CN115448034B - Conveyor for conveying new energy lithium battery materials - Google Patents

Abstract

The invention is applicable to the field of conveyors, and provides a conveyor for conveying new energy lithium battery materials, which comprises a conveying pipeline and a corner plate arranged at the bending part of the conveying pipeline, and further comprises: the device comprises a sealing box, a first guide sliding block, a moving plate and a guide plate; the sealing box is connected with the conveying pipeline, and a first guide chute is arranged in the sealing box. When new forms of energy lithium battery material piles up the kink in pipeline, the pressure grow at pipeline right-hand member, drive assembly passes through pipeline right-hand member's high pressure drive vibration subassembly and pulling subassembly work, vibration subassembly passes through drive assembly and drives the elbow board and vibrate with reciprocating pivoted mode, thereby make the loose of the internal piled up new forms of energy lithium battery material of pipeline become, and then improve the mobility of the internal new forms of energy lithium battery material of pipeline, discharge the internal piled up new forms of energy lithium battery material of pipeline, carry out self-dredging to pipeline through the pressure variation in the pipeline, save the manpower.

Description

Conveyor for conveying new energy lithium battery materials

Technical Field

The invention belongs to the field of conveyors, and particularly relates to a conveyor for conveying new energy lithium battery materials.

Background

The lithium ion battery electrode material is prepared from graphite and other powder, and the powder is troublesome in the transportation process, because once the powder is scattered in the air, the powder can cause air pollution, and after being inhaled by a human body, the powder can harm health and is further conveyed by a pneumatic conveying device.

The pneumatic conveying device, the conveying pipeline, the spherical tee joint, the booster elbow and the like form a sealed conveying system, the conveying pipeline is not straight due to the reasons of a conveying field or equipment, the conveying pipeline can be bent more, but new energy lithium battery materials can be often accumulated at the bending position of the conveying pipeline in the conveying process, and the conveying efficiency of the new energy lithium battery materials is further affected.

Disclosure of Invention

The embodiment of the invention aims to provide a conveyor for conveying new energy lithium battery materials, and aims to solve the problem that the new energy lithium battery materials are often accumulated at the bending part of a conveying pipeline in the conveying process, so that the conveying efficiency of the new energy lithium battery materials is affected.

The invention is realized in such a way that the conveyor for conveying the new energy lithium battery material comprises a conveying pipeline and a corner plate arranged at the bending part of the conveying pipeline, and further comprises:

the device comprises a sealing box, a first guide sliding block, a moving plate and a guide plate;

the sealing box is connected with the conveying pipeline, a first guide sliding groove is formed in the sealing box, the first guide sliding block is connected in the first guide sliding groove in a sliding mode, the moving plate is fixed on the first guide sliding block, a guide seat is fixed in the sealing box, the guide plate is connected in the guide seat in a sliding mode, a first fixed shaft is fixed on the guide plate, and the corner plate is connected on the first fixed shaft in a rotating mode;

the transmission assembly is arranged in the sealing box and drives the first guide sliding block to slide left and right through pressure in the conveying pipeline;

the vibration assembly is arranged on the corner plate and drives the corner plate to vibrate in a reciprocating rotation mode through the transmission assembly;

the pulling assembly is arranged on the guide plate and drives the corner plate to move away from the direction of the conveying pipeline through the transmission assembly.

Further technical scheme, drive assembly includes piston housing, piston, first pressure spring, first guiding axle and connecting plate, the piston housing is fixed on pipeline, piston sliding connection is in the piston housing, and the one end that the piston is close to pipeline is the same with pipeline inner wall shape, first pressure spring sets up in the piston housing, first guiding axle is fixed on the piston, the connecting plate is fixed on first direction slider, be provided with the inclined pushing groove on the connecting plate, and first guiding axle and inclined pushing groove sliding fit.

