CN216560482U

CN216560482U - Detection apparatus is used in carbon nanotube production

Info

Publication number: CN216560482U
Application number: CN202122900188.3U
Authority: CN
Inventors: 张世闯
Original assignee: Daye Wangke Nanotechnology Co ltd
Current assignee: Daye Zhanwang New Material Technology Co ltd
Priority date: 2021-11-24
Filing date: 2021-11-24
Publication date: 2022-05-17
Anticipated expiration: 2031-11-24

Abstract

The utility model discloses a detection device for carbon nanotube production, which comprises a bottom plate, wherein two sides of the upper end of the bottom plate are provided with vertical supports, a placing tube is movably arranged in each vertical support, one end of the placing tube penetrates through the outer wall of one side of each vertical support and is connected with a limiting sleeve, the inner wall of the end, away from one end, of the placing tube is provided with an electric telescopic rod, one end of the electric telescopic rod is connected with a push plate, electric push rods are arranged in the upper end and the lower end of each limiting sleeve, the opposite side of each electric push rod is connected with a pressing plate, the rear side of each vertical support is provided with a support frame at the upper end of the bottom plate, the upper end of each support frame is provided with a detection table right above the placing tube, two sides of the lower end of each detection table are provided with a nondestructive detector and a detection probe, the outer end of the end, away from one side of the placing tube is provided with a driven gear, and the device can carry out appearance and nondestructive detection on a workpiece, meanwhile, automatic and all-directional detection can be realized, and the overall detection effect is greatly improved.

Description

Detection apparatus is used in carbon nanotube production

Technical Field

The utility model belongs to the technical field of carbon nanotube detection, and particularly relates to a detection device for carbon nanotube production.

Background

The carbon nano tube is a tubular nano-scale graphite crystal, and is a seamless nano tube formed by curling a single-layer or multi-layer graphite sheet around a central shaft according to a certain helical angle, carbon atoms of each graphite layer are hybridized by SP2 and form a hexagonal net structure by three surrounding atoms, and recently, the carbon nano tube is known to have excellent mechanical strength, thermal conductivity and electrical conductivity and is widely applied to the field of cable production, and the appearance and the whole body of the carbon nano material are always required to be detected when a cable tube containing the carbon nano material is produced and formed.

The cable is detected through nondestructive test ware and test probe to present detection device, and whole intelligent inadequately can only detect the outward appearance and the inside detection of unilateral cable for whole detection precision greatly reduced for solve above problem, proposed a detection device for carbon nanotube production and solved above problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims to: in order to solve the above-mentioned problems, a detection apparatus for carbon nanotube production is provided.

The technical scheme adopted by the utility model is as follows: the utility model provides a detection device is used in carbon nanotube production, includes the bottom plate, the upper end both sides of bottom plate are provided with vertical support, the inside movable mounting of vertical support has places the pipe, one side outer wall connection that the one end of placing the pipe runs through vertical support has the stop collar, the one end of placing the pipe leaves mutually and installs electric telescopic handle on the one end inner wall, electric telescopic handle's one end is connected with the push pedal, the inside electric putter that is provided with in upper and lower both ends of stop collar, electric putter's relative one side is connected with the clamp plate, the support frame is installed in the upper end of bottom plate to the rear side of vertical support, the upper end of support frame is provided with directly over placing the pipe and detects the platform, the lower extreme both sides of detecting the platform are provided with nondestructive detector and test probe, the one side outer end that leaves mutually of placing the pipe is provided with driven gear.

In a preferred embodiment, driven gear's lower extreme and driving gear meshing are in the same place, the fixed outer end that sets up at the dwang of driving gear, the one end of separating of dwang runs through vertical support and separates one side inner wall and be connected with driving motor mutually.

In a preferred embodiment, the outer end of one side of the detection table is provided with a display screen and a control button, and the upper end of the detection table is provided with a heat dissipation hole.

In a preferred embodiment, the platen is semi-circular in cross-section, and the nondestructive detector and the inspection probe are positioned directly above the placement tube.

