CN115069530A - From suction formula mechanical shock broken sieving mechanism that gathers scattered - Google Patents

From suction formula mechanical shock broken sieving mechanism that gathers scattered Download PDF

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Publication number
CN115069530A
CN115069530A CN202210874993.XA CN202210874993A CN115069530A CN 115069530 A CN115069530 A CN 115069530A CN 202210874993 A CN202210874993 A CN 202210874993A CN 115069530 A CN115069530 A CN 115069530A
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China
Prior art keywords
self
crushing
filtering
gathering
suction
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CN202210874993.XA
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Chinese (zh)
Inventor
李克峰
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Peixian Huanyu Mining Machinery Parts Co ltd
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Peixian Huanyu Mining Machinery Parts Co ltd
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Priority to CN202210874993.XA priority Critical patent/CN115069530A/en
Publication of CN115069530A publication Critical patent/CN115069530A/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B07SEPARATING SOLIDS FROM SOLIDS; SORTING
    • B07BSEPARATING SOLIDS FROM SOLIDS BY SIEVING, SCREENING, SIFTING OR BY USING GAS CURRENTS; SEPARATING BY OTHER DRY METHODS APPLICABLE TO BULK MATERIAL, e.g. LOOSE ARTICLES FIT TO BE HANDLED LIKE BULK MATERIAL
    • B07B1/00Sieving, screening, sifting, or sorting solid materials using networks, gratings, grids, or the like
    • B07B1/18Drum screens
    • B07B1/22Revolving drums
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B07SEPARATING SOLIDS FROM SOLIDS; SORTING
    • B07BSEPARATING SOLIDS FROM SOLIDS BY SIEVING, SCREENING, SIFTING OR BY USING GAS CURRENTS; SEPARATING BY OTHER DRY METHODS APPLICABLE TO BULK MATERIAL, e.g. LOOSE ARTICLES FIT TO BE HANDLED LIKE BULK MATERIAL
    • B07B1/00Sieving, screening, sifting, or sorting solid materials using networks, gratings, grids, or the like
    • B07B1/28Moving screens not otherwise provided for, e.g. swinging, reciprocating, rocking, tilting or wobbling screens
    • B07B1/34Moving screens not otherwise provided for, e.g. swinging, reciprocating, rocking, tilting or wobbling screens jigging or moving to-and-fro perpendicularly or approximately perpendiculary to the plane of the screen
    • B07B1/343Moving screens not otherwise provided for, e.g. swinging, reciprocating, rocking, tilting or wobbling screens jigging or moving to-and-fro perpendicularly or approximately perpendiculary to the plane of the screen with mechanical drive elements other than electromagnets
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B07SEPARATING SOLIDS FROM SOLIDS; SORTING
    • B07BSEPARATING SOLIDS FROM SOLIDS BY SIEVING, SCREENING, SIFTING OR BY USING GAS CURRENTS; SEPARATING BY OTHER DRY METHODS APPLICABLE TO BULK MATERIAL, e.g. LOOSE ARTICLES FIT TO BE HANDLED LIKE BULK MATERIAL
    • B07B1/00Sieving, screening, sifting, or sorting solid materials using networks, gratings, grids, or the like
    • B07B1/42Drive mechanisms, regulating or controlling devices, or balancing devices, specially adapted for screens
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B07SEPARATING SOLIDS FROM SOLIDS; SORTING
    • B07BSEPARATING SOLIDS FROM SOLIDS BY SIEVING, SCREENING, SIFTING OR BY USING GAS CURRENTS; SEPARATING BY OTHER DRY METHODS APPLICABLE TO BULK MATERIAL, e.g. LOOSE ARTICLES FIT TO BE HANDLED LIKE BULK MATERIAL
    • B07B1/00Sieving, screening, sifting, or sorting solid materials using networks, gratings, grids, or the like
    • B07B1/46Constructional details of screens in general; Cleaning or heating of screens
    • B07B1/4609Constructional details of screens in general; Cleaning or heating of screens constructional details of screening surfaces or meshes
    • B07B1/4663Multi-layer screening surfaces

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Crushing And Grinding (AREA)

Abstract

The invention discloses a self-suction gathering and scattering type mechanical vibration crushing and screening device which comprises a self-suction type deformation filtering component, a self-driving bouncing component, a supporting plate, a bottom plate, a crushing and collecting outer box and a gathering and scattering type crushing filtering barrel, wherein one end of the supporting plate is arranged on the bottom plate, a sliding groove is formed in the supporting plate, the self-suction type deformation filtering component and the self-driving bouncing component are arranged in the sliding groove, and the self-driving bouncing component is connected with the self-suction type deformation filtering component; the crushing collection outer box is connected with the self-driven bouncing assembly, and the gathering type crushing filter barrel is connected with the self-driven bouncing assembly. The invention belongs to the technical field of crushing and screening equipment, and particularly relates to a self-suction gathering and scattering type mechanical vibration crushing and screening device which realizes the circulation and filtration of gas under the condition of no suction driving device; the method solves the problem that the granularity of crushed particles can not be too coarse or too fine when the ore is crushed and decomposed.

Description

From suction formula mechanical shock broken sieving mechanism that gathers loose
Technical Field
The invention belongs to the technical field of crushing and screening equipment, and particularly relates to a self-suction gathering and scattering type mechanical vibration crushing and screening device.
Background
Ore refers to a collection of minerals from which useful components can be extracted or which have some property of being utilized by themselves, and can be classified into metal minerals, non-metal minerals, in the concentrating mill, the crushing of the mine stones is an indispensable preparation stage before screening, firstly, most of the mine stones treated by the concentrating mill are the useful minerals and the gangue minerals which are closely connected together, and often become fine particles or even become embedded with fine particles, and only after the fine particles are crushed and fully dissociated, the fine particles can be enriched by the existing physical ore dressing method, secondly, all physical ore dressing methods are limited by the granularity, the effective separation can not be carried out when the granularity is too coarse or too fine, the ore needs to be screened again after the existing mine ore is crushed, the production procedures are increased, and a large amount of dust can be produced in the ore crushing process, so that the environmental pollution is caused, and the dust is required to be reduced.
