CN109926130B

CN109926130B - Metal ore screening equipment

Info

Publication number: CN109926130B
Application number: CN201910267729.8A
Authority: CN
Inventors: 余欢欢
Original assignee: Suixi Jindi Mining Co ltd
Current assignee: Suixi Jindi Mining Co ltd
Priority date: 2019-04-03
Filing date: 2019-04-03
Publication date: 2021-05-25
Anticipated expiration: 2039-04-03
Also published as: CN109926130A

Abstract

The invention discloses metal ore screening equipment which comprises a screening machine shell, wherein a screening cavity is arranged in the screening machine shell, a screening mechanism is arranged in the screening cavity, the screening mechanism comprises a separating mechanism and a transferring mechanism, the separating mechanism comprises a separating shaft in the screening cavity and a separating fan blade fixedly arranged on the end wall at the top of the separating shaft, and a separating belt cavity is arranged in the end wall at the left side of the screening cavity; this equipment is more reasonable and ingenious on overall structure, it is all very convenient to install, maintain and overhaul, and this equipment can carry out preprocessing to the ore and handle, improve the machining efficiency that the ore follow-up processing was added, and will not contain the lower waste ore of metal and metal content and discharge, improve the screening efficiency of this equipment, and reduce the dust pollution of screening process, improve equipment life, and this equipment has efficient degree of automation in the use, higher use and spreading value have.

Description

Metal ore screening equipment

Technical Field

The invention relates to the field of mineral screening, in particular to metal ore screening equipment.

Background

The ore refers to a mineral aggregate from which useful components can be extracted or which has certain utilizable properties, and as society develops, the demand of metal products is increasing, so that the demand of the ore is increasing, and the metal ore is required to be screened to improve the quality of the ore.

The screening process of present ore is the ore to excavating mostly and directly screens, and the useless ore that wherein mix with is difficult for rejecting reduces the screening efficiency, and dust pollution easily appears in present screening process, influences operational environment, reduces the holistic life of ore sieve separator, is difficult to satisfy the user demand of market and mine operation.

Therefore, there is a need for further improvement of the prior art metal ore screening apparatus to improve the efficiency of metal ore screening.

Disclosure of Invention

The invention aims to provide metal ore screening equipment which can overcome the defects in the prior art and improve the metal ore screening efficiency.

The metal ore screening equipment comprises a screening machine shell, wherein a screening cavity is arranged in the screening machine shell, a screening mechanism is arranged in the screening cavity and comprises a separating mechanism and a transferring mechanism, the separating mechanism comprises a separating shaft in the screening cavity and a separating fan blade fixedly arranged on the end wall at the top of the separating shaft, a separating belt cavity is arranged in the end wall at the left side of the screening cavity, the separating shaft is rotatably arranged in the separating belt cavity, the separating fan blade is rotatably arranged in the screening cavity, the transferring mechanism comprises a transferring belt in the screening cavity and a transferring baffle plate fixedly arranged on the end wall at the outer side of the transferring belt, the transferring belt is fixedly arranged in the screening cavity, a power mechanism is arranged between the separating mechanism and the transferring mechanism and drives the separating mechanism to rotate and simultaneously drive the transferring mechanism to rotate, be provided with the metal ore chamber in the wall of screening chamber right side end, be provided with the waste ore chamber in the wall of metal ore chamber rear end, metal ore chamber bottom with screening chamber bottom intercommunication, waste ore chamber top with screening chamber top intercommunication, wherein, actuating mechanism includes main drive axle and main driving motor, be provided with the main power chamber in the wall of screening chamber left side end, the main drive axle rotate set up in the main power intracavity, main drive axle bottom end with fixed set up in main driving motor power in the end wall of main power chamber bottom is connected, it sieves the work of mechanism to be provided with a drive mechanism drive between screening mechanism and the actuating mechanism.

Specifically, a separation driven belt wheel is fixedly arranged on the outer side end wall of the separation shaft in the separation belt cavity, a comprehensive power distribution cavity is arranged in the right side end wall of the main power cavity, a separation power shaft extending up and down is rotatably arranged between the separation belt cavities in the comprehensive power distribution cavity, a separation driving belt wheel is fixedly arranged at the tail end of the top of the separation power shaft in the separation belt cavity, a separation power belt is rotatably arranged between the separation driving belt wheel and the separation driven belt wheel, a separation driving bevel gear is fixedly arranged at the tail end of the bottom of the separation power shaft in the comprehensive power distribution cavity, a rotating shaft extending front and back is rotatably arranged in the screening cavity, the tail end of the rear side of the rotating shaft is in power connection with the transfer belt, a transfer driven bevel gear is fixedly arranged at the tail end of the front side of the rotating shaft, and a comprehensive power separation shaft extending left and right is rotatably arranged, the screening intracavity be provided with synthesize the fixed initiative bevel gear that is provided with in power separation axle right side end, transport initiative bevel gear in transport driven bevel gear meshing, synthesize the power distribution intracavity synthesize the fixed power distribution bevel gear that is provided with on the power separation axle outside end wall, power distribution bevel gear with separation initiative bevel gear meshing, the drive power intracavity synthesize the fixed driven bevel gear that is provided with in power separation axle left side end, the drive power intracavity the fixed initiative bevel gear that synthesizes that is provided with on the main drive axle outside end wall, synthesize the initiative bevel gear in synthesize driven bevel gear meshing, screening chamber bottom end wall internal fixation is provided with strong magnet piece, is favorable to sieving and separating metal ore to two chambeies, the subsequent handling of being convenient for.