According to a further technical scheme, an adjusting plate is further connected in the piston shell in a sliding mode, a bolt is connected to the piston shell in a threaded mode, the tail end of the bolt is in running fit with the adjusting plate, and a fastening bolt is connected to the bolt in a threaded mode.

Further technical scheme, vibration subassembly includes second fixed axle, second pressure spring, fixed cover, telescopic link, third pressure spring and driving lever subassembly, the second fixed axle is fixed on the deflector, be provided with the arc wall on the curved angle board, second fixed axle and arc wall sliding fit, the second pressure spring sets up in the arc wall, fixed cover is fixed on the curved angle board, be provided with the second guide way in the fixed cover, and telescopic link sliding connection is in the second guide way, the third pressure spring sets up in the second guide way, the driving lever subassembly sets up on the movable plate, the driving lever subassembly is used for intermittent type nature promotion telescopic link to rotate.

Further technical scheme, the driving lever subassembly includes mounting panel, mount pad, poking rod and extension spring, the mounting panel is fixed on the movable plate, the mount pad is fixed on the mounting panel, poking rod rotates to be connected on the mount pad, be provided with the mounting groove on the mount pad, the extension spring sets up in the mounting groove, and the both ends of extension spring are connected with poking rod and mounting groove inner wall respectively.

According to a further technical scheme, a plurality of groups of mounting seats, toggle rods, mounting grooves and tension springs are arranged.

Further technical scheme, pulling subassembly includes V-arrangement guide way and second guiding axle, V-arrangement guide way sets up on the movable plate, and the one end level setting of V-arrangement guide way, the second guiding axle is fixed on the deflector, second guiding axle and V-arrangement guide way sliding fit.

According to the conveyor for conveying the new energy lithium battery materials, when the new energy lithium battery materials are stacked at the bending position in the conveying pipeline, the pressure at the right end of the conveying pipeline is increased, the transmission assembly drives the vibration assembly and the pulling assembly to work through the high pressure at the right end of the conveying pipeline, the vibration assembly drives the bent plate to vibrate in a reciprocating rotation mode through the transmission assembly, so that the new energy lithium battery materials stacked in the conveying pipeline are loosened, the flowability of the new energy lithium battery materials in the conveying pipeline is improved, the new energy lithium battery materials stacked in the conveying pipeline are discharged, when the conveying pipeline cannot be dredged only through vibration, the pulling assembly drives the bent plate to move away from the direction of the conveying pipeline through the transmission assembly, the bent plate is separated from the conveying pipeline, the new energy lithium battery materials stacked at the bending position of the conveying pipeline fall down, the conveying pipeline is dredged through pressure change in the conveying pipeline, labor is saved, and the lower end of the sealing box is provided with an opening, and a sealing cover is connected at the opening through threads.

Drawings

Fig. 1 is a schematic structural diagram of a conveyor for conveying new energy lithium battery materials, which is provided by an embodiment of the invention;

fig. 2 is a schematic structural diagram of the moving plate in fig. 1 according to an embodiment of the present invention;

FIG. 3 is an enlarged schematic view of the structure of FIG. 1A according to an embodiment of the present invention;

fig. 4 is an enlarged schematic view of the structure of B in fig. 3 according to an embodiment of the present invention.

In the accompanying drawings: the conveying pipeline 101, the corner plate 102, the seal box 103, the first guide sliding groove 104, the first guide sliding block 105, the moving plate 106, the guide seat 107, the guide plate 108, the first fixed shaft 109, the transmission assembly 2, the piston housing 201, the piston 202, the first pressure spring 203, the first guide shaft 204, the inclined pushing groove 205, the connecting plate 206, the adjusting plate 301, the bolt 302, the fastening bolt 303, the vibration assembly 4, the second fixed shaft 401, the arc-shaped groove 402, the second pressure spring 403, the fixed sleeve 404, the second guide groove 405, the telescopic rod 406, the third pressure spring 407, the deflector rod assembly 5, the mounting plate 501, the mounting seat 502, the toggle rod 503, the mounting groove 504, the tension spring 505, the pulling assembly 6, the V-shaped guide groove 601 and the second guide shaft 602.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Specific implementations of the invention are described in detail below in connection with specific embodiments.