In a preferred embodiment, the outer diameter of the push plate is matched with the inner diameter of the placing pipe, and the lower end of the vertical support is connected with a sliding block.

In a preferred embodiment, the sliding block is slidably mounted on a linear module disposed at the upper end of the base plate.

Advantageous effects

Compared with the prior art, the utility model has the advantages that:

1. according to the utility model, the driving gear is driven to rotate by the driving motor, so that the placing pipe can be driven to rotate, the placing pipe drives the cable pipe to rotate, in the rotating process, the cable pipe is subjected to appearance detection by the detection probe, and is subjected to nondestructive detection treatment by the nondestructive detector, so that the automatic detection treatment of the workpiece is realized, and the detection efficiency and the detection effect are improved.

2. In the utility model, the device can realize omnibearing measurement on the cable pipe through the matching of the two groups of placing pipes, so that the overall measurement effect is greatly improved.

Drawings

FIG. 1 is a schematic cross-sectional structural view of the present invention in its entirety;

fig. 2 is a schematic overall perspective structure of the present invention.

The labels in the figure are: 1-heat dissipation hole, 2-support frame, 3-vertical support frame, 4-bottom plate, 5-driving motor, 6-detection table, 7-limit sleeve, 8-placing tube, 9-linear module, 10-nondestructive detector, 11-detection probe, 12-driven gear, 13-driving gear, 14-slide block, 15-electric telescopic rod, 16-push plate and 17-electric push rod.

Detailed Description

The utility model will be further described with reference to specific embodiments shown in the drawings.

Referring to fig. 1-2, a detection device for carbon nanotube production, comprising a bottom plate 4, wherein two sides of the upper end of the bottom plate 4 are provided with vertical supports 3, a placing tube 8 is movably mounted inside the vertical supports 3, one end of the placing tube 8 penetrates through the outer wall of one side of the vertical supports 3 and is connected with a limiting sleeve 7, the placing tube 8 plays an auxiliary supporting role for a workpiece, an electric telescopic rod 15 is mounted on the inner wall of the opposite end of the placing tube 8, one end of the electric telescopic rod 15 is connected with a push plate 16, the push plate 16 is driven by the electric telescopic rod 15 to work, the leaking length of the workpiece can be adjusted, electric push rods 17 are arranged inside the upper and lower ends of the limiting sleeve 7, the opposite side of the electric push rod 17 is connected with a pressing plate, the electric push rod 17 on one side of the placing tube 8 drives the pressing plate to work, secondary limiting is performed on a cable tube by the pressing plate, and the fixing effect on the workpiece is improved, support frame 2 is installed in the upper end of bottom plate 4 to the rear side of vertical support 3, and the upper end of support frame 2 is provided with directly over placing pipe 8 and examines test table 6, and the lower extreme both sides of examining test table 6 are provided with nondestructive test ware 10 and test probe 11, and the one side outer end that leaves mutually of placing pipe 8 is provided with driven gear 12, carries out outward appearance through test probe 11 to the cable pipe and detects, carries out nondestructive test through nondestructive test ware 10 and handles the cable pipe, realizes automated inspection and handles.

It should be noted that, driven gear 12's lower extreme and driving gear 13 meshing are in the same place, driving gear 13 is fixed to be set up in the outer end of dwang, the one end that separates of dwang runs through vertical support 3 and separates one side inner wall mutually and be connected with driving motor 5, drive driving gear 13 through driving motor 5 and rotate, drive driven gear 12 through driving gear 13 and rotate, alright drive place the pipe 8 and rotate, thereby the cable duct rotates, can make to carry out harmless and outward appearance detection to the cable duct round, detection effect has been improved.

It should be noted that the outer end of one side of the detection table 6 is provided with a display screen and a control button, the upper end of the detection table 6 is provided with a heat dissipation hole 1, the detection table 6 can be cooled through the heat dissipation hole 1, and the service life and the service time of the whole detection table 6 are prolonged.

It should be noted that the cross section of the pressing plate is semicircular, so that the pressing plate can adapt to the shape of a workpiece, the nondestructive detector 10 and the detection probe 11 which improve the limiting effect are positioned right above the placing pipe 8, and nondestructive detection and appearance detection are realized through the nondestructive detector 10 and the detection probe 11.