Preferably, the fixed stone belt that send that is provided with in screening casing top outside, screening casing top outside is rotated and is provided with the stone power shaft that send that extends around, send stone power shaft rear side terminal with send stone belt power connection, send the fixed driven bevel gear that send stone power shaft front side end to be provided with, the end extension of main drive axle top the main power chamber outside and the fixed stone drive bevel gear that send that is provided with in main drive axle top end, send stone drive bevel gear with send the driven bevel gear meshing of stone, be favorable to sending the ore into in the equipment.

Preferably, a crushing cavity is arranged in the end wall of the top of the screening cavity, the crushing cavity is communicated with the screening cavity, a crushing device is arranged in the crushing cavity, a static jaw is fixedly arranged on the end wall of the left side of the crushing cavity, a movable jaw is arranged on the right side of the crushing cavity in a left-right sliding manner, a crushing connecting rod extending left and right is arranged in the crushing cavity in a left-right sliding manner, the tail end of the left side of the crushing connecting rod is hinged with the end wall of the right side of the movable jaw, a crushing turntable is rotatably arranged in the crushing cavity, the tail end of the right side of the crushing connecting rod is hinged with the rear end wall of the crushing turntable, a crushing shaft extending front and back is rotatably arranged in the crushing cavity, the tail end of the rear side of the crushing shaft is fixedly connected with the crushing turntable, a crushing input bevel gear, drive breaker work is favorable to carrying out crushing treatment with the ore, is convenient for carry out screening treatment to the ore.

Specifically, a crushing power belt cavity is arranged in the end wall of the right side of the crushing cavity, a crushing input shaft extending leftwards and rightwards is rotatably arranged between the crushing cavity and the crushing power belt cavity, a crushing upper transmission bevel gear is fixedly arranged at the tail end of the left side of the crushing input shaft in the crushing cavity and meshed with the crushing input bevel gear, a crushing driven pulley is fixedly arranged at the tail end of the right side of the crushing input shaft in the crushing power belt cavity, a crushing power cavity is arranged in the end wall of the left side of the crushing power belt cavity, a crushing output shaft extending leftwards and rightwards is rotatably arranged between the crushing power cavity and the crushing power belt cavity, a crushing driving pulley is fixedly arranged at the tail end of the right side of the crushing output shaft in the crushing power belt cavity, and a crushing power belt is arranged between the crushing driving pulley and the crushing driven pulley in a, a crushing lower transmission bevel gear is fixedly arranged at the tail end of the left side of the crushing output shaft in the crushing power cavity, a power synchronous belt cavity is arranged in the end wall at the bottom of the crushing power cavity, a right synchronous power shaft extending up and down is rotatably arranged between the power synchronous belt cavity and the crushing power cavity, a crushing output bevel gear is fixedly arranged on the end wall at the outer side of the right synchronous power shaft in the crushing power cavity, the crushing output bevel gear is meshed with the crushing lower transmission bevel gear, a right synchronous belt pulley is fixedly arranged at the tail end of the bottom of the right synchronous power shaft in the power synchronous belt cavity, a left synchronous power shaft extending up and down is rotatably arranged between the comprehensive power distribution cavity and the power synchronous belt cavity, a left synchronous belt pulley is fixedly arranged at the tail end of the bottom of the left synchronous power shaft in the power synchronous belt cavity, the power synchronous belt is arranged between the left synchronous belt wheel and the right synchronous belt wheel in a transmission mode, a power synchronous bevel gear is fixedly arranged at the tail end of the top of the left synchronous power shaft in the comprehensive power distribution cavity and meshed with the power distribution bevel gear, and therefore the movable jaw can be driven to slide left and right to crush ores.

