CN214638094U

CN214638094U - Large-scale heavy metal particle ore dressing machine

Info

Publication number: CN214638094U
Application number: CN202120541948.3U
Authority: CN
Inventors: 李细国
Original assignee: Chenzhou Dongzhuo Mining Equipment Co ltd
Current assignee: Chenzhou Dongzhuo Mining Equipment Co ltd
Priority date: 2021-03-16
Filing date: 2021-03-16
Publication date: 2021-11-09
Anticipated expiration: 2031-03-16

Abstract

The utility model discloses a large-scale heavy metal particle ore dressing machine, which comprises an ore dressing table and a driving device, wherein the ore dressing table comprises a ladder-shaped bearing table and a water cavity which are formed by fixedly connecting at least two ore bearing nets, and the ladder-shaped bearing table is fixed on the upper part of the water cavity; the tail end of the ladder-shaped bearing table is provided with a discharging device; the discharging device comprises a flow distribution plate, a refined material outlet and a waste material outlet, and the top of the water cavity is open and fixed at the bottom of the ladder-shaped bearing table; two side walls of the water cavity are respectively provided with a compression hole corresponding to the ore bearing net; a spherical drum membrane for sealing the compression hole is arranged outside the compression hole and is fixedly connected with the outer wall of the compression hole in a sealing way; the driving device comprises a motor, a transmission device, a driven shaft, a linkage shaft, an eccentric wheel and a linkage rod, and the transmission device is in transmission connection with an output shaft of the motor; the driven shafts are respectively arranged on two sides of the water cavity and are in transmission connection with the transmission device; the linkage shaft is arranged on the outer side of the tympanic membrane and is in transmission connection with the driven shaft; two ends of the linkage rod are respectively connected with the tympanic membrane and the eccentric wheel.

Description

Large-scale heavy metal particle ore dressing machine

Technical Field

The utility model relates to a mining equipment especially relates to a large-scale heavy metal particle ore dressing machine.

Background

At present, in the mine production, a vibration concentrator is generally adopted to carry out layered screening on ores for heavy metal beneficiation. Because the vibration ore dressing machine adopts vibration to push the ore to be screened in a layering way, the speed is low, the production efficiency is low, and the ore dressing amount is small.

Secondly, because the ore is screened by the vibration concentrating machine in a layered way, a large amount of dust is difficult to collect, the environment is polluted, and the health of people is damaged.

And thirdly, the ore is screened in a layered mode by adopting the vibration concentrating machine, and rigid vibration is generated by hammering or impacting by using the motor as a vibration source, so that the energy consumption is high, parts are easy to damage, and the maintenance cost is high.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a large-scale heavy metal particle ore dressing machine of convenient to use, ore dressing volume are big, the energy consumption is little efficient, long service life, no dust produces.

In order to solve the technical problem, the utility model discloses a large-scale heavy metal particle ore dressing machine, including ore dressing platform and drive arrangement, the ore dressing platform includes echelonment plummer and water cavity that is formed by at least two ore bearing net fixed connection, the echelonment plummer is fixed in water cavity upper portion and is used for bearing the alternative ore; the tail end of the ladder-shaped bearing table is provided with a discharging device; the discharging device comprises a splitter plate, a refined material outlet and a waste material outlet, the splitter plate is fixed above the tail end of the ladder-shaped bearing table, a gap is formed between the front end of the splitter plate and the ladder-shaped bearing table, the top of the rear end of the splitter plate is communicated with the waste material outlet, and the bottom of the splitter plate is communicated with the refined material outlet; the top of the water cavity is open and is fixed at the bottom of the ladder-shaped bearing platform; two side walls of the water cavity are respectively provided with a compression hole corresponding to the ore bearing net; a spherical drum membrane for sealing the compression hole is arranged outside the compression hole and is fixedly connected with the outer wall of the compression hole in a sealing way; the driving device comprises a motor, a transmission device, a driven shaft, a linkage shaft, an eccentric wheel and a linkage rod, wherein the motor and the transmission device are arranged below the water cavity, and the transmission device is in transmission connection with an output shaft of the motor; the driven shafts are respectively arranged on two sides of the water cavity and are in transmission connection with the transmission device; the linkage shaft is arranged on the outer side of the tympanic membrane and is in transmission connection with the driven shaft; the eccentric wheel corresponds to the eardrum and is fixedly connected with the linkage shaft; and two ends of the linkage rod are respectively connected with the tympanic membrane and the eccentric wheel.

