CN113828385B - Vertical tooth rotary crusher - Google Patents

Abstract

The invention relates to the field of crushers, in particular to a vertical tooth rotating-back crusher. The technical problem of the invention is as follows: the environment around the crusher is seriously polluted by dust due to a large amount of dust in the crushing process, so that a large amount of stone materials needing secondary crushing and reworking can be generated in the crushing process, and the processing cost is increased. The technical implementation scheme of the invention is as follows: a vertical tooth rotary crusher comprises a fixed mounting table, a rotary crusher, a stuck stone cleaning system, a tooth deformation damage detection system and a dustproof flow guide system; the middle part of the fixed mounting table top is provided with a rotary crusher for crushing stones. The invention realizes the rapid lead-out of dust generated in the crushing process, avoids the dust from polluting the environment, realizes the automatic detection of the inner side teeth of the crusher, detects whether the teeth are damaged or not, is convenient for timely maintaining the teeth and ensures that the particle size of crushed stone materials meets the industrial requirements.

Description

Vertical tooth rotary crusher

Technical Field

The invention relates to the field of crushers, in particular to a vertical tooth rotating-back crusher.

Background

In the prior art, when a gyratory crusher carries out crushing work, the phenomenon that crushed dust moves upwards along the inner wall of the crusher and flows out of an opening at the top of the crusher can occur, so that the surrounding environment of the crusher is seriously polluted by dust, and the body health of workers is also seriously influenced; after the breaker long time work, partial deformation and wearing and tearing can appear in its inside tooth, lead to its crushing effect variation, make in the building stones of broken gained, the building stones composition that the particle diameter can't satisfy the requirement becomes many, can't satisfy the industrial requirement, need the secondary crushing, but the manual work is difficult to carry out high efficiency and accurate detection to the inboard tooth of breaker, lead to the inside tooth of breaker to take place to wear out and warp the back and can't in time be discover, make the building stones that a large amount of needs secondary crushing reworks can appear in the crushing work, and the processing cost is increased.

In view of the above problems, we propose a vertical tooth gyratory crusher.

Disclosure of Invention

In order to overcome the defects that the surrounding environment of the crusher is seriously polluted by dust due to a large amount of dust in the crushing process, but the teeth on the inner side of the crusher are difficult to detect efficiently and accurately by manpower, so that the teeth in the crusher cannot be found in time after being worn and deformed, a large amount of stones needing secondary crushing and reworking can be generated in the crushing process, and the processing cost is increased, the invention has the technical problems that: a vertical tooth gyratory crusher is provided.

The technical implementation scheme of the invention is as follows: a vertical tooth rotary crusher comprises a fixed mounting table, a rotary crusher, a tooth deformation damage detection system and a dustproof flow guide system; a rotary crusher for crushing stone is arranged in the middle of the top of the fixed mounting table; a tooth deformation damage detection system for detecting the damage of the teeth in the gyratory crusher is arranged at the left upper part of the gyratory crusher; four dustproof flow guide systems for guiding and separating raised dust in the crushing process are equidistantly arranged on an outer ring at the top of the gyratory crusher; the bottom parts of the four dustproof flow guide systems are connected with a fixed mounting table.

Furthermore, the gyratory crusher comprises a conical crushing cabin, a bearing sleeve, a first rotating shaft rod, a first bearing seat, a first transmission wheel, a first power motor, a second bearing seat, a second transmission wheel, a bevel gear, a conical fluted disc, a main shaft, a supporting plate, a blanking supporting inclined plate, an eccentric sleeve disc, a crushing movable tooth cone, a suspension bearing seat, a positioning ring, a first supporting beam and a second supporting beam; a conical crushing cabin is arranged in the middle of the top of the fixed mounting table; a bearing sleeve is arranged at the right lower part of the conical crushing cabin; the inner side of the bearing sleeve is rotationally connected with a first rotating shaft rod; two first bearing seats are arranged on the right side of the upper part of the fixed mounting table; the two first bearing seats are rotationally connected with the first rotating shaft rod; a first transmission wheel is fixedly sleeved at the right part of the outer surface of the first rotating shaft rod; a first power motor is fixedly connected to the rear side of the top of the fixed mounting table; a second bearing seat is fixedly connected to the rear side of the top of the fixed mounting table; the second bearing block is rotationally connected with an output shaft of the first power motor; a second driving wheel is fixedly connected with an output shaft of the first power motor; the outer ring surface of the second driving wheel is connected with the first driving wheel through a belt in a driving way; a bevel gear is fixedly connected to the left part of the outer surface of the first rotating shaft rod; a supporting plate is fixedly connected to the right bottom of the inner wall of the conical crushing cabin; the supporting plate is rotationally connected with a main shaft; a conical fluted disc is fixedly connected to the middle part of the outer surface of the main shaft; the bevel gear disc is meshed with the bevel gear; a blanking support inclined plate is fixedly connected to the right lower part of the inner wall of the conical crushing cabin; the left lower part of the blanking support inclined plate is fixedly connected with a support plate; the top of the main shaft is fixedly connected with an eccentric sleeve disc; the top of the eccentric sleeve disc is fixedly connected with a crushing movable tooth cone; the left side of the top of the conical crushing cabin and the right side of the top of the conical crushing cabin are fixedly connected with a first supporting beam and a second supporting beam respectively; a suspension bearing seat is fixedly connected between the first supporting beam and the second supporting beam; the lower part of the suspension bearing seat is rotatably connected with a crushing movable tooth cone; the outer ring of the top of the crushing movable tooth cone is fixedly connected with a positioning ring, and the crushing movable tooth cone and the positioning ring are coaxially distributed; the bottom of the first supporting beam is connected with a tooth deformation damage detection system; four dustproof flow guide systems are arranged on the outer ring of the top of the conical crushing cabin at equal intervals.

Furthermore, a bending part is arranged on the left side of the blanking support inclined plate.

Furthermore, the inner wall of the conical crushing cabin and the outer surface of the crushing movable tooth cone are both provided with pyramid teeth, and the pyramid teeth on the inner wall of the conical crushing cabin and the pyramid teeth on the outer surface of the crushing movable tooth cone are distributed in a staggered mode.

Furthermore, the vibration cleaning rod is made of elastic metal materials.

