CN213713917U - Casket-like bowl material vibrating device - Google Patents

Abstract

The application relates to the field of lithium battery material sintering auxiliary equipment, in particular to a casket-like bowl material vibration device. The device comprises a fixed frame, and a vibration mechanism, a lifting mechanism and a feeding mechanism which are arranged on the fixed frame, wherein the feeding mechanism is arranged below the vibration mechanism and the lifting mechanism; the vibration mechanism is arranged on the fixed frame and is connected with the fixed frame in a sliding way; the lifting mechanism is arranged on the vibration mechanism; the lifting mechanism can lift the sagger and separate the sagger from the feeding mechanism; the vibration mechanism can drive the saggar to vibrate through the lifting mechanism. The method has the effect of improving the sintering uniformity of the lithium battery material.

Description

Casket-like bowl material vibrating device

Technical Field

The application relates to the field of lithium battery material sintering auxiliary equipment, in particular to a casket-like bowl material vibration device.

Background

The lithium battery material sintering roller kiln is a light continuous industrial kiln, is widely applied to rapid firing of ternary anode materials, chemical powder, ceramic substrates and other products, and has the advantages of low energy consumption, short firing period, good furnace temperature uniformity, low labor intensity and the like.

The roller kiln is generally composed of a kiln chamber, heating equipment, cooling equipment and conveying equipment. The working process of the roller kiln is generally as follows: the method comprises the steps of firstly placing the lithium battery material on a conveying roller way through a sagger, then enabling the lithium battery material to enter a kiln along with the conveying roller way, completing the process of a sintering process in the kiln through heating equipment and cooling equipment, and finally collecting the cooled lithium battery material.

According to the related technology, the lithium battery material is placed in the sagger, the lithium battery material in the sagger directly enters the kiln to be sintered according to the placing state, the distribution density of the lithium battery material in the sagger is different, and the inventor thinks that the defect of uneven sintering of the lithium battery material exists at the same temperature.

SUMMERY OF THE UTILITY MODEL

In order to improve the homogeneity of lithium battery material sintering, this application provides a casket-like bowl material vibrating device.

The application provides a casket-like bowl material vibrating device adopts following technical scheme:

a vibration device for a casket-like bowl material comprises a fixed frame, and a vibration mechanism, a lifting mechanism and a feeding mechanism which are arranged on the fixed frame, wherein the feeding mechanism is arranged below the vibration mechanism and the lifting mechanism; the vibration mechanism is arranged on the fixed frame and is connected with the fixed frame in a sliding manner; the lifting mechanism is arranged on the vibration mechanism; the lifting mechanism can lift the sagger and separate from the feeding mechanism; the vibration mechanism can drive the sagger to vibrate through the lifting mechanism.

By adopting the technical scheme, when the materials in the sagger are vibrated and shaken uniformly by using the vibrating device, the feeding mechanism is adjusted to be opened, and the sagger is conveyed to the lower part of the vibrating mechanism by the feeding mechanism; adjusting the lifting mechanism to be opened, so that the lifting mechanism drives the saggar to move in the direction away from the feeding mechanism until the saggar completely leaves the feeding mechanism; adjusting the vibration mechanism to be started, so that the vibration mechanism drives the sagger to vibrate through the lifting mechanism until the materials in the sagger are vibrated to be relatively uniform; adjusting the lifting mechanism to be opened, so that the lifting mechanism drives the sagger to move towards the direction close to the feeding mechanism until the sagger is placed on the feeding mechanism; then the feeding mechanism conveys the sagger to the next procedure to finish the vibration and even shaking of the materials in the sagger; the feeding mechanism, the lifting mechanism and the vibrating mechanism are arranged, materials in the saggar can be shaken uniformly, the planes of the materials in the saggar are uniformly located on the same plane, the phenomenon that the materials are not uniformly sintered due to the fact that the heights of the materials are low is avoided, the uniformity of sintering of the materials in the same saggar is improved, and the sintering quality of the materials is improved.

Optionally, the vibration mechanism includes an eccentric wheel, a connecting rod, a sliding plate, and a first driving member, the eccentric wheel is rotatably connected to the fixed frame, the sliding plate is slidably connected to the fixed frame, one end of the connecting rod is disposed on an outer wall of the eccentric wheel, the other end of the connecting rod is hinged to the sliding plate, a hinge shaft of the connecting rod is axially parallel to a rotating shaft of the eccentric wheel, and the first driving member is disposed on the fixed frame and can rotate the eccentric wheel.