Disclosure of Invention
Aiming at the situation and overcoming the defects of the prior art, the invention provides a self-suction gathering and scattering type mechanical vibration crushing and screening device, wherein a self-driving bouncing component has the trend of up-down vibration during rotation by arranging an eccentric center of gravity, so that the self-suction type deformation filtering component is stretched or extruded, and the gas is circulated and filtered under the condition of no suction driving device through the self-regulation action of pressure intensity; the gathering and scattering type crushing and filtering barrel is used for crushing ores, the technical effects of rigid-gram and flexible-support-flexible are achieved by using fluid with a nonlinear relation between shearing stress and shearing strain rate as a medium, and the contradiction that the granularity of crushed particles cannot be too coarse (most of mine stones are useful minerals and gangue minerals which are closely connected together and often become fine particles or even are embedded with the fine particles, and the mine stones can be enriched by using the existing physical ore dressing method only by crushing and fully dissociating the mine stones) and cannot be too fine (the physical ore dressing method is limited by the granularity, and the physical ore dressing method is too fine and cannot effectively separate the mine stones) during crushing and decomposing of the ores is solved.
The technical scheme adopted by the invention is as follows: the invention provides a self-suction gathering and scattering type mechanical vibration crushing and screening device, which comprises a self-suction type deformation filtering component, a self-driving bouncing component, a supporting plate, a bottom plate, a crushing and collecting outer box and a gathering and scattering type crushing filtering barrel, wherein one end of the supporting plate is arranged on the bottom plate, the bottom plate supports and fixes the supporting plate, a chute is arranged in the supporting plate, the self-suction type deformation filtering component is arranged in the chute, the chute supports the self-suction type deformation filtering component, the self-driving bouncing component is arranged in the chute, the self-driving bouncing component is connected with the self-suction type deformation filtering component, when in screening and filtering, the self-driving bouncing component stretches or extrudes the self-suction type deformation filtering component by arranging an eccentric gravity center and has the trend of up-and down vibration when rotating, and under the condition of no suction driving device, the circulation and filtration of the gas are realized, and when the self-driven bouncing assembly needs to be fixed, the self-driven bouncing assembly is adsorbed in the chute through a magnetic field; the crushing and collecting outer box is connected with the self-driven bouncing assembly, the gathering and scattering type crushing filter barrel is connected with the self-driven bouncing assembly, and the gathering and scattering type crushing filter barrel is arranged in the crushing and collecting outer box; the gathering and scattering type crushing and filtering barrel is used for crushing ores, the technical effects of rigid-gram and flexible-support are realized by using fluid with a non-linear relation between shearing stress and shearing strain rate as a medium, and the contradiction that the granularity of crushed particles can not be too coarse or too fine when the ores are crushed and decomposed is solved; the self-suction type bag-shaped filtering piece is arranged in the first spring for deformation and the second spring for deformation respectively, a gap is arranged between the inner wall of the first spring for deformation and the inner wall of the second spring for deformation, and the self-suction type bag-shaped filtering piece is in a stretching state of the first spring for deformation and the second spring for deformation, when the self-suction bag-shaped filter element is compressed by the first spring, the self-suction bag-shaped filter element can deform and compress under the extrusion, the gas in the self-suction bag-shaped filter element is extruded and discharged into the crushing and collecting outer box, the pressure in the crushing and collecting outer box is increased, the second spring for deformation extends, the self-suction bag-shaped filter piece in the box stretches downwards during stretching, the volume is increased, the internal pressure is reduced, meanwhile, the pressure in the crushing and collecting outer box is increased, the air current mixed with dust in the self-suction type bag-shaped filter enters the self-suction type bag-shaped filter under the dual actions of extrusion of the crushing and collecting outer box and adsorption of the self-suction type bag-shaped filter, the one end and the broken outer container lateral wall of collecting of connecting pipe link up continuously, the other end of connecting pipe with from suction formula bag shape filter piece through connection, be equipped with filtering component in the connecting pipe, can filter the dust.
The gathering and scattering type crushing and filtering receiving outer barrel and the gathering and scattering type crushing and filtering receiving inner barrel are arranged in a gathering and scattering type crushing and filtering receiving inner barrel, the gathering and scattering type crushing and filtering receiving inner barrel is arranged close to the inner side wall of the gathering and scattering type crushing and filtering receiving outer barrel, the gathering and scattering type crushing and filtering receiving inner barrel is made of elastic materials, the gathering and scattering type crushing and filtering receiving outer barrel is made of hard materials, and in the crushing process, the gathering and scattering type crushing and filtering receiving outer barrel provides supporting force for the gathering and scattering type crushing and filtering receiving inner barrel and contributes to crushing; the crushing filtration of type of gathering together is equipped with on accepting outer bucket and filters the outer hole, it runs through the crushing filtration of type of gathering together and accepts outer bucket setting to filter the outer hole, it is equipped with the filtration hole on accepting interior bucket to gather together the crushing filtration of type of gathering together, filter the hole and run through the crushing filtration of type of gathering together and accept interior bucket setting, filter the hole and be close to and filter the outer hole setting, the ore that sieves out after the breakage enters into from filtering the hole and filters the outer hole back discharge and gathers together the crushing filter vat of type of gathering together.
