CN113731786A - Multifunctional planar rotary vibrating screen for raw material processing - Google Patents

Abstract

The invention provides a multifunctional planar rotary vibrating screen for raw material processing, which comprises a fixed outer frame, a feeding hopper, a transverse fixed plate, a positioning rod, a positioning pipe, a buffer spring, a transverse connecting plate, a dust hopper, a dust discharge pipe, a vibrating motor, a dust collecting frame, an adjustable vibrating frame structure, a temporary storage leading-out frame structure, a rear side guide pipe, a raw material conveying frame structure, a transverse rail, a longitudinal limiting frame, a proximity sensor, an intelligent conveying frame structure, fixed support legs, a controller, a power switch and a top pipe, wherein the feeding hopper is inserted at the left side of the upper part of the fixed outer frame; the transverse fixing plates are welded on the left side and the right side of the lower part of the inner wall of the fixed outer frame. The large-aperture screening hopper and the small-aperture screening hopper are respectively provided with two large-aperture screening hoppers and two small-aperture screening hoppers, and when the vibrating screen is used, the vibrating motor is used for driving the adjustable vibrating frame structure on the upper side of the transverse connecting plate to vibrate integrally, so that materials with different particle sizes are screened by the large-aperture screening hopper and the small-aperture screening hopper.

Description

Multifunctional planar rotary vibrating screen for raw material processing

Technical Field

The invention belongs to the technical field of grain processing machinery, and particularly relates to a multifunctional planar rotary vibrating screen for processing raw materials.

Background

The vibrating screen operates by utilizing reciprocating rotary type vibration generated by vibrator excitation. The upper rotary heavy hammer of the vibrator makes the screen surface generate plane rotary vibration, the lower rotary heavy hammer makes the screen surface generate conical surface rotary vibration, and the combined effect makes the screen surface generate re-rotary vibration. The vibration locus is a complex space curve. The curve is projected as a circle in the horizontal plane and as an ellipse in the vertical plane. The amplitude can be changed by adjusting the exciting force of the upper and lower rotary weights. And the curve shape of the motion trail of the screen surface can be changed and the motion trail of the materials on the screen surface can be changed by adjusting the space phase angle of the upper and lower heavy hammers.

But current plane rotary vibrating screen still has not had and sieves large granule and tiny particle, and the material thing gathers in the one side of transportation fill easily, and inconvenient transports the finished product and connect the hopper to remove the time problem that does not possess the function of keeping in to the material thing.

Therefore, the invention provides a multifunctional planar rotary vibrating screen for processing raw materials.

