CN114486450A - Mineral sample processing apparatus is used in rock ore deposit appraisal - Google Patents

Abstract

The invention discloses a mineral sample processing device for rock and ore identification, which comprises a base and a supporting sleeve supported on the base and used for supporting ores to be polished, wherein polishing mechanisms 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 used for driving the polishing mechanisms to synchronously move in the same direction and in opposite directions is arranged on the base, and a material pushing mechanism used for pushing out polished sheets in the supporting sleeve is arranged on one side of the supporting sleeve on the base. Placing ores into a supporting sleeve, driving a polishing mechanism to synchronously move inwards by a driving mechanism, and polishing the ores in the supporting sleeve by the polishing mechanism which extends into the supporting sleeve to polish the ores into slices; and then the grinding mechanism moves towards two sides, and the pushing mechanism pushes out the ore slices in the supporting sleeve. The uniformity of the polished mineral thin slices is improved, subsequent observation is facilitated, polishing efficiency is improved, defective rate is reduced, and the polishing process is safe and reliable.

Description

Mineral sample processing apparatus is used in rock ore deposit appraisal

Technical Field

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

Background

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

And (5) removing by a polarizing microscope. Grinding a mineral or rock specimen into slices, identifying the optical properties of the mineral under a polarizing microscope, determining the mineral composition of the rock, determining the type and cause characteristics of the rock, and finally determining the name of the rock, which is also called rock slice identification. This is the most common method of studying mineral rocks. The optical constants of the mineral such as color, shape, size, refractive index, extinction angle, birefringence, interference color, axiality, optical axis angle and the like can be obtained, and the characteristics of the mineral such as formation sequence, secondary variation, volume percentage content, structural structure of rock, cementing type and the like can also be obtained, so that the rock is named correctly.

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

Disclosure of Invention

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

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

a mineral sample processing device for rock and ore identification comprises a base and a supporting sleeve supported on the base and used for supporting ores to be polished, wherein polishing mechanisms used for synchronously polishing the left side and the right side of the ores are symmetrically arranged on two sides of 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 connected with the supporting plate in a sliding manner, and a second motor for driving the mounting frame to slide is arranged on the supporting plate;

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

Furthermore, a plurality of bulges are uniformly arranged on the inner cylindrical surface of the supporting sleeve along the circumferential direction of the supporting 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, a pot head in the guide bar outside is equipped with compression spring, the inboard one end of compression spring and sleeve contact, the baffle contact of compression spring outside one end and guide bar tip.

Further, be equipped with first lead screw in the backup pad, use first lead screw central point to divide into the reverse screw thread of left and right sides two parts as the center on the first lead screw outer cylindrical surface, two parts screw thread respectively correspond two mounting brackets and with threaded connection between the mounting bracket, second motor output shaft and first screw connection.

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

Furthermore, 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 side surface of the push plate.

Furthermore, a dust box used for storing the polished dust is arranged below the supporting sleeve, and a plurality of through holes are formed in the uniform array of the lower half portion of the supporting sleeve.

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

Furthermore, the bearing mechanism comprises a bearing groove arranged on the base, and foam is arranged in the bearing groove.

The invention has the beneficial effects that:

1. the automatic polishing device comprises a base and a supporting sleeve supported on the base and used for supporting ores to be polished, wherein polishing mechanisms 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 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 material pushing mechanism used for pushing out polished sheets in the supporting sleeve is arranged on one side of the supporting sleeve on the base. Placing ores into a supporting sleeve, driving a polishing mechanism to synchronously move inwards by a driving mechanism, and polishing the ores in the supporting sleeve by the polishing mechanism which extends into the supporting sleeve to polish the ores into slices; and then the grinding mechanism moves towards two sides, and the pushing mechanism pushes out the ore slices in the supporting sleeve. The automatic polishing of the ore is realized, the automatic pushing-out is realized, the uniformity of the polished mineral thin slice is improved, the subsequent observation is facilitated, the polishing efficiency is improved, the defective rate is reduced, and the polishing process is also ensured to be safe and reliable.

2. According to the invention, the plurality of bulges 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 bulges and the ore can be increased, the ore is prevented from rotating along with the grinding disc when the grinding disc is ground, 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 connected with the guide rod in a sliding manner, the compression spring is sleeved at one end outside the guide rod, one end inside the compression spring is contacted with the sleeve, one end outside the compression spring is contacted with the baffle plate at the end part of the guide rod, the mounting frame moves inwards, when the grinding disc is contacted with ores, the compression spring plays a buffering role, the grinding disc is not in hard contact with the ores, 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 sliding groove is arranged at the front end of the supporting sleeve, the connecting rod is matched with the sliding groove, and by arranging the connecting rod, the air cylinder is ensured not to generate interference with the grinding disc, and the waste of space is reduced.