Preferably, the gathering and dispersing type crushing and filtering receiving inner barrel is internally provided with a temporary storage part III and an elastic bag-shaped part, the temporary storage part III is made of hard materials, the elastic bag-shaped part is made of elastic materials and can deform under the action of external force, the temporary storage part III is arranged close to a filtering inner hole, a coil III is arranged in the temporary storage part III, the elastic bag-shaped part is connected with the temporary storage part III, an elastic extrusion bulge part is arranged on the inner side wall of the filtering inner hole and is made of elastic materials and deforms under the action of external force, the elastic bag-shaped part and the gathering and dispersing type crushing and filtering receiving inner barrel are filled with non-Newtonian fluid, the shearing stress and the shearing strain rate in the non-Newtonian fluid are not in a linear relation, and under the condition of no external force impact, the elastic bag-shaped part filled with the non-Newtonian fluid and the gathering and dispersing type crushing and filtering receiving inner barrel are in a flexible state, under the condition of external force impact, the elastic balloon filled with non-Newtonian fluid and the gathering and scattering type crushing filtering receiving inner barrel are in a rigid state; when the crushing is needed, the coil III is internally electrified, the coils III on the two opposite sides of the filtering inner hole are different in magnetism and mutually attracted, the elastic bag-shaped piece is dragged, the elastic bag-shaped piece deforms, the filtering inner hole is extruded and reduced under the attraction of the coil III, and meanwhile, the elastic extrusion protruding piece is extruded and deformed under the stress, protrudes outwards and extends out of the filtering inner hole, so that crushed ore can be conveniently turned over in the motion process, when the crushed fine ore is impacted on the filtering inner hole, the reaction force is small, the ore cannot be crushed again, when the ore with large action force and needing to be crushed is impacted on the filtering inner hole, the reaction force is large, and the technical effect of crushing is realized; when needing to filter, not circular telegram in the coil three, elasticity bag-shaped spare and elasticity extrusion protruding piece resume deformation, drive three of the temporary storage piece and resume to initial position, filter the hole and present, are convenient for filter the tiny ore after the breakage.
Preferably, the self-driven bounce component comprises a self-driven bounce plate, a driving roller and an eccentric driving piece, the self-driven bounce plate is movably clamped in a sliding groove, the upper end of the self-driven bounce plate is connected with the lower end of a first spring for deformation, the lower end of the self-driven bounce plate is connected with the upper end of a second spring for deformation, a self-suction bag-shaped filtering piece is connected with the self-driven bounce plate, a motor protecting shell is arranged on the self-driven bounce plate, the self-driven bounce plate supports and fixes the motor protecting shell, a motor is arranged in the motor protecting shell, the motor protecting shell supports and protects the motor, the driving roller is movably arranged through the self-driven bounce plate, the self-driven bounce plate supports and fixes the driving roller, the output shaft end of the motor is connected with one end of the driving roller, the motor works to drive the driving roller to rotate, the eccentric driving piece is eccentrically arranged on the driving roller, eccentric driving piece's setting, shift the focus of drive roller, when the drive roller is rotatory, it is rotatory to drive eccentric driving piece, the focus is also rotatory thereupon, drive the drive roller and follow spout luffing motion from the drive springboard, during the luffing motion from the drive springboard, drive with spring one and deformation with spring two for deformation, deformation is with spring one and deformation with spring two counteractions on the self-drive springboard, realize the extrusion or resume the technological effect of deformation from suction formula bag shape filter piece simultaneously, regulate and control and collect the pressure between the outer container from suction formula bag shape filter piece and breakage, under the condition of no suction drive arrangement, gaseous circulation and filtration have been realized.
Preferably, be equipped with the chamber of keeping in one in the self-driven springboard, the chamber of keeping in one sets up near the spout inside wall, be equipped with the coil one in the chamber of keeping in one, the circular telegram of coil one can produce magnetic field.
The magnetic suspension device is characterized in that a temporary storage cavity II is arranged in the supporting plate and is close to the temporary storage cavity I, a coil II is arranged in the temporary storage cavity II, the coil II can generate a magnetic field when electrified, and when the coil I and the coil II generate different magnetism, the coil I and the coil II are adsorbed to fix the self-driven springboard.
Preferably, the crushing and collecting outer box is provided with an outlet and an inlet, the inlet penetrates through the gathering and scattering type crushing and filtering barrel and can discharge screened ores, the ores to be crushed can be arranged in the gathering and scattering type crushing and filtering barrel through the inlet, and the side wall of the crushing and collecting outer box is provided with a ring clamping groove.
The crushing and collecting outer box and the gathering and scattering type crushing filter barrel are connected with the driving roller through the connecting piece; when the drive roller is rotatory, it is rotatory to drive the connecting piece, and the connecting piece drives the breakage and collects the outer container and hold together the broken filter vat of scattered type rotatory, produces centrifugal force, carries out breakage or screening to holding together the ore in the broken filter vat of scattered type.
Preferably, the broken outer container lateral wall activity of collecting is equipped with connects the annular member, connect the annular member activity and locate in the annular member draw-in groove, connect annular member and drive roller swing joint, connect the annular member laminating breakage to collect the outer container lateral wall and hold up the broken filter vat lateral wall setting of scattered type, when the drive roller is rotatory, can drive the breakage and collect the outer container rotation, because drive roller and go up annular member swing joint, go up the annular member and can not follow the rotation of drive roller and move.
Furthermore, the connecting ring piece is provided with a communication hole, and one end of the connecting pipe is communicated with the connecting ring piece.
The invention with the structure has the following beneficial effects: this scheme provides one kind from pumping and gathers scattered formula mechanical shock broken sieving mechanism beneficial effect as follows:
(1) the self-driven bouncing component stretches or extrudes the self-suction type deformation filtering component, and the circulation filtering of the gas is realized under the condition of no suction driving device through the self-regulation action of the pressure.
(2) Gather up broken filter vat of scattered type and be used for carrying out the breakage to the ore, through the fluid that is not linear relation between shear stress and the shear strain rate as the media, realize with just gram rigid, with gentle technological effect who holds in the palm gentle, solved the ore when smashing the decomposition, the granularity of broken granule can neither be too thick nor too thin problem.