As shown in fig. 1, a conveyor for conveying new energy lithium battery materials according to an embodiment of the present invention includes a conveying pipeline 101, and a corner plate 102 disposed at a bending position of the conveying pipeline 101, and further includes:

seal box 103, first guide slider 105, moving plate 106, and guide plate 108;

the sealing box 103 is connected with the conveying pipeline 101, a first guide sliding groove 104 is formed in the sealing box 103, the first guide sliding block 105 is slidably connected in the first guide sliding groove 104, the moving plate 106 is fixed on the first guide sliding block 105, a guide seat 107 is fixed in the sealing box 103, the guide plate 108 is slidably connected in the guide seat 107, a first fixed shaft 109 is fixed on the guide plate 108, and the corner plate 102 is rotatably connected on the first fixed shaft 109;

the transmission assembly 2 is arranged in the sealing box 103, and the transmission assembly 2 drives the first guide slide block 105 to slide left and right through the pressure in the conveying pipeline 101;

a vibration assembly 4, wherein the vibration assembly 4 is arranged on the corner plate 102, and the vibration assembly 4 drives the corner plate 102 to vibrate in a reciprocating rotation manner through the transmission assembly 2;

the pulling assembly 6 is arranged on the guide plate 108, and the pulling assembly 6 drives the corner plate 102 to move away from the conveying pipeline 101 through the transmission assembly 2.

In the embodiment of the invention, when new energy lithium battery materials are stacked at the bending position in the conveying pipeline 101 in the use process, the pressure at the right end of the conveying pipeline 101 is increased, the transmission assembly 2 drives the vibration assembly 4 and the pulling assembly 6 to work through the high pressure at the right end of the conveying pipeline 101, the vibration assembly 4 drives the corner plate 102 to vibrate in a reciprocating rotation mode through the transmission assembly 2, so that the new energy lithium battery materials stacked in the conveying pipeline 101 are loosened, the fluidity of the new energy lithium battery materials in the conveying pipeline 101 is improved, the new energy lithium battery materials stacked in the conveying pipeline 101 are discharged, when the conveying pipeline 101 cannot be dredged only through vibration, the pulling assembly 6 drives the corner plate 102 to move away from the direction of the conveying pipeline 101 through the transmission assembly 2, the corner plate 102 is separated from the conveying pipeline 101, the new energy lithium battery materials stacked at the conveying pipeline 101 drop, the conveying pipeline 101 is dredged through the pressure change in the conveying pipeline 101, the labor is saved, the lower end of the sealing box 103 is provided with an opening, and the sealing cover is connected with the bending position through threads.

As shown in fig. 1 and 2, as a preferred embodiment of the present invention, the transmission assembly 2 includes a piston housing 201, a piston 202, a first compression spring 203, a first guide shaft 204, and a connection plate 206, wherein the piston housing 201 is fixed on the conveying pipe 101, the piston 202 is slidably connected in the piston housing 201, an end of the piston 202 near the conveying pipe 101 has the same shape as an inner wall of the conveying pipe 101, the first compression spring 203 is disposed in the piston housing 201, the first guide shaft 204 is fixed on the piston 202, the connection plate 206 is fixed on the first guide slider 105, an inclined pushing groove 205 is disposed on the connection plate 206, and the first guide shaft 204 is slidably matched with the inclined pushing groove 205.

In the embodiment of the invention, the upper end of the piston housing 201 is communicated with the conveying pipeline 101, when the pressure at the right end of the conveying pipeline 101 is increased, the pressure pushes the piston 202 to move downwards, the piston 202 drives the first guide shaft 204 to move downwards, the first guide shaft 204 pushes the connecting plate 206 to move leftwards through the inclined pushing groove 205, the connecting plate 206 pushes the first guide slide block 105 to move leftwards, and when the pressure in the conveying pipeline 101 is restored, the first pressure spring 203 pushes the piston 202 to move upwards and reset, and the connecting plate 206 drives the first guide slide block 105 to move rightwards and reset.