Preferably, be provided with in the broken power chamber top end wall and stir the chamber, stir the intracavity the terminal fixed carousel of stirring that is provided with in right side synchronous power shaft top, stir the intracavity swing and be provided with stir the pendulum rod, stir fixed being provided with on the pendulum rod bottom end wall and stir the brush, it is provided with to stir to slide on the pendulum rod outside end wall and stir the loop bar, stir loop bar bottom end with it is articulated to stir carousel top end wall, is favorable to constantly following the metal ore chamber top and dials the ore of selecting.

Specifically, the equipment is provided with front and back symmetrical conveying devices, the front and back conveying devices have the same function and similar structure, the front side is taken as an example for detailed description, a conveying power cavity is arranged in the end wall at the top of the crushing power cavity, a conveying driving bevel gear is fixedly arranged on the end wall at the outer side of the right synchronous power shaft in the conveying power cavity, a conveying power belt cavity is arranged in the front side end wall of the conveying power cavity, a conveying driving shaft extending forwards and backwards is rotatably arranged between the conveying power belt cavity and the conveying power cavity, a conveying driven bevel gear is fixedly arranged at the tail end at the rear side of the conveying driving shaft in the conveying power cavity, the conveying driven bevel gear is meshed with the conveying driving bevel gear, a conveying driving pulley is fixedly arranged at the tail end at the front side of the conveying driving shaft in the conveying power belt cavity, and a conveying cavity is arranged in the front, transport power belt chamber with rotate between the transportation chamber and be provided with the transportation power axle that extends around, transport power belt intracavity the terminal fixed transportation driven pulleys that is provided with in transportation power axle front side, transportation driven pulleys with the transmission is provided with the transportation power belt between the transportation driving pulley, transport intracavity transportation power axle front side terminal with fixed set up in transport belt power in the transportation intracavity is connected, be favorable to outside the ore delivery device with the screening.

The invention has the beneficial effects that: this equipment is more reasonable and ingenious on overall structure, it is all very convenient to install, maintain and overhaul, and this equipment can carry out preprocessing to the ore and handle, improve the machining efficiency that the ore follow-up processing was added, and will not contain the lower waste ore of metal and metal content and discharge, improve the screening efficiency of this equipment, and reduce the dust pollution of screening process, improve equipment life, and this equipment has efficient degree of automation in the use, higher use and spreading value have.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic view showing the overall construction of a metal ore screening apparatus of the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

fig. 3 is a schematic diagram of the structure B in fig. 1.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

Any feature disclosed in this specification (including any accompanying claims, abstract and drawings), may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc., indicate orientations or positional relationships based on those shown in fig. 1, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referenced device or element must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be considered as limiting the present invention.

As shown in fig. 1-3, the metal ore screening apparatus of the present invention includes a screening housing 114, a screening chamber 115 is disposed in the screening housing 114, a screening mechanism is disposed in the screening chamber 115, the screening mechanism includes a separating mechanism and a transferring mechanism, the separating mechanism includes a separating shaft 117 disposed in the screening chamber 115, and a separating fan 116 fixedly disposed on a top end wall of the separating shaft 117, a separating belt chamber 121 is disposed in a left end wall of the screening chamber 115, the separating shaft 117 is rotatably disposed in the separating belt chamber 121, and the separating fan 116 is rotatably disposed in the screening chamber 115, the transferring mechanism includes a transferring belt 145 disposed in the screening chamber 115, and a transferring baffle 146 fixedly disposed on an outer end wall of the transferring belt 145, the transferring belt 145 is fixedly disposed in the screening chamber 115, a power mechanism is arranged between the separating mechanism and the transferring mechanism to drive the separating mechanism to rotate and the transferring mechanism to rotate simultaneously, a metal ore cavity 149 is arranged in the end wall of the right side of the screening cavity 115, a waste ore cavity 177 is arranged in the end wall of the rear side of the metal ore cavity 149, the bottom of the metal ore cavity 149 is in communication with the bottom of the screening cavity 115, the top of the waste ore cavity 177 is in communication with the top of the screening cavity 115, wherein the driving mechanism comprises a main driving shaft 131 and a main driving motor 132, a main power cavity 127 is arranged in the left end wall of the screening cavity 115, the main driving shaft 131 is rotatably arranged in the main power cavity 127, the bottom end of the main driving shaft 131 is in power connection with a main driving motor 132 fixedly arranged in the bottom end wall of the main power cavity 127, and a transmission mechanism is arranged between the screening mechanism and the driving mechanism to drive the screening mechanism to work.

