CN111891642B

CN111891642B - Ore lifting machine is used in mine

Info

Publication number: CN111891642B
Application number: CN202010753320.XA
Authority: CN
Inventors: 陈金汀
Original assignee: Lianyuan Luojiaping Quarry Co ltd
Current assignee: Lianyuan Luojiaping Quarry Co ltd
Priority date: 2020-07-30
Filing date: 2020-07-30
Publication date: 2022-11-08
Anticipated expiration: 2040-07-30
Also published as: CN111891642A

Abstract

The invention discloses an ore hoisting machine for a mine, which structurally comprises a machine body, a base and a feeding hopper, wherein the feeding hopper is fixedly embedded at the lower position of the left side of the machine body, the machine body is welded with the base, the other half of fractured ore can be borne by the lower hem of a lower swinging plate, and the ore can be clamped by the lower swinging plate and an upper supporting plate through the matching of elastic pieces, so that the situation that an ore main body is fractured into two parts can be effectively avoided, the bearing plate can not simultaneously convey the fractured ore into two parts at one time, the stress plate can be inwards swung along a lifting plate through the extrusion of the small ore on the stress plate, the lifting plate can be driven to ascend along a fixed rod while the stress plate swings inwards, the small ore can be blocked by the stress plate and the lifting plate, and the situation that the lower swinging plate can not clamp and fix the small ore can be effectively avoided.

Description

Ore lifting machine is used in mine

Technical Field

The invention relates to the field of hoists, in particular to an ore hoist for a mine.

Background

The ore lifting machine is mainly used for carrying out the equipment of vertical transfer to the ore of mining, can be through putting into the hopper with the ore of mining, and the rethread internal transfer device conveys the ore vertically to the grotto upper strata, and extensive the application is in the ore mining trade, based on the above-mentioned description the inventor discovers that current ore lifting machine for mine mainly has following not enough, for example:

because the ore lifting machine shovels the ore in the feeding hopper through the bearing plate on the internal conveying device for vertical conveying, if the ore has deep cracks due to impact in the mining process, the ore is broken into two parts when the bearing plate is shoveled from one side of the ore main body, so that the bearing plate cannot convey the ore which is broken into two parts at the same time.

Disclosure of Invention

In order to solve the above problems, the present invention provides an ore hoisting machine for a mine.

In order to realize the purpose, the invention is realized by the following technical scheme: the ore hoisting machine for the mine structurally comprises a machine body, a base and a feeding hopper, wherein the feeding hopper is fixedly embedded at the lower position of the left side of the machine body, and the machine body is welded with the base; the machine body comprises an outer frame, a transmission chain and a bearing plate, wherein the transmission chain is movably clamped in the inner position of the outer frame, and the bearing plate and the transmission chain are of an integrated structure.

As a further optimization of the invention, the bearing plate comprises upper connection plates, boosting strips and connecting plates, the upper connection plates are movably clamped with the connecting plates, the boosting strips are arranged between the upper connection plates and the connecting plates, and concave surfaces are arranged on the upper surfaces of the upper connection plates.

As a further optimization of the invention, the connecting plate comprises a top plate, an elastic sheet, a lower swinging plate and a lower pushing block, wherein the elastic sheet is installed between the top plate and the lower swinging plate, the lower pushing block is in clearance fit with the top plate, and the lower swinging plate can be pushed downwards by the lower pushing block through the extrusion of an object on the lower pushing block.

As a further optimization of the invention, the lower swing plate comprises a clamping block, a guide frame, a plate body and a plate surface, wherein the clamping block is embedded and fixed at the position of the upper surface of the plate surface, the guide frame and the plate body are of an integrated structure, the plate surface is movably clamped with the guide frame, and the eight clamping blocks are uniformly distributed on the upper surface of the plate surface in parallel.

As a further optimization of the invention, the clamping block comprises a stress plate, a fixed rod, a bottom plate and two lifting plates, wherein the stress plate is hinged with the lifting plates, the fixed rod is fixedly embedded at the upper end of the bottom plate, the lifting plates are movably clamped with the fixed rod, and the two stress plates are uniformly and symmetrically distributed at the left side and the right side of the lifting plates.

As a further optimization of the invention, the stress plate comprises elastic pieces, movable rods, three attaching blocks and a bottom plate, wherein the elastic pieces are arranged between the movable rods and the bottom plate, the movable rods are movably clamped with the bottom plate, the attaching blocks are hinged with the front ends of the movable rods, and the three attaching blocks are uniformly matched with the movable rods and are distributed on the right side of the bottom plate in parallel.

As a further optimization of the invention, the attaching block comprises a pressing block, a combining block and a fixing plate, the pressing block and the combining block are of an integrated structure, the combining block is embedded and fixed at the right side position of the fixing plate, and the inside of the pressing block is of an oval structure.

