CN114486450B - Mineral sample processing device for rock and ore identification - Google Patents

Abstract

The invention discloses a mineral sample processing device for rock and ore identification, which comprises a base, and a supporting sleeve which is supported on the base and used for supporting an ore to be polished, wherein polishing mechanisms for synchronously polishing the left side and the right side of the ore are symmetrically arranged on two sides of the supporting sleeve, a driving mechanism for driving the polishing mechanisms to synchronously move in the same direction and in the opposite direction is arranged on the base, and a pushing mechanism for pushing out polished sheets in the supporting sleeve is arranged on one side of the supporting sleeve on the base. Placing ore into a supporting sleeve, driving a polishing mechanism to synchronously move inwards by a driving mechanism, enabling the polishing mechanism to penetrate into the supporting sleeve to polish the ore in the supporting sleeve, and polishing the ore into slices; and then the polishing mechanism moves to two sides, and the pushing mechanism pushes out the ore slices in the supporting sleeve. The uniformity of the polished mineral slices is improved, follow-up observation is facilitated, polishing efficiency is improved, defective rate is reduced, and safe and reliable polishing process can be guaranteed.

Description

Mineral sample processing device for rock and ore identification

Technical Field

The invention relates to the technical field of rock and mineral identification, in particular to a mineral sample processing device for rock and mineral identification.

Background

Rock mineral identification refers to a technical method for observing and identifying rock, mineral samples, including light (thin) sheets, sand sheets, scraps and powder to distinguish mineral categories thereof by using various mineralogy principles and methods and through the light, electricity, sound, heat, magnetism, weight, hardness, smell and the like of the minerals and main chemical component characteristics thereof, and researching main mineral composition, mineral generation sequence, structure and rock (ore) type of the rock and ore.

And (5) removing by using a polarizing microscope. Grinding the mineral or rock specimen into flakes, identifying the optical properties of the mineral under a polarized microscope, determining the mineral components of the rock, determining the rock type and the causative characteristics thereof, and finally determining the rock name, which is also called a rock flake identification method. This is the most common method of studying mineral rock. The method can obtain the optical constants of the minerals such as color, shape, size, refractive index, extinction angle, refolding rate, interference color, axiality, optical axis angle and the like, and can also obtain the characteristics of the formation sequence, secondary change, volume percentage content, structural structure, cementation type and the like of the minerals, so as to accurately name the rock.

But when polishing to the mineral, all polish on the emery wheel through artifical handheld mineral, this kind of mode has a problem, 1, the back mineral flake thickness of polishing is different, influences subsequent observation, 2, the inefficiency of polishing wastes time and energy, and mineral flake easy fracture when polishing, the rejection rate is high, 3, when polishing, causes the injury to operating personnel's finger easily, the danger is high.

Disclosure of Invention

The invention aims to solve the problems, and provides a mineral sample processing device for rock and mineral identification, which can improve the uniformity of polished mineral slices, facilitate subsequent observation, improve polishing efficiency, reduce defective rate and ensure the safety and reliability of the polishing process.

The technical scheme adopted for solving the technical problems is as follows:

the mineral sample processing device for rock and ore identification comprises a base, a supporting sleeve, a grinding mechanism and a pushing mechanism, wherein the supporting sleeve is supported on the base and used for supporting an ore to be ground, the grinding mechanisms are symmetrically arranged on two sides of the supporting sleeve and used for synchronously grinding the left side and the right side of the ore, the driving mechanism is arranged on the base and used for driving the grinding mechanisms to synchronously move in the same direction and in the opposite direction, and the pushing mechanism is arranged on one side of the supporting sleeve, which is positioned on the base, and used for pushing out a polished sheet in the supporting sleeve;

the grinding mechanism comprises a grinding disc for grinding ores, a first motor for driving the grinding disc to rotate and a mounting frame for supporting the first motor;

the driving mechanism comprises a supporting plate arranged at the upper end of the base, the mounting frame is in sliding connection with the supporting plate, and a second motor for driving the mounting frame to slide is arranged on the supporting plate;

the pushing mechanism comprises a pushing plate for pushing out the ore slices, an air cylinder for driving the pushing plate to move and a supporting frame for supporting the air cylinder, and the air cylinder moves back and forth on the supporting frame.