And a spoiler is arranged at the tail end of the ore bearing net.

An adjusting device is further arranged above the flow distribution plate and comprises a fixed rod and an adjusting rod, and the fixed rod is provided with a fixed hole and is fixed above the flow distribution plate; the lower end of the adjusting rod is fixedly connected with the flow distribution plate, the upper end of the adjusting rod is provided with threads and penetrates through a fixing hole of the fixing rod to be in threaded connection with the nut, and the adjusting rod is used for screwing the nut to enable the flow distribution plate to ascend or descend.

The flow distribution plate is provided with an observation hole.

The water cavity is also internally provided with a clapboard which is corresponding to the ore bearing net to separate the water cavity into at least two water distributing cavities.

And a pressurizing plate is also arranged in the water dividing cavity and divides the water dividing cavity into pressurizing cavities with communicated bottoms.

Divide the chamber bottom lateral wall to be equipped with the scum hole, divide the intracavity inner bottom to be equipped with the guide way, the export and the scum hole intercommunication of guide way.

The water supply device also comprises a water supply pipe, wherein the outlet of the water supply pipe is respectively arranged at the bottom of the water distribution cavity, and the inlet of the water supply pipe is communicated with a water source through a valve or a high-pressure pump.

The transmission device is an automobile rear axle.

The ore carrying net is 2-6 blocks.

Adopt the utility model discloses a structure, owing to including ore dressing platform and drive arrangement, the ore dressing platform includes echelonment plummer and the water cavity that is formed by two piece at least ore bearing net fixed connection, during the use, the ore passes through the initiating terminal of the echelonment plummer that conveying equipment carried to, the water in the water cavity is extruded in succession to drive arrangement drive spherical tympanic membrane, water production negative pressure promotes the ore and removes to the end of echelonment plummer, the ore carries out the layering under the effect of gravity at the removal in-process ore, it comes to pass through discharging device's flow distribution plate outflow at last, high durability and convenient use, the ore dressing volume is big and the energy consumption is little, high efficiency. Because the negative pressure generated by adopting water pushes the ores to move to the tail end of the step-shaped bearing table, the bearing table has no rigid vibration, long service life and no dust, protects the environment and maintains the health of people.

And because the spoiler is arranged at the tail end of the ore bearing net, the phenomenon that the ore moves too fast is effectively prevented, the ore layering effect is better, namely, the ore dressing effect is better, the ore dressing efficiency is higher, and the use is more convenient.

The adjusting device is also arranged above the flow distribution plate and comprises a fixed rod and an adjusting rod, and the fixed rod is provided with a fixed hole and is fixed above the flow distribution plate; adjust pole lower extreme and flow distribution plate fixed connection, upper end and be equipped with the screw thread and pass the fixed orifices and the nut threaded connection of dead lever for twist and move the nut and make the flow distribution plate rise or descend, so that can adjust the flow distribution plate better, can adjust the ore reposition of redundant personnel better, the operation is simpler, and it is more convenient to use.

Because the flow distribution plate is provided with the observation hole, the flowing condition of the ore after the flow distribution can be directly observed, and the use is more convenient.

Because the water cavity still is equipped with the baffle, the baffle corresponds the ore bearing net and keeps apart into two at least branch water cavity with the water cavity, and drive arrangement drive spherical tympanic membrane extrudees the water of dividing the water cavity in succession and can make the aquatic of dividing the water cavity produce the negative pressure better to make better promotion ore remove to the end of echelonment plummer, ore layering efficiency is higher promptly, and ore dressing efficiency is higher, and it is more convenient to use.

