CN218222654U - High-efficient dust removal mineral processing equipment - Google Patents

Abstract

The utility model provides a high-efficient dust removal mineral processing equipment, which relates to the technical field of mineral processing equipment and comprises a damping component and a sorting component, wherein a shell component is arranged at the top end of the damping component, the sorting component is arranged on the inner side of the shell component, and a sleeved dust removal part is arranged on the end side of the shell component; the utility model discloses mainly utilize the sorting unit who installs the inboard separation assembly who closely laminates at the casing component, make first plug socket and second plug socket and two sets of oblique form structures on the sorting unit first inclined wire netting and second inclined wire netting, export the sorting and classifying isolation, like this because the power motor among the utilization vibration mechanism of the initiative sorting mode of equipment drives a vibration section of thick bamboo and transmits vibration power to first inclined wire netting and second inclined wire netting, played the effect that utilizes vibration power to carry out vibration letter sorting sieve to the crushing ore on first inclined wire netting and the second inclined wire netting like this and strain, possess the operating condition who avoids with ore initiative contact, consequently can be long-time keep efficient separation efficiency.

Description

High-efficient dust removal mineral processing equipment

Technical Field

The utility model relates to a mineral processing equipment technical field especially relates to a high-efficient dust removal mineral processing equipment.

Background

The ore is at the exploitation in-process, need smash into the fritter to the bold ore of exploitation in order to conveniently transport and subsequent processing, carries out the processing procedure to the ore, and the ore is smashed and is produced a large amount of dusts, if not handle the dust, can cause environmental pollution, and operating personnel inhales the dust and can lead to the fact the influence to its health, consequently need utilize professional dust collector to carry out effectual dust removal in equipment.

Current mineral processing equipment is when using, generally adopts the mode of initiatively selecting separately, select the letter sorting with the ore of smashing the completion, and the net cover of separation carries out the letter sorting screening with the ore in the cooperation, in order to reach the effect of ore dressing, nevertheless the mining site generally needs equipment to use for a long time, and the output of work is great, in the time of initiatively selecting separately, the ore can carry out long-time contact with the letter sorting pole, cause a large amount of structural wear of letter sorting pole under long-term letter sorting easily like this, can cause the efficiency step-down of letter sorting, be unfavorable for the high-efficient use in mining site, therefore, the utility model provides a high-efficient mineral processing dust collecting equipment is in order to solve the problem that exists among the prior art.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides a high-efficient dust removal mineral processing equipment, this high-efficient dust removal mineral processing equipment mainly utilizes the sorting subassembly of installing in the inboard inseparable laminating of casing member, make first spliced seat and second spliced seat and the first inclined wire and the second inclined wire of two sets of slope form structures on the sorting subassembly, export the sorting and carry out categorised isolation, like this because the driving motor among the utilization vibration mechanism of the initiative sorting mode of equipment drives vibration section of thick bamboo and transmits vibration power to first inclined wire and second inclined wire, played the effect that utilizes the vibration power to carry out vibration sorting sieve with the crushing ore on first inclined wire and the second inclined wire and strain like this, possess the operating condition who avoids with ore initiative contact, consequently, can be long-time keep efficient sorting efficiency, and when first inclined wire and the second inclined wire are blockked up to the ore, the user of also being convenient for taking off equipment, quick clearance of clearing up, use cost with saving user.

For realizing the purpose of the utility model, the utility model discloses a following technical scheme realizes: a high-efficiency dust removal ore dressing equipment comprises a shock absorption assembly and a separation assembly, wherein a shell member is arranged at the top end of the shock absorption assembly, a crushing mechanism is arranged on the side of the shell member, a vibration mechanism is arranged on the bottom side of the shell member, the separation assembly is arranged on the inner side of the shell member, and a sleeved dust removal component is arranged on the end side of the shell member;

the sorting component comprises a first plug socket, a first inclined net, a second plug socket, hinge pieces, a second inclined net and a height bracket, the first plug socket is arranged on the inner edge side of the shell member, the first plug socket is connected with the first inclined net in a clamping mode, one end of the first inclined net is connected with the second plug socket for installing the hinge pieces in a clamping mode, the second inclined net connected in a clamping mode is arranged on the inner side of one end of the second plug socket, and one end of the second inclined net is provided with the low end of the height bracket.

In a further improvement, the first inclined net and the second inclined net are both in a grid structure, the first inclined net and the second inclined net are obliquely distributed, and the pore density of the second inclined net is greater than that of the first inclined net.