Further, a plurality of bulges are uniformly arranged on the inner cylindrical surface of the support sleeve along the circumferential direction of the support sleeve.

Further, be equipped with the guide bar on the mounting bracket, be equipped with the sleeve on the base of first motor, the sleeve with sliding connection between the guide bar, one pot head is equipped with compression spring in the guide bar outside, the inboard one end of compression spring contacts with the sleeve, and the baffle contact of compression spring outside one end and guide bar tip.

Further, be equipped with first lead screw in the backup pad, be divided into left and right sides two parts's reverse screw thread on the first lead screw outer cylinder about first lead screw central point as the center, two part screw threads correspond respectively two mounting brackets and with the mounting bracket between threaded connection, second motor output shaft and first lead screw connection.

Further, be equipped with the slide that is used for supporting the cylinder on the support frame, sliding connection between slide and the support frame, be equipped with the second lead screw of pivoted on the support frame, threaded connection between second lead screw and the slide, the support frame front end is equipped with the pivoted third motor of drive second lead screw.

Further, a connecting rod is arranged at the front end of the push plate, a piston rod of the air cylinder is connected with the front end of the connecting rod, a sliding groove is arranged at the front end of the supporting sleeve, and the connecting rod is matched with the sliding groove;

and a rubber layer is arranged on the inner testing surface of the push plate.

Further, a dust box for storing dust after polishing is arranged below the supporting sleeve, and a plurality of through holes are uniformly arrayed in the lower half part of the supporting sleeve.

Further, a receiving mechanism for receiving the ore slices is arranged on one side, opposite to the pushing mechanism, of the supporting sleeve on the base.

Further, the receiving mechanism comprises a receiving groove arranged on the base, and foam is arranged in the receiving groove.

The beneficial effects of the invention are as follows:

1. the ore polishing device comprises a base, a supporting sleeve which is supported on the base and used for supporting ores to be polished, polishing mechanisms which are used for synchronously polishing the left side and the right side of the ores are symmetrically arranged on two sides of the supporting sleeve, a driving mechanism which is used for driving the polishing mechanisms to synchronously move in the same direction and in the opposite direction is arranged on the base, and a pushing mechanism which is used for pushing out polished sheets in the supporting sleeve is arranged on one side of the supporting sleeve on the base. Placing ore into a supporting sleeve, driving a polishing mechanism to synchronously move inwards by a driving mechanism, enabling the polishing mechanism to penetrate into the supporting sleeve to polish the ore in the supporting sleeve, and polishing the ore into slices; and then the polishing mechanism moves to two sides, and the pushing mechanism pushes out the ore slices in the supporting sleeve. The automatic grinding of ore is realized, automatic release is carried out, the uniformity of the polished mineral slices is improved, the subsequent observation is convenient, the grinding efficiency is improved, the defective rate is reduced, and the safe and reliable grinding process can be ensured.

2. According to the invention, the plurality of protrusions are uniformly arranged on the inner cylindrical surface of the supporting sleeve along the circumferential direction of the supporting sleeve, so that the friction force between the protrusions and ore can be increased, the ore is prevented from rotating along with the grinding disc during grinding, and the grinding efficiency is improved.

3. According to the invention, the guide rod is arranged on the mounting frame, the sleeve is arranged on the base of the first motor, the sleeve is in sliding connection with the guide rod, the compression spring is sleeved at one end of the outer side of the guide rod, one end of the inner side of the compression spring is in contact with the sleeve, one end of the outer side of the compression spring is in contact with the baffle plate at the end part of the guide rod, the mounting frame moves inwards, when the grinding disc is in contact with ore, the compression spring plays a role in buffering, the grinding disc is not in hard contact with the ore, the possibility of ore fragmentation is low, and the yield is high.

4. According to the invention, the connecting rod is arranged at the front end of the push plate, the piston rod of the air cylinder is connected with the front end of the connecting rod, the front end of the supporting sleeve is provided with the sliding groove, the connecting rod is matched with the sliding groove, and the connecting rod ensures that the air cylinder cannot interfere with the grinding disc, so that the space waste is reduced.

5. According to the invention, the dust box for storing polished dust is arranged below the supporting sleeve, the lower half part of the supporting sleeve is uniformly provided with the plurality of through holes, and polished dust falls into the dust box through the through holes, so that the dust is prevented from being reserved in the supporting sleeve, and meanwhile, the dust can be automatically recovered.