In the following, a specific implementation manner for implementing the operation of the sieving mechanism will be described in detail, wherein a separation driven pulley 118 is fixedly disposed on an outer side end wall of the separation shaft 117 in the separation belt cavity 121, a comprehensive power distribution cavity 136 is disposed in a right side end wall of the driving power cavity 127, the comprehensive power distribution cavity 136 is rotatably disposed between the separation belt cavities 121 and is provided with a separation driving shaft 122 extending up and down, a separation driving pulley 120 is fixedly disposed at a top end of the separation driving shaft 122 in the separation belt cavity 121, a separation power belt 119 is rotatably disposed between the separation driving pulley 120 and the separation driven pulley 118, a separation driving bevel gear 133 is fixedly disposed at a bottom end of the separation driving shaft 122 in the comprehensive power distribution cavity 136, a rotation shaft 144 extending up and down is rotatably disposed in the sieving cavity 115, and a rear end of the rotation shaft 144 is dynamically connected with the transfer belt 145, a transfer driven bevel gear 143 is fixedly arranged at the front end of the rotating shaft 144, a comprehensive power separating shaft 129 extending left and right is rotatably arranged between the comprehensive power distributing cavity 136 and the sieving cavity 115, a transfer driving bevel gear 142 is fixedly arranged at the right end of the comprehensive power separating shaft 129 arranged in the sieving cavity 115, the transfer driving bevel gear 142 is engaged with the transfer driven bevel gear 143, a power distributing bevel gear 134 is fixedly arranged on the outer side end wall of the comprehensive power separating shaft 129 in the comprehensive power distributing cavity 136, the power distributing bevel gear 134 is engaged with the separating driving bevel gear 133, a comprehensive driven bevel gear 128 is fixedly arranged at the left end of the comprehensive power separating shaft 129 in the driving cavity 127, and a comprehensive driving bevel gear 130 is fixedly arranged on the outer side end wall of the driving shaft 131 in the driving cavity 127, the integrated driving bevel gear 130 is engaged with the integrated driven bevel gear 128, and a strong magnet block 141 is fixedly arranged in the end wall of the bottom of the screening cavity 115, so that metal ores can be screened and separated into two cavities, and subsequent operation is facilitated.

Advantageously, the stone feeding mechanism of the present application is described in detail with reference to fig. 1, wherein a stone feeding belt 111 is fixedly disposed on the outer side of the top of the screening machine casing 114, a stone feeding power shaft 124 extending back and forth is rotatably disposed on the outer side of the top of the screening machine casing 114, the rear end of the stone feeding power shaft 124 is in power connection with the stone feeding belt 111, a stone feeding driven bevel gear 123 is fixedly disposed on the front end of the stone feeding power shaft 124, the top end of the main driving shaft 131 extends to the outer side of the main power chamber 127, a stone feeding driving bevel gear 125 is fixedly disposed on the top end of the main driving shaft 131, and the stone feeding driving bevel gear 125 is engaged with the stone feeding driven bevel gear 123 to facilitate feeding ore into the equipment.

Advantageously, the crushing device of the present application is described in detail with reference to fig. 1, wherein a crushing cavity 113 is disposed in an end wall at the top of the sieving cavity 115, the crushing cavity 113 is communicated with the sieving cavity 115, a crushing device is disposed in the crushing cavity 113, a stationary jaw 112 is fixedly disposed on an end wall at the left side of the crushing cavity 113, a movable jaw 169 is slidably disposed at the right side of the crushing cavity 113, a crushing link 168 extending left and right is slidably disposed at the left and right in the crushing cavity 113, a left end of the crushing link 168 is hinged to an end wall at the right side of the movable jaw 169, a crushing turntable 167 is rotatably disposed in the crushing cavity 113, a right end of the crushing link 168 is hinged to an end wall at the rear side of the crushing turntable 167, a crushing shaft 165 extending front and rear, a rear end of the crushing shaft 165 is fixedly connected to the crushing turntable 167, a crushing input bevel gear 166 is fixedly disposed at a front end of the crushing shaft 165, be provided with a broken drive mechanism between breaker and the actuating mechanism, the drive breaker work is favorable to carrying out crushing treatment with the ore, is convenient for carry out screening treatment to the ore.