(3) The eccentric driving piece arranged on the self-driven bouncing assembly enables the center of gravity on the driving roller to shift, and the driving roller has the trend of shaking up and down during rotation, so that conditions are created for the realization of the driving roller.
(4) The elastic bag-shaped piece is made of elastic materials, can deform under the action of external force, stretches out and filters the inner hole after being protruded outwards, and is convenient for stirring broken ores in the motion process.
(5) The broken setting of accepting interior bucket of filtering of type of gathering together, when the tiny ore impact that has broken was last, the reaction force that receives is little, is unlikely to breakage once more, and the big needs broken ore impact that the effort is last, and the reaction force that receives is big, has realized broken technological effect.
(6) The layered design of the inner filtering hole and the outer filtering hole can conveniently convert vibration type crushing and screening, and the functions of crushing, screening and dust removal are integrated.
Drawings
Fig. 1 is a schematic structural diagram of a self-suction gathering and scattering type mechanical vibration crushing screening device provided by the invention;
fig. 2 is a schematic structural view of a gathering and scattering type crushing filter vat of the self-suction gathering and scattering type mechanical vibration crushing screening device provided by the invention;
fig. 3 is a front view of a self-suction gathering and scattering type mechanical vibration crushing screening device provided by the invention;
fig. 4 is a cross-sectional view of a self-suction gathering and scattering type mechanical vibration crushing screening device provided by the invention;
fig. 5 is an axonometric view of a gathering and scattering type crushing filter barrel of the self-suction gathering and scattering type mechanical vibration crushing screening device provided by the invention;
fig. 6 is a cross-sectional view of a self-driven springboard and a supporting board of the self-suction gathering and scattering type mechanical vibration crushing screening device provided by the invention;
fig. 7 is a schematic structural diagram of a self-driven bouncing assembly of a self-suction converging-diverging mechanical-vibration crushing screening device according to the present invention;
fig. 8 is an expanded view of a gathering and dispersing type crushing filter vat of the self-suction gathering and dispersing type mechanical vibration crushing screening device provided by the invention;
fig. 9 is a cross-sectional view of a gathering and scattering type crushing filter vat of the self-suction gathering and scattering type mechanical vibration crushing screening device provided by the invention.
The device comprises a self-suction type deformation filtering component, a self-driving bouncing component, a support plate, a base plate, a crushing and collecting outer box, a self-suction type crushing filtering barrel, a self-driving bouncing component, a support plate, a base plate, a bottom plate, a crushing and collecting outer box, a self-suction type crushing filtering barrel, a 7, a sliding chute, a self-suction type bag-shaped filtering piece, a 9, a first spring for deformation, a second spring for deformation, a 11, a connecting pipe, a 12, a first collecting and filtering outer barrel, a 13, a first collecting and filtering inner barrel, a 14, an outer filtering hole, a 15, an inner filtering hole, a 16, a third temporary storage piece, a 17, an elastic bag-shaped piece, a 18, a third coil, a 19, an elastic extrusion convex piece, a 20, non-Newtonian fluid, a self-driving bouncing plate, a 22, a driving roller, a 23, an eccentric driving piece, a 24, a motor protective shell, a 25, a motor, a 26, a first temporary storage cavity, a 27, a first coil, a second coil, a 29, a second coil annular piece, a clamping groove, a 31, a connecting piece, a 32, a connecting piece, a, Connecting ring piece, 33, communication hole.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present invention.
As shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 6 and fig. 7, the self-suction gathering-type mechanical vibration crushing screening device provided by the present invention comprises a self-suction type deformation filtering component 1, a self-driving bouncing component 2, a supporting plate 3, a bottom plate 4, a crushing and collecting outer box 5 and a gathering-type crushing filtering barrel 6, wherein one end of the supporting plate 3 is arranged on the bottom plate 4, the bottom plate 4 supports and fixes the supporting plate 3, a chute 7 is arranged in the supporting plate 3, the self-suction type deformation filtering component 1 is arranged in the chute 7, the chute 7 supports the self-suction type deformation filtering component 1, the self-driving bouncing component 2 is arranged in the chute 7, the self-driving bouncing component 2 is connected with the self-suction type deformation filtering component 1, and during screening and filtering, the self-driving bouncing component 2 has an eccentric center of gravity and has a tendency of shaking up and down during rotation, so as to stretch or extrude the self-suction type deformation filtering component 1, through the self-regulation action of the pressure, the circulation and filtration of the gas are realized under the condition of no suction driving device, and when the self-driven bouncing component 2 needs to be fixed, the self-driven bouncing component is adsorbed in the chute 7 through a magnetic field; the crushing and collecting outer box 5 is connected with the self-driven bouncing component 2, the gathering and scattering type crushing filter barrel 6 is connected with the self-driven bouncing component 2, and the gathering and scattering type crushing filter barrel 6 is arranged in the crushing and collecting outer box 5; the gathering and scattering type crushing and filtering barrel 6 is used for crushing ores, the technical effects of rigid-gram and flexible-support are realized by taking fluid which is not in a linear relation between shearing stress and shearing strain rate as a medium, and the contradiction that the granularity of crushed particles can not be too coarse or too fine when the ores are crushed and decomposed is solved; the supporting plate 3 is symmetrically arranged on the bottom plate 4 by taking the central axis of the bottom plate 4 as a symmetry axis, the self-suction type deformation filtering component 1 is arranged on the supporting plate 3 and symmetrically arranged, the self-suction type deformation filtering component 1 comprises a self-suction type bag-shaped filtering piece 8, a first deformation spring 9, a second deformation spring 10 and a connecting pipe 11, the upper end of the first deformation spring 9 is connected with the upper wall of the chute 7, the lower end of the first deformation spring 9 is connected with the upper end of the self-driving bouncing component 2, the lower end of the second deformation spring 10 is connected with the bottom wall of the chute 7, the upper end of the second deformation spring 10 is connected with the lower end of the self-driving bouncing component 2, the self-suction type bag-shaped filtering piece 8 is respectively arranged in the first deformation spring 9 and the second deformation spring 10, a gap is arranged between the inner wall of the self-suction type bag-shaped filtering piece 8 and the first deformation spring 9 and the inner wall of the second deformation spring 10, when the self-suction type bag-shaped filtering piece 8 is in a stretching state by the first deformation spring 9 and the second deformation spring 10, in a natural state without deformation, when the deformation is compressed by a first spring 9, the self-suction type bag-shaped filtering piece 8 can deform under extrusion and is compressed, internal gas is extruded and discharged into the crushing and collecting outer box 5, the pressure in the crushing and collecting outer box 5 is increased, a second spring 10 for deformation extends, the self-suction type bag-shaped filtering piece 8 in the self-suction type bag-shaped filtering piece extends under the stretching condition, the volume is increased, the internal pressure is reduced, the pressure in the crushing and collecting outer box 5 is increased, air flow mixed with dust in the self-suction type bag-shaped filtering piece 8 enters the self-suction type bag-shaped filtering piece 8 under the dual functions of extrusion of the crushing and collecting outer box 5 and adsorption of the self-suction type bag-shaped filtering piece 8, one end of a connecting pipe 11 is communicated with the side wall of the crushing and collecting outer box 5, the other end of the connecting pipe 11 is communicated with the self-suction type bag-shaped filtering piece 8, and a filtering component is arranged in the connecting pipe 11, the dust can be filtered.