The further improvement lies in that the shock absorption assembly comprises a shock absorption pad, a base platform and a bolt lifting frame, wherein the base platform is arranged on the top side of the shock absorption pad, and the bolt lifting frame assembled by bolts is arranged on the top side of the base platform.

The improved structure is characterized in that the shell component comprises a bottom shell, a separation outlet, a side shell plate, an end shell plate, a motor cover, a top plate and a feeding port, the bottom shell is arranged at the top end of the bolt lifting frame, three groups of separation outlets are arranged on the inner side of the bottom shell, the side shell plate and the end shell plate are arranged above the side of the bottom shell, the motor cover assembled by bolts is arranged on one side of the side shell plate, and the top sides of the side shell plate and the end shell plate are provided with the top plate provided with the feeding port.

The crushing mechanism is further improved in that the crushing mechanism comprises a bearing base, a gear set, a driving motor, a roll shaft, a crushing tooth group and a first mesh enclosure, the bearing base is arranged on the side shell plate, the gear set connected with the output end of the driving motor is arranged on the outer side of the bearing base, the input end of the gear set penetrates through the bearing base and is connected with the roll shaft through the side shell plate, the crushing tooth groups distributed in a staggered mode are arranged on the outer side of the roll shaft, and the first mesh enclosure is arranged below the crushing tooth group.

The vibration mechanism comprises a vibration barrel, a belt pulley, a driving wheel and a power motor, wherein the vibration barrel is arranged on the bottom side of the bottom shell, the vibration barrel is connected with the input end of the belt pulley, the belt pulley is in transmission connection with a belt of the driving wheel, and the driving wheel is connected with the input end of the power motor.

The dust removal component comprises a duct pipe, a bearing box, a non-woven fabric cover, a bolt cover and an exhaust fan, the duct pipe is sleeved on one side of the end shell plate, the bearing box is arranged at one end of the duct pipe, the non-woven fabric cover is arranged on the inner side of the bearing box, the bolt cover assembled by bolts is arranged on the bottom side of the bearing box, and the exhaust fan is arranged on the top side of the bearing box.

The utility model has the advantages that:

the utility model discloses mainly be the separation subassembly of the inboard inseparable laminating of casing member is installed in the utilization, make first plug socket and second plug socket and the first inclined wire and the second inclined wire of two sets of slope form structures on the separation subassembly, export the classification of will sorting and keep apart, like this because the power motor among the utilization vibration mechanism of the initiative sorting mode of equipment drives a vibration section of thick bamboo and transmits the vibrational force to first inclined wire and second inclined wire, the effect of utilizing the vibrational force to carry out vibration letter sorting sieve to strain with the crushing ore on first inclined wire and the second inclined wire has been played like this, possess the operating condition who avoids with ore active contact, consequently can be long-time keep efficient separation efficiency, and when the ore blocks up first inclined wire and second inclined wire, also be convenient for the user take off equipment, quick clearance, in order to save user's use cost.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic bottom perspective view of the present invention;

FIG. 3 is a schematic view of the three-dimensional structure of the crushing mechanism of the present invention;

fig. 4 is a schematic perspective view of the sorting assembly of the present invention;

fig. 5 is a schematic view of the cross-sectional three-dimensional structure of the dust removing component of the present invention.

Wherein: 1. a shock absorbing assembly; 101. a shock pad; 102. a base table; 103. lifting the bolt; 2. a housing member; 201. a bottom case; 202. a sorting outlet; 203. a side shell plate; 204. an end shell plate; 205. a motor cover; 206. a top plate; 207. a feeding port; 3. a crushing mechanism; 301. a bearing base; 302. a gear set; 303. a drive motor; 304. a roll shaft; 305. crushing the tooth group; 306. a first mesh enclosure; 4. a vibration mechanism; 401. a vibration cylinder; 402. a pulley; 403. a driving wheel; 404. a power motor; 5. a sorting assembly; 501. a first socket; 502. a first inclined net; 503. a second socket; 504. a hinge plate; 505. a second inclined net; 506. a high-low bracket; 6. a dust removal component; 601. a culvert pipe; 602. a carrying case; 603. a non-woven fabric cover; 604. a bolt cover; 605. an exhaust fan.

Detailed Description

In order to deepen the understanding of the present invention, the following embodiments will be combined to make the present invention do further details, and the present embodiment is only used for explaining the present invention, and does not constitute the limitation of the protection scope of the present invention.