Next, referring to fig. 1-2, a transmission mechanism of the crushing device will be described in detail, wherein a crushing power belt cavity 161 is disposed in a right end wall of the crushing cavity 113, a crushing input shaft 163 extending left and right is rotatably disposed between the crushing cavity 113 and the crushing power belt cavity 161, a crushing upper transmission bevel gear 164 is fixedly disposed at a left end of the crushing input shaft 163 in the crushing cavity 113, the crushing upper transmission bevel gear 164 is engaged with the crushing input bevel gear 166, a crushing driven pulley 162 is fixedly disposed at a right end of the crushing input shaft 163 in the crushing power belt cavity 161, a crushing power cavity 150 is disposed in a left end wall of the crushing power belt cavity 161, a crushing output shaft 154 extending left and right is rotatably disposed between the crushing power belt cavity 150 and the crushing power belt cavity 161, a crushing driving pulley 152 is fixedly disposed at a right end of the crushing output shaft 154 in the crushing power belt cavity 161 A crushing power belt 156 is arranged between the crushing driving pulley 152 and the crushing driven pulley 162 in a transmission manner, a crushing lower transmission bevel gear 151 is fixedly arranged at the tail end of the left side of the crushing output shaft 154 in the crushing power cavity 150, a power synchronization belt cavity 140 is arranged in the end wall of the bottom of the crushing power cavity 150, a right synchronization power shaft 148 extending up and down is rotatably arranged between the power synchronization belt cavity 140 and the crushing power cavity 150, a crushing output bevel gear 155 is fixedly arranged on the end wall of the outer side of the right synchronization power shaft 148 in the crushing power cavity 150, the crushing output bevel gear 155 is engaged with the crushing lower transmission bevel gear 151, a right synchronization pulley 147 is fixedly arranged at the tail end of the bottom of the right synchronization power shaft 148 in the power synchronization belt cavity 140, and a left synchronization power shaft 137 extending up and down is rotatably arranged between the comprehensive power distribution cavity 136 and the power synchronization belt cavity 140, a left synchronous belt wheel 138 is fixedly arranged at the tail end of the bottom of the left synchronous power shaft 137 in the power synchronous belt cavity 140, a power synchronous belt 139 is arranged between the left synchronous belt wheel 138 and the right synchronous belt wheel 147 in a transmission manner, a power synchronous bevel gear 135 is fixedly arranged at the tail end of the top of the left synchronous power shaft 137 in the comprehensive power distribution cavity 136, and the power synchronous bevel gear 135 is meshed with the power distribution bevel gear 134, so that the movable jaw 169 can be driven to slide left and right to crush ores.

Beneficially, the conveying mechanism of the present application is described in detail with reference to fig. 1 to fig. 3, wherein a shifting cavity 184 is disposed in a top end wall of the crushing power cavity 150, a shifting rotary table 180 is fixedly disposed at a top end of the right synchronous power shaft 148 in the shifting cavity 184, a shifting swing rod 181 is arranged in the shifting cavity 184 in a swinging manner, a shifting brush 183 is fixedly disposed on a bottom end wall of the shifting swing rod 181, a shifting sleeve rod 182 is slidably disposed on an outer side end wall of the shifting swing rod 181, and a bottom end of the shifting sleeve rod 182 is hinged to the top end wall of the shifting rotary table 180, so as to facilitate continuous shifting of the screened ore out from the top end of the metal ore cavity 149.

Next, referring to fig. 1-2, a transportation device of the transportation mechanism will be described in detail, wherein the apparatus is provided with a transportation device that is symmetrical in front and back, the transportation device has the same function and similar structure, and here, the front side is taken as an example for detailed description, a transportation power cavity 157 is arranged in the top end wall of the crushing power cavity 150, a transportation driving bevel gear 160 is fixedly arranged on the outer side end wall of the right synchronization power shaft 148 in the transportation power cavity 157, a transportation power belt cavity 171 is arranged in the front side end wall of the transportation power cavity 157, a transportation driving shaft 159 extending in front and back is rotatably arranged between the transportation power belt cavity 171 and the transportation power cavity 157, a transportation driven bevel gear 158 is fixedly arranged at the rear end of the transportation driving shaft 159 in the transportation power cavity 157, the transportation driven bevel gear 158 is engaged with the transportation driving bevel gear 160, transport in the power belt chamber 171 the end is fixed to be provided with the transportation driving pulley 170 at transportation driving shaft 159 front side, be provided with transportation chamber 176 in the end wall before transportation power belt chamber 171, transportation power belt chamber 171 with it is provided with the transportation power axle 174 of extending around to rotate between the transportation chamber 176, in the transportation power belt chamber 171 the end is fixed to be provided with the transportation driven pulley 173 at transportation power axle 174 front side, the transportation driven pulley 173 with the transmission is provided with transportation power belt 172 between the transportation driving pulley 170, in the transportation chamber 176 the transportation power axle 174 front side end with fixed set up in transportation belt 175 power connection in the transportation chamber 176 is favorable to sending out the ore of screening outside the equipment.