As shown in fig. 1, 2 and 4, an outlet and an inlet are arranged on the crushing and collecting outer box 5, the inlet is arranged to penetrate through the gathering and scattering type crushing and filtering barrel 6, and can discharge the screened ore, the ore to be crushed can be arranged in the gathering and scattering type crushing and filtering barrel 6 through the inlet, and a ring clamping groove 30 is arranged on the side wall of the crushing and collecting outer box 5; the driving roller 22 is provided with a connecting piece 31, and the crushing and collecting outer box 5 and the gathering and scattering type crushing filter barrel 6 are connected with the driving roller 22 through the connecting piece 31; when the driving roller 22 rotates, the connecting piece 31 is driven to rotate, the connecting piece 31 drives the crushing and collecting outer box 5 and the gathering and scattering type crushing and filtering barrel 6 to rotate, centrifugal force is generated, and ores in the gathering and scattering type crushing and filtering barrel 6 are crushed or screened; the outer side wall of the crushing and collecting outer box 5 is movably provided with a connecting ring piece 32, the connecting ring piece 32 is movably arranged in a ring piece clamping groove 30, the connecting ring piece 32 is movably connected with the driving roller 22, the connecting ring piece 32 is attached to the side wall of the crushing and collecting outer box 5 and the side wall of the gathering and scattering type crushing filter barrel 6, the driving roller 22 can drive the crushing and collecting outer box 5 to rotate when rotating, and the connecting ring piece 32 cannot move along with the rotation of the driving roller 22 due to the movable connection of the driving roller 22 and the connecting ring piece 32; the connecting ring-shaped member 32 is provided with a communication hole 33, and one end of the connecting pipe 11 is connected with the connecting ring-shaped member 32 in a penetrating manner.
As shown in fig. 2, 4, 5, 7, 8 and 9, the gathering and scattering type crushing and filtering barrel 6 comprises a gathering and scattering type crushing and filtering receiving outer barrel 12 and a gathering and scattering type crushing and filtering receiving inner barrel 13, the gathering and scattering type crushing and filtering receiving inner barrel 13 is arranged to be attached to the inner side wall of the gathering and scattering type crushing and filtering receiving outer barrel 12, the gathering and scattering type crushing and filtering receiving inner barrel 13 is arranged by adopting an elastic material, the gathering and scattering type crushing and filtering receiving outer barrel 12 is arranged by adopting a hard material, and the gathering and scattering type crushing and filtering receiving outer barrel 12 provides a supporting force for the gathering and scattering type crushing and filtering receiving inner barrel 13 in the crushing process so as to facilitate crushing; a filtering outer hole 14 is formed in the gathering and dispersing type crushing and filtering receiving outer barrel 12, the filtering outer hole 14 penetrates through the gathering and dispersing type crushing and filtering receiving outer barrel 12, a filtering inner hole 15 is formed in the gathering and dispersing type crushing and filtering receiving inner barrel 13, the filtering inner hole 15 penetrates through the gathering and dispersing type crushing and filtering receiving inner barrel 13, the filtering inner hole 15 is arranged close to the filtering outer hole 14, and ores screened out after crushing enter the filtering outer hole 14 from the filtering inner hole 15 and then are discharged out of the gathering and dispersing type crushing and filtering barrel 6; the gathering and scattering type crushing and filtering receiving inner barrel 13 is internally provided with a temporary storage part III 16 and an elastic sac-shaped part 17, the temporary storage part III 16 is arranged by hard materials, the elastic sac-shaped part 17 is arranged by elastic materials and can deform under the action of external force, the temporary storage part III 16 is arranged close to a filtering inner hole 15, a coil III 18 is arranged in the temporary storage part III 16, the elastic sac-shaped part 17 is connected with the temporary storage part III 16, an elastic extrusion convex part 19 is arranged on the inner side wall of the filtering inner hole 15, the elastic extrusion convex part 19 is arranged by elastic materials and deforms under the action of external force, the elastic sac-shaped part 17 and the gathering and scattering type crushing and filtering receiving inner barrel 13 are filled with non-Newtonian fluid 20, the shearing stress and the shearing rate in the non-Newtonian fluid 20 are not in a linear relation, and under the condition of no external force impact, the elastic sac-shaped part 17 filled with the non-Newtonian fluid 20 and the gathering and scattering type crushing and filtering receiving inner barrel 13 are in a flexible state, under the condition of external force impact, the elastic balloon 17 filled with the non-Newtonian fluid 20 and the gathering and scattering type crushing, filtering and receiving inner barrel 13 are in a rigid state; when the crushing is needed, the coils III 18 are powered on, the coils III 18 on the two opposite sides of the filtering inner hole 15 are different in magnetism and mutually attract, the elastic bag-shaped piece 17 is dragged, the elastic bag-shaped piece 17 deforms, the filtering inner hole 15 is extruded and reduced under the attraction of the coils III 18, meanwhile, the elastic extrusion protruding piece 19 is extruded, the elastic extrusion protruding piece 19 is stressed and deformed and protrudes outwards to extend out of the filtering inner hole 15, the crushed ore is convenient to turn over in the motion process, when the crushed fine ore is impacted on the filtering inner hole, the reaction force is small, the ore cannot be crushed again, the ore which is large in acting force and needs to be crushed is impacted on the filtering inner hole, the reaction force is large, and the technical effect of crushing is achieved; when needing to filter, do not circular telegram in the coil three 18, elasticity cystic 17 and elasticity extrusion protruding piece 19 resume deformation, drive and keep in a temporary position three 16 and resume to initial position, filter hole 15 and present, are convenient for filter the tiny ore after the breakage.