Further, the tooth deformation damage detection system comprises a motor seat plate, a second power motor, a first linkage rod, a shaft connecting seat, a second linkage rod, a mounting plate, a first reset spring, a mounting block, a mounting bar, a detection touch bar, a rotating sleeve seat and a first mounting shaft seat; a motor seat plate is fixedly connected to the left part of the lower side of the first supporting beam; a second power motor is arranged at the rear side of the motor seat plate; a first linkage rod is fixedly connected with an output shaft of the second power motor; the right side of the first linkage rod is rotatably connected with a shaft connecting seat; the lower part of the connecting shaft seat is rotationally connected with a second linkage rod; the left side of the second linkage rod is rotatably connected with a mounting plate; two first reset springs are arranged at the bottom of the mounting plate; the bottoms of the two first return springs are connected with the mounting blocks; the right side of the mounting block is fixedly connected with a mounting bar; a plurality of detection contact bars are arranged on the lower part of the mounting bar rod at equal intervals; a first mounting shaft seat is fixedly connected to the right part of the lower side of the first supporting beam; the lower part of the first mounting shaft seat is rotatably connected with a rotating sleeve seat; the left side of the rotating sleeve seat is fixedly connected with an installation bar.

Furthermore, the dustproof diversion system comprises a motor base, a third power motor, a third transmission wheel, a fourth transmission wheel, a second rotating shaft rod, a connecting rotating seat plate, a connecting seat, an arc-shaped diversion cover, a buffering protection assembly and a dustproof diversion assembly; a motor base is fixedly connected to the right front side of the top of the fixed mounting table; the top of the motor base is fixedly connected with a third power motor; a third driving wheel is fixedly connected with an output shaft of the third power motor; the upper part of the right front side of the outer wall of the conical crushing cabin is fixedly connected with a connecting rotating seat plate; the connecting rotating seat plate is rotatably connected with a second rotating shaft rod; a fourth driving wheel is fixedly sleeved on the rear side of the outer surface of the second rotating shaft rod; the outer ring surface of the fourth driving wheel is connected with a third driving wheel through belt transmission; the second rotating shaft rod is fixedly connected with a connecting seat; the upper part of the left side of the connecting seat is fixedly connected with an arc-shaped air guide sleeve; the arc-shaped air guide sleeve is provided with a buffer protection component; two dustproof flow guide assemblies are mounted on the arc-shaped flow guide cover.

Furthermore, the buffering protection assembly comprises a second reset spring, an arc-shaped vibration plate, a protection screen plate, an electric push rod and an intercepting flexible strip; a plurality of second return springs are equidistantly arranged at the inner top of the arc-shaped air guide sleeve; the bottom of each second return spring is connected with the arc-shaped vibrating plate; two protection screen plates are arranged on the arc-shaped vibrating plate; two electric push rods are arranged on the arc-shaped vibrating plate; the telescopic ends of the two electric push rods are connected with the arc-shaped vibrating plate; the lower part of the inner wall of the arc-shaped air guide sleeve is connected with an intercepting flexible strip; the inner side of the interception flexible strip is contacted with the arc-shaped vibration plate.

Furthermore, the dustproof flow guide assembly comprises a rectangular flow guide cylinder, a limiting sliding seat, a connecting sliding rod, an installation batten, a vibration inserted rod, an inclined sliding rail seat, a sliding limiting seat, a limiting rod, a swinging plate, a first hook plate, a torsion spring, a second installation shaft seat, a second hook plate, a balancing weight and a third reset spring; a rectangular guide cylinder is fixedly inserted on the arc-shaped guide cover; openings of the arc-shaped air guide sleeve, which are close to one side of the arc-shaped vibration plate, are respectively opposite to the protection screen plate; a limiting sliding seat is fixedly connected to the middle part of the inner bottom of the rectangular guide cylinder; the inner side of the limiting sliding seat is connected with a connecting sliding rod in a sliding manner; one end of the connecting slide rod close to the arc-shaped vibrating plate is fixedly connected with an installation batten; the connecting sliding rod penetrates through the inner side of the third return spring; two ends of the third return spring are respectively connected with the limiting sliding seat and the installation ribbon board; a plurality of vibration insertion rods are arranged on one side, close to the arc-shaped vibration plate, of the mounting strip plate at equal intervals; two inclined slide rail seats are arranged on the bottom wall of the rectangular guide cylinder; the upper parts of the two inclined slide rail seats are respectively connected with a sliding limiting seat in a sliding way; two second mounting shaft seats are arranged on the inner bottom wall of the rectangular guide cylinder; the upper parts of the two second mounting shaft seats are respectively connected with a swinging plate in a rotating way; one side of the upper parts of the two swing plates, which is close to the sliding limiting seat, is respectively provided with a limiting rod; the lower parts of the two swinging plates close to one side of the mounting strip plate are respectively fixedly connected with a first hook plate; the upper part of each second mounting shaft seat is sleeved with two torsion springs; each swinging plate is connected with the free ends of the two torsion springs; one side of the mounting strip plate close to the limiting sliding seat is provided with two second hook plates; the two second hook plates are respectively matched with the two first hook plates; one side of the mounting strip plate close to the limiting sliding seat is provided with two balancing weights.

Furthermore, the stone clamping cleaning system is further included, the bottom of the second supporting beam is connected with the stone clamping cleaning system, and the stone clamping cleaning system comprises an electric sliding rail, an electric sliding seat, a mounting seat, an electric rotating shaft seat, a supporting rotating frame, a movable sleeve seat, a universal ball and a vibration cleaning rod; the bottom of the first supporting beam is fixedly connected with an electric sliding rail; the lower part of the electric sliding rail is connected with an electric sliding seat in a sliding way; the bottom of the electric sliding seat is fixedly connected with a mounting seat; the mounting seat is provided with an electric rotating shaft seat; the rotating end of the electric rotating shaft seat is fixedly connected with a supporting rotating frame; the top in the mounting seat is provided with a movable sleeve seat; the lower part of the movable sleeve seat is connected with a universal ball in a sliding way; the right side of the universal ball is fixedly connected with a vibration cleaning rod; the left side of the lower part of the vibrating cleaning rod contacts and supports the rotating frame.