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

6. The receiving mechanism comprises a receiving groove arranged on the base, foam is arranged in the receiving groove, the push plate pushes out the ore slices in the supporting sleeve, the ore slices fall into the receiving groove, the ore slices are automatically collected, 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 or technical solutions in the prior art of the present invention, the drawings used in the description of the embodiments or prior art will be briefly described below, 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 first schematic structural diagram of the present invention;

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

FIG. 3 is a second schematic structural view of the present invention;

FIG. 4 is a schematic view of a support sleeve according to 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 a grinding mechanism according to the present invention;

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

In the figure: the grinding disc 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, a 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 groove 20, a rubber layer 21, a dust box 22, a through hole 23, a bearing groove 24 and foam 25.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the technical solution in the embodiment of the present invention will be clearly and completely described below with reference to the drawings in the embodiment of the present invention, and it is obvious that the described embodiment is only a part of the embodiment of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 and 3, a mineral sample processing apparatus for rock and ore appraisal, including base 1, support the support sleeve 2 that is used for supporting the ore of waiting to polish on base 1, support sleeve 2 is ring shape sleeve, and support sleeve 2 supports on base 1 through the landing leg, and support sleeve 2 axis is the horizontal direction, 2 bilateral symmetry of support sleeve are equipped with and are used for the grinding machanism who polishes in step to the ore left and right sides, are equipped with the actuating mechanism who is used for driving grinding machanism synchronous syntropy and reverse movement on base 1, it is equipped with the pushing equipment who is used for pushing out the good thin slice of polishing in the support sleeve 2 to lie in support sleeve 2 one side on base 1.

As shown in fig. 1 and 6, the grinding mechanism comprises a grinding disc 3 for grinding ore, a first motor 4 for driving the grinding disc 3 to rotate and a mounting frame 5 for supporting the first motor 4, 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 and the supporting plate 6 are connected in a sliding mode through a guide rail and slider pair, the sliding direction of the mounting frame is the 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 push plate 8 used for pushing out the ore slices, a cylinder 9 used for driving the push plate 8 to move and a support frame 10 used for supporting the cylinder 9, the cylinder 9 moves back and forth on the support frame 10, the push plate 8 is circular, and the size of the push plate corresponds to that of an inner hole of the support sleeve 2. The cylinder 9 is connected with the source through an air pipe, an electromagnetic valve is arranged on the air pipe, and the expansion and contraction of a piston rod of the cylinder are controlled through the opening and closing of the electromagnetic valve, which is the prior art and is not described in more detail herein.

When the ore grinding machine works, firstly, ores are placed in the supporting sleeve 2, then the mounting frame 5 synchronously moves inwards under the driving of the second motor 7, the grinding discs 3 on the two sides are driven by the first motor 4 to rotate reversely, the grinding discs 3 go deep into the supporting sleeve 2 to grind the ores in the supporting sleeve, and the ores are ground into slices; then the grinding disc 3 moves towards two sides and is removed from the supporting sleeve, the air cylinder 9 moves backwards until the push plate 8 corresponds to the supporting sleeve, and the piston rod of the air cylinder 9 extends out to push out the ore slices in the supporting sleeve. The automatic polishing of the ore is realized, the automatic pushing-out is realized, the uniformity of the polished mineral thin slice is improved, the subsequent observation is facilitated, the polishing efficiency is improved, the defective rate is reduced, and the polishing process is also ensured to be safe and reliable.

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, and the protrusions 11 can increase the friction force between the protrusions and the ore, so that the ore is prevented from rotating along with the protrusions when the grinding disc 3 is ground, and the grinding efficiency is improved.

As shown in fig. 6, be equipped with guide bar 12 on the mounting bracket 5, be equipped with sleeve 13 on the base of first motor 4, sleeve 13 with sliding connection between guide bar 12, a pot head in the guide bar 12 outside is equipped with compression spring 14, the inboard one end of compression spring 14 contacts with sleeve 13, and the baffle contact of 14 outside one end of compression spring and guide bar 12 tip, mounting bracket 5 move to the inboard, and when mill 3 and ore contact, compression spring 14 plays the effect of buffering, and mill 3 can not contact with the ore is hard, and the cracked possibility of ore is low, and the yield is high.

As shown in fig. 1 to 3, be equipped with first lead screw 15 in the backup pad 6, be connected through the bearing rotation between first lead screw 15 both ends and the backup pad 6, use first lead screw 15 central point to divide into the reverse screw thread of left and right parts as the center on the first lead screw 15 outer cylindrical surface, two parts screw thread respectively correspond two mounting brackets 5 and with mounting bracket 5 between threaded connection, second motor 7 output shaft is connected with first lead screw 15, and second motor 7 passes through two mounting bracket 5 synchronous syntropy of lead screw drive or reverse synchronous motion.

