CN220104870U - Graphene coating detection device - Google Patents

Abstract

The utility model discloses a graphene coating detection device, and relates to the technical field of coating detection. The utility model comprises the following steps: a frame on which a Gao Qingchuan sensor is provided; place the board, slide and set up in the frame, be provided with actuating mechanism in the frame, it is used for driving place the intermittent type nature straight line reciprocating sliding of board, be provided with the mounting on placing the board, it is used for fixing or releasing the fixing to graphene glass insulating pot, be provided with the driving medium on frame, place board and the mounting, works as when placing the board and slide, pass through the driving medium drives the mounting operation or stops the operation. When the graphene glass electric kettle is used, the graphene glass electric kettle is continuously detected, and the processes of placing, fixing, releasing and taking down the graphene glass electric kettle are not required to be repeated by staff, so that the graphene glass electric kettle is convenient to operate, small in manual participation workload and high in detection efficiency, and has practicability.

Description

Graphene coating detection device

Technical Field

The utility model relates to the technical field of graphene coating detection, in particular to a graphene coating detection device.

Background

Graphene is a new material with a single-layer two-dimensional honeycomb lattice structure formed by closely stacking SP2 hybridized carbon atoms, has excellent optical, electrical and mechanical properties, has important application prospects in the aspects of materialization, micro-nano processing, energy, biomedicine, drug delivery and the like, and is used for detecting the quality condition of a graphene coating in order to ensure good contact of the electrode plate, wherein in the production process of a graphene glass electric kettle, one procedure is to attach the electrode plate to the graphene coating at the bottom of the glass kettle;

according to the scheme, firstly, each group of graphene glass electric kettles are respectively fixed on each group of fixing plates, then a motor is started to work and drive all-gear intermittent rotation through a single gear, at the moment, each group of fixing plates on a supporting plate can rotate to the lower part of a Gao Qingchuan sensor on a support in sequence and stop for a moment and then continue to rotate, so that at the moment that the graphene glass electric kettles on the fixing plates stop below a Gao Qingchuan sensor, a high-definition sensor can detect the graphene coating on the graphene glass electric kettles at the moment, after one group of graphene glass electric kettles are detected to be far away from the Gao Qingchuan sensor, a worker takes down the detected graphene glass electric kettles and fixes the non-detected graphene glass electric kettles again, and accordingly, the Gao Qingchuan sensor can continuously detect each group of graphene glass electric kettles, the detection speed of the graphene glass electric kettles is improved, the graphene electric kettles can be continuously detected, the graphene electric kettles are required to be repeatedly placed by the worker, the graphene electric kettles are fixed, the graphene electric kettles are not required to be manually detected, and the graphene electric kettles are manually detected.

Disclosure of Invention

The utility model aims at: the utility model provides a graphene coating detection device, which aims to solve the technical problems that a worker is required to repeatedly place, fix, release and take down a graphene glass electric kettle, the operation is troublesome, the manual participation workload is large, and the detection efficiency is reduced.

The utility model adopts the following technical scheme for realizing the purposes:

graphene coating detection device includes:

a frame on which a Gao Qingchuan sensor is provided;

the placing plate is arranged on the frame in a sliding manner, a driving mechanism is arranged on the frame and used for driving the placing plate to intermittently and linearly reciprocate, a fixing piece is arranged on the placing plate and used for fixing or releasing the graphene glass electric kettle, and transmission pieces are arranged on the frame, the placing plate and the fixing piece;

the feeding frame and the discharging frame are arranged on the frame and symmetrically distributed by taking the placing plate as a center, the opposite sides of the feeding frame and the discharging frame are corresponding to the conveying belt, the feeding frame and the frame are provided with feeding mechanisms for driving the graphene glass electric kettles to move from the feeding frame to the placing plate, and the discharging frame is provided with discharging mechanisms for driving the graphene glass electric kettles to move from the placing plate to the discharging frame.

Further, the driving mechanism comprises a reciprocating screw rod which is rotatably arranged on the frame, the placing plate is in threaded fit with the reciprocating screw rod, a driving motor is arranged on the frame, a notch of the notch is provided with a beaver tail plate, a fixed gear meshed with the notch is arranged on the reciprocating screw rod, two rollers which are distributed at intervals are rotatably arranged on the fixed gear, and the beaver tail plate and the two rollers are in rolling lap joint.