6. The receiving mechanism comprises the receiving groove arranged on the base, foam is arranged in the receiving groove, the pushing plate pushes out the ore slices in the supporting sleeve, the ore slices fall into the receiving groove, automatic collection of the ore slices is achieved, and meanwhile the foam can also protect the ore slices and prevent the ore slices from being broken.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required to be used in the description of the embodiments or the prior art will be briefly described below, and it will be obvious to those skilled in the art that other drawings can be obtained from these drawings without inventive effort.

FIG. 1 is a schematic diagram of a first embodiment of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is a second schematic diagram of the structure of the present invention;

FIG. 4 is a schematic view of the support sleeve structure of the present invention;

FIG. 5 is a right side view of the support sleeve of the present invention;

FIG. 6 is a schematic view of the polishing mechanism of the present invention;

fig. 7 is a schematic structural diagram of a pushing mechanism of the present invention.

In the figure: the grinding disc grinding machine comprises a base 1, a supporting sleeve 2, a grinding disc 3, a first motor 4, a mounting frame 5, a supporting plate 6, a second motor 7, a push plate 8, an air cylinder 9, a supporting frame 10, a protrusion 11, a guide rod 12, a sleeve 13, a compression spring 14, a first lead screw 15, a sliding seat 16, a second lead screw 17, a third motor 18, a connecting rod 19, a sliding chute 20, a rubber layer 21, a dust box 22, a through hole 23, a receiving groove 24 and foam 25.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present invention without making any inventive effort, shall fall within the scope of the present invention.

As shown in fig. 1 and 3, a mineral sample processing device for rock and mineral identification comprises a base 1, a supporting sleeve 2 which is supported on the base 1 and used for supporting the ore to be polished, the supporting sleeve 2 is a circular sleeve, the supporting sleeve 2 is supported on the base 1 through supporting legs, the axis of the supporting sleeve 2 is in a horizontal direction, polishing mechanisms which are used for synchronously polishing the left side and the right side of the ore are symmetrically arranged on two sides of the supporting sleeve 2, a driving mechanism which is used for driving the polishing mechanisms to synchronously move in the same direction and in the opposite direction is arranged on the base 1, and a pushing mechanism which is used for pushing out polished sheets in the supporting sleeve 2 is arranged on one side of the base 1.

As shown in fig. 1 and 6, the grinding mechanism comprises a grinding disc 3 for grinding ores, a first motor 4 for driving the grinding disc 3 to rotate and a mounting frame 5 for supporting the first motor 4, wherein the grinding disc 3 is disc-shaped, and the grinding disc 3 is matched with the inner wall of the supporting sleeve 2; the driving mechanism comprises a supporting plate 6 arranged at the upper end of the base 1, the supporting plate 6 is fixed on the base 1 through supporting legs, the mounting frame 5 is in sliding connection with the supporting plate 6 through a guide rail sliding block pair, the sliding direction is a horizontal direction, a second motor 7 for driving the mounting frame 5 to slide is arranged on the supporting plate 6, and the second motor 7 is fixed on one side of the supporting plate 6; the pushing mechanism comprises a pushing plate 8 for pushing out ore slices, an air cylinder 9 for driving the pushing plate 8 to move and a supporting frame 10 for supporting the air cylinder 9, wherein the air cylinder 9 moves back and forth on the supporting frame 10, the pushing plate 8 is circular, and the size of the pushing plate 8 corresponds to the inner hole of the supporting sleeve 2. The cylinder 9 is connected with the origin through the trachea, is equipped with the solenoid valve on the trachea, and the start and stop of through the solenoid valve and then control the flexible of cylinder piston rod, this is prior art, does not make excessive description here.

When the device works, firstly ore is placed into the supporting sleeve 2, then the mounting frame 5 synchronously moves inwards under the drive of the second motor 7, the first motor 4 drives the grinding discs 3 at two sides to reversely rotate, the grinding discs 3 penetrate into the supporting sleeve 2 to polish the ore in the supporting sleeve, and the ore is polished into slices; the grinding disc 3 is then moved to both sides, removed from the support sleeve, and the cylinder 9 is moved backwards until the push plate 8 corresponds to the support sleeve, and the cylinder 9 piston rod extends out to push out the mineral flakes in the support sleeve. The automatic grinding of ore is realized, automatic release is carried out, the uniformity of the polished mineral slices is improved, the subsequent observation is convenient, the grinding efficiency is improved, the defective rate is reduced, and the safe and reliable grinding process can be ensured.