By adopting the technical scheme, when the vibration mechanism is started, the first driving piece is adjusted to be opened, so that the first driving piece drives the eccentric wheel to rotate, the eccentric wheel drives one end, close to the eccentric wheel, of the connecting rod to swing along the vertical direction along with the eccentric wheel in the rotating process, and one end, far away from the eccentric wheel, of the connecting rod drives the sliding plate to slide along the horizontal direction and reciprocate, so that the vibration of the sliding plate is completed; the eccentric wheel, the connecting rod, the sliding plate and the first driving piece that set up, the reciprocating motion of rotation drive sliding plate through the eccentric wheel, realize turning into the horizontal direction displacement with the displacement of vertical direction through articulated, and then realize the rotation of sliding plate, the vibration frequency of sliding plate can be adjusted through the rotational speed of adjusting the eccentric wheel, and then the vibration frequency of control sagger, the material of being convenient for in with the sagger shakes evenly.

Optionally, the feeding mechanism includes a plurality of feeding rollers, a roller and a second driving member for driving the feeding rollers to rotate, the feeding rollers are arranged on the fixed frame in parallel along a horizontal direction, the roller is uniformly sleeved on the feeding rollers in a coaxial manner, and the second driving member is arranged on the fixed frame and can enable all the feeding rollers to rotate synchronously.

Through adopting above-mentioned technical scheme, material roller, gyro wheel and the second driving piece that sets up support the sagger to drive sagger and material motion to each process, guarantee rollgang circulation system's is complete.

Optionally, the second driving member includes a second servo motor, a transmission gear and a toothed chain, and an output shaft of the second servo motor is coaxially connected with any one of the feeding rollers and can enable any one of the feeding rollers to rotate; the transmission gear is coaxially fixed at the end part of the feeding roller and is provided with two rows of gear teeth, and the gear chain is sleeved on two adjacent transmission gears and is meshed with the transmission gears.

By adopting the technical scheme, when the feeding mechanism works, the second servo motor is adjusted to be started, so that the output shaft of the second servo motor drives any one feeding roller and the roller on the feeding roller to rotate, the transmission gear is driven to rotate, the transmission gear drives the rest transmission gears and the feeding rollers to synchronously rotate through the toothed chain, and the conveying mechanism starts to work; the second servo motor, the transmission gear and the toothed chain are meshed with the toothed chain through the transmission gear, so that all the feeding rollers synchronously rotate, the transmission is stable, the loss is small, and the use function of the conveying mechanism is ensured.

Optionally, the lifting mechanism includes two lifting plates, a positioning member and a lifting cylinder, the positioning member is disposed between the sliding plate and the feeding mechanism, one end of each lifting plate is connected to the positioning member, and the other end of each lifting plate penetrates through the sliding plate and is slidably connected to the sliding plate; the lifting cylinder is fixedly arranged at one end, penetrating out of the sliding plate, of the lifting plate, and a telescopic rod of the lifting cylinder is pushed against the sliding plate.

By adopting the technical scheme, when the saggar is far away from the feeding mechanism and evenly shaken, the adjusting and fixing piece is used for fixing the saggar, then the lifting cylinder is adjusted to be opened, so that the telescopic rod of the lifting cylinder pushes the sliding plate to move towards the direction far away from the sliding plate, and the saggar is driven to be far away from the feeding mechanism through the lifting plate and the fixing piece until the saggar completely leaves the feeding mechanism; the sagger is far away from the feeding mechanism by the aid of the lifting plate, the positioning piece and the lifting cylinder, vibration of the sagger is separated from motion of the feeding mechanism, and the phenomenon that the motion of the feeding mechanism influences the vibration of the sagger is avoided.

Optionally, the positioning element comprises a pressing plate and a plurality of supporting plates, and the pressing plate is slidably connected below the sliding plate through a connecting element; the length direction of the supporting plate is parallel to the feeding rollers and is arranged between the two feeding rollers; one end of the supporting plate is arranged at one end of the lifting plate close to the feeding roller, and the other end of the supporting plate is arranged close to the other lifting plate; the supporting plate is arranged below the highest point of the roller in the height direction.

Through adopting above-mentioned technical scheme, the clamp plate and the layer board that set up fix the sagger between clamp plate and layer board, fix the sagger, carry out the shutoff to the sagger opening simultaneously, avoid the sagger along the vibration of vertical direction, reduce the material that scatters out the sagger in the vibration process.