The invention has the beneficial effects that: the problem that the processing cost is increased because a large amount of stone materials needing secondary crushing and reworking can be generated in the crushing work because the teeth inside the crusher cannot be found in time after being worn and deformed due to the fact that the teeth inside the crusher are difficult to detect efficiently and accurately due to the fact that the surrounding environment of the crusher is seriously polluted by dust generated in the crushing process is solved;

the invention designs the gyratory crusher, and the crushing effect is enhanced by matching the conical teeth which are staggered with each other with the teeth on the inner wall;

the invention designs a stone clamping cleaning system which can automatically clean stones clamped in the inner side teeth of the crusher;

the invention designs a tooth deformation damage detection system, after the crusher finishes working, the automatic detection of the inner side teeth of the crusher is realized, and whether the teeth are damaged or not is detected, so that the teeth can be maintained in time, and the particle size of crushed stone materials is ensured to meet the industrial requirements;

the invention designs the dustproof flow guide system, which can quickly guide out dust generated in the crushing process, thereby preventing the dust from polluting the environment and influencing the human health.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a perspective view of a second wheel according to the present invention;

FIG. 3 is a first partially cut-away perspective view of the gyratory crusher of the present invention;

FIG. 4 is a second partially cut-away perspective view of the gyratory crusher of the present invention;

FIG. 5 is a schematic perspective view of a stuck stone cleaning system according to the present invention;

FIG. 6 is a schematic partial perspective view of a stuck stone cleaning system of the present invention;

FIG. 7 is a schematic perspective view of a tooth deformation damage detection system of the present invention;

FIG. 8 is a schematic view of the dust-proof diversion system of the present invention;

FIG. 9 is a schematic view of a first partial perspective view of the dust diversion system of the present invention;

FIG. 10 is a schematic perspective view of a second partial structure of the dustproof diversion system of the present invention;

fig. 11 is a schematic perspective view of a third partial structure of the dustproof diversion system of the present invention;

fig. 12 is an enlarged view of region a of the present invention.

The meaning of the reference symbols in the figures: 1-a fixed mounting table, 2-a gyratory crusher, 3-a stone-clamping cleaning system, 4-a tooth deformation damage detection system, 5-a dustproof diversion system, 201-a conical crushing cabin, 202-a bearing sleeve, 203-a first rotating shaft rod, 204-a first bearing seat, 205-a first transmission wheel, 206-a first power motor, 207-a second bearing seat, 208-a second transmission wheel, 209-a bevel gear, 2010-a conical fluted disc, 2011-a main shaft, 2012-a support plate, 2013-a blanking support inclined plate, 2014-an eccentric sleeve disc, 2015-a crushing movable tooth cone, 2016-a suspension bearing seat, 2017-a positioning ring, 2018-a first support beam, 2019-a second support beam, 301-an electric sliding rail, 302-an electric sliding seat, 303-a mounting seat, 304-an electric rotating shaft seat, 305-a supporting rotating frame, 306-a movable sleeve seat, 307-a universal ball, 308-a vibration cleaning rod, 401-a motor seat plate, 402-a second power motor, 403-a first linkage rod, 404-a connecting shaft seat, 405-a second linkage rod, 406-a mounting plate, 407-a first return spring, 408-a mounting block, 409-a mounting bar, 4010-a detection touch strip, 4011-a rotating sleeve seat, 4012-a first mounting shaft seat, 501-a motor base, 502-a third power motor, 503-a third transmission wheel, 504-a fourth transmission wheel, 505-a second rotating shaft rod, 506-a connecting rotating seat plate, 507-a connecting seat, 508-an arc-shaped guide cover, 509-a rectangular guide cylinder and 5010-a second return spring, 5011-arc vibrating plate, 5012-guard net plate, 5013-limit slide carriage, 5014-connecting slide bar, 5015-mounting strip plate, 5016-vibrating inserted bar, 5017-inclined slide rail seat, 5018-slide limit seat, 5019-limit bar, 5020-swinging plate, 5021-first hook plate, 5022-torsion spring, 5023-second mounting shaft seat, 5024-second hook plate, 5025-balancing weight, 5026-third return spring, 5027-electric push rod and 5028-intercepting flexible strip.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings.

Example 1

According to the drawings of fig. 1-2, a vertical tooth gyratory crusher comprises a fixed mounting table 1, a gyratory crusher 2, a stuck stone cleaning system 3, a tooth deformation damage detection system 4 and a dustproof flow guide system 5; a rotary crusher 2 is arranged in the middle of the top of the fixed mounting table 1; a stuck stone cleaning system 3 is arranged at the upper right part of the gyratory crusher 2; a tooth deformation damage detection system 4 is arranged at the left upper part of the gyratory crusher 2; four dustproof flow guide systems 5 are equidistantly arranged on the outer ring at the top of the gyratory crusher 2; the bottom parts of the four dustproof diversion systems 5 are connected with the fixed mounting table 1.

When in use, the vertical tooth gyratory crusher 2 is firstly fixed to a specified installation position, namely, the vertical tooth gyratory crusher is fixed through the fixed installation platform 1, the external dust suction pipeline is respectively connected to the four dustproof flow guide systems 5, then the power supply is switched on, the equipment starts to operate, the four dustproof flow guide systems 5 are controlled to be opened outwards, then enough stone is added into the gyratory crusher 2, namely, the gyratory crusher 2 crushes the stone, after the crushing starts, the four dustproof flow guide systems 5 are controlled to rotate upwards and surround the top of the gyratory crusher 2, the dust floating from the top of the gyratory crusher 2 in the crushing process is collected and conveyed out of the gyratory crusher 2, and the crushed stone is continuously discharged from the left opening at the bottom of the gyratory crusher 2, the continuous play of passageway from fixed mounting platform 1 left part, accomplish the breakage, treat after crushing work accomplishes, after the gyratory crusher 2 inside does not have the building stones promptly, the stone that blocks is gone into on the tooth of steerable card stone cleaning system 3 inside the gyratory crusher 2 the stone of card cleans, then control tooth deformation damage detecting system 4 detects the most advanced of the inside tooth of gyratory crusher 2 again, whether the most advanced of detection tooth is intact, whether warp, the quick derivation of the dust that appears in the fragmentation process has been realized, avoid the dust pollution environment, influence the health, and after the breaker work is accomplished, realize the automated inspection to the inside tooth of crusher, detect whether there is the damage in the tooth, in time maintain the tooth, guarantee that the particle diameter that the broken building stones obtained accords with the industrial requirement.