Further, the fixing piece comprises a positive and negative screw rod which is rotatably arranged on the placing plate, sliding blocks which are in sliding fit with the placing plate are arranged on positive and negative screw thread sections of the positive and negative screw rod in a threaded mode, and fixing rods which are in a V-shaped structure are arranged on the sliding blocks.

Further, the transmission piece comprises a transmission rack arranged on the frame, a transmission rod is rotatably arranged on the placing plate, a transmission gear meshed with the transmission rack is arranged on the transmission rod, and the transmission rod is in transmission connection with the positive and negative screw rod through a bevel gear assembly.

Further, the feeding mechanism comprises a rotating rod which is arranged on the feeding frame in a rotating mode, four feeding rods which are distributed in an annular array mode are arranged on the rotating rod, a feeding motor is arranged on the frame, and the rotating rod is connected with an output shaft of the feeding motor in a transmission mode through an external meshing grooved pulley mechanism.

Further, the blanking mechanism comprises a shaft rod which is rotatably arranged on the blanking frame, a blanking rod which is in a U shape in structure is arranged on the shaft rod, a contact wheel is rotatably arranged at the free end of the blanking rod, and a blanking motor with an output shaft connected with the shaft rod is arranged on the blanking frame.

Further, through grooves are formed in the feeding frame and the discharging frame, and a plurality of rotating rollers distributed in an array are rotationally arranged in the through grooves.

Further, two guide rods are symmetrically arranged on one side, far away from the discharging frame, of the feeding frame.

The beneficial effects of the utility model are as follows: when the graphene glass electric kettle is used, the graphene glass electric kettle is continuously detected, and the processes of placing, fixing, releasing and taking down the graphene glass electric kettle are not required to be repeated by staff, so that the graphene glass electric kettle is convenient to operate, small in manual participation workload and high in detection efficiency, and has practicability.

Drawings

FIG. 1 is a perspective view of the structure of the present utility model;

FIG. 2 is an exploded perspective view of a portion of the construction of the present utility model;

FIG. 3 is an enlarged view of the utility model at A in FIG. 2;

FIG. 4 is an enlarged view of the utility model at B in FIG. 2;

FIG. 5 is a perspective view of a portion of the structure of the present utility model;

fig. 6 is a perspective view of another part of the structure of the present utility model.

Reference numerals: 1. a frame; 2. gao Qingchuan sensor; 3. placing a plate; 4. a driving mechanism; 401. a reciprocating screw rod; 402. a driving motor; 403. a gear-missing; 404. a beaver tail; 405. a fixed gear; 406. a roller; 5. a fixing member; 501. a positive and negative screw rod; 502. a slide block; 503. a fixed rod; 6. a transmission member; 601. a drive rack; 602. a transmission rod; 603. a transmission gear; 604. a bevel gear assembly; 7. a feeding frame; 8. a blanking frame; 9. a feeding mechanism; 901. a rotating rod; 902. a feeding rod; 903. a feeding motor; 904. an external engagement sheave mechanism; 10. a blanking mechanism; 1001. a shaft lever; 1002. a blanking rod; 1003. a contact wheel; 1004. a blanking motor; 11. penetrating a groove; 12. a rotating roller; 13. a guide rod.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

As shown in fig. 1 to 6, a graphene coating detection device according to an embodiment of the present utility model includes:

the device comprises a frame 1, wherein a high-definition sensor 2 and a Gao Qingchuan sensor 2 are arranged on the frame 1 and are used for detecting a graphene coating of a graphene glass electric kettle;

the placing plate 3 is arranged on the frame 1 in a sliding manner, the placing plate 3 slides horizontally and along the horizontal direction, the frame 1 is provided with a driving mechanism 4 for driving the placing plate 3 to slide intermittently and linearly in a reciprocating manner, the intermittent linear reciprocating sliding means that the placing plate 3 stays in place for a period of time when sliding to a limit position and then continues to slide along the opposite direction of the previous sliding direction, the placing plate 3 is provided with a fixing piece 5 for fixing or releasing the graphene glass electric kettle, and the frame 1, the placing plate 3 and the fixing piece 5 are provided with a driving piece 6, when the placing plate 3 slides, the driving piece 6 drives the fixing piece 5 to operate or stop operating;