Optionally, a plurality of fixture blocks are arranged at one end of the pressing plate close to the feeding roller, and the fixture blocks are clamped on the inner wall of the sagger and can enable the sagger and the pressing plate to keep relatively static.

Through adopting above-mentioned technical scheme, the position of sagger at the horizontal direction is restricted to the fixture block that sets up, reduces the sagger at the removal of horizontal direction in the vibration process, and further the fixed sagger of son for the sagger keeps relative stillness with the clamp plate.

Optionally, a material blocking mechanism is arranged on the fixed frame and comprises two sets of material blocking pieces which are arranged oppositely, each material blocking piece comprises a material blocking cylinder and a material blocking wheel, the material blocking cylinders are arranged on the fixed frame, the axial directions of piston rods of the material blocking cylinders are parallel to the axial direction of the feeding roller, and the material blocking wheels are coaxially arranged on the piston rods of the material blocking cylinders.

By adopting the technical scheme, the material blocking mechanism limits the movement of the sagger, when the feeding mechanism is in a working state, the sagger slides on the conveying mechanism, so that the movement of the sagger along with the feeding mechanism is prevented, and the sagger is convenient to fix by the lifting mechanism; the material blocking wheel is arranged, so that the friction between the material blocking wheel and the sagger is reduced when the movement of the sagger is limited.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the feeding mechanism, the lifting mechanism and the vibrating mechanism are arranged, so that materials in the saggar can be shaken uniformly, the planes of the materials in the saggar are uniformly positioned on the same plane, the phenomenon that the materials are not uniformly sintered due to the height of the materials is avoided, the sintering uniformity of the materials in the same saggar is improved, and the sintering quality of the materials is improved;

2. the rotary sagger comprises an eccentric wheel, a connecting rod, a sliding plate and a first driving piece, wherein the eccentric wheel rotates to drive the sliding plate to reciprocate, the vertical displacement is converted into the horizontal displacement through hinging, the sliding plate rotates, the vibration frequency of the sliding plate can be adjusted by adjusting the rotating speed of the eccentric wheel, the vibration frequency of the sagger is further controlled, and materials in the sagger can be conveniently shaken uniformly;

3. the material blocking mechanism is arranged to limit the movement of the sagger, and when the feeding mechanism is in a working state, the sagger slides on the conveying mechanism to prevent the displacement of the sagger along with the movement of the feeding mechanism, so that the sagger is conveniently fixed by the lifting mechanism; the material blocking wheel is arranged, so that the friction between the material blocking wheel and the sagger is reduced when the movement of the sagger is limited.

Drawings

Fig. 1 is a schematic overall structure diagram of a sagger material vibration device according to an embodiment of the present application.

Fig. 2 is an enlarged view of a portion a in fig. 1.

Fig. 3 is a schematic view of the structure of the connector of fig. 1.

Description of reference numerals: 1. a fixed frame; 11. a support; 12. a cross bar; 13. fixing the shield; 2. a vibration mechanism; 21. an eccentric wheel; 22. a connecting rod; 23. a sliding plate; 24. a sliding shaft; 25. a first servo motor; 26. a mounting seat; 27. a slider; 28. a fixed seat; 3. a lifting mechanism; 31. a lifting plate; 32. a lifting cylinder; 33. a positioning member; 331. pressing a plate; 332. a support plate; 333. a clamping block; 34. pushing the plate; 35. a connecting member; 351. a guide post; 352. a spring; 353. connecting columns; 354. a rubber cushion layer; 355. a limiting block; 4. a feeding mechanism; 41. a feed roller; 42. a roller; 43. a second servo motor; 44. a transmission gear; 45. a toothed chain; 5. a stock stop mechanism; 51. a material blocking cylinder; 52. a material blocking wheel; 6. a material receiving mechanism; 61. drawing the groove; 62. a collection cabinet; 63. the handle is drawn.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses casket-like bowl material vibrating device. Referring to fig. 1, the sagger material vibration device comprises a fixed frame 1, a vibration mechanism 2, a lifting mechanism 3, a feeding mechanism 4, a material blocking mechanism 5 and a material receiving mechanism 6. The fixed frame 1 comprises supports 11, cross bars 12 and a fixed shield 13, wherein the supports 11 are fixed on the ground through expansion bolts, and the cross bars 12 are arranged in parallel and welded on the supports 11; the fixed shield 13 is welded over the two crossbars 12. The feeding mechanism 4 is arranged on the cross rod 12, and the vibrating mechanism 2 is connected above the fixed shield 13 in a sliding manner; the lifting mechanism 3 is arranged on the vibration mechanism 2; the material blocking mechanism 5 is arranged at one end of the cross rod 12 close to the discharging end of the feeding mechanism 4; receiving agencies 6 sets up in horizontal pole 12 below, and receiving agencies 6 includes drawing groove 61 and collection cabinet 62, and drawing groove 61 welds at horizontal pole 12 diapire, collects cabinet 62 stretch into drawing groove 61 and with drawing groove 61 sliding connection, collects and is fixed with pull handle 63 through the bolt on the cabinet 62 end wall.