Disclosure of Invention

In order to solve the technical problems, the invention provides a multifunctional planar rotary vibrating screen for raw material processing, which aims to solve the problems that the existing planar rotary vibrating screen does not have the function of screening large particles and small particles, materials are easy to gather at one side of a conveying hopper, and the function of temporarily storing the materials is not convenient to transport finished products and move a receiving hopper. A multifunctional planar rotary vibrating screen for raw material processing comprises a fixed outer frame, a feeding hopper, a transverse fixing plate, a positioning rod, a positioning pipe, a buffer spring, a transverse connecting plate, a dust hopper, a dust discharge pipe, a vibrating motor, a dust collecting frame, an adjustable vibrating frame structure, a temporary storage and lead-out frame structure, a rear side guide pipe, a raw material conveying frame structure, a transverse rail, a longitudinal limiting frame, a proximity sensor, an intelligent conveying frame structure, fixed support legs, a controller, a power switch and a top pipe, wherein the feeding hopper is inserted in the left side of the upper portion of the fixed outer frame; the transverse fixing plates are welded on the left side and the right side of the lower part of the inner wall of the fixed outer frame; the positioning rods are welded on the front side and the rear side of the upper part of the transverse fixing plate; the positioning pipe is sleeved outside the positioning rod and welded on the front side and the rear side of the lower part of the transverse connecting plate; the buffer spring is sleeved outside the positioning rod and the positioning tube, and the upper side and the lower side of the buffer spring are in contact with the lower part of the transverse connecting plate and the upper part of the transverse fixing plate; the transverse connecting plate is arranged on the upper side of the transverse fixing plate; the dust hopper bolt is arranged at the upper part of the transverse connecting plate; the dust discharge pipe penetrates through the lower part of the transverse connecting plate and is communicated with the dust hopper; the vibration motor bolts are arranged on the left side and the right side of the middle lower part of the transverse connecting plate; the dust collecting frame is arranged in the middle of the bottom of the fixed outer frame; the adjustable vibration frame structure is arranged on the inner side of the fixed outer frame and is arranged on the upper part of the transverse connecting plate; the temporary storage leading-out frame structure is respectively arranged at the middle position of the left side of the fixed outer frame and the lower part of the left side of the fixed outer frame; the raw material conveying frame structure is arranged on the rear side of the feeding hopper; the transverse track is arranged at the lower part of the left side of the fixed outer frame; the longitudinal limiting frame bolts are arranged on the left side and the right side of the upper part of the transverse track; the proximity sensors are respectively installed on the upper part of the inner side of the longitudinal limiting frame through screws; the intelligent conveying frame structures are respectively arranged on the upper sides of the transverse rails; the fixed supporting legs are respectively welded at the four corners of the lower part of the fixed outer frame; the controller bolt is arranged at the left lower side in the fixed outer frame; the power switch is glued to the left lower side of the front part of the fixed outer frame; the adjustable vibration frame structure comprises a threaded rod, an installation pipe, a positioning ring, an adjusting nut, a large-aperture screening hopper, a small-aperture screening hopper and a material guide frame, wherein the threaded rod is welded at the four corners of the upper part of the transverse connecting plate; the mounting pipes are respectively sleeved on the outer sides of the threaded rods; the positioning ring is sleeved on the outer side of the threaded rod and is welded on the upper side and the lower side of the installation pipe; the adjusting nuts are in threaded connection with the outer side of the threaded rod and are respectively arranged on the upper side and the lower side of the mounting pipe; the large-aperture screen hopper is arranged on the upper side of the threaded rod and is welded with the mounting pipe; the small-aperture screen hopper is arranged on the lower side of the threaded rod and is welded on the inner side of the mounting pipe; the top pipe is welded at the four corners of the top of the fixed outer frame and is sleeved on the upper part of the threaded rod.

Preferably, the temporary storage leading-out frame structure comprises a leading-out hopper, a receiving hopper, a temporary storage box, a leading-out pipe and an electromagnetic valve, wherein the leading-out hopper is respectively arranged on the left lower side of the large-aperture screening hopper and the left lower side of the small-aperture screening hopper and is welded on the left side of the fixed outer frame; the delivery pipe is welded on the left side of the temporary storage box; the solenoid valve threaded connection in the left side of contact tube.

Preferably, the intelligent conveying frame structure comprises a conveying bucket, a wheel frame, a rail wheel, a rotating motor, a bottom storage frame, a guide plate, a jacking spring and a silica gel sealing gasket, wherein the wheel frame is welded at the four corners of the lower part of the conveying bucket; the rail wheel is connected to the lower part of the wheel frame and is placed on the upper side of the transverse rail; the bottom storage frame is embedded in the right side of the lower part of the transportation hopper; the guide plate is arranged at the lower part of the inner side of the conveying hopper, and the left end of the guide plate is coupled with the lower left part of the conveying hopper.

Preferably, the raw material conveying frame structure comprises a raw material box, a material lifting pipe, a material lifting motor, a rectangular lead-in frame, a rotating pipe, a spiral material lifting blade and a material discharging frame, wherein the raw material box is placed at the lower part of the rear side of the fixed outer frame; the material lifting pipe is inserted into the inner side of the raw material box; the lifting motor is arranged on the upper part of the raw material box through a bolt, and an output shaft is connected with the upper end of the rotary pipe through a bolt; the rectangular lead-in frames are welded on the left side and the right side of the lower part of the material lifting pipe; the rotating pipe is arranged on the inner side of the raw material box; the spiral lifting blade is arranged on the inner side of the material lifting pipe and is welded on the outer side of the rotating pipe; the discharging frame is inserted at the upper part of the front side of the material lifting pipe and is placed at the upper part of the material feeding hopper.

Preferably, the large-aperture sieve hopper and the small-aperture sieve hopper are respectively provided with two hoppers.

Preferably, one end of the jacking spring is mounted at the top of the inner side of the bottom storage frame through a bolt, and the other end of the jacking spring is mounted at the right side of the lower part of the guide plate through a bolt.

Preferably, the rotating motor is mounted on the lower part of the front side of the wheel frame through a bolt, and the front side of the output shaft rail wheel is connected through a bolt.

Preferably, the temporary storage box is welded on the left side of the export hopper.

Preferably, the spiral lifting material vanes are welded on the outer side of the rotating pipe.