The applicant will now describe in detail the use of ore screening with reference to the accompanying figures 1 to 3 and the specific composition of a metal ore screening apparatus of the present application described above: firstly, in an initial state, the distance between the static jaw 112 and the movable jaw 169 is the smallest, the toggle swing link 181 is located at the rear side of the toggle cavity 184 to the maximum extent, and the power distribution bevel gear 134 is meshed with the separation drive bevel gear 133 and the power synchronization bevel gear 135;

when the device is used, the main driving motor 132 starts to work, the main driving motor 132 drives the main driving shaft 131 to rotate, the main driving shaft 131 drives the stone conveying driving bevel gear 125 to rotate, the stone conveying driving bevel gear 125 drives the stone conveying driven bevel gear 123 to rotate, the stone conveying driven bevel gear 123 drives the stone conveying power shaft 124 to rotate, the stone conveying power shaft 124 drives the stone conveying belt 111 to work, the stone conveying belt 111 conveys unscreened ore into the crushing cavity 113, the main driving shaft 131 drives the comprehensive driving bevel gear 130 to rotate, the comprehensive driving bevel gear 130 drives the comprehensive driven bevel gear 128 to rotate, the comprehensive driven bevel gear 128 drives the comprehensive power separating shaft 129 to rotate, the comprehensive power separating shaft 129 drives the power distributing bevel gear 134 to rotate, and the power distributing bevel gear 134 drives the power synchronizing bevel gear 135 to rotate, the power synchronization bevel gear 135 drives the left synchronization power shaft 137 to rotate, the left synchronization pulley 138 to drive the right synchronization pulley 147 to rotate, the right synchronization pulley 147 to drive the right synchronization power shaft 148 to rotate, the right synchronization power shaft 148 to drive the crushing output bevel gear 155 to rotate, the crushing lower transmission bevel gear 151 to rotate, the crushing output shaft 154 to rotate, the crushing driving pulley 152 to rotate, the crushing driven pulley 162 to rotate, the crushing input shaft 163 to rotate, the crushing upper transmission bevel gear 164 to rotate, the crushing input bevel gear 166 to rotate, the crushing input bevel gear 166 drives the crushing shaft 165 to rotate, the crushing shaft 165 drives the crushing turntable 167 to rotate, the crushing turntable 167 drives the crushing connecting rod 168 to slide back and forth, the crushing connecting rod 168 drives the movable jaw 169 to slide left and right, the distance between the movable jaw 169 and the static jaw 112 is constantly changed to crush ores, the crushed ores enter the sieving cavity 115, ores containing metal are downward slid under the action of the strong magnet block 141, meanwhile, the power distribution bevel gear 134 drives the separation driving bevel gear 133 to rotate, the separation driving bevel gear 133 drives the separation driving shaft 122 to rotate, the separation driving shaft 122 drives the separation driving pulley 120 to rotate, the separation driving pulley 120 drives the separation driven pulley 118 to rotate, and the separation driven pulley 118 drives the separation shaft 117 to rotate, the separation shaft 117 drives the separation fan blade 116 to rotate, the separation fan blade 116 separates metal-free ores from the downward sliding process of the metal ores, the metal ores fall onto the transfer belt 145, meanwhile, the comprehensive power separation shaft 129 drives the transfer drive bevel gear 142 to rotate, the transfer drive bevel gear 142 drives the transfer driven bevel gear 143 to rotate, the transfer driven bevel gear 143 drives the rotation shaft 144 to rotate, the rotation shaft 144 drives the transfer belt 145 to rotate, the transfer belt 145 drives the transfer baffle 146 to slide, the transfer baffle 146 sends the metal ores falling onto the transfer belt 145 into the metal ore cavity 149, the metal ores in the metal ore cavity 149 slide upwards to the top, and meanwhile, the right synchronous power shaft 148 drives the rotary disk 180 to rotate, the toggle rotary table 180 drives the toggle sleeve rod 182 to rotate circumferentially, the toggle sleeve rod 182 drives the toggle swing rod 181 to swing back and forth, so as to toggle the metal ore at the top of the metal ore cavity 149 to the outside of the metal ore cavity 149, the metal ore falls onto the conveying belt 175 in the conveying cavity 176, at the same time, the right synchronization power shaft 148 drives the transport drive bevel gear 160 to rotate, the transport driving bevel gear 160 drives the transport driven bevel gear 158 to rotate, the transport driven bevel gear 158 drives the transport driving shaft 159 to rotate, the transport driving shaft 159 rotates the transport driving pulley 170, the transport driving pulley 170 rotates the transport driven pulley 173, the transportation driven pulley 173 drives the transportation power shaft 174 to rotate, the transportation power shaft 174 drives the transportation belt 175 to rotate, and the transportation belt 175 conveys the screened metal ore out of the equipment.

From the above detailed analysis it can be seen that: because the distance between the static jaw and the movable jaw is continuously changed, the ore is crushed and preprocessed, and meanwhile, the separation fan blades are continuously rotated to separate the waste ore and the metal ore clamped in the gliding process, so that the screening efficiency of the device is improved.