Referring to fig. 1 and 2, the feeding mechanism 4 includes a plurality of feeding rollers 41, a roller 42, and a second driving member including a second servo motor 43, a plurality of transmission gears 44, and a toothed chain 45; the rollers 42 are uniformly distributed on the feeding roller 41 and are coaxially welded on the feeding roller 41; the plurality of feeding rollers 41 are arranged in parallel along the horizontal direction, two ends of each feeding roller 41 are rotatably connected between the two cross rods 12 through bearings, and the distribution direction of the feeding rollers 41 is the same as the length direction of the cross rods 12; a motor base is welded on the cross rod 12, a second servo motor 43 is fixed on the motor base through bolts, and an output shaft of the second servo motor 43 is coaxially connected with any one feeding roller 41; the transmission gears 44 are coaxially fixed at two end parts of the feeding roller 41, two rows of gear teeth are arranged on the side wall of each transmission gear 44, and the gear chains 45 are sleeved on the two adjacent transmission gears 44 and meshed with the transmission gears 44.

Referring to fig. 1, the vibration mechanism 2 includes an eccentric 21, a connecting rod 22, a slide plate 23, a slide shaft 24, and a first driving member provided as a first servo motor 25; a motor frame and a mounting seat 26 are welded on the fixed shield 13, the first servo motor 25 is fixed on the fixed shield 13 through bolts, an output shaft of the first servo motor 25 penetrates through the mounting seat 26 and is rotatably connected with the mounting seat 26 through a bearing, and the axial direction of the output shaft of the first servo motor 25 is the same as the axial direction of the feed roller 41; the eccentric wheel 21 is coaxially welded at one end of the output shaft of the first servo motor 25 passing through the mounting seat 26. The four corners of the bottom wall of the sliding plate 23 are welded with sliding blocks 27, two sliding shafts 24 are arranged, the sliding shafts 24 penetrate through the two sliding blocks 27 on the same side along the length direction of the cross rod 12, and the sliding blocks 27 can slide along the sliding shafts 24; four groups of fixed seats 28 are fixed on the fixed shield 13 through bolts, and two ends of the sliding shaft 24 are welded on the fixed seats 28. The connecting rod 22 is disposed on the eccentric wheel 21, one end of the connecting rod 22 is welded on the outer wall of the eccentric wheel 21, and the other end is hinged on the sliding plate 23, and the hinge shaft of the connecting rod 22 is disposed in parallel with the axial direction of the output shaft of the first servo motor 25.

Referring to fig. 1, the lifting mechanism 3 includes two lifting plates 31, a positioning member 33 and a lifting cylinder 32, the two lifting plates 31 are disposed at two ends of the feed roller 41, and one end of the lifting plate 31 passes through the sliding plate 23 along the vertical direction and is slidably connected with the sliding rod; the lifting cylinder 32 is fixed on the side wall of the lifting plate 31 penetrating through one end of the sliding plate 23 through a bolt, the end part of a telescopic rod of the lifting cylinder 32 is welded with a push plate 34, and one end of the push plate 34 far away from the lifting cylinder 32 is welded on the top wall of the sliding plate 23.