According to the drawings shown in fig. 1-5, the embodiment provides a high-efficiency dust-removing mineral processing device, which includes a damping component 1 and a separation component 5, wherein a shell member 2 is arranged at the top end of the damping component 1, a crushing mechanism 3 is arranged at the side of the shell member 2, a vibrating mechanism 4 is arranged at the bottom side of the shell member 2, the separation component 5 is arranged at the inner side of the shell member 2, and a sleeved dust-removing part 6 is arranged at the end side of the shell member 2;

the sorting component 5 comprises a first socket 501, a first inclined net 502, a second socket 503, a hinge plate 504, a second inclined net 505 and a height bracket 506, wherein the first socket 501 is arranged on the inner side of the shell member 2, the first socket 501 is connected with the first inclined net 502 in a clamping manner, one end of the first inclined net 502 is connected with the second socket 503 for installing the hinge plate 504 in a clamping manner, the inner side of one end of the second socket 503 is provided with the second inclined net 505 in a clamping manner, and one end of the second inclined net 505 is provided with the lower end of the height bracket 506.

The first inclined wire 502 and the second inclined wire 505 are both in a grid-shaped structure, the first inclined wire 502 and the second inclined wire 505 are both distributed in an inclined manner, and the pore density of the second inclined wire 505 is greater than that of the first inclined wire 502.

In this embodiment, when the vibration force is transmitted to the housing member 2, the first and second sockets 501 and 503 and the height bracket 506 transmit the vibration force to the first and second inclined nets 502 and 505, because the first and second inclined nets 502 and 505 are both in a grid-like structure with an inclined distribution, and the pores of the second inclined net 505 are smaller than the pores of the first inclined net 502, large ore is output through the hinge piece 504 on the second socket 503, medium ore is output through the second inclined net 505 after being separated by the first inclined net 502, and small ore is output after being separated by the second inclined net 505, so that the three groups of separation outlets 202 arranged on the inner side of the bottom case 201 can output large ore, medium ore and small ore after being separated, so as to be conveniently carried by a user.

The shock-absorbing assembly 1 comprises a shock-absorbing pad 101, a base platform 102 and a bolt lifting frame 103, wherein the base platform 102 is arranged on the top side of the shock-absorbing pad 101, and the bolt lifting frame 103 assembled by bolts is arranged on the top side of the base platform 102.

In this embodiment, when the vibration mechanism 4 operates, since the shock absorbing pad 101 is disposed on the bottom side of the base table 102, and the shock absorbing pad 101 is configured with a damping spring, a shock absorbing effect can be achieved, so as to achieve an effect of protecting the device.

The shell member 2 comprises a bottom shell 201, a sorting outlet 202, a side shell plate 203, an end shell plate 204, a motor cover 205, a top plate 206 and a feeding port 207, wherein the bottom shell 201 is arranged at the top end of the bolt lifting frame 103, the three-group sorting outlet 202 is arranged on the inner side of the bottom shell 201, the side shell plate 203 and the end shell plate 204 are arranged above the side of the bottom shell 201, the motor cover 205 assembled by bolts is arranged on one side of the side shell plate 203, and the top plate 206 provided with the feeding port 207 is arranged on the top sides of the side shell plate 203 and the end shell plate 204.

In this embodiment, when the crushing mechanism 3 is operated, the motor cover 205 provided on the side of the side casing 203 has an effect of protecting the crushing mechanism 3, and thus when ore to be processed is input into the apparatus through the material inlet 207 above the top plate 206 and falls near the crushing tooth group 305, the crushing action on large ore is achieved under the operation of the crushing tooth group 305, and the crushed ore falls onto the first inclined net 502 under the action of the first net cover 306 due to the large pores of the first net cover 306.

The crushing mechanism 3 comprises a bearing base 301, a gear set 302, a driving motor 303, a roller 304, a crushing tooth group 305 and a first mesh enclosure 306, wherein the bearing base 301 is arranged on a side shell plate 203, the outer side of the bearing base 301 is provided with the gear set 302 connected with the output end of the driving motor 303, the input end of the gear set 302 penetrates through the bearing base 301 and is connected with the roller 304 with the side shell plate 203, the outer side of the roller 304 is provided with the crushing tooth group 305 in staggered distribution, and the first mesh enclosure 306 is arranged below the crushing tooth group 305.

In this embodiment, at first start, driving motor 303 output power drives driving motor 303 output and rotates for driving motor 303 output drives gear train 302 and meshes the transmission, lets gear train 302's input drive the inboard roller 304 of bearing base 301 and inwards rotates, and the mutual operation of roller 304 and crushing tooth group 305 is down in order to wait to smash like this.