As shown in fig. 1, 2, 3, 4, 6 and 7, the self-driven bouncing assembly 2 includes a self-driven bouncing plate 21, a driving roller 22 and an eccentric driving member 23, the self-driven bouncing plate 21 is movably clamped in the sliding chute 7, the upper end of the self-driven bouncing plate 21 is connected with the lower end of a first spring 9 for deformation, the lower end of the self-driven bouncing plate 21 is connected with the upper end of a second spring 10 for deformation, a self-suction bag-shaped filtering member 8 is connected with the self-driven bouncing plate 21, a motor protecting shell 24 is arranged on the self-driven bouncing plate 21, the self-driven bouncing plate 21 supports and fixes the motor protecting shell 24, a motor 25 is arranged in the motor protecting shell 24, the motor protecting shell 24 supports and protects the motor 25, the driving roller 22 is movably arranged through the self-driven bouncing plate 21, the driving roller 22 is supported and fixed by the self-driven bouncing plate 21, the output shaft end of the motor 25 is connected with one end of the driving roller 22, the motor 25 works to drive the driving roller 22 to rotate, the eccentric driving piece 23 is eccentrically arranged on the driving roller 22, the eccentric driving piece 23 is arranged to transfer the gravity center of the driving roller 22, when the driving roller 22 rotates, the eccentric driving piece 23 is driven to rotate, the gravity center also rotates to drive the driving roller 22 and the self-driven springboard 21 to swing up and down along the chute 7, when the self-driven springboard 21 swings up and down, the first spring 9 for deformation and the second spring 10 for deformation are driven, the first spring 9 for deformation and the second spring 10 for deformation react on the self-driven springboard 21, meanwhile, the self-suction type bag-shaped filter piece 8 realizes the technical effect of extrusion or deformation recovery, the pressure between the self-suction type bag-shaped filter piece 8 and the crushing and collecting outer box 5 is regulated and controlled, and the circulation and filtration of gas are realized under the condition without a suction driving device; a temporary storage cavity I26 is arranged in the self-driven springboard 21, the temporary storage cavity I26 is arranged close to the inner side wall of the sliding chute 7, a coil I27 is arranged in the temporary storage cavity I26, and the coil I27 can generate a magnetic field when being electrified; be equipped with temporary storage chamber two 28 in the backup pad 3, temporary storage chamber two 28 is close to temporary storage chamber one 26 and sets up, is equipped with coil two 29 in the temporary storage chamber two 28, and coil two 29 circular telegram can produce the magnetic field, and when coil one 27 and coil two 29 circular telegram produced different magnetism, coil one 27 and coil two 29 adsorb, fix self-driven springboard 21.
When in specific use:
through the inlet, firstly, crushing is carried out, the coil III 18 is internally electrified, the coils III 18 on the two opposite sides of the filtering inner hole 15 are different in magnetism and mutually attract, the elastic bag-shaped piece 17 is dragged, the elastic bag-shaped piece 17 is deformed, the filtering inner hole 15 is extruded and reduced under the attraction of the coil III 18, meanwhile, the elastic extrusion convex piece 19 is extruded, the two elastic extrusion convex pieces 19 are stressed and deformed after contacting and are convex outwards, the elastic extrusion convex piece extends out of the filtering inner hole 15 and is arranged in the gathering and scattering type crushing filtering barrel 6, ores to be crushed are arranged in the gathering and scattering type crushing filtering barrel 6, then the inlet is closed, the coil I27 and the coil II 29 are electrified to generate different magnetism, the coil I27 and the coil II 29 are adsorbed to fix the self-driven springboard 21, then the motor 25 works to drive the driving roller 22 to rotate, the driving roller 22 rotates to drive the connecting piece 31 to rotate, the connecting piece 31 drives the crushing and collecting outer box 5 and the gathering and scattering type crushing and filtering barrel 6 to rotate to generate centrifugal force, the driving roller 22 is movably connected with the connecting ring piece 32, the connecting ring piece 32 cannot move along with the rotation of the driving roller 22, the ores in the gathering and scattering type crushing and filtering barrel 6 impact the inner wall of the gathering and scattering type crushing and filtering barrel 6 under the action of the centrifugal force, the gathering and scattering type crushing and filtering bearing outer barrel 12 is made of hard materials, the gathering and scattering type crushing and filtering bearing inner barrel 13 is provided with supporting force to facilitate crushing, meanwhile, the elastic extrusion bulge piece 19 is convenient for turning the crushed ores in the rotating process, the elastic balloon piece 17 and the gathering and scattering type crushing and filtering bearing inner barrel 13 are filled with non-Newton fluid 20, the ores which have large inertia force and need to be crushed impact the elastic balloon piece 17 and the gathering and scattering type crushing and filtering bearing inner barrel 13, the reaction force is large, the technical effect of crushing is realized; when the crushed fine ores impact on the elastic bag-shaped piece 17 and the upper surface of the gathering type crushing filtering receiving inner barrel 13, the reaction force is small, so that the crushed fine ores cannot be crushed again;