As shown in fig. 4 and 5, a plurality of protrusions 11 are uniformly arranged on the inner cylindrical surface of the supporting sleeve 2 along the circumferential direction of the supporting sleeve 2, the protrusions 11 can increase friction force with ore, the ore is prevented from rotating along with the grinding disc 3 when the grinding disc 3 is polished, and polishing efficiency is improved.

As shown in fig. 6, the mounting frame 5 is provided with a guide rod 12, the base of the first motor 4 is provided with a sleeve 13, the sleeve 13 is in sliding connection with the guide rod 12, one end of the outer side of the guide rod 12 is sleeved with a compression spring 14, one end of the inner side of the compression spring 14 is in contact with the sleeve 13, one end of the outer side of the compression spring 14 is in contact with a baffle plate at the end of the guide rod 12, the mounting frame 5 moves inwards, when the grinding disc 3 is in contact with ore, the compression spring 14 plays a role of buffering, the grinding disc 3 is not in hard contact with the ore, the possibility of ore breakage is low, and the yield is high.

As shown in fig. 1 to 3, a first screw rod 15 is disposed on the support plate 6, two ends of the first screw rod 15 are rotatably connected with the support plate 6 through bearings, reverse threads of left and right parts are formed on an outer cylindrical surface of the first screw rod 15 by taking a center point of the first screw rod 15 as a center, the threads of the two parts correspond to the two mounting frames 5 respectively and are in threaded connection with the mounting frames 5, an output shaft of the second motor 7 is connected with the first screw rod 15, and the second motor 7 synchronously moves in the same direction or in the opposite direction through the screw rod driving of the two mounting frames 5.

As shown in fig. 7, the support frame 10 is provided with a slide seat 16 for supporting the air cylinder 9, the cylinder body end of the air cylinder 9 is fixed on the slide seat 16, the slide seat 16 is slidably connected with the support frame 10 through a guide rail slide block pair, the support frame 10 is provided with a second lead screw 17 rotating on the support frame 10, two ends of the second lead screw 17 are rotatably connected with the support frame 10 through bearings, the second lead screw 17 is in threaded connection with the slide seat 16, the front end of the support frame 10 is provided with a third motor 18 for driving the second lead screw 17 to rotate, and an output shaft of the third motor 18 is connected with the front end of the second lead screw 17 through a coupling. When the mounting frame 5 moves outwards, the third motor 18 drives the sliding seat 16 to move backwards, the push plate 8 corresponds to the supporting sleeve 2, and when polishing is needed, the third motor 18 drives the sliding seat 16 to move forwards, so that the grinding disc 3 cannot be interfered to enter the supporting sleeve 2 to polish ores.

As shown in fig. 1 and 7, the front end of the push plate 8 is provided with a connecting rod 19, a piston rod of the air cylinder 9 is connected with the front end of the connecting rod 19, the front end of the support sleeve 2 is provided with a sliding groove 20, the sliding groove 20 is a long groove in the horizontal direction, the connecting rod 19 is matched with the sliding groove 20, and the connecting rod 19 slides in the sliding groove 20; by arranging the connecting rod, the air cylinder 9 is ensured not to interfere with the grinding disc 3, and the space waste is reduced.

As shown in fig. 7, a rubber layer 21 is disposed on the inner surface of the push plate 8, and the rubber layer 21 can protect the ore sheet when the push plate 8 pushes the ore sheet out.

As shown in fig. 2 and 3, a dust box 22 for storing polished dust is arranged below the supporting sleeve 2, a plurality of through holes 23 are uniformly arrayed in the lower half part of the supporting sleeve 2, and polished dust falls into the dust box 22 through the through holes 23, so that the dust is prevented from being reserved in the supporting sleeve 2, and meanwhile, the dust can be automatically recovered.