the feeding frame 7 and the discharging frame 8 are arranged on the frame 1 and are symmetrically distributed by taking the placing plate 3 as a center, the feeding frame 7 and the discharging frame 8 are fixedly arranged on the frame 1, the opposite sides of the placing plate 3 are respectively contacted with the feeding frame 7 and the discharging frame 8, the opposite sides of the feeding frame 7 and the discharging frame 8 are respectively corresponding to conveying belts, the conveying belts are not shown in the drawings of the specification, the feeding frame 7 and the frame 1 are provided with a feeding mechanism 9 which is used for driving the graphene glass electric kettles to move from the feeding frame 7 to the placing plate 3, and the discharging frame 8 is provided with a discharging mechanism 10 which is used for driving the graphene glass electric kettles to move from the placing plate 3 to the discharging frame 8;

in an initial state, the placing plate 3 is positioned at the limit position and is positioned between opposite sides of the upper material frame 7 and the lower material frame 8, when the graphene glass electric kettle is used, the graphene glass electric kettle is conveyed through a conveying belt corresponding to the upper material frame 7, the graphene glass electric kettle is moved to the upper material frame 7 through the conveying belt, the graphene glass electric kettle is driven to move to the placing plate 3 from the upper material frame 7 through the feeding mechanism 9, the placing plate 3 is driven to intermittently and linearly reciprocate through the driving mechanism 4 until the placing plate 3 is positioned at the other limit position, at the moment, the placing plate 3 is positioned below the high-definition sensor 2 and stays in place for a period of time, in the process, the fixing piece 5 is driven to operate through the driving piece 6, the graphene glass electric kettle is fixed through the fixing piece 5, the graphene glass electric kettle is positioned below the Gao Qingchuan sensor 2, in the time of the placing plate 3, at the moment, the graphene electric kettle is driven to detect a graphene coating of the graphene glass electric kettle through the Gao Qingchuan sensor 2, then the placing plate 3 slides to the initial position along the opposite direction of the previous sliding direction, the placing plate 3 stays in place for a period of time, the graphene glass electric kettle is driven to move to the graphene electric kettle through the driving piece 6, the fixing piece 6 is driven to move to the graphene glass electric kettle in the single electric kettle through the fixing piece 5, namely, the graphene glass electric kettle is stopped in the process is stopped by the fixing piece 5, and the graphene glass electric kettle is conveyed by the fixing piece is repeatedly, and the graphene glass electric kettle is conveyed by the fixing piece, namely, the graphene glass electric kettle is moved to the graphene glass coating by the fixing frame by the fixing piece 5 through the fixing piece 5 in the corresponding to the fixing piece, and the graphene glass electric kettle through the fixing piece 5;

in summary, when the graphene glass electric kettle is used, the graphene glass electric kettle is continuously detected, and the processes of placing, fixing, releasing fixing and taking down the graphene glass electric kettle are not required to be repeated by staff, so that the graphene glass electric kettle is convenient to operate, small in manual participation workload and high in detection efficiency, and has practicability.