Preferably, the receiving hopper is embedded in the lower part of the fixed outer frame and welded on the lower part of the guiding hopper.

Preferably, one end of the silica gel sealing gasket is connected to the right end of the guide plate and the other end of the silica gel sealing gasket is connected to the right upper part of the inner wall of the conveying hopper.

Preferably, the rear guide pipe is arranged in the middle of the left side of the fixed outer frame and is glued to the lower part of the delivery pipe.

Preferably, the transverse rails are provided with a plurality of transverse rails, and the rail wheels are respectively arranged on the front side and the rear side of the upper part of the transverse rails.

Preferably, the material guide frames are respectively installed on the right upper part of the large-aperture screen hopper and the right upper part of the small-aperture screen hopper through bolts.

Preferably, the controller adopts FX2N-48 series PLC, the proximity sensor adopts a sensor with the model of XQ12-2DN, the rotating electrical machine adopts a motor with the model of 68KTY, the material lifting motor adopts a Y2-1 motor, the vibrating electrical machine adopts a vibrating electrical machine with the model of CMV, the electromagnetic valve adopts a two-watt normally closed electromagnetic valve, the proximity sensor and a power switch are respectively and electrically connected with the input end of the controller, and the material lifting motor, the rotating electrical machine, the vibrating electrical machine and the electromagnetic valve are respectively and electrically connected with the output end of the controller.

Compared with the prior art, the invention has the beneficial effects that:

1. in the invention, two large-aperture screening hoppers and two small-aperture screening hoppers are respectively arranged, and when the vibrating screen is used, the vibrating motor is utilized to drive the adjustable vibrating frame structure on the upper side of the transverse connecting plate to integrally vibrate, so that materials with different particle sizes are screened by the large-aperture screening hoppers and the small-aperture screening hoppers.

2. According to the invention, one end of the jacking spring is arranged at the top of the inner side of the bottom storage frame through the bolt, the other end of the jacking spring is arranged at the right side of the lower part of the guide plate through the bolt, so that the function of guiding materials falling into the conveying hopper to the left side is facilitated when the conveying hopper is used, and the jacking spring can be extruded downwards when more particles of the materials exist, so that the normal storage of the materials is not influenced.

3. In the invention, the rotating motor bolt is arranged at the lower part of the front side of the wheel frame, and the front side of the output shaft rail wheel is connected by the bolt, so that the rotating motor is conveniently utilized to drive the rail wheel to move left and right on the transverse rail, thereby realizing the transportation of the transportation bucket.

4. In the invention, the temporary storage box is welded on the left side of the guiding-out hopper, and the electromagnetic valves on the corresponding conveying hoppers are controlled to be closed by the controller after the conveying hoppers are fully stored, so that materials are temporarily stored in the temporary storage box, and the waste caused by the scattering of the materials on the ground can be avoided.

5. In the invention, the spiral lifting blade is welded on the outer side of the rotating pipe, and the lifting motor drives the spiral lifting blade to rotate through the rotating pipe, so that the raw material guided into the lifting pipe from the rectangular guide-in frame is lifted upwards.

6. In the invention, the receiving hopper is embedded in the lower part of the fixed outer frame and is welded at the lower part of the guiding hopper, so that the collecting function of materials guided out from the left lower side of the large-aperture screen hopper or the small-aperture screen hopper is conveniently realized when the receiving hopper is used, and the materials are prevented from falling to the inner side of the fixed outer frame.

7. In the invention, one end of the silica gel sealing gasket is connected to the right end of the guide plate in a gluing mode, and the other end of the silica gel sealing gasket is connected to the right upper part of the inner wall of the conveying hopper in a gluing mode.

8. In the invention, the rear side guide pipe is arranged in the middle position of the left side of the fixed outer frame, and is glued at the lower part of the delivery pipe, so that the delivery hopper arranged at the upper side can be conveniently guided to the rear side in use, and large particles can be separated from small particles.

9. According to the invention, the plurality of transverse rails are arranged, and the rail wheels are respectively arranged at the front side and the rear side of the upper part of each transverse rail, so that the material receiving of large-particle materials and small-particle materials can be simultaneously realized when the material receiving device is used.

10. In the invention, the material guide frames are respectively installed on the right upper part of the large-aperture screen hopper and the right upper part of the small-aperture screen hopper through bolts, so that when in use, materials arranged on the large-aperture screen hopper at the upper side are conveniently guided to the large-aperture screen hopper arranged at the lower side, and materials arranged in the small-aperture screen hopper at the upper side are conveniently guided to the small-aperture screen hopper arranged at the lower side.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic structural view of an adjustable vibration mount structure of the present invention.