Therefore, the method is more reasonable and ingenious in overall structure, installation, maintenance and overhaul are all very convenient, the equipment can be used for preprocessing the ore, the processing efficiency of subsequent processing of the ore is improved, waste ore which does not contain metal and has lower metal content is discharged, the screening efficiency of the equipment is improved, the dust pollution in the screening process is reduced, the service life of the equipment is prolonged, the equipment has high-efficiency automation degree in the using process, and high use and popularization values are achieved.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a metal ore screening equipment, includes the screening casing, be provided with screening chamber in the screening casing, its characterized in that: the screening mechanism is arranged in the screening cavity and comprises a separating mechanism and a transferring mechanism, the separating mechanism comprises a separating shaft in the screening cavity and a separating fan blade fixedly arranged on the end wall at the top of the separating shaft, a separating belt cavity is arranged in the end wall at the left side of the screening cavity, the separating shaft is rotatably arranged in the separating belt cavity, the separating fan blade is rotatably arranged in the screening cavity, the transferring mechanism comprises a transferring belt in the screening cavity and a transferring baffle fixedly arranged on the end wall at the outer side of the transferring belt, the transferring belt is fixedly arranged in the screening cavity, a power mechanism is arranged between the separating mechanism and the transferring mechanism to drive the separating mechanism to rotate and drive the transferring mechanism to rotate, a metal ore cavity is arranged in the end wall at the right side of the screening cavity, a waste ore cavity is arranged in the rear end wall of the metal ore cavity, the bottom of the metal ore cavity is communicated with the bottom of the screening cavity, the top of the waste ore cavity is communicated with the top of the screening cavity, the driving mechanism comprises a main driving shaft and a main driving motor, a main power cavity is arranged in the left end wall of the screening cavity, the main driving shaft is rotatably arranged in the main power cavity, the bottom end of the main driving shaft is in power connection with the main driving motor fixedly arranged in the bottom end wall of the main power cavity, and a transmission mechanism is arranged between the screening mechanism and the driving mechanism to drive the screening mechanism to work; wherein, a separation driven belt wheel is fixedly arranged on the outer end wall of the separation shaft in the separation belt cavity, a comprehensive power distribution cavity is arranged in the right end wall of the main power cavity, a separation power shaft extending from top to bottom is rotatably arranged between the separation belt cavities in the comprehensive power distribution cavity, a separation driving belt wheel is fixedly arranged at the tail end of the top of the separation power shaft in the separation belt cavity, a separation power belt is rotatably arranged between the separation driving belt wheel and the separation driven belt wheel, a separation driving bevel gear is fixedly arranged at the tail end of the bottom of the separation power shaft in the comprehensive power distribution cavity, a rotating shaft extending from front to back is rotatably arranged in the screening cavity, the tail end of the rear side of the rotating shaft is in power connection with the transfer belt, a transfer driven bevel gear is fixedly arranged at the tail end of the front side of the rotating shaft, and a comprehensive power separation shaft extending from left to right is, a transfer driving bevel gear is fixedly arranged at the tail end of the right side of the comprehensive power separation shaft arranged in the screening cavity, the transfer driving bevel gear is meshed with the transfer driven bevel gear, a power distribution bevel gear is fixedly arranged on the end wall of the outer side of the comprehensive power separation shaft in the comprehensive power distribution cavity, the power distribution bevel gear is meshed with the separation driving bevel gear, a comprehensive driven bevel gear is fixedly arranged at the tail end of the left side of the comprehensive power separation shaft in the driving power cavity, a comprehensive driving bevel gear is fixedly arranged on the end wall of the outer side of the driving shaft in the driving power cavity, the comprehensive driving bevel gear is meshed with the comprehensive driven bevel gear, and a strong magnet block is fixedly arranged in the end wall of the bottom of the screening cavity, so that metal ores can be screened and separated into two cavities, and subsequent; a stone conveying belt is fixedly arranged on the outer side of the top of the screening machine shell, a stone conveying power shaft extending forwards and backwards is rotatably arranged on the outer side of the top of the screening machine shell, the tail end of the rear side of the stone conveying power shaft is in power connection with the stone conveying belt, a stone conveying driven bevel gear is fixedly arranged at the tail end of the front side of the stone conveying power shaft, the tail end of the top of the main driving shaft extends to the outer side of the main power cavity, a stone conveying driving bevel gear is fixedly arranged at the tail end of the top of the main driving shaft, the stone conveying driving bevel gear is meshed with the stone conveying driven bevel gear, and ore is; a crushing cavity is arranged in the end wall at the top of the screening cavity and is communicated with the screening cavity, a crushing device is arranged in the crushing cavity, a static jaw is fixedly arranged on the end wall at the left side of the crushing cavity, a movable jaw is