As shown in fig. 3, in some embodiments, the driving mechanism 4 includes a reciprocating screw 401 rotatably disposed on the frame 1, the reciprocating screw 401 is horizontally disposed, the placement plate 3 is in threaded engagement with the reciprocating screw 401, the frame 1 is provided with a driving motor 402, the driving motor 402 is fixedly disposed on the frame 1, an output shaft of the driving motor 402 is provided with a notch gear 403, the notch of the notch gear 403 is vertically disposed and fixedly connected with an output of the driving motor 402, a beaver tail plate 404 is disposed at the notch of the notch gear 403, the beaver tail plate 404 is fixedly disposed on the notch gear 403 and corresponds to the notch of the beaver tail plate, a fixed gear 405 meshed with the notch gear 403 is disposed on the reciprocating screw 401, the fixed gear 405 is vertically disposed and fixedly connected with the reciprocating screw 401, two rollers 406 are rotatably disposed on the fixed gear 405, the two rollers 406 are horizontally disposed and annularly in an array, the beaver tail plate 404 and the two rollers 406 are all in rolling contact with each other, in an initial state, the notch of the beaver tail plate 403 is far away from the fixed gear 405, when the motor 403 is used, the motor is opened, the driving gear 402 is driven by the motor 403 to rotate along with the notch gear 403, the corresponding to the notch gear 405, the fixed gear 405 is stopped when the two rollers are in a certain time, the two rollers 3 are rotated and the corresponding to the notch plate is placed along with the corresponding position of the fixed gear 405, the fixed position is stopped, and the fixed gear is rotated along with the corresponding position of the fixed gear 405, and the fixed gear is rotated, and the fixed gear 405 is in a certain time, and the fixed position is rotated along with the fixed position, and the fixed gear 3 is in a certain position, and the fixed position and is rotated and stopped, the notch of the gear-lack 403 continues to rotate, the notch of the gear-lack 403 is far away from the fixed gear 405, the beaver tail 404 is far away from the two rollers 406, the fixed gear 405 continues to rotate, the reciprocating screw 401 also continues to rotate, and accordingly, the placing plate 3 slides to the initial position along the opposite direction of the previous sliding direction, and then the moving state of the placing plate 3 corresponds to the moving direction, so that the intermittent linear reciprocating sliding of the placing plate 3 is driven without redundant description.

As shown in fig. 4, in some embodiments, the fixing piece 5 includes a positive and negative lead screw 501 rotatably disposed on the placement plate 3, the positive and negative lead screw 501 is in a horizontal direction, positive and negative thread sections of the positive and negative lead screw 501 are both in threaded arrangement with a slider 502 slidably engaged with the placement plate 3, the slider 502 is in a vertical direction and is slidably engaged with the placement plate 3 in a horizontal direction, a fixing rod 503 configured in a V-shape is disposed on the slider 502, the fixing rod 503 is in a horizontal direction and is fixedly disposed on the slider 502, the placement plate 3 is located at an initial position in reference to the above, the two sliders 502 are mutually far away from each other, when the placement plate 3 slides to another limit position in the horizontal direction, the positive and negative lead screw 501 is driven to rotate forward by the driving piece 6, the two sliders 502 are synchronously and reversely slid to approach each other due to the positive and negative thread action, the two fixing rods 503 are respectively moved together with the two sliders 502 until the two fixing rods are mutually and reversely slid to the graphene glass kettle, and on the opposite sides of the two fixing rods are mutually far away from each other due to the mutual sliding of the two fixing rods, and the two fixing rods are mutually opposite slide to the two fixing rods, and the two fixing rods are mutually opposite, and the two fixing rods are respectively, and the two fixing rods are mutually opposite, and the two fixing rods and the two graphene glass kettles are mutually opposite, and the two opposite.

As shown in fig. 4, in some embodiments, the transmission member 6 includes a transmission rack 601 disposed on the frame 1, the transmission rack 601 is horizontally and fixedly disposed on the frame 1, a transmission rod 602 is rotatably disposed on the placement plate 3, the transmission rod 602 is horizontally, a transmission gear 603 meshed with the transmission rack 601 is disposed on the transmission rod 602, the transmission gear 603 is vertically and fixedly connected with the transmission rod 602, the transmission rod 602 is connected with the positive and negative screw rods 501 through a bevel gear assembly 604, the bevel gear assembly 604 is composed of two meshed bevel gears, the two bevel gears are respectively fixedly connected with the transmission rod 602 and the positive and negative screw rods 501, referring to the above, in an initial state, the placement plate 3 is located at an initial position, at this time, the transmission gear 603 is meshed with the transmission rack 601, when the placement plate 3 slides to another limit position in the horizontal direction, the transmission gear 603 rotates due to the meshing effect, the transmission rod 602 rotates together, the positive and negative screw rods 501 are driven to rotate through the bevel gear assembly 604, and then the transmission gear 603 is far away from the transmission rod 601, and the positive and negative screw rods 501 stop rotating, otherwise, when the placement plate 3 returns to the initial position, the transmission gear 603 rotates together, and the positive and negative screw rods 501 rotate due to the meshing effect, and the positive and negative screw rods are driven to the positive and negative screw rods 501 rotate.