The invention has the following beneficial effects:

1. the lower pendulum through the lower pendulum plate can bear cracked second half ore, and through the cooperation of elasticity piece, can make lower pendulum plate and overhead board carry out the centre gripping to the ore, has effectually avoided the ore main part to split into two halves, then can make the loading board can not once only carry out the condition of conveying simultaneously to the ore that splits into two parts.

2. Through the extrusion that small-size ore produced the stress board, can make the stress board along the lifter plate internal swing, and can drive the lifter plate and rise along the dead lever when the stress board is internal swing to make stress board and lifter plate can block small-size ore, the effectual lower hem board of having avoided can't carry out the fixed condition of centre gripping to small-size ore.

Drawings

Fig. 1 is a schematic structural diagram of an ore hoist for a mine according to the present invention.

Fig. 2 is a schematic structural view of a front section of the machine body of the present invention.

FIG. 3 is a schematic front sectional view of the carrier plate according to the present invention.

Figure 4 is a schematic structural view in elevation of a cross-section of a connector tile according to the present invention.

FIG. 5 is a schematic front view of a half-section of the lower swing plate of the present invention.

FIG. 6 is a schematic front view of a cross section of the clamping block of the present invention.

Fig. 7 is a schematic structural view of a front half section of the stress plate of the invention.

Fig. 8 is a schematic structural diagram of a front cross section of the fitting block of the present invention.

In the figure: the device comprises a machine body-1, a base-2, a feeding hopper-3, an outer frame-11, a conveying chain-12, a bearing plate-13, an upper connecting plate-a 1, a boosting strip-a 2, a connecting plate-a 3, an overhead plate-a 31, an elastic sheet-a 32, a lower swinging plate-a 33, a lower pushing block-a 34, a clamping block-b 1, a guide frame-b 2, a plate body-b 3, a plate surface-b 4, a stress plate-b 11, a fixed rod-b 12, a bottom plate-b 13, a lifting plate-b 14, an elastic sheet-c 1, a movable rod-c 2, a fitting block-c 3, a bottoming plate-c 4, a pressing block-c 31, a combining block-c 32 and a fixed plate-c 33.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Example 1

As shown in fig. 1-5:

the invention provides an ore hoisting machine for mines, which structurally comprises a machine body 1, a base 2 and a feeding hopper 3, wherein the feeding hopper 3 is embedded at the lower position of the left side of the machine body 1, and the machine body 1 is welded with the base 2; the machine body 1 comprises an outer frame 11, a transmission chain 12 and a bearing plate 13, wherein the transmission chain 12 is movably clamped in the inner position of the outer frame 11, and the bearing plate 13 and the transmission chain 12 are of an integrated structure.

The bearing plate 13 comprises an upper fishplate bar a1, a boosting strip a2 and a connecting fishplate bar a3, the upper fishplate bar a1 is movably clamped with the connecting fishplate bar a3, the boosting strip a2 is installed between the upper fishplate bar a1 and the connecting fishplate bar a3, and a concave surface is arranged on the upper surface of the upper fishplate bar a1 and can stably bear ores.

The connecting plate a3 comprises an abutting plate a31, an elastic piece a32, a lower swing plate a33 and a lower pushing block a34, wherein the elastic piece a32 is installed between the abutting plate a31 and the lower swing plate a33, the lower pushing block a34 is in clearance fit with the abutting plate a31, and the lower pushing block a34 can push the lower swing plate a33 downwards through the pushing of the lower pushing block a34 by an object, so that the lower swing plate a33 can swing downwards along the abutting plate a31, and the lower pushing block a34 can clamp the other half of broken ore.

The lower swing plate a33 comprises a clamping block b1, a guide frame b2, a plate body b3 and a plate surface b4, wherein the clamping block b1 is embedded in the upper surface of the plate surface b4, the guide frame b2 and the plate body b3 are of an integrated structure, the plate surface b4 is movably clamped with the guide frame b2, the clamping blocks b1 are eight, the upper surfaces of the plate surfaces b4 are uniformly distributed in parallel, and the clamping blocks b1 can extend into the concave surface of ore, so that the grabbing force of the mechanism on the ore can be enhanced.