Because the intracavity that divides water still is equipped with the pressure boost board, the pressure boost board will divide the water cavity to separate into the pressure boost chamber that the bottom is linked together, and drive arrangement drive spherical tympanic membrane extrudees the hydroenergy in the pressure boost intracavity in succession and makes the aquatic of pressure boost intracavity generate the negative pressure better to make better promotion ore remove to the end of echelonment plummer, ore layering efficiency is higher promptly, and ore dressing efficiency is higher, and it is more convenient to use.

And because the side wall of the bottom of the water diversion cavity is provided with the slag discharge port, the inner bottom of the water diversion cavity is provided with the guide groove, and the outlet of the guide groove is communicated with the slag discharge port, when the device is used, dust or microparticles adhered to the surface of large-grained ore enter the water diversion cavity along with negative pressure water and are deposited, and the deposited ore dust or microparticles are discharged through the slag discharge port for treatment, so that the device is simpler to clean the water diversion cavity and more convenient to use.

Because still include the moisturizing pipe, the moisturizing pipe export is arranged in respectively and is divided the chamber bottom, the entry passes through valve or high-pressure pump and water source intercommunication, when the surface of water of dividing the chamber is less than branch chamber upper portion, ore bearing net bottom, utilize the moisturizing pipe to supply, the hydroenergy of dividing the intracavity makes the aquatic products of dividing the intracavity better produce the negative pressure to make better promotion ore remove to the end of echelonment plummer, ore layering efficiency is higher promptly, ore dressing efficiency is higher, it is more convenient to use.

Drawings

FIG. 1 is a schematic front view of the structure of the present invention;

FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1;

FIG. 3 is a cross-sectional view taken along line B-B of FIG. 1;

fig. 4 is a cross-sectional view taken along line C-C of fig. 3.

Detailed Description

The invention is described in detail below with reference to the following drawings and embodiments:

as shown in fig. 1, fig. 2, fig. 3 and fig. 4, the utility model discloses a large-scale heavy metal particle ore dressing machine, including ore dressing platform and drive arrangement. The mineral processing platform comprises a step-shaped bearing platform and a water cavity which are formed by fixedly connecting at least two ore bearing nets 14. The preferred range of values for the ore carrying net 14 is 2-6, preferably 4. The ladder-shaped bearing platform is fixed on the upper part of the water cavity and used for bearing the alternative ore. The tail end of the ladder-shaped bearing table is provided with a discharging device. The discharging device comprises a flow distribution plate 10, a concentrate outlet 2 and a waste outlet 1. The flow distribution plate 10 is fixed above the tail end of the ladder-shaped bearing table, a gap is formed between the front end of the flow distribution plate 10 and the ladder-shaped bearing table, the top of the rear end of the flow distribution plate 10 is communicated with the waste outlet 1, and the bottom of the flow distribution plate is communicated with the fine material outlet 2. The top of the water cavity is open and is fixed at the bottom of the ladder-shaped bearing platform. The two side walls of the water cavity are respectively provided with a compression hole corresponding to the ore bearing net 14. The outer side of the compression hole is provided with a spherical drum membrane 3 for sealing the compression hole, and the drum membrane 3 is fixedly connected with the outer wall of the compression hole in a sealing way. The spherical tympanic membrane 3 can be made of rubber material, and can also be made of other composite materials with the function of rubber material. The driving device comprises a motor 6, a transmission device 12, a driven shaft 5, a linkage shaft 4, an eccentric wheel 13 and a linkage rod 11. The motor 6 and the transmission device 12 are arranged below the water cavity. The transmission device 12 is in transmission connection with an output shaft of the motor 6. The transmission 12 is preferably a rear axle of a vehicle. The driven shafts 5 are respectively arranged at two sides of the water cavity and are in transmission connection with the transmission device. The driven shaft 5 and the transmission may adopt, for example: the transmission shaft is matched with the connector for transmission connection or is in transmission connection through a synchronous wheel and a synchronous belt or is in transmission connection through a chain and a chain wheel. The linkage shaft 4 is arranged on the outer side of the tympanic membrane 3 and is in transmission connection with the driven shaft 5. The driving connection of the linkage shaft 4 and the driven shaft 5 can be as follows: the transmission shaft is matched with the connector for transmission connection or is in transmission connection through a synchronous wheel and a synchronous belt or is in transmission connection through a chain and a chain wheel. The eccentric wheel 13 corresponds to the tympanic membrane 3 and is fixedly connected with the linkage shaft 4. Two ends of the linkage rod 11 are respectively connected with the tympanic membrane 3 and the eccentric wheel 13.