As shown in fig. 1, as a preferred embodiment of the present invention, an adjusting plate 301 is further slidably connected to the piston housing 201, a bolt 302 is screwed to the piston housing 201, a distal end of the bolt 302 is in a rotating fit with the adjusting plate 301, and a fastening bolt 303 is screwed to the bolt 302.

In the embodiment of the present invention, when the elastic potential energy of the first compression spring 203 is needed, the bolt 302 is turned, the bolt 302 drives the adjusting plate 301 to move up and down in a manner of being in threaded fit with the piston housing 201, when the adjusting plate 301 moves up, the elastic potential energy of the first compression spring 203 is increased, and when the adjusting plate 301 moves up, the elastic potential energy of the first compression spring 203 is reduced.

As shown in fig. 1 to 3, as a preferred embodiment of the present invention, the vibration assembly 4 includes a second fixing shaft 401, a second compression spring 403, a fixing sleeve 404, a telescopic rod 406, a third compression spring 407, and a shift lever assembly 5, where the second fixing shaft 401 is fixed on the guide plate 108, an arc-shaped groove 402 is provided on the corner plate 102, the second fixing shaft 401 is slidably matched with the arc-shaped groove 402, the second compression spring 403 is provided in the arc-shaped groove 402, the fixing sleeve 404 is fixed on the corner plate 102, a second guide groove 405 is provided in the fixing sleeve 404, the telescopic rod 406 is slidably connected in the second guide groove 405, the third compression spring 407 is provided in the second guide groove 405, the shift lever assembly 5 is provided on the moving plate 106, and the shift lever assembly 5 is used for intermittently pushing the telescopic rod 406 to rotate.

In the embodiment of the present invention, when the moving plate 106 moves leftwards, the moving plate 106 drives the deflector rod assembly 5 to move leftwards, and then the deflector rod assembly 5 is pushed to rotate clockwise through the telescopic rod 406 and the fixed sleeve 404 until the deflector rod assembly 5 does not contact with the telescopic rod 406, the second pressure spring 403 pushes the deflector plate 102 to rotate reversely and reset, and then the deflector plate 102 vibrates in a reciprocating rotation manner, and when the deflector plate 102 moves leftwards and downwards, the telescopic rod 406 contacts with the mounting plate 501, so that the second pressure spring 403 is compressed, the height of the telescopic rod 406 is reduced, and thus when the deflector plate 102 moves leftwards and downwards, the deflector rod assembly 5 can still push the deflector plate 102 to rotate.

As shown in fig. 3 and 4, as a preferred embodiment of the present invention, the lever assembly 5 includes a mounting plate 501, a mounting seat 502, a toggle rod 503 and a tension spring 505, the mounting plate 501 is fixed on the moving plate 106, the mounting seat 502 is fixed on the mounting plate 501, the toggle rod 503 is rotatably connected to the mounting seat 502, a mounting groove 504 is provided on the mounting seat 502, the tension spring 505 is disposed in the mounting groove 504, two ends of the tension spring 505 are respectively connected with the toggle rod 503 and the inner wall of the mounting groove 504, and a plurality of groups of the mounting seat 502, the toggle rod 503, the mounting groove 504 and the tension spring 505 are provided.

In the embodiment of the invention, when the moving plate 106 moves leftwards, the toggle rod 503 pushes the telescopic rod 406 to rotate clockwise, and by arranging a plurality of groups of mounting seats 502, the toggle rod 503, the mounting grooves 504 and the tension springs 505, the telescopic rod 406 intermittently rotates, so that the corner plate 102 is driven to intermittently vibrate, and when the moving plate 106 moves rightwards and resets, the telescopic rod 406 pushes the toggle rod 503 to rotate anticlockwise to avoid.