Fig. 3 is a schematic structural diagram of a temporary storage leading-out frame structure of the invention.

Fig. 4 is a schematic structural view of the material conveyance rack structure of the present invention.

Fig. 5 is a schematic structural diagram of the intelligent carriage structure of the present invention.

Fig. 6 is a schematic electrical wiring diagram of the present invention.

In the figure:

1. fixing the outer frame; 2. feeding into a hopper; 3. a transverse fixing plate; 4. positioning a rod; 5. a positioning tube; 6. a buffer spring; 7. a transverse connecting plate; 8. a dust hopper; 9. a dust discharge pipe; 10. a vibration motor; 11. a dust collection frame; 12. the structure of the vibration frame can be adjusted; 121. a threaded rod; 122. installing a pipe; 123. a positioning ring; 124. adjusting the nut; 125. a large-aperture screen hopper; 126. a small-aperture screen hopper; 127. a material guiding frame; 13. a temporary storage lead-out frame structure; 131. a leading-out hopper; 132. a receiving hopper; 133. a temporary storage box; 134. a delivery pipe; 135. an electromagnetic valve; 14. a back side guide pipe; 15. a raw material conveying frame structure; 151. a raw material tank; 152. a material lifting pipe; 153. a material lifting motor; 154. a rectangular import frame; 155. rotating the tube; 156. spirally lifting the material leaves; 157. discharging the material frame; 16. a transverse rail; 17. a longitudinal limiting frame; 18. a proximity sensor; 19. an intelligent carriage structure; 191. a transport hopper; 192. a wheel carrier; 193. a rail wheel; 194. a rotating electric machine; 195. a bottom storage frame; 196. a guide plate; 197. the spring is tightly propped; 198. a silica gel sealing gasket; 20. fixing the supporting legs; 21. a controller; 22. a power switch; 23. a top tube.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example (b):