Example 2

Based on embodiment 1, according to fig. 1 and fig. 3 to 4, the gyratory crusher 2 includes a cone-shaped crushing bin 201, a bearing sleeve 202, a first rotating shaft rod 203, a first bearing seat 204, a first driving pulley 205, a first motor 206, a second bearing seat 207, a second driving pulley 208, a bevel gear 209, a bevel gear disc 2010, a main shaft 2011, a support plate 2012, a blanking support tilt plate 2013, an eccentric sleeve 2014, a crushing moving gear cone 2015, a suspension bearing seat 2016, a positioning ring 2017, a first support beam 2018 and a second support beam 2019; the middle of the top of the fixed mounting platform 1 is provided with a conical crushing cabin 201; a bearing sleeve 202 is arranged at the right lower part of the conical crushing cabin 201; a first rotating shaft rod 203 is rotatably connected to the inner side of the bearing sleeve 202; two first bearing seats 204 are arranged on the right side of the upper part of the fixed mounting table 1; the two first bearing seats 204 are rotatably connected with the first rotating shaft rod 203; a first driving wheel 205 is fixedly sleeved at the right part of the outer surface of the first rotating shaft rod 203; a first power motor 206 is connected to the rear side of the top of the fixed mounting table 1 through a bolt; a second bearing seat 207 is connected to the rear side of the top of the fixed mounting table 1 through a bolt; the second bearing block 207 is rotatably connected with an output shaft of the first power motor 206; a second driving wheel 208 is fixedly connected with an output shaft of the first power motor 206; the outer ring surface of the second transmission wheel 208 is connected with the first transmission wheel 205 through belt transmission; a bevel gear 209 is fixedly connected to the left part of the outer surface of the first rotating shaft rod 203; a support plate 2012 is welded at the right bottom of the inner wall of the conical crushing cabin 201; the support plate 2012 is rotatably connected with a main shaft 2011; a bevel gear disc 2010 is fixedly connected to the middle of the outer surface of the main shaft 2011; bevel gear disc 2010 is meshed with bevel gear 209; a blanking supporting inclined plate 2013 is welded at the right lower part of the inner wall of the conical crushing cabin 201; a supporting plate 2012 is welded at the lower left part of the blanking supporting sloping plate 2013; an eccentric sleeve disc 2014 is welded at the top of the main shaft 2011; a crushing movable tooth cone 2015 is fixedly connected to the top of the eccentric sleeve disc 2014; a first supporting beam 2018 and a second supporting beam 2019 are fixedly connected to the left side of the top and the right side of the top of the conical crushing cabin 201 respectively; a suspension bearing seat 2016 is fixedly connected between the first supporting beam 2018 and the second supporting beam 2019; the lower part of the suspension bearing seat 2016 is rotatably connected with a crushing movable tooth cone 2015; a positioning ring 2017 is fixedly connected to the outer ring of the top of the crushing movable tooth cone 2015, and the crushing movable tooth cone 2015 and the positioning ring 2017 are coaxially distributed; the bottom of the first supporting beam 2018 is connected with a tooth deformation damage detection system 4; the bottom of the second supporting beam 2019 is connected with a stone clamping cleaning system 3; four dustproof diversion systems 5 are equidistantly arranged on the outer ring at the top of the conical crushing cabin 201.

Firstly, stone is added into a conical crushing cabin 201, then a power supply of a first power motor 206 is controlled to be switched on, the first power motor 206 drives a second driving wheel 208 to rotate, then the second driving wheel 208 drives a first driving wheel 205 to rotate, the first driving wheel 205 drives a first rotating shaft rod 203 to rotate, then the first rotating shaft rod 203 drives a bevel gear 209 to rotate, the bevel gear 209 drives a bevel gear disc 2010 to rotate, the bevel gear disc 2010 drives a main shaft 2011 to rotate, the main shaft 2011 drives a crushing movable cone 2015 to eccentrically rotate through an eccentric sleeve 2014, the crushing movable cone 2015 rotates below a suspension bearing seat 2016, the crushing movable cone 2015 drives a positioning ring 2017 to synchronously rotate, and then the stone falling into the conical crushing cabin 201 is subjected to crushing effect under the rotating extrusion of the crushing movable cone 2015 and the inner wall of the conical crushing cabin 201, so that the stone is subjected to high-efficiency crushing.

A bending part is arranged on the left side of the blanking support sloping plate 2013.

So that a space is formed between the bent part on the left side of the blanking supporting inclined plate 2013 and the inner wall of the conical crushing cabin 201 for discharging crushed stone in the conical crushing cabin 201.

The inner wall of the conical crushing cabin 201 and the outer surface of the crushing movable cone 2015 are both provided with pyramid teeth, and the pyramid teeth on the inner wall of the conical crushing cabin 201 and the pyramid teeth on the outer surface of the crushing movable cone 2015 are distributed in a staggered manner.

Make the breakage move the awl 2015 at the rotation in-process, the broken awl tooth that moves the awl 2015 surface can form two side spacing extrudees to the building stones with the awl tooth of the broken cabin 201 inner wall of toper, and the pyramid tooth can disect insertion to the inside of part building stones simultaneously, reinforcing crushing effect.

Example 3

On the basis of embodiment 2, according to fig. 1 and fig. 5-6, the stuck stone cleaning system 3 comprises an electric slide rail 301, an electric slide base 302, a mounting base 303, an electric rotating shaft base 304, a supporting rotating frame 305, a movable sleeve base 306, a universal ball 307 and a vibration cleaning rod 308; the bottom of the first supporting beam 2018 is connected with an electric slide rail 301 through a bolt; the lower part of the electric slide rail 301 is connected with an electric slide base 302 in a sliding way; the bottom of the electric sliding seat 302 is connected with a mounting seat 303 through a bolt; the mounting seat 303 is provided with an electric rotating shaft seat 304; a support rotating frame 305 is fixedly connected to the rotating end of the electric rotating shaft base 304; a movable sleeve seat 306 is arranged at the top in the mounting seat 303; the lower part of the movable sleeve seat 306 is connected with a universal ball 307 in a sliding way; a vibration cleaning rod 308 is fixedly connected to the right side of the universal ball 307; the lower left side of the vibration cleaning bar 308 supports the rotating frame 305 in contact.

After the crushing work is completed, that is, after no stone exists in the conical crushing cabin 201, at this time, the crushing movable tooth awl 2015 continuously rotates, then the electric rotating shaft seat 304 is controlled to drive the supporting rotating frame 305 to rotate downwards, after the supporting rotating frame 305 rotates downwards, the vibrating cleaning rod 308 and the self gravity, the vibrating cleaning rod 308 can slide and rotate in the movable sleeve seat 306 through the universal ball 307, and then the vibrating cleaning rod 308 can rotate to a sagging state, then the bottom end of the vibrating cleaning rod 308 can contact the surface of the crushing movable tooth awl 2015, then the vibrating cleaning rod 308 can be driven to repeatedly vibrate inside the conical crushing cabin 201 by controlling the rotation of the crushing movable tooth awl 2015, and further in the process that the vibrating cleaning rod 308 repeatedly vibrates, the vibrating cleaning rod 308 can also deform, so that the stone clamped into the teeth on the inner wall of the conical crushing cabin 201 and the teeth on the outer surface of the crushing movable tooth awl 2015 can be cleaned, the electric sliding rail 301 can be controlled to drive the electric sliding seat 302 to move, so as to adjust the position of the vibrating cleaning rod 308, and realize the cleaning of the inner wall of the conical crushing cabin 201 and the outer surface of the crushing movable tooth awl 2015.