In order to effectively prevent the ore from moving too fast, the ore layering effect is better, and the ore dressing effect is better promptly, and the ore dressing efficiency is higher, and it is more convenient to use, the tail end of ore bearing net 14 is equipped with spoiler 20.

In order to better adjust ore diversion, the operation is simpler, the use is more convenient, and an adjusting device is arranged above the diversion plate 10. The adjusting device comprises a fixed rod 7 and an adjusting rod 9. The fixing rod 7 is provided with a fixing hole and fixed above the flow distribution plate 10. The lower end of the adjusting rod 9 is fixedly connected with the flow distribution plate 10, the upper end of the adjusting rod is provided with threads and penetrates through a fixing hole of the fixing rod 7 to be in threaded connection with a nut, and the adjusting rod is used for screwing the nut to enable the flow distribution plate 10 to ascend or descend.

In order to directly observe the flowing condition of the ore after the flow division and to be more convenient to use, the flow dividing plate 10 is provided with an observation hole 8.

For the ore layering efficiency is higher, ore dressing efficiency is higher, and it is more convenient to use, still be equipped with baffle 21 in the water cavity. The partition plate 21 divides the water cavity into at least two water dividing cavities corresponding to the ore bearing net 14. The water in the water diversion cavity can be better generated by the driving device driving the spherical tympanic membrane to continuously extrude the water in the water diversion cavity, so that the ore is better pushed to move towards the tail end of the stepped bearing platform, namely, the ore layering efficiency is higher, the ore dressing efficiency is higher, and the use is more convenient.

For ore layering efficiency is higher, ore dressing efficiency is higher, and it is more convenient to use, still be equipped with pressure boost plate 15 in the branch water intracavity. The pressurizing plate 15 divides the water dividing cavity into pressurizing cavities 19 with communicated bottoms. The hydroenergy that drive arrangement drive spherical tympanic membrane continuous extrusion pressure boost intracavity makes the aquatic products production negative pressure in the pressure boost intracavity better to make better promotion ore remove to the end of echelonment plummer, ore layering efficiency is higher promptly, and ore dressing efficiency is higher, and it is more convenient to use.

In order to clean the water distribution cavity, the operation is simpler, the use is more convenient, and the side wall of the bottom of the water distribution cavity is provided with a slag discharge port 17. The inner bottom of the water diversion cavity is provided with a guide groove 16. The outlet of the guide groove 16 is communicated with a slag discharge port 17. The dust or microparticles adhered to the surface of the large-particle ore enter the water diversion cavity along with the negative pressure water and are deposited, the deposited ore dust or microparticles are discharged through the slag discharge port for treatment, and the water diversion cavity is simpler to clean and more convenient to use.

In order to improve the ore layering efficiency, the ore dressing efficiency and the use convenience, the ore dressing device also comprises a water replenishing pipe 18. The outlet of the water replenishing pipe 18 is respectively arranged at the bottom of the water distributing cavity, and the inlet is communicated with a water source through a valve or a high-pressure pump. When the surface of water of dividing the water cavity is less than dividing water cavity upper portion, ore bearing net bottom, utilize the moisturizing pipe to supply, the hydroenergy of dividing the water cavity makes the aquatic of dividing the water cavity produce the negative pressure better to make better promotion ore remove to the end of echelonment plummer, ore layering efficiency is higher promptly, and ore dressing efficiency is higher, and it is more convenient to use.