As shown in fig. 7, a sliding seat 16 for supporting the air cylinder 9 is arranged on the supporting frame 10, a cylinder end of the air cylinder 9 is fixed on the sliding seat 16, the sliding seat 16 is connected with the supporting frame 10 through a guide rail and slider pair in a sliding manner, a second lead screw 17 which rotates on the supporting frame 10 is arranged on the supporting frame 10, two ends of the second lead screw 17 are connected with the supporting frame 10 in a rotating manner through a bearing, the second lead screw 17 is connected with the sliding seat 16 in a threaded manner, a third motor 18 for driving the second lead screw 17 to rotate is arranged at the front end of the supporting frame 10, 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 grinding 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 grind ores.

As shown in fig. 1 and 7, a connecting rod 19 is arranged at the front end of the push plate 8, a piston rod of the air cylinder 9 is connected with the front end of the connecting rod 19, a sliding groove 20 is arranged at the front end of the support sleeve 2, the sliding groove 20 is a horizontal long-strip groove, the connecting rod 19 is matched with the sliding groove 20, and the connecting rod 19 slides in the sliding groove 20; through setting up the connecting rod, guarantee that cylinder 9 can not produce the interference with producing between mill 3, reduce the waste in space.

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

As shown in fig. 2 and 3, be equipped with the dust box 22 that is used for saving the back dust of polishing below the support sleeve 2, the even array of support sleeve 2 the latter half has a plurality of through-holes 23, and the dust after polishing falls into dust box 22 through-hole 23 in, prevents that the dust from persisting in support sleeve 2, can realize the automatic recovery of dust simultaneously.

As shown in fig. 1, a receiving mechanism for receiving ore flakes is arranged on the base 1 at a side of the supporting sleeve 2 opposite to the pushing mechanism. Receiving mechanism is including installing the groove 24 of accepting on base 1, accepts the groove 24 and fixes on base 1 through the landing leg, accept to be equipped with in the groove 24 and steep cotton 25, push pedal 8 releases the ore thin slice in the support sleeve 2, and the ore thin slice falls into and connects the groove 24 in, realizes that the ore thin slice is automatic to be collected, and steep cotton 25 simultaneously also can protect the ore thin slice, prevents that the ore thin slice from breaking into pieces.

In the description of the present invention, it should be noted that the terms "left", "right", "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be mechanically or electrically connected, directly or indirectly through intervening media, or may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Claims (9)

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

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

the driving mechanism comprises a supporting plate (6) arranged at the upper end of the base (1), the mounting frame (5) is connected with the supporting plate (6) in a sliding manner, 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) used for pushing out the ore slices, a cylinder (9) used for driving the pushing plate (8) to move and a supporting frame (10) used for supporting the cylinder (9), and the cylinder (9) moves back and forth on the supporting frame (10).

2. A mineral sample processing device for rock mine identification according to claim 1, characterized in that the inner cylindrical surface of the support sleeve (2) is provided with a plurality of protrusions (11) uniformly along the circumferential direction of the support sleeve (2).

3. The mineral sample processing device for rock and ore identification as claimed in claim 1, wherein a guide rod (12) is arranged on the mounting frame (5), a sleeve (13) is arranged on the base of the first motor (4), the sleeve (13) is slidably connected with the guide rod (12), a compression spring (14) is sleeved at one end of the outer side of the guide rod (12), 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 at the end part of the guide rod (12).

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

5. The mineral sample processing device for rock and ore identification as claimed in claim 1, wherein the support frame (10) is provided with a slide seat (16) for supporting the cylinder (9), the slide seat (16) is connected with the support frame (10) in a sliding manner, the support frame (10) is provided with a second lead screw (17) which rotates on the support frame (10), the second lead screw (17) is connected with the slide seat (16) in a threaded manner, and the front end of the support frame (10) is provided with a third motor (18) for driving the second lead screw (17) to rotate.

6. The mineral sample processing device for rock and ore identification as claimed in claim 5, wherein the front end of the push plate (8) is provided with a connecting rod (19), the piston rod of the air cylinder (9) is connected with the front end of the connecting rod (19), the front end of the supporting sleeve (2) is provided with a sliding groove (20), and the connecting rod (19) is matched with the sliding groove (20);

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

7. The apparatus for processing mineral samples for rock mine identification according to claim 1, wherein a dust box (22) for storing ground dust is provided below the supporting sleeve (2), and a plurality of through holes (23) are uniformly arranged in the lower half portion of the supporting sleeve (2).

8. A mineral sample processing apparatus for rock mine identification according to claim 1 wherein the base (1) is provided with receiving means for receiving mineral flakes on the side of the support sleeve (2) opposite the pushing means.

9. A mineral sample processing apparatus for rock mine identification according to claim 8 wherein the receiving means comprises a receiving chamber (24) mounted on the base (1), the receiving chamber (24) being provided with foam (25).

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