when screening is needed, the coil III 18 is not electrified, the elastic sac-shaped part 17 and the elastic extrusion bulge part 19 recover to deform to drive the temporary storage part III 16 to recover to the initial position, the filtering inner hole 15 is shown, the coil I27 and the coil II 29 are powered off, then the motor 25 works to drive the driving roller 22 to rotate, when the driving roller 22 rotates, the eccentric driving part 23 is driven to rotate, the center of gravity also rotates along with the eccentric driving part, the driving roller 22 and the self-driven bounce plate 21 are driven to swing up and down along the chute 7, when the self-driven bounce plate 21 swings up and down, the first deformation spring 9 and the second deformation spring 10 are driven, the first deformation spring 9 and the second deformation spring 10 react on the self-driven bounce plate 21, when the self-driven bounce plate 21 moves up, the first deformation spring 9 is compressed, the self-suction type sac-shaped filtering part 8 can deform under extrusion and is compressed, the internal gas is extruded and discharged to the crushing collection outer box 5 through the connecting pipe 11, the pressure in the crushing and collecting outer box 5 is increased, the second deformation spring 10 is extended, the self-suction type bag-shaped filter piece 8 in the crushing and collecting outer box is extended when being stretched, the size is increased, the internal pressure is reduced, the pressure in the crushing and collecting outer box 5 is increased, the gathering and scattering type crushing and filtering accepting air flow mixed with dust in the inner barrel 13 is achieved, under the dual effects of extrusion of the crushing and collecting outer box 5 and adsorption of the self-suction type bag-shaped filter piece 8, the air flow enters the self-suction type bag-shaped filter piece 8 in the second deformation spring 10 through the connecting pipe 11, and the filtering assembly is arranged in the connecting pipe 11 and can filter dust; when the self-driven springboard 21 moves downwards, the deformation is compressed by the spring two 10, the self-suction type bag-shaped filter piece 8 can deform and compress under extrusion, the filtered gas in the self-suction type bag-shaped filter piece is extruded and discharged into the crushing and collecting outer box 5 through the connecting pipe 11, the pressure in the crushing and collecting outer box 5 is increased, and meanwhile, the deformation is extended by the spring one 9, the self-suction type bag-shaped filter piece 8 in the self-suction type bag-shaped filter piece stretches when being stretched, the volume is enlarged, the internal pressure is reduced, meanwhile, the pressure intensity in the crushing and collecting outer box 5 is increased, the gathering and scattering type crushing and filtering is used for receiving the airflow mixed with the dust in the inner barrel 13, under the dual actions of the squeezing of the crushing and collecting outer box 5 and the adsorption of the self-suction type bag-shaped filter piece 8, the filter powder enters a self-suction type bag-shaped filter piece 8 in a first deformation spring 9 through a connecting pipe 11, and a filter assembly is arranged in the connecting pipe 11 and can filter dust; the dust removal treatment of the internal dust is realized by reciprocating in this way; the crushed ore is discharged into the crushing and collecting outer box 5 from the filtering inner hole 15 and the filtering outer hole 14, and then a discharge port on the crushing and collecting outer box 5 is opened to discharge the screened ore.
The specific working process of the invention is described above, and the steps are repeated when the device is used next time.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides a from garrulous formula mechanical shock crushing sieving mechanism that draws, its characterized in that: the crushing and collecting device comprises a self-suction type deformation filtering component, a self-driving bouncing component, a supporting plate, a bottom plate, a crushing and collecting outer box and a gathering and scattering type crushing filtering barrel, wherein one end of the supporting plate is arranged on the bottom plate, a chute is arranged in the supporting plate, the self-suction type deformation filtering component is arranged in the chute, the self-driving bouncing component is arranged in the chute, and the self-driving bouncing component is connected with the self-suction type deformation filtering component; the crushing and collecting outer box is connected with the self-driven bouncing assembly, the gathering and scattering type crushing filter barrel is connected with the self-driven bouncing assembly, and the gathering and scattering type crushing filter barrel is arranged in the crushing and collecting outer box; the supporting plate is symmetrically arranged on the bottom plate by taking the central axis of the bottom plate as a symmetry axis, the self-suction type deformation filtering component is arranged on the supporting plate and symmetrically arranged, the self-suction type deformation filtering component comprises a self-suction type bag-shaped filtering piece, a first deformation spring, a second deformation spring and a connecting pipe, the upper end of the first deformation spring is connected with the upper wall of the chute, the lower end of the first deformation spring is connected with the upper end of the self-driven bouncing component, the lower end of the second deformation spring is connected with the bottom wall of the chute, the upper end of the second deformation spring is connected with the lower end of the self-driven bouncing component, the self-suction type bag-shaped filter element is respectively arranged in the first deformation spring and the second deformation spring, one end of the connecting pipe is communicated with the side wall of the crushing collection outer box, the other end of the connecting pipe is communicated with the self-suction bag-shaped filtering piece, and a filtering component is arranged in the connecting pipe.