Claims

1. A large-scale heavy metal particle ore dressing machine is characterized in that: comprises a mineral processing platform and a driving device, wherein the mineral processing platform comprises a step-shaped bearing platform and a water cavity which are formed by fixedly connecting at least two ore bearing nets (14),

the ladder-shaped bearing table is fixed at the upper part of the water cavity and used for bearing alternative ores; the tail end of the ladder-shaped bearing table is provided with a discharging device;

the discharging device comprises a splitter plate (10), a refined material outlet (2) and a waste material outlet (1), the splitter plate (10) is fixed above the tail end of the ladder-shaped bearing table, a gap is formed between the front end of the splitter plate (10) and the ladder-shaped bearing table, the top of the rear end of the splitter plate (10) is communicated with the waste material outlet (1), and the bottom of the rear end of the splitter plate (10) is communicated with the refined material outlet (2);

the top of the water cavity is open and is fixed at the bottom of the ladder-shaped bearing platform; two side walls of the water cavity are respectively provided with a compression hole corresponding to the ore bearing net (14); a spherical drum membrane (3) for sealing the compression hole is arranged outside the compression hole, and the drum membrane (3) is fixedly connected with the outer wall of the compression hole in a sealing way;

the driving device comprises a motor (6), a transmission device (12), a driven shaft (5), a linkage shaft (4), an eccentric wheel (13) and a linkage rod (11), the motor (6) and the transmission device (12) are arranged below the water cavity, and the transmission device (12) is in transmission connection with an output shaft of the motor (6); the driven shafts (5) are respectively arranged on two sides of the water cavity and are in transmission connection with the transmission device; the linkage shaft (4) is arranged on the outer side of the tympanic membrane (3) and is in transmission connection with the driven shaft (5); the eccentric wheel (13) corresponds to the tympanic membrane (3) and is fixedly connected with the linkage shaft (4); two ends of the linkage rod (11) are respectively connected with the tympanic membrane (3) and the eccentric wheel (13).

2. A large heavy metal particle ore separator according to claim 1, wherein: the tail end of the ore bearing net (14) is provided with a spoiler (20).

3. A large heavy metal particle ore separator according to claim 1, wherein: an adjusting device is further arranged above the flow distribution plate (10), the adjusting device comprises a fixed rod (7) and an adjusting rod (9), and the fixed rod (7) is provided with a fixed hole and is fixed above the flow distribution plate (10); the lower end of the adjusting rod (9) is fixedly connected with the flow distribution plate (10), the upper end of the adjusting rod is provided with threads and penetrates through a fixing hole of the fixing rod (7) to be in threaded connection with a nut, and the adjusting rod is used for screwing the nut to enable the flow distribution plate (10) to ascend or descend.

4. A large heavy metal particle ore separator according to claim 1, 2 or 3, wherein: the flow distribution plate (10) is provided with an observation hole (8).

5. A large heavy metal particle ore separator according to claim 1, wherein: still be equipped with baffle (21) in the water cavity, baffle (21) correspond ore bearing net (14) and keep apart into two at least minute water cavity with the water cavity.

6. A large heavy metal particle ore separator according to claim 5, wherein: and a pressurizing plate (15) is also arranged in the water distribution cavity, and the water distribution cavity is divided into pressurizing cavities (19) with communicated bottoms by the pressurizing plate (15).

7. A large heavy metal particle ore separator according to claim 5 or 6, wherein: divide the chamber bottom lateral wall to be equipped with row cinder notch (17), divide the intracavity bottom to be equipped with guide way (16), the export and the row cinder notch (17) intercommunication of guide way (16).

8. A large heavy metal particle ore separator according to claim 5 or 6, wherein: the water distribution device also comprises a water supply pipe (18), wherein the outlet of the water supply pipe (18) is respectively arranged at the bottom of the water distribution cavity, and the inlet of the water supply pipe is communicated with a water source through a valve or a high-pressure pump.

9. A large heavy metal particle ore separator according to claim 1, wherein: the transmission device is an automobile rear axle.

10. A large heavy metal particle ore separator according to claim 1, wherein: the ore carrying net (14) is 2-6 blocks.