The vibration mechanism 4 comprises a vibration cylinder 401, a belt pulley 402, a transmission wheel 403 and a power motor 404, wherein the vibration cylinder 401 is arranged at the bottom side of the bottom shell 201, the vibration cylinder 401 is connected with an input end of the belt pulley 402, the belt pulley 402 is in belt transmission connection with the transmission wheel 403, and the transmission wheel 403 is connected with an input end of the power motor 404.

In this embodiment, when the ore is crushed and falls down to the first inclined wire 502, the power motor 404 is started to output power to drive the driving wheel 403 to rotate, so that the driving wheel 403 is output to the belt pulley 402 by means of belt transmission, and under the rotation operation of the belt pulley 402, the belt pulley 402 drives the vibration drum 401 to effectively rotate, so that the vibration drum 401 generates vibration force and transmits the vibration force to the shell member 2.

The dust removing component 6 comprises a duct pipe 601, a bearing box 602, a non-woven fabric cover 603, a bolt cover 604 and an exhaust fan 605, wherein the duct pipe 601 is sleeved on one side of the end shell plate 204, the bearing box 602 is arranged at one end of the duct pipe 601, the non-woven fabric cover 603 is arranged on the inner side of the bearing box 602, the bolt cover 604 assembled by bolts is arranged on the bottom side of the bearing box 602, and the exhaust fan 605 is arranged on the top side of the bearing box 602.

In this embodiment, when the equipment is smashing and sorting ore, through starting the exhaust fan 605 output wind-force, can extract the inside dust gas that produces of casing component 2 for dust gas gets into bearing box 602 through bypass pipe 601, and keep apart by nonwoven cloth cover 603, deposit among bearing box 602, because possess the vibrational force of vibrating mechanism 4, consequently when the dust is more on nonwoven cloth cover 603, can shake the dust and fall, when the dust gathers the angle, through carrying out effectual clearance to bearing box 602 after opening bolt cover 604.

The working principle of the high-efficiency dust removal mineral processing equipment is as follows: firstly, when starting, the driving motor 303 outputs power to drive the output end of the driving motor 303 to rotate, so that the output end of the driving motor 303 drives the gear set 302 to carry out meshing transmission, the input end of the gear set 302 drives the roller shaft 304 inside the bearing base 301 to rotate inwards, so that the roller shaft 304 and the crushing tooth set 305 run mutually to be crushed, when the crushing mechanism 3 runs, the motor cover 205 arranged on one side of the side shell plate 203 has the effect of protecting the crushing mechanism 3, so that ore to be processed is input into the device through the feeding port 207 above the top plate 206, when the ore falls to the vicinity of the crushing tooth set 305, under the running of the crushing tooth set 305, the effect of crushing large ore is achieved, because the pores of the first mesh cover 306 are large, the crushed ore falls onto the first inclined mesh 502 under the action of the first mesh cover 306, the power motor 404 is started to output power to drive the driving wheel 403 to rotate, so that the driving wheel 403 is output to the pulley 402 by the belt transmission, when the ore falls onto the first inclined mesh 502 after being crushed, the rotation of the pulley 402, so that the vibration damping cushion 505 and the vibration pad 501 are both connected to the vibration base 101, when the vibration cushion 501 and the vibration base 101 are connected to the vibration pad 501, the vibration mechanism, when the vibration mechanism 3 is connected to the vibration pad 501, the vibration pad 501 is connected to the vibration base 101, the vibration pad 501, and the vibration pad 401, and the vibration pad 501, when the vibration pad 502, when the vibration pad 502, the vibration pad is connected to generate the vibration pad 401, when the vibration mechanism 3 is connected to generate the vibration pad structure, and the second inclined net 505 has smaller pores than the first inclined net 502, so that large ores are output through the hinge plate 504 on the second socket 503, medium ores are output through the second inclined net 505 after being separated by the first inclined net 502, and smaller ores are output after being separated by the second inclined net 505, so that the three groups of sorting outlets 202 arranged on the inner side of the bottom case 201 can respectively discharge large, medium and small ores after being sorted for convenient carrying by a user, when the device crushes and sorts ores, dust gas generated inside the case member 2 can be extracted by starting the suction fan 605 to output wind power, so that the dust gas enters the carrying case 602 through the bypass pipe 601 and is isolated by the non-woven fabric cover 603 and stored in the carrying case 602, due to the vibrating force of the vibrating mechanism 4, when dust is more on the non-woven fabric cover 603, the dust can be vibrated down, and when the dust is gathered, the carrying case 602 can be effectively cleaned after the carrying cover 604 is opened.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides a high-efficient dust removal mineral processing equipment, includes damper (1) and selects separately subassembly (5), its characterized in that: a shell component (2) is arranged at the top end of the shock absorption component (1), a crushing mechanism (3) is arranged on the side of the shell component (2), a vibration mechanism (4) is arranged on the bottom side of the shell component (2), a sorting component (5) is arranged on the inner side of the shell component (2), and a sleeved dust removal component (6) is arranged on the end side of the shell component (2);