As shown in fig. 1 and 2, the pulling assembly 6 includes a V-shaped guide groove 601 and a second guide shaft 602, the V-shaped guide groove 601 is provided on the moving plate 106, one end of the V-shaped guide groove 601 is horizontally provided, the second guide shaft 602 is fixed on the guide plate 108, and the second guide shaft 602 is slidably engaged with the V-shaped guide groove 601.

In the embodiment of the invention, when the moving plate 106 moves rightwards, because the left end of the V-shaped guide groove 601 is horizontally arranged, when the moving plate 106 moves leftwards, the V-shaped guide groove 601 does not push the guide plate 108 to move leftwards and downwards through the second guide shaft 602, at this time, the new energy lithium battery material accumulated at the bending position of the conveying pipeline 101 is dredged only through the vibration mode of the bent angle plate 102, when the new energy lithium battery material accumulated at the bending position of the conveying pipeline 101 can not be dredged through vibration, the pressure at the right end of the conveying pipeline 101 is continuously increased, the moving plate 106 is further made to move leftwards, the moving plate 106 is matched with the second guide shaft 602 through the right half section of the V-shaped guide groove 601, and then the guide plate 108 is driven to move leftwards and downwards, the guide plate 108 drives the bent angle plate 102 to move leftwards and downwards, so that the new energy lithium battery material accumulated at the bending position of the conveying pipeline 101 is dropped, and meanwhile the bent angle plate 102 is continuously vibrated, and the discharging efficiency of the new energy lithium battery material accumulated at the bending position of the conveying pipeline 101 is further improved.

In the above embodiment of the present invention, there is provided a conveyor for conveying new energy lithium battery materials, in which, when new energy lithium battery materials are stacked at a bend in a conveying pipe 101 during use, the pressure at the right end of the conveying pipe 101 becomes larger, the upper end of a piston housing 201 is communicated with the conveying pipe 101, when the pressure at the right end of the conveying pipe 101 increases, a pressure pushing piston 202 moves down, the piston 202 drives a first guiding shaft 204 to move down, the first guiding shaft 204 pushes a connecting plate 206 to move left through a diagonal pushing groove 205, the connecting plate 206 pushes a first guiding slide 105 to move left, when a moving plate 106 moves left, the moving plate 106 drives a deflector rod assembly 5 to move left, and then pushes a bent plate 102 to rotate clockwise through a telescopic rod 406 and a fixed sleeve 404 until the deflector rod assembly 5 does not contact with the telescopic rod 406, a second compression spring pushes the bent plate 102 to rotate reversely and reset, when the bent angle plate 102 moves leftwards and downwards, the telescopic rod 406 contacts with the mounting plate 501, so that the second pressure spring 403 is compressed, the height of the telescopic rod 406 is reduced, when the bent angle plate 102 moves leftwards and downwards, the deflector rod assembly 5 can still push the bent angle plate 102 to rotate, so that new energy lithium battery materials accumulated in the conveying pipeline 101 are loosened, the fluidity of the new energy lithium battery materials in the conveying pipeline 101 is improved, the new energy lithium battery materials accumulated in the conveying pipeline 101 are discharged, when the conveying pipeline 101 cannot be dredged by vibration, the moving plate 106 moves rightwards, the V-shaped guide groove 601 does not push the guide plate 108 leftwards and downwards through the second guide shaft 602 when the moving plate 106 moves leftwards due to the left end horizontal arrangement of the V-shaped guide groove 601, at this time, the new energy lithium battery material accumulated at the bending position of the conveying pipeline 101 is dredged only by vibrating the bent plate 102, when the new energy lithium battery material accumulated at the bending position of the conveying pipeline 101 cannot be dredged only by vibrating, the pressure at the right end of the conveying pipeline 101 is continuously increased, the moving plate 106 is further enabled to move leftwards, the moving plate 106 is matched with the second guide shaft 602 through the right half section of the V-shaped guide groove 601, the guide plate 108 is further driven to move leftwards and downwards, the guide plate 108 drives the bent plate 102 to move leftwards and downwards, the new energy lithium battery material accumulated at the bending position of the conveying pipeline 101 falls out, meanwhile, the bent plate 102 is continuously vibrated, the discharging efficiency of the new energy lithium battery material accumulated at the bending position of the conveying pipeline 101 is further improved, the conveying pipeline 101 is self-dredged by pressure change in the conveying pipeline 101, and labor is saved.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (2)