The vibrating cleaning bar 308 is a resilient metal material.

The vibration cleaning rod 308 can be deformed freely, so that cleaning work can be carried out conveniently without being clamped.

Example 4

On the basis of embodiment 3, as shown in fig. 1 and 7, the tooth deformation damage detection system 4 includes a motor seat plate 401, a second power motor 402, a first linkage rod 403, a coupling seat 404, a second linkage rod 405, a mounting plate 406, a first return spring 407, a mounting block 408, a mounting bar 409, a detection touch bar 4010, a rotating sleeve seat 4011, and a first mounting shaft seat 4012; the left part of the lower side of the first supporting beam 2018 is connected with a motor seat plate 401 through a bolt; a second power motor 402 is arranged at the rear side of the motor seat plate 401; a first linkage rod 403 is fixedly connected to an output shaft of the second power motor 402; the right side of the first linkage rod 403 is rotatably connected with a shaft connecting seat 404; the lower part of the shaft connecting seat 404 is rotatably connected with a second linkage rod 405; a mounting plate 406 is rotatably connected to the left side of the second linkage rod 405; two first return springs 407 are mounted at the bottom of the mounting plate 406; the bottoms of the two first return springs 407 are connected with the mounting block 408; the right side of the mounting block 408 is fixedly connected with a mounting bar 409; a plurality of detection contact bars 4010 are equidistantly arranged on the lower part of the installation bar 409; the right part of the lower side of the first supporting beam 2018 is connected with a first mounting shaft seat 4012 through a bolt; the lower part of the first installation shaft seat 4012 is rotatably connected with a rotating sleeve seat 4011; the left side of the rotating sleeve seat 4011 is fixedly connected with an installation bar 409.

When the stone clamping cleaning system 3 finishes cleaning stone clamped into the teeth of the gyratory crusher 2, the crushing movable tooth awl 2015 continuously rotates, the crushing movable tooth awl 2015 drives the positioning ring 2017 to synchronously rotate, the crushing movable tooth awl 2015 and the positioning ring 2017 keep synchronously rotating eccentrically, the second power motor 402 is controlled to rotate at the moment, then the second power motor 402 drives the first linkage rod 403 to downwards swing and rotate, the first linkage rod 403 drives the second linkage rod 405 to downwards move through the shaft connecting seat 404, the second linkage rod 405 drives the installation bar 409 to downwards rotate through the installation plate 406, the first return spring 407 and the installation block 408, namely, the installation bar 409 downwards rotates around the installation bar 409 through the installation bar 409, the right part of the lower side of the installation bar 409 is attached to the edge of the positioning ring 2017, and the second power motor 402 is controlled to stop rotating at the moment, namely, the installation bar 409 stops rotating, because the broken tooth awl 2015 and the locating ring 2017 are coaxially arranged, and then after the lower right part of the installation bar 409 is attached to the locating ring 2017, the angle of the installation bar 409 can be adjusted in real time in the eccentric rotation process of the locating ring 2017, so that the whole installation bar 409 can be parallel to the outer annular surface of the broken tooth awl 2015, and then a plurality of detection contact strips 4010 on the lower side of the installation bar 409 can be in contact with the tips of a row of teeth in the vertical direction of the outer annular surface of the broken tooth awl 2015, the detection contact strips 4010 contacting the teeth can send signals to be transmitted to external signal receiving equipment, the detection contact strips 4010 at corresponding positions send signals to prove that the teeth at corresponding positions are in normal states, and the detection contact strips 4010 without sending signals prove that the tips of the teeth at corresponding positions are deformed and damaged.

Example 5

Based on embodiment 4, as shown in fig. 1 and fig. 8-12, the dustproof diversion system 5 includes a motor base 501, a third power motor 502, a third driving wheel 503, a fourth driving wheel 504, a second rotating shaft 505, a connecting rotating seat plate 506, an engaging seat 507, an arc-shaped diversion cover 508, a buffer protection assembly and a dustproof diversion assembly; the right front side bolt at the top of the fixed mounting table 1 is connected with a motor base 501; the top of the motor base 501 is connected with a third power motor 502 through bolts; an output shaft of the third power motor 502 is fixedly connected with a third driving wheel 503; a connecting rotary seat plate 506 is fixedly connected to the upper part of the right front side of the outer wall of the conical crushing cabin 201; the connecting rotation base plate 506 is rotatably connected with a second rotation shaft 505; a fourth driving wheel 504 is fixedly sleeved on the rear side of the outer surface of the second rotating shaft rod 505; the outer ring surface of the fourth driving wheel 504 is connected with a third driving wheel 503 through belt transmission; the second rotating shaft rod 505 is fixedly connected with a connecting seat 507; an arc-shaped air guide sleeve 508 is fixedly connected to the upper part of the left side of the connecting seat 507; the arc-shaped air guide sleeve 508 is provided with a buffer protection component; two dustproof diversion assemblies are mounted on the arc-shaped diversion cover 508.

Before stone is added into the conical crushing cabin 201, in order to avoid the influence of the dustproof guide systems 5 on stone entering, four dustproof guide systems 5 are controlled to be opened outwards, namely, a power supply of a third power motor 502 is controlled to be switched on, then the third power motor 502 drives a third driving wheel 503 to rotate, then the third driving wheel 503 drives a fourth driving wheel 504 to rotate, then the fourth driving wheel 504 drives a second rotating shaft rod 505 to rotate, then the second rotating shaft rod 505 can drive an engagement seat 507 to rotate in the direction away from the conical crushing cabin 201, namely, the engagement seat 507 can drive an arc-shaped guide cover 508, a buffer protection assembly and a dustproof guide assembly to rotate outwards, so that the area of an outer ring at the top of the conical crushing cabin 201 is opened, and stone adding is facilitated.

The buffer protection component comprises a second reset spring 5010, an arc-shaped vibrating plate 5011, a protection screen 5012, an electric push rod 5027 and an intercepting flexible strip 5028; a plurality of second return springs 5010 are equidistantly arranged at the top of the arc-shaped air guide sleeve 508; the bottom of each second return spring 5010 is connected with an arc-shaped vibrating plate 5011; the arc-shaped vibrating plate 5011 is provided with two protective screen plates 5012; the arc-shaped vibrating plate 5011 is provided with two electric push rods 5027; the telescopic ends of the two electric push rods 5027 are connected with the arc-shaped vibrating plate 5011; the lower part of the inner wall of the arc-shaped diversion cover 508 is connected with an intercepting flexible strip 5028; the inner side of the intercepting flexible strip 5028 contacts the arc-shaped vibrating plate 5011.

