecting device according to claim 2, wherein the suction port is provided at one end of the suction plate, and the suction port is a bar-shaped port.

4. The carbon nanotube collecting device according to claim 2, wherein the surface of the scraping blade, the inner wall of the suction port, the inner wall of the suction chamber, and the inner wall of the suction pipe are coated with an anti-sticking layer.

5. The carbon nanotube collecting device according to claim 2, wherein the scraper and the suction plate are moved in a radial direction of the mat from the scraper toward the suction plate during the collection of the carbon nanotubes, the scraper being attached to the mat, and the suction plate being spaced apart from the mat by a predetermined distance.

6. The carbon nanotube collecting device according to claim 5, wherein the scraper is inclined with respect to the jig, and the suction plate is inclined with respect to the jig; and the inclination direction of the suction plate is opposite to that of the scraper.

7. The carbon nanotube collecting device according to claim 6, wherein the suction port is disposed opposite to the scraping blade, and a predetermined distance is maintained between the suction port and the scraping blade during the radial movement of the squeegee and the suction plate along the pad.

8. The carbon nanotube collecting device according to claim 5, further comprising a support, a horizontal driver provided on the support, and a lifting driver provided on the horizontal driver; the lifting driver is connected with the scraper and the suction plate, and the scraper and the suction plate are located between the lifting driver and the clamp.

9. The carbon nanotube collecting device according to claim 8, wherein a piston rod of the elevating driver is connected to an adapter plate, the scraper is connected to a hanging rod, the hanging rod is connected to the adapter plate, the getter plate is connected to a suspension rod, and the suspension rod is connected to the adapter plate.

10. The carbon nanotube collecting device according to claim 1, wherein the clamp comprises a clamping driver and at least two clamping jaws connected to the clamping driver, the clamping driver is disposed on the base, and the at least two clamping jaws are disposed opposite to each other; the clamping jaw comprises a telescopic rod and a stop block, one end of the telescopic rod is connected with the clamping driver, and the stop block is arranged at one end, far away from the clamping driver, of the telescopic rod.

11. The carbon nanotube collecting device according to claim 10, wherein the scraping edge is located between two stoppers disposed opposite to each other when the carbon nanotubes are collected.

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