as shown in figures 1 and 2

The invention provides a multifunctional planar rotary vibrating screen for raw material processing, which comprises a fixed outer frame 1, a feeding hopper 2, a transverse fixed plate 3, a positioning rod 4, a positioning pipe 5, a buffer spring 6, a transverse connecting plate 7, a dust hopper 8, a dust discharge pipe 9, a vibrating motor 10, a dust collecting frame 11, an adjustable vibrating frame structure 12, a temporary storage leading-out frame structure 13, a rear side guide pipe 14, a raw material conveying frame structure 15, a transverse rail 16, a longitudinal limiting frame 17, a proximity sensor 18, an intelligent conveying frame structure 19, fixed support legs 20, a controller 21, a power switch 22 and a top pipe 23, wherein the feeding hopper 2 is inserted in the left side of the upper part of the fixed outer frame 1; the transverse fixing plates 3 are welded at the left side and the right side of the lower part of the inner wall of the fixing outer frame 1; the positioning rods 4 are welded on the front side and the rear side of the upper part of the transverse fixing plate 3; the positioning pipe 5 is sleeved outside the positioning rod 4 and welded on the front side and the rear side of the lower part of the transverse connecting plate 7; the buffer spring 6 is sleeved outside the positioning rod 4 and the positioning tube 5, and the upper side and the lower side of the buffer spring are in contact with the lower part of the transverse connecting plate 7 and the upper part of the transverse fixing plate 3; the transverse connecting plate 7 is arranged on the upper side of the transverse fixing plate 3; the dust hopper 8 is mounted on the upper part of the transverse connecting plate 7 through bolts; the dust discharge pipe 9 penetrates through the lower part of the transverse connecting plate 7 and is communicated with the dust hopper 8; the vibration motor 10 is installed on the left side and the right side of the middle lower part of the transverse connecting plate 7 through bolts; the dust collecting frame 11 is arranged in the middle of the bottom of the fixed outer frame 1; the adjustable vibration frame structure 12 is arranged on the inner side of the fixed outer frame 1 and is arranged on the upper part of the transverse connecting plate 7; the temporary storage leading-out frame structure 13 is respectively arranged at the middle position of the left side of the fixed outer frame 1 and the lower part of the left side of the fixed outer frame 1; the raw material conveying frame structure 15 is arranged on the rear side of the feeding hopper 2; the transverse rail 16 is arranged at the lower part of the left side of the fixed outer frame 1; the longitudinal limiting frame 17 is mounted on the left side and the right side of the upper part of the transverse rail 16 through bolts; the proximity sensors 18 are respectively mounted on the upper part of the inner side of the longitudinal limiting frame 17 through screws; the intelligent conveying frame structures 19 are respectively arranged on the upper sides of the transverse rails 16; the fixed supporting legs 20 are respectively welded at the four lower corners of the fixed outer frame 1; the controller 21 is mounted at the left lower side of the inner part of the fixed outer frame 1 through bolts; the power switch 22 is glued on the left lower side of the front part of the fixed outer frame 1; the rear guide pipe 14 is arranged at the middle position of the left side of the fixed outer frame 1, and is glued at the lower part of the delivery pipe 134, so that the delivery hopper 131 arranged at the upper side can be conveniently guided to the rear side in use, so that large particles can be separated from small particles, a plurality of transverse rails 16 are arranged, the rail wheels 193 are respectively arranged at the front side and the rear side of the upper part of the transverse rails 16, and large particles and small particles can be simultaneously received in use; the adjustable vibration frame structure 12 comprises a threaded rod 121, a mounting pipe 122, a positioning ring 123, an adjusting nut 124, a large-aperture screen hopper 125, a small-aperture screen hopper 126 and a material guide frame 127, wherein the threaded rod 121 is welded at the four corners of the upper part of the transverse connecting plate 7; the mounting pipes 122 are respectively sleeved on the outer sides of the threaded rods 121; the positioning ring 123 is sleeved on the outer side of the threaded rod 121 and welded on the upper side and the lower side of the mounting pipe 122; the adjusting nuts 124 are in threaded connection with the outer side of the threaded rod 121 and are respectively arranged on the upper side and the lower side of the mounting tube 122; the large-aperture screen hopper 125 is arranged on the upper side of the threaded rod 121 and is welded with the mounting pipe 122; the small-aperture sieve hopper 126 is arranged on the lower side of the threaded rod 121 and is welded on the inner side of the mounting pipe 122; the top pipes 23 are welded at the four corners of the top of the fixed outer frame 1 and are sleeved on the upper part of the threaded rod 121; big aperture sieve hopper 125 and aperture sieve hopper 126 be provided with two respectively, utilize vibrating motor 10 to drive the whole vibration of adjustable vibration frame structure 12 of transverse connection board 7 upside when using to sieve the material thing of granule size difference with big aperture sieve hopper 125 and aperture sieve hopper 126, guide frame 127 respectively bolted mounting sieve the upper right portion of hopper 125 and the upper right portion of aperture sieve hopper 126 at big aperture sieve hopper 125, conveniently set up the upside and sieve the hopper 125 direction to the big aperture that the downside set up at big aperture sieve hopper 125 when using to and sieve the material thing of hopper 126 internal guide to setting up the aperture sieve hopper 126 internal guide at the downside at the small aperture of upside.

As shown in fig. 3, in the above embodiment, specifically, the temporary storage leading-out frame structure 13 includes a leading-out bucket 131, a receiving bucket 132, a temporary storage box 133, a leading-out pipe 134 and an electromagnetic valve 135, where the leading-out bucket 131 is respectively disposed at the left lower side of the large-aperture screening bucket 125 and the left lower side of the small-aperture screening bucket 126, and is welded at the left side of the fixed outer frame 1; the delivery pipe 134 is welded on the left side of the temporary storage box 133; the electromagnetic valve 135 is screwed on the left side of the delivery pipe 134; temporary storage box 133 weld in the left side of deriving fill 131, transport fill 191 store up the back and utilize the solenoid valve 135 on the corresponding transport fill 191 of controller 21 control to close to temporarily store the material thing in temporary storage box 133, and can avoid the material thing to scatter and fall subaerial and cause the waste, connect hopper 132 embedding in the lower part of fixed frame 1, the welding is in the lower part of deriving fill 131 simultaneously, conveniently plays the collection function to the material thing of deriving from large aperture sieve hopper 125 or the left downside of aperture sieve hopper 126 when using, thereby avoids the material thing to fall the inboard of fixed frame 1.