arranged at the right side of the crushing cavity in a left-right sliding manner, a crushing connecting rod extending left and right is arranged in the crushing cavity in a left-right sliding manner, the tail end at the left side of the crushing connecting rod is hinged with the end wall at the right side of the movable jaw, a crushing rotary disc is rotatably arranged in the crushing cavity, the tail end at the right side of the crushing connecting rod is hinged with the rear end wall of the crushing rotary disc, a crushing shaft extending front and back is rotatably arranged in the crushing cavity, the tail end at the rear side of the crushing shaft is fixedly connected with the crushing rotary disc, a crushing input bevel gear is fixedly arranged at the, the ore can be crushed and screened conveniently; a crushing power belt cavity is arranged in the end wall of the right side of the crushing cavity, a crushing input shaft extending leftwards and rightwards is rotatably arranged between the crushing cavity and the crushing power belt cavity, a crushing upper transmission bevel gear is fixedly arranged at the tail end of the left side of the crushing input shaft in the crushing cavity and is meshed with the crushing input bevel gear, a crushing driven pulley is fixedly arranged at the tail end of the right side of the crushing input shaft in the crushing power belt cavity, a crushing power cavity is arranged in the end wall of the left side of the crushing power belt cavity, a crushing output shaft extending leftwards and rightwards is rotatably arranged between the crushing power cavity and the crushing power belt cavity, a crushing driving pulley is fixedly arranged at the tail end of the right side of the crushing output shaft in the crushing power belt cavity, and a crushing power belt is arranged between the crushing driving pulley and the crushing driven pulley, a crushing lower transmission bevel gear is fixedly arranged at the tail end of the left side of the crushing output shaft in the crushing power cavity, a power synchronous belt cavity is arranged in the end wall at the bottom of the crushing power cavity, a right synchronous power shaft extending up and down is rotatably arranged between the power synchronous belt cavity and the crushing power cavity, a crushing output bevel gear is fixedly arranged on the end wall at the outer side of the right synchronous power shaft in the crushing power cavity, the crushing output bevel gear is meshed with the crushing lower transmission bevel gear, a right synchronous belt pulley is fixedly arranged at the tail end of the bottom of the right synchronous power shaft in the power synchronous belt cavity, a left synchronous power shaft extending up and down is rotatably arranged between the comprehensive power distribution cavity and the power synchronous belt cavity, a left synchronous belt pulley is fixedly arranged at the tail end of the bottom of the left synchronous power shaft in the power synchronous belt cavity, a power synchronous belt is arranged between the left synchronous belt wheel and the right synchronous belt wheel in a transmission manner, a power synchronous bevel gear is fixedly arranged at the tail end of the top of the left synchronous power shaft in the comprehensive power distribution cavity, and the power synchronous bevel gear is meshed with the power distribution bevel gear, so that the movable jaw can be driven to slide left and right to crush ores; a stirring cavity is arranged in the end wall of the top of the crushing power cavity, a stirring turntable is fixedly arranged at the tail end of the top of the right synchronous power shaft in the stirring cavity, a stirring swing rod is arranged in the stirring cavity in a swinging mode, a stirring brush is fixedly arranged on the end wall of the bottom of the stirring swing rod, a stirring loop bar is slidably arranged on the end wall of the outer side of the stirring swing rod, and the tail end of the bottom of the stirring loop bar is hinged with the end wall of the top of the stirring turntable, so that screened ore can be continuously stirred out from the top end of; wherein, the device is provided with a front and a back symmetrical transportation device, the front and the back transportation devices have the same function and similar structure, the front side is taken as an example for detailed description, a transportation power cavity is arranged in the end wall at the top of the crushing power cavity, a transportation driving bevel gear is fixedly arranged on the end wall at the outer side of the right synchronous power shaft in the transportation power cavity, a transportation power belt cavity is arranged in the front side end wall of the transportation power cavity, a transportation driving shaft extending forwards and backwards is rotatably arranged between the transportation power belt cavity and the transportation power cavity, a transportation driven bevel gear is fixedly arranged at the tail end at the back side of the transportation driving shaft in the transportation power cavity, the transportation driven bevel gear is meshed with the transportation driving bevel gear, a transportation driving pulley is fixedly arranged at the tail end at the front side of the transportation driving shaft in the transportation power belt cavity, a transportation cavity is arranged, transport power belt chamber with rotate between the transportation chamber and be provided with the transportation power axle that extends around, transport power belt intracavity the terminal fixed transportation driven pulleys that is provided with in transportation power axle front side, transportation driven pulleys with the transmission is provided with the transportation power belt between the transportation driving pulley, transport intracavity transportation power axle front side terminal with fixed set up in transport belt power in the transportation intracavity is connected, be favorable to outside the ore delivery device with the screening.