After the stone is added, the third power motor 502 is controlled to rotate reversely, then the arc-shaped air guide sleeve 508, the buffer protection assembly and the dustproof air guide assembly encircle the top of the conical crushing cabin 201 again, at the moment, the gyratory crusher 2 starts to crush, broken stones are separated upwards from the interior of the conical crushing cabin 201 in the crushing process, then the conical crushing cabin 201 can be intercepted by the arc-shaped area in the arc-shaped air guide sleeve 508, the broken stones firstly contact the arc-shaped vibration plate 5011, then the second return spring 5010 at the top of the arc-shaped vibration plate 5011 contracts, the vibration buffering effect of the arc-shaped vibration plate 5011 on the broken stones is formed, the broken stones can be stably intercepted by a screen and fall back into the conical crushing cabin 201, in the vibration process of the arc-shaped vibration plate 5011, the interception flexible strip 5028 can ensure that the gap between the lower part of the arc-shaped vibration plate 5011 and the arc-shaped air guide sleeve 508 is closed, the stones are prevented from entering the interior of the arc-shaped vibration plate 5011, and dust can be prevented from overflowing from the air guide plate 5012 to the exterior of the conical air guide sleeve 201 in the crushing work process; after the crushing operation is finished, aiming at dust accumulated on the inner side of the arc-shaped vibrating plate 5011, the two electric push rods 5027 can be controlled to extend to drive the arc-shaped vibrating plate 5011 to move in the direction far away from the arc-shaped flow guide cover 508, so that a gap on the inner side of the arc-shaped vibrating plate 5011 is opened, and then the inner side dust falls and is separated.

The dustproof flow guide assembly comprises a rectangular flow guide cylinder 509, a limiting sliding seat 5013, a connecting sliding rod 5014, a mounting strip plate 5015, a vibrating inserted rod 5016, an inclined sliding rail seat 5017, a sliding limiting seat 5018, a limiting rod 5019, a swinging plate 5020, a first hook plate 5021, a torsion spring 5022, a second mounting shaft seat 5023, a second hook plate 5024, a balancing weight 5025 and a third return spring 5026; a rectangular guide cylinder 509 is fixedly inserted on the arc-shaped guide cover 508; openings of the arc-shaped air guide sleeve 508, close to one side of the arc-shaped vibrating plate 5011, are opposite to the protective screen plate 5012 respectively; the middle part of the inner bottom of the rectangular guide cylinder 509 is connected with a limiting sliding seat 5013 through a bolt; the inner side of the limiting sliding seat 5013 is connected with a connecting sliding rod 5014 in a sliding manner; one end of the connecting slide rod 5014 close to the arc-shaped vibrating plate 5011 is fixedly connected with an installation strip plate 5015; the connecting slide 5014 passes through the inside of the third return spring 5026; two ends of the third return spring 5026 are connected with the limiting sliding seat 5013 and the mounting strip 5015 respectively; a plurality of vibrating inserted rods 5016 are arranged on one side, close to the arc-shaped vibrating plate 5011, of the installation strip plate 5015 at equal intervals; the inner bottom wall of the rectangular guide cylinder 509 is provided with two inclined slide rail seats 5017; the upper parts of the two inclined slide rail seats 5017 are respectively connected with a sliding limiting seat 5018 in a sliding manner; the inner bottom wall of the rectangular guide cylinder 509 is provided with two second mounting shaft seats 5023; the upper parts of the two second mounting shaft seats 5023 are respectively connected with a swinging plate 5020 in a rotating way; one side of the upper parts of the two swinging plates 5020 close to the sliding limit seat 5018 is provided with a limit rod 5019 respectively; the lower parts of the two swing plates 5020 close to one side of the mounting strip plate 5015 are fixedly connected with a first hook plate 5021 respectively; the upper part of each second mounting shaft seat 5023 is sleeved with two torsion springs 5022; each swing plate 5020 is connected to the free ends of two torsion springs 5022; one side of the installation strip plate 5015 close to the limiting sliding seat 5013 is provided with two second hook plates 5024; the two second hook plates 5024 are respectively matched with the two first hook plates 5021; one side of the mounting slat 5015 near the limit slide 5013 is provided with two balancing weights 5025.

The inclined rail seat 5017 is initially inclined toward the mounting strip 5015, so that when the arc-shaped air guide sleeve 508 drives the rectangular air guide cylinder 509 to rotate outward, before the top surface of the inclined rail seat 5017 rotates to the horizontal direction, the sliding limit seat 5018 does not slide outward, i.e. the first hook 5021 is still, the rectangular air guide cylinder 509 gradually rotates to the outside in an inclined manner, the mounting strip 5015 and the vibrating insert 5016 also rotate to the inclined upward direction, then due to the falling effect of the gravity of the two balancing weights 5025 on the mounting strip 5015, the mounting strip 5015 drives the connecting slide 5014 to slide downward inside the limit slide 5013, i.e. the third return spring 5026 is compressed, and meanwhile, the second hook 5024 moves toward the first hook 5021, then the second hook 5024 is clamped into the first hook 5021, and at this time, the top of the inclined rail seat 5017 also rotates to the horizontal position, as the inclined rail seat 5017 continues to rotate outwards, the sliding limit seat 5018 also starts to slide towards the outer side of the inclined rail seat 5017, at this time, the torsion spring 5022 releases elasticity, so that the swing plate 5020 drives the limit rod 5019 to be attached to the bent position of the sliding limit seat 5018, the first hook plate 5021 forms a limit effect on the second hook plate 5024, the third reset spring 5026 keeps the state of compressing and accumulating elasticity, then the arc-shaped diversion cover 508 rotates outwards, stones are added into the rotary crusher 2, after the completion of the addition, the arc-shaped diversion cover 508 rotates upwards and resets under control, during the upward rotation of the arc-shaped diversion cover 508, the first hook plate 5021 and the second hook plate 5024 rotate upwards synchronously, then the sliding limit seat 5018 cannot slide until the inclined rail seat 5017 rotates to the horizontal position, and when the mounting bar 5015 rotates to the horizontal position, the inclined rail seat 5017 rotates to the horizontal position right, at this time, the sliding limiting seat 5018 starts to slide towards the direction close to the mounting bar 5015, then the sliding limiting seat 5018 presses the limiting rod 5019 towards the direction close to the mounting bar 5015 again, and the limiting rod 5019 drives the first hook plate 5021 to rotate towards the direction close to the mounting bar 5015 through the swing plate 5020, so that the first hook plate 5021 rotates downwards from the lower side bent part of the second hook plate 5024 to get out of the way, and then the third return spring 5026 starts to release the elastic force to drive the connecting slide bar 5014 to move towards the direction close to the protection screen 5012, so that the connecting slide bar 5014 drives the mounting bar 5015 and the vibrating insert bar 5016 to synchronously and rapidly move towards the position of the protection screen 5012, that is, the plurality of vibrating insert bars 5016 rapidly impact on the protection screen 5012, so that the protection screen 5012 vibrates, and a part of stones clamped in the meshes of the protection screen 5012 can be separated under the action of vibration.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope of the present invention, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims (9)