1. A conveyer for new forms of energy lithium battery material is carried, includes pipeline to and pipeline bending part sets up the corner plate, its characterized in that still includes:

the device comprises a sealing box, a first guide sliding block, a moving plate and a guide plate;

the sealing box is connected with the conveying pipeline, a first guide sliding groove is formed in the sealing box, the first guide sliding block is connected in the first guide sliding groove in a sliding mode, the moving plate is fixed on the first guide sliding block, a guide seat is fixed in the sealing box, the guide plate is connected in the guide seat in a sliding mode, a first fixed shaft is fixed on the guide plate, and the corner plate is connected on the first fixed shaft in a rotating mode;

the transmission assembly is arranged in the sealing box and drives the first guide sliding block to slide left and right through pressure in the conveying pipeline;

the vibration assembly is arranged on the corner plate and drives the corner plate to vibrate in a reciprocating rotation mode through the transmission assembly;

the pulling assembly is arranged on the guide plate and drives the corner plate to move away from the direction of the conveying pipeline through the transmission assembly;

the transmission assembly comprises a piston shell, a piston, a first pressure spring, a first guide shaft and a connecting plate, wherein the piston shell is fixed on a conveying pipeline, the piston is slidably connected in the piston shell, one end of the piston, which is close to the conveying pipeline, is identical to the inner wall of the conveying pipeline in shape, the first pressure spring is arranged in the piston shell, the first guide shaft is fixed on the piston, the connecting plate is fixed on a first guide sliding block, an inclined pushing groove is formed in the connecting plate, and the first guide shaft is slidably matched with the inclined pushing groove;

an adjusting plate is also connected in the piston shell in a sliding way, a bolt is connected to the piston shell through threads, the tail end of the bolt is in running fit with the adjusting plate, and a fastening bolt is connected to the bolt through threads;

the vibration assembly comprises a second fixed shaft, a second pressure spring, a fixed sleeve, a telescopic rod, a third pressure spring and a deflector rod assembly, wherein the second fixed shaft is fixed on a guide plate, an arc-shaped groove is formed in a curved angle plate, the second fixed shaft is in sliding fit with the arc-shaped groove, the second pressure spring is arranged in the arc-shaped groove, the fixed sleeve is fixed on the curved angle plate, a second guide groove is formed in the fixed sleeve, the telescopic rod is in sliding connection with the second guide groove, the third pressure spring is arranged in the second guide groove, the deflector rod assembly is arranged on a moving plate, and the deflector rod assembly is used for intermittently pushing the telescopic rod to rotate;

the poking rod assembly comprises a mounting plate, a mounting seat, a poking rod and a tension spring, wherein the mounting plate is fixed on the moving plate, the mounting seat is fixed on the mounting plate, the poking rod is rotationally connected to the mounting seat, a mounting groove is formed in the mounting seat, the tension spring is arranged in the mounting groove, and two ends of the tension spring are respectively connected with the poking rod and the inner wall of the mounting groove;

the pulling assembly comprises a V-shaped guide groove and a second guide shaft, the V-shaped guide groove is formed in the moving plate, one end of the V-shaped guide groove is horizontally arranged, the second guide shaft is fixed on the guide plate, and the second guide shaft is in sliding fit with the V-shaped guide groove.

2. The conveyor for new energy lithium battery material delivery of claim 1, wherein the mounting base, the tap lever, the mounting groove and the tension spring are provided with a plurality of groups.

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