As shown in fig. 1, a receiving mechanism for receiving the ore slices is arranged on the base 1 at the side opposite to the supporting sleeve 2 and the pushing mechanism. The receiving mechanism comprises a receiving groove 24 arranged on the base 1, the receiving groove 24 is fixed on the base 1 through supporting legs, foam 25 is arranged in the receiving groove 24, the pushing plate 8 pushes out ore slices in the supporting sleeve 2, the ore slices fall into the receiving groove 24, automatic collection of the ore slices is achieved, and meanwhile the foam 25 can also protect the ore slices and prevent the ore slices from being broken.

In describing the present invention, it should be noted that the azimuth or positional relationship indicated by the terms "left", "right", "upper", "lower", etc. are based on the azimuth or positional relationship shown in the drawings, and are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; the two components can be connected mechanically or electrically, can be connected directly or indirectly through an intermediate medium, and can be communicated inside the two components. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Claims (5)

1. The mineral sample processing device for rock and ore identification is characterized by comprising a base (1), a supporting sleeve (2) which is supported on the base (1) and used for supporting an ore to be polished, polishing mechanisms which are used for synchronously polishing the left side and the right side of the ore are symmetrically arranged on two sides of the supporting sleeve (2), a driving mechanism which is used for driving the polishing mechanisms to synchronously move in the same direction and in the opposite direction is arranged on the base (1), and a pushing mechanism which is used for pushing out polished slices in the supporting sleeve (2) is arranged on one side of the supporting sleeve (1);

a plurality of bulges (11) are uniformly arranged on the inner cylindrical surface of the supporting sleeve (2) along the circumferential direction of the supporting sleeve (2);

the grinding mechanism comprises a grinding disc (3) for grinding ores, a first motor (4) for driving the grinding disc (3) to rotate and a mounting frame (5) for supporting the first motor (4);

the mounting frame (5) is provided with a guide rod (12), a base of the first motor (4) is provided with a sleeve (13), the sleeve (13) is in sliding connection with the guide rod (12), one end of the outer side of the guide rod (12) is sleeved with a compression spring (14), one end of the inner side of the compression spring (14) is in contact with the sleeve (13), and one end of the outer side of the compression spring (14) is in contact with a baffle plate at the end of the guide rod (12);

the driving mechanism comprises a supporting plate (6) arranged at the upper end of the base (1), the mounting frame (5) is in sliding connection with the supporting plate (6), and a second motor (7) for driving the mounting frame (5) to slide is arranged on the supporting plate (6);

the pushing mechanism comprises a pushing plate (8) for pushing out the ore slices, an air cylinder (9) for driving the pushing plate (8) to move and a supporting frame (10) for supporting the air cylinder (9), wherein the air cylinder (9) moves back and forth on the supporting frame (10);

the supporting sleeve (2) is arranged on one side, opposite to the pushing mechanism, of the base (1) and comprises a supporting groove (24) arranged on the base (1), and foam (25) is arranged in the supporting groove (24).

2. The mineral sample processing device for rock and mineral identification according to claim 1, wherein the supporting plate (6) is provided with a first screw rod (15), the outer cylindrical surface of the first screw rod (15) is divided into left and right opposite threads with the center point of the first screw rod (15) as the center, the two threads correspond to the two mounting frames (5) respectively and are in threaded connection with the mounting frames (5), and the output shaft of the second motor (7) is connected with the first screw rod (15).

3. A mineral sample processing device for rock and mineral identification according to claim 1, characterized in that the support frame (10) is provided with a slide seat (16) for supporting the air cylinder (9), the slide seat (16) is in sliding connection with the support frame (10), the support frame (10) is provided with a second screw (17) rotating on the support frame (10), the second screw (17) is in threaded connection with the slide seat (16), and the front end of the support frame (10) is provided with a third motor (18) for driving the second screw (17) to rotate.

4. A mineral sample processing apparatus for rock and mineral identification according to claim 3, wherein the front end of the push plate (8) is provided with a connecting rod (19), the piston rod of the cylinder (9) is connected with the front end of the connecting rod (19), the front end of the support sleeve (2) is provided with a chute (20), and the connecting rod (19) is matched with the chute (20);

a rubber layer (21) is arranged on the inner measuring surface of the push plate (8).

5. A mineral sample processing apparatus for rock and mineral identification according to claim 1, characterized in that a dust box (22) for storing dust after grinding is arranged below the support sleeve (2), and a plurality of through holes (23) are uniformly arrayed in the lower half part of the support sleeve (2).