1. A vertical tooth rotary crusher is characterized by comprising a fixed mounting table (1) and a rotary crusher (2); a rotary crusher (2) for crushing stone is arranged in the middle of the top of the fixed mounting platform (1); the method is characterized in that: the device also comprises a tooth deformation damage detection system (4) and a dustproof flow guide system (5); a tooth deformation damage detection system (4) for detecting the damage of the teeth in the crusher is arranged at the upper left part of the gyratory crusher (2); four dustproof flow guide systems (5) for guiding and separating raised dust in the crushing process are equidistantly arranged on the outer ring at the top of the gyratory crusher (2); the bottoms of the four dustproof flow guide systems (5) are connected with the fixed mounting table (1);

the tooth deformation damage detection system (4) comprises a motor seat plate (401), a second power motor (402), a first linkage rod (403), a connecting shaft seat (404), a second linkage rod (405), a mounting plate (406), a first reset spring (407), a mounting block (408), a mounting bar rod (409), a detection touch bar (4010), a rotating sleeve seat (4011) and a first mounting shaft seat (4012); a motor seat plate (401) is fixedly connected to the left part of the lower side of the first supporting beam (2018); a second power motor (402) is arranged at the rear side of the motor base plate (401); a first linkage rod (403) is fixedly connected with an output shaft of the second power motor (402); the right side of the first linkage rod (403) is rotatably connected with a shaft connecting seat (404); the lower part of the shaft connecting seat (404) is rotationally connected with a second linkage rod (405); a mounting plate (406) is rotatably connected to the left side of the second linkage rod (405); two first return springs (407) are mounted at the bottom of the mounting plate (406); the bottoms of the two first return springs (407) are connected with the mounting block (408); a mounting bar (409) is fixedly connected to the right side of the mounting block (408); a plurality of detection contact bars (4010) are arranged on the lower part of the mounting bar (409) at equal intervals; a first mounting shaft seat (4012) is fixedly connected to the right part of the lower side of the first support beam (2018); the lower part of the first mounting shaft seat (4012) is rotatably connected with a rotating sleeve seat (4011); the left side of the rotating sleeve seat (4011) is fixedly connected with an installation bar (409).

2. A vertical tooth gyratory crusher according to claim 1, characterized in that the gyratory crusher (2) comprises a conical crushing bin (201), a bearing sleeve (202), a first rotating shaft rod (203), a first bearing block (204), a first drive pulley (205), a first power motor (206), a second bearing block (207), a second drive pulley (208), a bevel gear (209), a conical tooth disc (2010), a main shaft (2011), a support plate (2012), a blanking support swash plate (2013), an eccentric sleeve disc (2014), a crushing movable tooth cone (2015), a suspension bearing block (2016), a positioning ring (2017), a first support beam (2018) and a second support beam (2019); a conical crushing cabin (201) is arranged in the middle of the top of the fixed mounting table (1); a bearing sleeve (202) is arranged at the right lower part of the conical crushing cabin (201); a first rotating shaft rod (203) is rotatably connected to the inner side of the bearing sleeve (202); two first bearing seats (204) are arranged on the right side of the upper part of the fixed mounting table (1); the two first bearing seats (204) are rotatably connected with the first rotating shaft rod (203); a first driving wheel (205) is fixedly sleeved at the right part of the outer surface of the first rotating shaft rod (203); a first power motor (206) is fixedly connected to the rear side of the top of the fixed mounting table (1); a second bearing seat (207) is fixedly connected to the rear side of the top of the fixed mounting table (1); the second bearing seat (207) is rotationally connected with an output shaft of the first power motor (206); the output shaft of the first power motor (206) is fixedly connected with a second driving wheel (208); the outer ring surface of the second driving wheel (208) is connected with the first driving wheel (205) through belt transmission; a bevel gear (209) is fixedly connected to the left part of the outer surface of the first rotating shaft rod (203); a supporting plate (2012) is fixedly connected to the right bottom of the inner wall of the conical crushing cabin (201); the support plate (2012) is rotatably connected with a main shaft (2011); a conical fluted disc (2010) is fixedly connected to the middle part of the outer surface of the main shaft (2011); the bevel gear disc (2010) is meshed with the bevel gear (209); a blanking supporting inclined plate (2013) is fixedly connected to the right lower part of the inner wall of the conical crushing cabin (201); the left lower part of the blanking support sloping plate (2013) is fixedly connected with a support plate (2012); the top of the main shaft (2011) is fixedly connected with an eccentric sleeve disc (2014); the top of the eccentric sleeve disc (2014) is fixedly connected with a crushing movable tooth cone (2015); a first supporting beam (2018) and a second supporting beam (2019) are fixedly connected to the left side of the top of the conical crushing cabin (201) and the right side of the top of the conical crushing cabin respectively; a suspension bearing seat (2016) is fixedly connected between the first supporting beam (2018) and the second supporting beam (2019); the lower part of the suspension bearing seat (2016) is rotatably connected with a crushing movable tooth cone (2015); a positioning ring (2017) is fixedly connected to the outer ring at the top of the crushing movable tooth cone (2015), and the crushing movable tooth cone (2015) and the positioning ring (2017) are coaxially distributed; the bottom of the first supporting beam (2018) is connected with a tooth deformation damage detection system (4); four dustproof flow guide systems (5) are arranged on the outer ring of the top of the conical crushing cabin (201) at equal intervals.

3. A vertical gyratory crusher according to claim 2, characterised in that the left side of the blanking support ramp (2013) is provided with a bend.