The detailed use method and action of the embodiment are as follows:

according to the ore conveying device, the machine body 1 shovels ores fed into the hopper 3 through the bearing plate 13 on the internal conveying chain 12 to convey vertically, if deep cracks occur in the ores due to impact in the mining process, the ores are broken into two halves when the bearing plate 13 is shoveled from one side of an ore main body, so that the bearing plate 13 cannot convey the ores broken into two parts at one time, the problem can be effectively solved through the connecting plate a3 on the bearing plate 13, the upper connecting plate a1 can be pushed to extend forwards through the boosting strip a2, the upper connecting plate a1 can shovel and convey the ores fed into the hopper 3, the upper connecting plate a1 can be squeezed through the inner wall of the outer frame 11, the lower pushing block a34 can be squeezed when the upper connecting plate a1 contracts inwards, the lower pushing block a34 can push the lower swinging plate a33 downwards along the elastic sheet a32 to swing downwards, the lower swinging plate a33 can bear the broken ores, the other half of the ores can be pushed inwards to be matched with the elastic sheet a32, and the ores can be prevented from being clamped into the ore main body 13 through the clamping force of the ore 33, and the ore can be prevented from being broken ore from being conveyed into the ore main body at one time.

Example 2

As shown in fig. 6-8:

the clamping block b1 comprises a stress plate b11, a fixing rod b12, a bottom plate b13 and a lifting plate b14, the stress plate b11 is hinged to the lifting plate b14, the fixing rod b12 is embedded in the upper end of the bottom plate b13, the lifting plate b14 is movably clamped with the fixing rod b12, the stress plate b11 is provided with two stress plates, the stress plates are evenly symmetrically distributed on the left side and the right side of the lifting plate b14, the outer side of the stress plate b11 is inwards extruded through small-sized ore, the stress plate b11 can swing inwards along the bottom plate b13, the lifting plate b14 can be driven to ascend upwards along the fixing rod b12 while swinging inwards, and therefore the small-sized ore can be blocked.

Wherein, atress board b11 includes flexure strip c1, movable rod c2, laminating piece c3, bottoming plate c4, flexure strip c1 installs between movable rod c2 and bottoming plate c4, movable rod c2 and the movable block of bottoming plate c4 activity block, laminating piece c3 is connected with movable rod c 2's front end hinge, laminating piece c3 is equipped with threely, and is parallel distribution on bottoming plate c 4's right side through movable rod c 2's the even cooperation, can follow the unsmooth swing on ore surface through laminating piece c3, laminates with the ore surface until laminating piece c 3.

The attaching block c3 comprises a pressing block c31, a combining block c32 and a fixing plate c33, the pressing block c31 and the combining block c32 are of an integrated structure, the combining block c32 is embedded in the right side position of the fixing plate c33, the inside of the pressing block c31 is of an oval structure, and the clamping degree of the mechanism on ores can be enhanced.

The detailed use method and action of the embodiment are as follows:

according to the invention, because the degree of the closing of the lower swing plate a33 after the lower push block a34 is extruded is not so large that ore with small size after being broken cannot be clamped and fixed by the lower swing plate a33, the problem can be effectively solved by matching the stress plate b11 on the lower swing plate a33 with the lifting plate b14, the stress plate b11 can swing inwards along the lifting plate b14 by extruding the stress plate b11 by small ore, the lifting plate b14 can be driven to ascend along the fixing rod b12 while the stress plate b11 swings inwards, so that the stress plate b11 and the lifting plate b14 can block the small ore, the adhesion block c3 can swing along with the concave-convex of the ore surface until the adhesion block c3 is adhered to the ore surface, and the clamping degree of two adjacent stress plates b11 to the small ore can be enhanced by the application block c31, thereby effectively avoiding the situation that the lower swing plate a33 cannot clamp and fix the small ore.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.

Claims

1. The utility model provides an ore lifting machine for mine, its structure includes organism (1), base (2), goes into hopper (3), go into hopper (3) and build in the left side of organism (1) and lean on lower position, its characterized in that: the machine body (1) is welded with the base (2);

the machine body (1) comprises an outer frame (11), a transmission chain (12) and a bearing plate (13), wherein the transmission chain (12) is movably clamped in the inner position of the outer frame (11), and the bearing plate (13) and the transmission chain (12) are of an integrated structure;

the bearing plate (13) comprises upper fishplates (a 1), boosting strips (a 2) and connecting plates (a 3), the upper fishplates (a 1) are movably clamped with the connecting plates (a 3), the boosting strips (a 2) are installed between the upper fishplates (a 1) and the connecting plates (a 3), and concave surfaces are arranged on the upper surfaces of the upper fishplates (a 1) and can stably bear ores;

the connecting plate (a 3) comprises an ejector plate (a 31), an elastic sheet (a 32), a lower swinging plate (a 33) and a lower pushing block (a 34), wherein the elastic sheet (a 32) is installed between the ejector plate (a 31) and the lower swinging plate (a 33), the lower pushing block (a 34) is in clearance fit with the ejector plate (a 31), and the lower swinging plate (a 33) can be pushed downwards by the lower pushing block (a 34) through the extrusion of the lower pushing block (a 34) by an object, so that the lower swinging plate (a 33) can swing downwards along the ejector plate (a 31), and the lower pushing block (a 34) can clamp the other half of broken ore;