Referring to fig. 1 and 3, the positioning member 33 includes a pressing plate 331, a plurality of support plates 332 and a fixture block 333, the support plates 332 are welded at one end of the lifting plate 31 far away from the lifting cylinder 32, the support plates 332 extend between the two feed rollers 41 and are axially parallel to the feed rollers 41 along the length direction, one end of each support plate 332 is arranged at one end of the lifting plate 31 close to one feed roller 41, and the other end of each support plate 332 is arranged close to the other lifting plate 31; the pallet 332 is positioned lower than the highest point of the roller 42 in the height direction. The pressing plate 331 is slidably connected below the sliding plate 23 through a connecting piece 35; the connecting piece 35 comprises a guide post 351, a spring 352 and two groups of connecting posts 353, wherein one end of the guide post 351 is welded at the center of the pressure plate 331, and the other end of the guide post 351 penetrates through the sliding plate 23 and is connected with the sliding plate 23 in a sliding manner; a rubber cushion 354 is sleeved on the side wall of the pressing plate 331 and the sliding plate 23 close to each other around the guide post 351, a spring 352 is sleeved on the guide post 351 and between the pressing plate 331 and the sliding plate 23, one end of the spring 352 is abutted against the rubber cushion 354 on the pressing plate 331, the other end of the spring 352 is abutted against the rubber cushion 354 on the sliding plate 23, and the spring 352 can enable the area of the pressing plate 331 to move close to the direction of the feed roller 41; two sets of connecting columns 353 are correspondingly arranged on two sides of the guide column 351 and are parallel to the guide column 351, one end of each connecting column 353 is welded in the center of the pressing plate 331, the other end of each connecting column 353 penetrates through the sliding plate 23 and is in sliding connection with the sliding plate 23, a rubber sleeve is fixed on the sliding plate 23 around the corresponding connecting column 353 through a bolt, and one end of each connecting column 353, which is far away from the pressing plate 331, is. The four clamping blocks 333 are welded at one end, close to the feeding roller 41, of the pressing plate 331, the positions of the clamping blocks 333 are arranged corresponding to the positions of the four included angles of the sagger, and the clamping blocks 333 can be clamped in the four inner corners of the sagger and enable the sagger and the pressing plate 331 to keep relatively static.

Referring to fig. 1, the material blocking mechanism 5 includes two sets of material blocking members which are arranged oppositely, the material blocking members include a material blocking cylinder 51 and a material blocking wheel 52, a material blocking opening is formed in the fixed protective cover 13, the material blocking cylinder 51 is fixed on the cross rod 12 through a bolt, a piston rod of the material blocking cylinder 51 extends into the material blocking opening, the axial direction of the piston rod of the material blocking cylinder 51 is parallel to the axial direction of the feeding roller 41, and the material blocking wheel 52 is coaxially connected in a rotating mode and extends into one end of the material blocking opening through the piston rod of the material blocking cylinder 51.

The implementation principle of the casket-like bowl material vibrating device in the embodiment of the application is as follows: when the materials in the sagger are vibrated and shaken uniformly by using the vibrating device, the second servo motor 43 is adjusted to be started, so that the output shaft of the second servo motor 43 drives any one of the feeding rollers 41 and the roller 42 on the feeding roller 41 to rotate, further the transmission gear 44 is driven to rotate, the transmission gear 44 drives the other transmission gears 44 and the feeding rollers 41 to synchronously rotate through the toothed chain 45, and the conveying mechanism starts to work; the opening of the material blocking cylinder 51 is adjusted, so that the telescopic rod of the material blocking cylinder 51 drives the material blocking wheels 52 to move towards the position between the two cross rods 12 until the distance between the two material blocking wheels 52 is smaller than the width of the sagger; the sagger then moves with the feeding roller 41 until it abuts against one side of the two wheels 52, at which point it is above the pallet 332, after which it is raised.

When the sagger is lifted by using the lifting mechanism 3, the lifting cylinder 32 is adjusted to be opened, so that the telescopic rod of the lifting cylinder 32 abuts against the sliding plate 23 to drive the supporting plate 332 to vertically move upwards, in the lifting process, the supporting plate 332 abuts against the bottom wall of the sagger and drives the sagger to be far away from the feeding roller 41 until the opening of the sagger abuts against the bottom wall of the pressing plate 331, and the spring 352 is in a compression state at the moment.

When shaking the material in the sagger evenly, start vibration mechanism 2, adjust first servo motor 25 and open for the output shaft of first servo motor 25 drives eccentric wheel 21 and rotates, and eccentric wheel 21 is at the rotation in-process, and drive connecting rod 22 and be close to eccentric wheel 21 one end and follow eccentric wheel 21 along vertical direction swing, and connecting rod 22 keeps away from eccentric wheel 21 one end and drives sliding plate 23 and slide along the horizontal direction to do reciprocating motion, and then drive the sagger and shake along the horizontal direction, until the material in the sagger is shaken evenly, accomplish the vibration of the material in the sagger and shake evenly.