4. A vertical gyratory crusher as claimed in claim 3, characterised in that the inner wall of the cone-shaped crushing cabin (201) and the outer surface of the crushing moving cone (2015) are provided with pyramid teeth, and the pyramid teeth of the inner wall of the cone-shaped crushing cabin (201) and the pyramid teeth of the outer surface of the crushing moving cone (2015) are distributed in a staggered manner.

5. A vertical gyratory tooth crusher as claimed in claim 4, characterized in that the vibrating cleaning rod (308) is of a resilient metal material.

6. A vertical tooth gyratory crusher according to claim 5, characterized in that the dustproof diversion system (5) comprises a motor base (501), a third power motor (502), a third driving wheel (503), a fourth driving wheel (504), a second rotating shaft rod (505), a connecting rotating seat plate (506), a linking seat (507), an arc-shaped diversion cover (508), a buffering protection component and a dustproof diversion component; a motor base (501) is fixedly connected to the right front side of the top of the fixed mounting table (1); the top of the motor base (501) is fixedly connected with a third power motor (502); an output shaft of the third power motor (502) is fixedly connected with a third driving wheel (503); a connecting rotary seat plate (506) is fixedly connected to the upper part of the right front side of the outer wall of the conical crushing cabin (201); the connecting rotating seat plate (506) is rotatably connected with a second rotating shaft rod (505); a fourth driving wheel (504) is fixedly sleeved on the rear side of the outer surface of the second rotating shaft rod (505); the outer ring surface of the fourth driving wheel (504) is connected with a third driving wheel (503) through belt transmission; a connecting seat (507) is fixedly connected to the second rotating shaft rod (505); an arc-shaped air guide sleeve (508) is fixedly connected to the upper part of the left side of the connecting seat (507); a buffering protection component is arranged on the arc-shaped air guide sleeve (508); two dustproof flow guide assemblies are arranged on the arc-shaped flow guide cover (508).

7. The vertical tooth gyratory crusher according to claim 6, wherein the buffer guard assembly comprises a second return spring (5010), an arc-shaped vibrating plate (5011), a guard screen (5012), an electric push rod (5027) and an intercepting flexible bar (5028); a plurality of second reset springs (5010) are equidistantly arranged at the top in the arc-shaped air guide sleeve (508); the bottom of each second return spring (5010) is connected with an arc-shaped vibrating plate (5011); two protection screen plates (5012) are arranged on the arc-shaped vibrating plate (5011); two electric push rods (5027) are arranged on the arc-shaped vibrating plate (5011); the telescopic ends of the two electric push rods (5027) are connected with the arc-shaped vibrating plate (5011); the lower part of the inner wall of the arc-shaped diversion cover (508) is connected with an intercepting flexible strip (5028); the inner side of the intercepting flexible strip (5028) is in contact with the arc-shaped vibrating plate (5011).

8. The vertical tooth gyratory crusher according to claim 7, wherein the dustproof guide assembly comprises a rectangular guide cylinder (509), a limit sliding seat (5013), a connecting sliding rod (5014), a mounting strip plate (5015), a vibrating inserted rod (5016), an inclined sliding rail seat (5017), a sliding limit seat (5018), a limit rod (5019), a swinging plate (5020), a first hook plate (5021), a torsion spring (5022), a second mounting shaft seat (5023), a second hook plate (5024), a balancing weight (5025) and a third return spring (5026); a rectangular guide shell (509) is fixedly inserted on the arc-shaped guide shell (508); openings of the arc-shaped air guide sleeve (508) close to one side of the arc-shaped vibrating plate (5011) are respectively opposite to the protective screen plate (5012); a limiting sliding seat (5013) is fixedly connected to the middle part of the inner bottom of the rectangular guide cylinder (509); the inner side of the limiting sliding seat (5013) is connected with a connecting sliding rod (5014) in a sliding manner; one end of the connecting sliding rod (5014) close to the arc-shaped vibrating plate (5011) is fixedly connected with an installation batten (5015); the connecting sliding rod (5014) penetrates through the inner side of the third return spring (5026); two ends of the third return spring (5026) are respectively connected with the limiting sliding seat (5013) and the mounting strip plate (5015); a plurality of vibration insertion rods (5016) are equidistantly arranged on one side of the installation slat (5015) close to the arc-shaped vibration plate (5011); two inclined slide rail seats (5017) are arranged on the inner bottom wall of the rectangular guide cylinder (509); the upper parts of the two inclined slide rail seats (5017) are respectively connected with a sliding limiting seat (5018) in a sliding manner; two second mounting shaft seats (5023) are arranged on the inner bottom wall of the rectangular guide cylinder (509); the upper parts of the two second mounting shaft seats (5023) are respectively connected with a swinging plate (5020) in a rotating way; one side of the upper parts of the two swinging plates (5020) close to the sliding limit seat (5018) is respectively provided with a limit rod (5019); the lower parts of the two swinging plates (5020) close to one side of the installation strip plate (5015) are fixedly connected with a first hook plate (5021) respectively; the upper part of each second mounting shaft seat (5023) is sleeved with two torsion springs (5022); each swinging plate (5020) is connected with the free ends of two torsion springs (5022); one side of the installation batten (5015) close to the limiting sliding seat (5013) is provided with two second hook plates (5024); the two second hook plates (5024) are respectively matched with the two first hook plates (5021); one side of the installation slat (5015) close to the limiting sliding seat (5013) is provided with two balancing weights (5025).

9. The vertical tooth gyratory crusher according to any one of claims 1-8, characterized in that it further comprises a stuck stone cleaning system (3), the bottom of the second supporting beam (2019) is connected with the stuck stone cleaning system (3), and the stuck stone cleaning system (3) comprises an electric slide rail (301), an electric slide seat (302), a mounting seat (303), an electric rotating shaft seat (304), a supporting rotating frame (305), a movable sleeve seat (306), a universal ball (307) and a vibrating cleaning rod (308); the bottom of the first supporting beam (2018) is fixedly connected with an electric sliding rail (301); the lower part of the electric slide rail (301) is connected with an electric slide seat (302) in a sliding way; the bottom of the electric sliding seat (302) is fixedly connected with a mounting seat (303); an electric rotating shaft seat (304) is arranged on the mounting seat (303); the rotating end of the electric rotating shaft seat (304) is fixedly connected with a supporting rotating frame (305); a movable sleeve seat (306) is arranged at the top in the mounting seat (303); the lower part of the movable sleeve seat (306) is connected with a universal ball (307) in a sliding way; a vibration cleaning rod (308) is fixedly connected to the right side of the universal ball (307); the lower left side of the vibrating cleaning rod (308) contacts and supports the rotating frame (305).

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