2. The self-suction gathering and dispersing type mechanical vibration crushing and screening device as claimed in claim 1, wherein: the gathering and dispersing type crushing and filtering barrel comprises a gathering and dispersing type crushing and filtering receiving outer barrel and a gathering and dispersing type crushing and filtering receiving inner barrel, and the gathering and dispersing type crushing and filtering receiving inner barrel is arranged close to the inner side wall of the gathering and dispersing type crushing and filtering receiving outer barrel; the filtering device is characterized in that a filtering outer hole is formed in the collecting type crushing filtering and collecting outer barrel, the filtering outer hole penetrates through the collecting type crushing filtering and collecting outer barrel, a filtering inner hole is formed in the collecting type crushing filtering and collecting inner barrel, the filtering inner hole penetrates through the collecting type crushing filtering and collecting inner barrel, and the filtering inner hole is close to the filtering outer hole.
3. The self-suction gathering and dispersing type mechanical vibration crushing and screening device as claimed in claim 2, wherein: the collecting and dispersing type crushing filtration accepting inner barrel is internally provided with a temporary storage part III and an elastic sac-shaped part, the temporary storage part III is close to a filtration inner hole, a coil III is arranged in the temporary storage part III, the elastic sac-shaped part is connected with the temporary storage part III, an elastic extrusion protruding part is arranged on the inner side wall of the filtration inner hole, and the elastic sac-shaped part and the collecting and dispersing type crushing filtration accepting inner barrel are filled with non-Newtonian fluid.
4. The self-suction gathering and dispersing type mechanical vibration crushing and screening device as claimed in claim 3, wherein: self-driven bounce subassembly includes self-driven springboard, drive roller and eccentric driving piece, self-driven springboard activity joint is located in the spout, the upper end of self-driven springboard links to each other with the lower extreme of deformation with spring one, the lower extreme of self-driven springboard links to each other with the upper end of deformation with spring two, self-suction formula bag shape is filtered and is linked to each other with self-driven springboard, be equipped with the motor protecting crust on the self-driven springboard, be equipped with the motor in the motor protecting crust, the drive roller activity runs through the setting of self-driven springboard, the output shaft end of motor links to each other with the one end of drive roller, eccentric driving piece is eccentric to be located on the drive roller.
5. The self-suction gathering and dispersing type mechanical vibration crushing and screening device as claimed in claim 4, wherein: the self-driven springboard is characterized in that a first temporary storage cavity is arranged in the self-driven springboard, the first temporary storage cavity is arranged close to the inner side wall of the sliding chute, and a first coil is arranged in the first temporary storage cavity.
6. The self-suction gathering and dispersing type mechanical vibration crushing and screening device as claimed in claim 5, wherein: the coil temporary storage device is characterized in that a temporary storage cavity II is arranged in the supporting plate, the temporary storage cavity II is arranged close to the temporary storage cavity I, and a coil II is arranged in the temporary storage cavity II.
7. The self-suction gathering and dispersing type mechanical vibration crushing and screening device as claimed in claim 6, wherein: the crushing and collecting outer box is provided with an outlet and an inlet, the inlet penetrates through the gathering type crushing filter barrel, and the side wall of the crushing and collecting outer box is provided with a ring clamping groove.
8. The self-suction gathering and dispersing type mechanical vibration crushing and screening device as claimed in claim 7, wherein: the driving roller is provided with a connecting piece, and the crushing collecting outer box and the gathering type crushing filter barrel are connected with the driving roller through the connecting piece.
9. The self-pumping converging-diverging mechanical vibratory crushing screening device of claim 8, wherein: the broken outer container lateral wall activity of collecting is equipped with connects the loop forming element, connect the loop forming element activity and locate in the loop forming element draw-in groove, connect loop forming element and drive roller swing joint, go up the broken outer container lateral wall of collecting of loop forming element laminating and hold up the broken filter vat lateral wall setting of type that looses.
10. The self-pumping converging-diverging mechanical vibratory crushing screening device of claim 9, wherein: the connecting ring-shaped piece is provided with a communicating hole, and one end of the connecting pipe is communicated with the connecting ring-shaped piece.
CN202210874993.XA 2022-07-25 2022-07-25 From suction formula mechanical shock broken sieving mechanism that gathers scattered Pending CN115069530A (en)

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Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN203380077U (en) * 2013-06-24 2014-01-08 南京万德斯环保科技有限公司 Kitchen waste smashing and sorting device
CN108906601A (en) * 2018-08-29 2018-11-30 东至县雨庭畜禽有限公司 A kind of herding feed filter device
CN208482518U (en) * 2018-05-12 2019-02-12 宗源生态肥业有限公司 A kind of Organic Ingredients grinding device being used to prepare fertilizer
CN112058492A (en) * 2020-08-29 2020-12-11 彭龙香 Can arrange indisputable device to quartz sand rotation type of different density
CN112515189A (en) * 2020-12-03 2021-03-19 李晓锋 Peanut shelling device for agriculture
CN112827828A (en) * 2020-12-31 2021-05-25 新沂市永恒熔融石英有限公司 Quartz sand production is with high-efficient equipment of sieving
CN214555096U (en) * 2021-04-10 2021-11-02 浙江利源重工科技有限公司 Screening device for smelting process ingredients

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN203380077U (en) * 2013-06-24 2014-01-08 南京万德斯环保科技有限公司 Kitchen waste smashing and sorting device
CN208482518U (en) * 2018-05-12 2019-02-12 宗源生态肥业有限公司 A kind of Organic Ingredients grinding device being used to prepare fertilizer
CN108906601A (en) * 2018-08-29 2018-11-30 东至县雨庭畜禽有限公司 A kind of herding feed filter device
CN112058492A (en) * 2020-08-29 2020-12-11 彭龙香 Can arrange indisputable device to quartz sand rotation type of different density
CN112515189A (en) * 2020-12-03 2021-03-19 李晓锋 Peanut shelling device for agriculture
CN112827828A (en) * 2020-12-31 2021-05-25 新沂市永恒熔融石英有限公司 Quartz sand production is with high-efficient equipment of sieving
CN214555096U (en) * 2021-04-10 2021-11-02 浙江利源重工科技有限公司 Screening device for smelting process ingredients

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