As shown in fig. 5, in the above embodiment, specifically, the intelligent transportation frame structure 19 includes a transportation bucket 191, a wheel frame 192, a track wheel 193, a rotating motor 194, a bottom storage frame 195, a guide plate 196, a tightening spring 197 and a silicone gasket 198, wherein the wheel frame 192 is welded at four lower corners of the transportation bucket 191; the track wheel 193 is coupled to the lower part of the wheel frame 192 and is placed on the upper side of the transverse track 16; the bottom storage frame 195 is embedded at the right side of the lower part of the transportation bucket 191; the guide plate 196 is arranged at the lower part of the inner side of the conveying bucket 191, and the left end of the guide plate is in shaft connection with the lower left part of the conveying bucket 191; one end of the jacking spring 197 is arranged at the top of the inner side of the bottom storage frame 195 by a bolt, the other end of the jacking spring 197 is arranged at the right side of the lower part of the guide plate 196 by a bolt, when in use, the material falling into the transportation hopper 191 is conveniently guided to the left, and when the material has more particles, the jacking spring 197 can be pressed downwards, so that the normal storage of the materials is not affected, the rotating motor 194 is mounted at the lower part of the front side of the wheel frame 192 through bolts, meanwhile, the front side of the output shaft track wheel 193 is connected through a bolt, so that the track wheel 193 is driven to move left and right on the transverse track 16 by the rotating motor 194 conveniently, thereby realizing the transportation of the transportation bucket 191, one end of the silica gel sealing pad 198 is glued to the right end of the guide plate 196, the other end is glued to the right upper part of the inner wall of the transportation bucket 191, in use, particles are prevented from falling from the gap between the guide plate 196 and the right side of the bucket 191 to the bottom of the bucket 191.

As shown in fig. 4, in the above embodiment, specifically, the raw material conveying frame structure 15 includes a raw material box 151, a material lifting pipe 152, a material lifting motor 153, a rectangular introducing frame 154, a rotating pipe 155, a spiral lifting blade 156 and a discharging frame 157, and the raw material box 151 is placed at the lower part of the rear side of the fixed outer frame 1; the material lifting pipe 152 is inserted into the inner side of the raw material box 151; the material lifting motor 153 is arranged at the upper part of the raw material box 151 through bolts, and an output shaft is connected with the upper end of the rotating pipe 155 through bolts; the rectangular lead-in frames 154 are welded at the left side and the right side of the lower part of the material lifting pipe 152; the rotary pipe 155 is arranged inside the raw material tank 151; the spiral lifting blade 156 is arranged on the inner side of the material lifting pipe 152 and is welded on the outer side of the rotating pipe 155; the discharging frame 157 is inserted at the upper part of the front side of the material lifting pipe 152 and is placed at the upper part of the material feeding hopper 2; the spiral lifting blade 156 is welded to the outer side of the rotary pipe 155, and the lifting motor 153 rotates the spiral lifting blade 156 through the rotary pipe 155, so that the raw material introduced into the lifting pipe 152 from the rectangular introduction frame 154 is lifted upward.

Principle of operation

In the working process of the invention, a power switch 22 is turned on, a controller 21 controls a material lifting motor 153 to drive a spiral material lifting blade 156 to rotate through a rotating pipe 155, so that materials in a raw material box 151 poured into the material lifting pipe 152 through a rectangular guide-in frame 154 are conveyed upwards, the materials enter a fixed outer frame 1 from a feeding hopper 2 through a discharging frame 157 and fall onto a large-aperture screen hopper 125, meanwhile, a vibration motor 10 drives a transverse connecting plate 7 and an adjustable vibration frame structure 12 to vibrate on a buffer spring 6 integrally so as to screen the raw materials, the large-aperture screen hopper 125 is used for separating large-particle raw materials, small-particle raw materials fall onto a small-aperture screen hopper 126, the small-aperture screen hopper 126 filters dust in the small-particle raw materials, the dust is guided into a dust collecting frame 11 from a dust discharge pipe 9 through a dust hopper 8 to be stored, and the large-particle raw materials and the small-particle raw materials are respectively guided into a storage box 133 through a guide-out hopper 131 and a receiving hopper 132, and discharged from the delivery pipe 134, the large granular raw material is discharged into the transport hopper 191 arranged at the rear side through the rear side guide pipe 14 for storage, and the small granular raw material is directly discharged into the transport hopper 191 arranged at the front side through the delivery pipe 134, the particles falling into the transport hopper 191 are guided to the left side through the guide plate 196 while avoiding the raw material from being gathered at one side, and the tightening spring 197 is pressed downwards into the bottom storage frame 195 when the amount of the granular material is large, so that the storage is not affected when in use, when the worker sees that the transport hopper 191 is full, the controller 21 controls the corresponding electromagnetic valve 135 to be closed, the temporary storage box 133 is used to temporarily store the particles, the controller 21 controls the rotating motor 194 to drive the rail wheel 193 to move in the transverse rail 16 so as to transport the finished raw material, and the proximity sensor 18 is used to sense the transport hopper 191 after being transported to the left end, the controller 21 is used for controlling the rotating motor 194 to stop rotating, so that finished particles can be discharged by a user conveniently, after the discharging is finished, the controller 21 is used for controlling the rotating motor 194 to drive the track wheel 193 to move from the transverse track 16 to the right side to the lower part of the delivery pipe 134 or the rear guide pipe 14 for receiving materials, and when the dust collecting frame 11 is not used, the dust collecting frame 11 is taken out of the fixed outer frame 1 for discharging.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.