the lower swing plate (a 33) comprises clamping blocks (b 1), guide frames (b 2), a plate body (b 3) and a plate surface (b 4), the clamping blocks (b 1) are embedded in the upper surface of the plate surface (b 4), the guide frames (b 2) and the plate body (b 3) are of an integrated structure, the plate surface (b 4) is movably clamped with the guide frames (b 2), the clamping blocks (b 1) are eight, the clamping blocks are uniformly distributed on the upper surface of the plate surface (b 4) in parallel, and the clamping blocks (b 1) can extend into the concave surface of the ore, so that the holding power of the mechanism on the ore can be enhanced;

the clamping block (b 1) comprises a stress plate (b 11), a fixed rod (b 12), a bottom plate (b 13) and a lifting plate (b 14), the stress plate (b 11) is hinged to the lifting plate (b 14), the fixed rod (b 12) is embedded at the upper end of the bottom plate (b 13), the lifting plate (b 14) is movably clamped with the fixed rod (b 12), the stress plate (b 11) is provided with two stress plates which are uniformly and symmetrically distributed on the left side and the right side of the lifting plate (b 14), the outer side of the stress plate (b 11) is inwards extruded through small ore, the stress plate (b 11) can swing inwards along the bottom plate (b 13), and the lifting plate (b 14) can be driven to ascend upwards along the fixed rod (b 12) while swinging inwards, so that the small ore can be blocked;

the stress plate (b 11) comprises elastic pieces (c 1), movable rods (c 2), three attaching blocks (c 3) and a bottoming plate (c 4), the elastic pieces (c 1) are installed between the movable rods (c 2) and the bottoming plate (c 4), the movable rods (c 2) are movably clamped with the bottoming plate (c 4), the attaching blocks (c 3) are hinged to the front ends of the movable rods (c 2), the three attaching blocks (c 3) are arranged, the attaching blocks (c 3) are uniformly matched with the movable rods (c 2) and are distributed on the right side of the bottoming plate (c 4) in parallel, and the attaching blocks (c 3) can swing along with the concave-convex of the surface of ore until the attaching blocks (c 3) are attached to the surface of the ore;

the bonding block (c 3) comprises a pressing block (c 31), a combining block (c 32) and a fixing plate (c 33), the pressing block (c 31) and the combining block (c 32) are of an integrated structure, the combining block (c 32) is embedded at the right side position of the fixing plate (c 33), the pressing block (c 31) is internally of an oval structure, and the clamping degree of a mechanism to ores can be enhanced;

because the machine body (1) shovels ores in the feeding hopper (3) through the bearing plate (13) on the internal transmission chain (12) for vertical transmission, if the ores are deeply cracked due to impact in the mining process, the ores are split into two halves when the bearing plate (13) is shoveled from one side of an ore main body, so that the bearing plate (13) cannot simultaneously transmit the ores split into two parts at one time, the problems can be effectively solved through the connecting plate (a 3) on the bearing plate (13), the upper connecting plate (a 1) can be pushed to forwards extend through the boosting strip (a 2), so that the upper connecting plate (a 1) can shovel and transmit the ores in the feeding hopper (3), the upper connecting plate (a 1) is extruded through the inner wall of the outer frame (11), when the upper connecting plate (a 1) is retracted inwards, the lower pushing block (a 34) is extruded, so that the lower pushing block (a 34) can push the lower swinging plate (a) downwards to push the lower swinging plate (33 a) to be matched with the ore swinging force of the upper swinging plate (33), and the ore swinging of the upper swinging plate (33) can be prevented from passing through the clamping plate (33 a) and the ore swinging concave surface (33 a) and the ore main body (33 a) from being clamped and being matched with the ore clamping force of the ore clamping plate (33 a) so that the ore can be effectively clamped and the ore can be transmitted, the situation that the bearing plate (13) can not simultaneously transmit the ore which is broken into two parts at one time can be caused;

the degree that the lower swing plate (a 33) can be closed after the lower push block (a 34) is extruded is not large, so that ores which are broken into small size cannot be clamped and fixed by the lower swing plate (a 33), the stress plate (b 11) on the lower swing plate (a 33) is matched with the lifting plate (b 14), the problem can be effectively solved, the stress plate (b 11) can swing inwards along the lifting plate (b 14) through the extrusion of the small ores on the stress plate (b 11), the lifting plate (b 14) can be driven to lift along the fixing rod (b 12) while the stress plate (b 11) swings inwards, the stress plate (b 11) and the lifting plate (b 14) can block the small ores, the adhesion block (c 3) can swing along with the concave-convex of the surface of the ores until the adhesion block (c 3) is adhered to the surface of the ores, the application block (c 31) can enhance the degree that the two adjacent stress plates (b 11) can not clamp the small ores, and the situation that the small ores cannot be clamped by the stress plate (b 11) can be effectively avoided.