As shown in fig. 5, in some embodiments, the feeding mechanism 9 includes a rotating rod 901 rotatably disposed on a feeding frame 7, the rotating rod 901 is in a vertical direction, four feeding rods 902 distributed in a ring array are disposed on the rotating rod 901, the feeding rods 902 are in a horizontal direction and are fixedly connected with the rotating rod 901, a feeding motor 903 is disposed on the frame 1, the feeding motor 903 is fixedly disposed on the frame 1, the rotating rod 901 is in transmission connection with an output shaft of the feeding motor 903 through an external engagement sheave mechanism 904, a transmission ratio of the external engagement sheave mechanism 904 is four to one, the external engagement sheave mechanism 904 is composed of a driving dial, a cylindrical pin and a driven sheave, the driving dial is fixedly disposed on an output shaft of the feeding motor 903, the driven sheave is fixedly disposed on the rotating rod 901, wherein, the cylindrical pin is arranged on the driving plate, the driving plate is provided with a locking arc, the driven grooved pulley is provided with a locking arc and a radial groove, the working principle sequence is approximately as follows, the driving plate rotates, the cylindrical pin enters the radial groove, the locking arc is released, the driven sheave rotates, the cylindrical pin is separated from the radial groove, the other locking arc of the driven sheave is locked by the locking arc of the driving plate, the driving plate rotates, the driven sheave is static, namely, the driving plate rotates one circle in the forward direction, the driven grooved pulley rotates one quarter circle in the reverse direction, when in use, the feeding motor 903 is turned on, the feeding motor 903 works, the output shaft rotates one circle to drive the rotating rod 901 to rotate one quarter circle, the four feeding rods 902 all rotate along with the rotating rod 901, then the rotating rod 901 continues to rotate one quarter circle after a certain time interval, when the rotating rod 901 rotates one quarter circle, wherein two feed bars 902 will contact the graphene glass electric kettle and drive the graphene glass electric kettle to move from the feed rack 7 to the placing plate 3.

As shown in fig. 6, in some embodiments, the blanking mechanism 10 includes a shaft 1001 rotatably disposed on the blanking frame 8, the shaft 1001 is in a horizontal direction, a blanking rod 1002 having a U-shape structure is disposed on the shaft 1001, the blanking rod 1002 is fixedly disposed on the shaft 1001, a collision wheel 1003 is rotatably disposed at a free end of the blanking rod 1002, a blanking motor 1004 having an output shaft connected to the shaft 1001 is disposed on the blanking frame 8, the blanking motor 1004 is fixedly disposed on the blanking frame 8, the blanking rod 1002 is in a horizontal direction in an initial state, the collision wheel 1003 is far away from the graphene glass electric kettle, when the graphene glass electric kettle is detected, the placement plate 3 is located at the initial position, the blanking motor 1004 is turned on, the blanking motor 1004 is operated, the output shaft is rotated forward, the shaft 1001 is driven to rotate, the blanking rod 1002 is rotated downward to a vertical direction, in this process, the collision wheel 1003 is in contact with the graphene glass electric kettle and drives the graphene glass electric kettle to move from the placement plate 3 to the blanking frame 8, and then the output shaft of the blanking motor 1004 is rotated backward until the blanking rod 1002 returns to the initial position.

As shown in fig. 5, in some embodiments, the feeding frame 7 and the discharging frame 8 are provided with through grooves 11, a plurality of rotating rollers 12 distributed in arrays are rotationally arranged in the through grooves 11, the rotating rollers 12 are in a horizontal direction, and according to the above, when the graphene glass electric kettle moves on the feeding frame 7 and the discharging frame 8, the rotating rollers 12 are driven to rotate together, sliding friction is converted into rolling friction through the rotating rollers 12, so that friction force is reduced, and the movement of the graphene glass electric kettle is smoother.