Claims (10)

1. A multifunctional plane rotary vibrating screen for raw material processing is characterized by comprising a fixed outer frame (1), a feeding hopper (2), a transverse fixed plate (3), a positioning rod (4), a positioning pipe (5), a buffer spring (6), a transverse connecting plate (7), a dust hopper (8), a dust discharge pipe (9), a vibrating motor (10) and a dust collecting frame (11), an adjustable vibration frame structure (12), a temporary storage leading-out frame structure (13), a rear side guide pipe (14), a raw material conveying frame structure (15), a transverse track (16), a longitudinal limiting frame (17), a proximity sensor (18), an intelligent conveying frame structure (19), fixed supporting legs (20), a controller (21), a power switch (22) and a top pipe (23), the feeding hopper (2) is inserted at the left side of the upper part of the fixed outer frame (1); the transverse fixing plates (3) are welded at the left side and the right side of the lower part of the inner wall of the fixing outer frame (1); the positioning rods (4) are welded on the front side and the rear side of the upper part of the transverse fixing plate (3); the positioning pipe (5) is sleeved outside the positioning rod (4) and welded on the front side and the rear side of the lower part of the transverse connecting plate (7) at the same time; the buffer spring (6) is sleeved outside the positioning rod (4) and the positioning pipe (5), and the upper side and the lower side of the buffer spring are in contact with the lower part of the transverse connecting plate (7) and the upper part of the transverse fixing plate (3); the transverse connecting plate (7) is arranged on the upper side of the transverse fixing plate (3); the dust hopper (8) is arranged at the upper part of the transverse connecting plate (7) by bolts; the dust discharge pipe (9) penetrates through the lower part of the transverse connecting plate (7) and is communicated with the dust hopper (8) at the same time; the vibration motor (10) is arranged on the left side and the right side of the middle lower part of the transverse connecting plate (7) through bolts; the dust collecting frame (11) is arranged in the middle of the bottom of the fixed outer frame (1); the adjustable vibration frame structure (12) is arranged on the inner side of the fixed outer frame (1) and is arranged on the upper part of the transverse connecting plate (7) at the same time; the temporary storage leading-out frame structure (13) is respectively arranged at the middle position of the left side of the fixed outer frame (1) and the lower part of the left side of the fixed outer frame (1); the raw material conveying frame structure (15) is arranged on the rear side of the feeding hopper (2); the transverse track (16) is arranged at the lower part of the left side of the fixed outer frame (1); the longitudinal limiting frame (17) is arranged on the left side and the right side of the upper part of the transverse track (16) through bolts; the proximity sensors (18) are respectively mounted on the upper part of the inner side of the longitudinal limiting frame (17) through screws; the intelligent conveying frame structures (19) are respectively placed on the upper sides of the transverse rails (16); the fixed supporting legs (20) are respectively welded at the four corners of the lower part of the fixed outer frame (1); the controller (21) is arranged at the left lower side inside the fixed outer frame (1) through bolts; the power switch (22) is glued to the left lower side of the front part of the fixed outer frame (1); the adjustable vibration frame structure (12) comprises a threaded rod (121), a mounting pipe (122), a positioning ring (123), an adjusting nut (124), a large-aperture screening hopper (125), a small-aperture screening hopper (126) and a material guide frame (127), wherein the threaded rod (121) is welded at the four corners of the upper part of the transverse connecting plate (7); the mounting pipes (122) are respectively sleeved on the outer sides of the threaded rods (121); the positioning ring (123) is sleeved on the outer side of the threaded rod (121) and welded on the upper side and the lower side of the mounting pipe (122) at the same time; the adjusting nut (124) is in threaded connection with the outer side of the threaded rod (121) and is arranged on the upper side and the lower side of the mounting pipe (122) respectively; the large-aperture screen hopper (125) is arranged on the upper side of the threaded rod (121) and is welded with the mounting pipe (122) at the same time; the small-aperture sieve hopper (126) is arranged on the lower side of the threaded rod (121) and is welded on the inner side of the mounting pipe (122); the top pipe (23) is welded at the four corners of the top of the fixed outer frame (1) and is sleeved on the upper part of the threaded rod (121).