It should be noted that the outer diameter of the push plate 16 is matched with the inner diameter of the placing tube 8, and the lower end of the vertical bracket 3 is connected with the slide block 14.

It should be noted that, the slider 14 is slidably mounted on the linear module 9 disposed at the upper end of the bottom plate 4, and the position of the vertical support 3 can be adjusted by the cooperation of the linear module 9 and the slider 14, so that the position of the placing pipe 8 can be adjusted, and the device can be suitable for workpieces with different lengths.

The working principle is as follows: this device is before using, the whole external power supply of device, when using, at first put into the cable duct after the shaping in the pipe 8 of placing on the vertical support 3 of one end, then drive the clamp plate work through the electric putter 17 of placing pipe 8 one side at the place, play supplementary spacing back to the cable duct through the clamp plate, it rotates to drive driving gear 13 through driving motor 5, drive driven gear 12 through driving gear 13 and rotate, alright drive and place pipe 8 and rotate, thereby the cable duct rotates, at the pivoted in-process, carry out outward appearance through test probe 11 to the cable duct and detect, carry out nondestructive test through nondestructive test ware 10 and handle the cable duct, realize automated inspection and handle.

Some detect and finish the back and drive the 16 motions of push pedal through electric telescopic handle 15, place the pipe 8 with the cable duct to another and release, then push the cable duct and place in the pipe 8 to another, carry out the detection of another side cable duct for can realize the omnidirectional detection to the cable duct, improve detection effect, improve the holistic practicality of device greatly.

The above is only a preferred embodiment of the present invention, and it should be noted that it is obvious to those skilled in the art that several variations and modifications can be made without departing from the structure of the present invention, which will not affect the effect of the implementation of the present invention and the utility of the patent.

Claims

1. The utility model provides a detection device is used in carbon nanotube production, includes bottom plate (4), its characterized in that: the device is characterized in that vertical supports (3) are arranged on two sides of the upper end of the bottom plate (4), a placing pipe (8) is movably arranged in the vertical supports (3), one end of the placing pipe (8) penetrates through the outer wall of one side of the vertical supports (3) and is connected with a limiting sleeve (7), an electric telescopic rod (15) is arranged on the inner wall of the separated end of the placing pipe (8), one end of the electric telescopic rod (15) is connected with a push plate (16), electric push rods (17) are arranged in the upper end and the lower end of the limiting sleeve (7), a pressing plate is connected to one opposite side of each electric push rod (17), a supporting frame (2) is arranged at the upper end of the bottom plate (4) on the rear side of the vertical supports (3), an inspection table (6) is arranged right above the placing pipe (8) on the upper end of the supporting frame (2), nondestructive detectors (10) and inspection probes (11) are arranged on two sides of the lower end of the inspection table (6), the outer end of the side, away from the side of the placing pipe (8), is provided with a driven gear (12).

2. The detecting device for carbon nanotube production according to claim 1, wherein: the lower extreme and the driving gear (13) meshing of driven gear (12) are in the same place, the fixed outer end that sets up at the dwang in driving gear (13), the one end that separates mutually of dwang runs through vertical support (3) and separates one side inner wall mutually and be connected with driving motor (5).

3. The detecting device for carbon nanotube production according to claim 1, wherein: the outer end of one side of the detection table (6) is provided with a display screen and a control button, and the upper end of the detection table (6) is provided with a heat dissipation hole (1).

4. The detecting device for carbon nanotube production according to claim 1, wherein: the cross section of the pressing plate is semicircular, and the nondestructive detector (10) and the detection probe (11) are positioned right above the placing pipe (8).

5. The detecting device for carbon nanotube production according to claim 1, wherein: the outer diameter of the push plate (16) is matched with the inner diameter of the placing pipe (8), and the lower end of the vertical support (3) is connected with a sliding block (14).

6. The detecting device for carbon nanotube production as set forth in claim 5, wherein: the sliding block (14) is slidably mounted on a linear module (9) arranged at the upper end of the bottom plate (4).