Finally, the sagger is reset, and the lifting cylinder 32 is adjusted to be opened, so that the sagger is reset; the material blocking cylinder 51 is adjusted to be opened, so that the material blocking wheel 52 returns; then the feeding roller 41 conveys the sagger to the next process, and the vibration and even shaking of the materials in the sagger are completed.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a casket-like bowl material vibrating device which characterized in that: the device comprises a fixed frame (1), and a vibration mechanism (2), a lifting mechanism (3) and a feeding mechanism (4) which are arranged on the fixed frame (1), wherein the feeding mechanism (4) is arranged below the vibration mechanism (2) and the lifting mechanism (3); the vibration mechanism (2) is arranged on the fixed frame (1) and is connected with the fixed frame (1) in a sliding manner; the lifting mechanism (3) is arranged on the vibration mechanism (2); the lifting mechanism (3) can lift the sagger and separate from the feeding mechanism (4); the vibration mechanism (2) can drive the sagger to vibrate through the lifting mechanism (3).

2. The sagger material vibrating device according to claim 1, wherein: the vibration mechanism (2) comprises an eccentric wheel (21), a connecting rod (22), a sliding plate (23) and a first driving piece, the eccentric wheel (21) is rotatably connected to the fixed frame (1), the sliding plate (23) is slidably connected to the fixed frame (1), one end of the connecting rod (22) is arranged on the outer wall of the eccentric wheel (21), the other end of the connecting rod is hinged to the sliding plate (23), a hinged shaft of the connecting rod (22) is axially parallel to a rotating shaft of the eccentric wheel (21), and the first driving piece is arranged on the fixed frame (1) and can enable the eccentric wheel (21) to rotate.

3. The sagger material vibrating device according to claim 2, wherein: the feeding mechanism (4) comprises a plurality of feeding rollers (41), idler wheels (42) and a second driving piece for driving the feeding rollers (41) to rotate, the feeding rollers (41) are arranged on the fixed frame (1) in parallel along the horizontal direction, the idler wheels (42) are uniformly sleeved on the feeding rollers (41) in a coaxial mode, and the second driving piece is arranged on the fixed frame (1) and can enable all the feeding rollers (41) to rotate synchronously.

4. The sagger material vibrating device according to claim 3, wherein: the second driving piece comprises a second servo motor (43), a transmission gear (44) and a toothed chain (45), an output shaft of the second servo motor (43) is coaxially connected with any one feeding roller (41), and can enable any one feeding roller (41) to rotate; the transmission gear (44) is coaxially fixed at the end part of the feeding roller (41), two rows of gear teeth are arranged on the transmission gear (44), and the gear chain (45) is sleeved on two adjacent transmission gears (44) and is meshed with the transmission gears (44).

5. The sagger material vibrating device according to claim 3, wherein: the lifting mechanism (3) comprises a lifting plate (31), two positioning pieces (33) and a lifting cylinder (32), the positioning pieces (33) are arranged between the sliding plate (23) and the feeding mechanism (4), one end of each lifting plate (31) is connected with the corresponding positioning piece (33), and the other end of each lifting plate (31) penetrates through the corresponding sliding plate (23) and is in sliding connection with the corresponding sliding plate (23); the lifting cylinder (32) is fixedly arranged at one end, penetrating out of the sliding plate (23), of the lifting plate (31), and a telescopic rod of the lifting cylinder (32) is pushed against the sliding plate (23).

6. The sagger material vibrating device according to claim 5, wherein: the positioning piece (33) comprises a pressing plate (331) and a plurality of supporting plates (332), and the pressing plate (331) is connected below the sliding plate (23) in a sliding mode through a connecting piece (35); the length direction of the supporting plate (332) is parallel to the feeding rollers (41), and the supporting plate is arranged between the two feeding rollers (41); one end of the supporting plate (332) is arranged at one end, close to the feeding roller (41), of the lifting plate (31), and the other end of the supporting plate is arranged close to the other lifting plate (31); the supporting plate (332) is arranged lower than the highest point of the roller (42) in the height direction.

7. The sagger material vibrating device according to claim 6, wherein: one end of the pressing plate (331) close to the feeding roller (41) is provided with a plurality of clamping blocks (333), the clamping blocks (333) are clamped on the inner wall of the sagger, and the sagger and the pressing plate (331) can be kept relatively static.

8. The sagger material vibrating device according to claim 3, wherein: be provided with stock stop (5) on fixed frame (1), stock stop (5) are including two sets of fender material spare of relative setting, keep off material spare including keeping off material cylinder (51) and keeping off material wheel (52), keep off material cylinder (51) and set up on fixed frame (1), keep off the piston rod axial of material cylinder (51) with feed roll (41) axial parallel, keep off material wheel (52) coaxial setting and be in keep off on the piston rod of material cylinder (51).

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