2. The multifunctional raw material processing plane rotary vibration sieve as claimed in claim 1, wherein said temporary storage lead-out frame structure (13) comprises a lead-out hopper (131), a receiving hopper (132), a temporary storage box (133), a lead-out pipe (134) and an electromagnetic valve (135), said lead-out hopper (131) is respectively arranged at the left lower side of the large-aperture sieve hopper (125) and the left lower side of the small-aperture sieve hopper (126), and is welded at the left side of the fixed outer frame (1); the delivery pipe (134) is welded on the left side of the temporary storage box (133); the electromagnetic valve (135) is in threaded connection with the left side of the delivery pipe (134).

3. The multifunctional flat rotary vibrating screen for processing raw materials as claimed in claim 1, wherein the intelligent conveying frame structure (19) comprises a conveying hopper (191), a wheel frame (192), a track wheel (193), a rotating motor (194), a bottom storage frame (195), a guide plate (196), a jacking spring (197) and a silica gel sealing gasket (198), wherein the wheel frame (192) is welded at four lower corners of the conveying hopper (191); the track wheel (193) is coupled to the lower part of the wheel frame (192) and is placed on the upper side of the transverse track (16); the bottom storage frame (195) is embedded at the right side of the lower part of the transportation hopper (191); the guide plate (196) is arranged at the lower part of the inner side of the conveying hopper (191), and the left end of the guide plate is in shaft connection with the lower left part of the conveying hopper (191).

4. The multifunctional flat rotary vibration screen for processing raw materials as claimed in claim 1, wherein said raw material transporting frame structure (15) comprises a raw material box (151), a lifting pipe (152), a lifting motor (153), a rectangular lead-in frame (154), a rotary pipe (155), a spiral lifting blade (156) and a discharge frame (157), said raw material box (151) is placed at the lower part of the rear side of the fixed outer frame (1); the material lifting pipe (152) is inserted into the inner side of the raw material box (151); the lifting motor (153) is arranged on the upper part of the raw material box (151) through bolts, and an output shaft is connected with the upper end of the rotating pipe (155) through bolts; the rectangular lead-in frames (154) are welded at the left side and the right side of the lower part of the material lifting pipe (152); the rotating pipe (155) is arranged on the inner side of the raw material box (151); the spiral lifting blade (156) is arranged on the inner side of the material lifting pipe (152) and is welded on the outer side of the rotating pipe (155); the discharging frame (157) is inserted at the upper part of the front side of the material lifting pipe (152) and is placed at the upper part of the material feeding hopper (2).

5. The multi-functional flat rotary vibration sieve for processing raw material as claimed in claim 3, wherein said urging spring (197) is bolted at one end to the top of the inner side of the bottom storage frame (195) and at the other end to the right of the lower part of the guide plate (196).

6. The multifunctional flat rotary vibration screen for processing raw material as claimed in claim 3, wherein the rotary motor (194) is bolted to the lower portion of the front side of the wheel frame (192), and the rail wheel (193) of the output shaft is bolted to the front side.

7. The multifunctional flat rotary vibration sieve for processing raw material as claimed in claim 2, wherein said receiving hopper (132) is embedded in the lower part of the fixed frame (1) and welded to the lower part of the discharging hopper (131).

8. The multifunctional flat rotary vibrating screen for processing raw materials as claimed in claim 3, wherein one end of the silica gel sealing pad (198) is glued to the right end of the guide plate (196) and the other end is glued to the upper right portion of the inner wall of the transport hopper (191).

9. The multifunctional flat rotary vibration sieve for processing raw materials as claimed in claim 1, wherein said rear guide pipe (14) is installed at the middle position of the left side of the fixed outer frame (1) and is glued to the lower part of the guide pipe (134).

10. The multifunctional flat rotary vibration sieve for processing raw material as claimed in claim 3, wherein said transverse rail (16) is provided in plurality, and said rail wheels (193) are respectively provided on the front and rear sides of the upper portion of the transverse rail (16).

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