the sorting component (5) comprises a first plug socket (501), a first inclined net (502), a second plug socket (503), a hinge piece (504), a second inclined net (505) and a high-low bracket (506), wherein the first plug socket (501) is arranged on the inner side of the shell component (2), the first plug socket (501) is connected with the first inclined net (502) in a clamping mode, one end of the first inclined net (502) is connected with the second plug socket (503) for installing the hinge piece (504) in a clamping mode, the second inclined net (505) in the clamping mode is arranged on the inner side of one end of the second plug socket (503), and the low end of the high-low bracket (506) is arranged at one end of the second inclined net (505).

2. The efficient dust removal beneficiation equipment according to claim 1, wherein: the first inclined wire (502) and the second inclined wire (505) are both in a grid-shaped structure, the first inclined wire (502) and the second inclined wire (505) are both distributed in an inclined manner, and the pore density of the second inclined wire (505) is greater than that of the first inclined wire (502).

3. The efficient dust removal beneficiation equipment according to claim 1, wherein: the shock absorption assembly (1) comprises a shock absorption pad (101), a base platform (102) and a bolt lifting frame (103), wherein the base platform (102) is arranged on the top side of the shock absorption pad (101), and the bolt lifting frame (103) assembled by bolts is arranged on the top side of the base platform (102).

4. The efficient dust removal beneficiation equipment according to claim 3, wherein: the shell component (2) comprises a bottom shell (201), a sorting outlet (202), a side shell plate (203), an end shell plate (204), a motor cover (205), a top plate (206) and a feeding port (207), wherein the bottom shell (201) is arranged at the top end of the bolt lifting frame (103), three groups of sorting outlets (202) are arranged on the inner side of the bottom shell (201), the side shell plate (203) and the end shell plate (204) are arranged above the side of the bottom shell (201), the motor cover (205) assembled by bolts is arranged on one side of the side shell plate (203), and the top plates (206) provided with the feeding port (207) are arranged on the top sides of the side shell plate (203) and the end shell plate (204).

5. The efficient dust removal beneficiation equipment according to claim 4, wherein: the grinding mechanism (3) comprises a bearing base (301), a gear set (302), a driving motor (303), a roller shaft (304), a grinding tooth group (305) and a first mesh enclosure (306), wherein the bearing base (301) is arranged on the side shell plate (203), the gear set (302) connected with the output end of the driving motor (303) is arranged outside the bearing base (301), the input end of the gear set (302) penetrates through the bearing base (301) and is connected with the roller shaft (304) with the side shell plate (203), the grinding tooth group (305) which are distributed in a staggered mode is arranged outside the roller shaft (304), and the first mesh enclosure (306) is arranged below the grinding tooth group (305).

6. The efficient dust removal beneficiation equipment according to claim 4, wherein: the vibration mechanism (4) comprises a vibration barrel (401), a belt pulley (402), a transmission wheel (403) and a power motor (404), the vibration barrel (401) is arranged on the bottom side of the bottom shell (201), the vibration barrel (401) is connected with the input end of the belt pulley (402), the belt pulley (402) is in belt transmission connection with the transmission wheel (403), and the transmission wheel (403) is connected with the input end of the power motor (404).

7. The efficient dust removal beneficiation equipment according to claim 4, wherein: the dust removal part (6) comprises a duct pipe (601), a bearing box (602), a non-woven fabric cover (603), a bolt cover (604) and an exhaust fan (605), wherein the duct pipe (601) is sleeved on one side of the end shell plate (204), the bearing box (602) is arranged at one end of the duct pipe (601), the non-woven fabric cover (603) is arranged on the inner side of the bearing box (602), the bolt cover (604) assembled by bolts is arranged on the bottom side of the bearing box (602), and the exhaust fan (605) is arranged on the top side of the bearing box (602).

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