As shown in fig. 5, in some embodiments, two guide rods 13 are symmetrically disposed on one side of the upper material frame 7 far away from the lower material frame 8, the two guide rods 13 are both in a horizontal direction and are both fixedly disposed on the upper material frame 7, the two guide rods 13 are distributed in a splayed shape, and when the graphene glass electric kettle moves onto the upper material frame 7 by the conveying belt, the graphene glass electric kettle is guided and limited by the two guide rods 13 according to the above, so that the graphene glass electric kettle moves onto the upper material frame 7 smoothly by the conveying belt.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. Graphene coating detection device, its characterized in that includes:

the rack (1) is provided with a high-definition sensor (2);

the placing plate (3) is arranged on the frame (1) in a sliding manner, a driving mechanism (4) is arranged on the frame (1) and used for driving the placing plate (3) to slide intermittently and linearly in a reciprocating manner, a fixing piece (5) is arranged on the placing plate (3) and used for fixing or releasing the graphene glass electric kettle, and a transmission piece (6) is arranged on the frame (1), the placing plate (3) and the fixing piece (5), and when the placing plate (3) slides, the fixing piece (5) is driven to operate or stops operating through the transmission piece (6);

go up work or material rest (7) and unloading frame (8) all set up just use place board (3) on frame (1) as central symmetry distribution, go up work or material rest (7) and the opposite side of unloading frame (8) all correspond with the conveyer belt, be provided with feed mechanism (9) on going up work or material rest (7) and frame (1), it is used for driving graphene glass insulating pot by last work or material rest (7) motion to place on board (3), be provided with unloading mechanism (10) on unloading frame (8), it is used for driving graphene glass insulating pot by place board (3) motion to on unloading frame (8).

2. The graphene coating detection device according to claim 1, wherein the driving mechanism (4) comprises a reciprocating screw rod (401) rotatably arranged on the frame (1), the placing plate (3) is in threaded fit with the reciprocating screw rod (401), a driving motor (402) is arranged on the frame (1), a notch gear (403) is arranged on an output shaft of the driving motor (402), a beaver tail plate (404) is arranged at a notch of the notch gear (403), a fixed gear (405) meshed with the notch gear (403) is arranged on the reciprocating screw rod (401), two rollers (406) which are distributed at intervals are rotatably arranged on the fixed gear (405), and the beaver tail plate (404) is in rolling lap joint with the two rollers (406).

3. The graphene coating detection device according to claim 1, wherein the fixing piece (5) comprises a positive and negative screw rod (501) rotatably arranged on the placement plate (3), positive and negative screw thread sections of the positive and negative screw rod (501) are respectively provided with a sliding block (502) in sliding fit with the placement plate (3), and a fixing rod (503) with a V-shaped structure is arranged on the sliding block (502).

4. A graphene coating detection device according to claim 3, wherein the transmission member (6) comprises a transmission rack (601) arranged on the frame (1), a transmission rod (602) is rotatably arranged on the placement plate (3), a transmission gear (603) meshed with the transmission rack (601) is arranged on the transmission rod (602), and the transmission rod (602) is in transmission connection with the positive and negative screw rod (501) through a bevel gear assembly (604).

5. The graphene coating detection device according to claim 1, wherein the feeding mechanism (9) comprises a rotating rod (901) rotatably arranged on a feeding frame (7), four feeding rods (902) distributed in a ring-shaped array are arranged on the rotating rod (901), a feeding motor (903) is arranged on the frame (1), and the rotating rod (901) is in transmission connection with an output shaft of the feeding motor (903) through an external meshing grooved pulley mechanism (904).

6. The graphene coating detection device according to claim 1, wherein the blanking mechanism (10) comprises a shaft lever (1001) rotatably arranged on a blanking frame (8), a blanking rod (1002) with a U-shaped structure is arranged on the shaft lever (1001), a contact wheel (1003) is rotatably arranged at the free end of the blanking rod (1002), and a blanking motor (1004) with an output shaft connected with the shaft lever (1001) is arranged on the blanking frame (8).

7. The graphene coating detection device according to claim 1, wherein through grooves (11) are formed in the upper material rack (7) and the lower material rack (8), and a plurality of rotating rollers (12) distributed in an array are rotationally arranged in the through grooves (11).

8. The graphene coating detection device according to claim 1, wherein two guide rods (13) are symmetrically arranged on one side of the upper material rack (7) far away from the lower material rack (8).