CN215963788U - Stable work geology sample reducing mechanism - Google Patents

Abstract

The utility model discloses a geological sampling and crushing device with stable work, which relates to the field of geological exploration and comprises a heating box, wherein a group of preliminary crushing rollers are rotatably arranged on the inner side of the heating box through a connecting rod, one side of each preliminary crushing roller is rotatably arranged on an external driving device through the connecting rod, a cover plate is embedded in the top of the heating box, and a heat insulation plate is welded at the axis of the top of the cover plate. This steady operation geology sample reducing mechanism, through heating module and ventilative net, can realize the preliminary drying to the ore, guaranteed that the ore can not take place the phenomenon of agglomeration after smashing, avoid the ore powder to adhere to at the device inner wall simultaneously, the crushing ejection of compact effect of device has been improved, this steady operation geology sample reducing mechanism, through gas transmission hole and water supply valve, can avoid the inner wall siltation ore powder and the moisture of the device, sample inaccurate and equipment rust when leading to reuse, the reuse deployment time of the device has been reduced.

Description

Stable work geology sample reducing mechanism

Technical Field

The utility model relates to the technical field of geological exploration, in particular to a geological sampling and crushing device capable of working stably.

Background

The geological exploration is to survey and detect geology by various means and methods, determine a proper bearing stratum, determine a foundation type according to the foundation bearing capacity of the bearing stratum, calculate the investigation and research activities of basic parameters, find an industrially significant mineral deposit in the mineral product general survey, provide mineral product reserves and geological data required by mine construction design for finding out the quality and quantity of the mineral product and the technical conditions of mining and utilization, and carry out investigation and research work on the geological conditions of rocks, strata, structures, mineral products, hydrology, landforms and the like in a certain area.

One of the flows of geological exploration is smashed the sample of ore, in the actual adoption in-process, because adopt quantity less, consequently, the mode of adopting the grinding more often smashes, but along with the aggravation of geological exploration task, often need handle a wholesale ore, therefore the mode of artifical grinding just is unsuitable, traditional crushing apparatus is before the grinding, all need expose to the sun the drying to the ore, prevent that ore powder from taking place the phenomenon of conglomeration because too moist, finally lead to the sample failure, at last just ore powder is very easily at the inside siltation of reducing mechanism, be unfavorable for the sample, and the ore powder of siltation pollutes next batch of ore powder easily, lead to chemical examination detection distortion.

SUMMERY OF THE UTILITY MODEL

The utility model provides a stable working geological sampling and crushing device, which can realize primary drying of ores through a heating module and a breathable net, ensure that the ores are not agglomerated after being crushed, simultaneously avoid mineral powder from being attached to the inner wall of the device, and avoid the inner wall of the device from being silted up with the mineral powder through a gas transmission hole and a water supply valve, so that inaccurate sampling is caused during reuse, and the reuse and deployment time of the device is shortened.

In order to achieve the purpose, the utility model is realized by the following technical scheme: a geological sampling and crushing device with stable work comprises a heating box, wherein a group of preliminary crushing rollers are arranged on the inner side of the heating box through the rotation of a connecting rod, one side of each preliminary crushing roller is arranged on an external driving device through the rotation of the connecting rod, a cover plate is embedded at the top of the heating box, a heat insulation plate is welded at the axis of the top of the cover plate, a breathable net is embedded on the inner side of the cover plate, a lifting motor is fixedly arranged at the axis of the inner side of the heat insulation plate through bolts, a threaded rod is arranged at the output end of the lifting motor through the rotation of a rotating shaft, a lifting plate is sleeved at one end of the threaded rod, a fixed connecting rod is embedded at the inner side of the lifting plate, a group of lifting slide blocks are welded on the outer wall of the lifting plate, the outer wall of each lifting slide block is arranged at the inner side of the heating box in a sliding manner through a sliding chute, and heating blocks are welded at the position, close to the bottom, on the inner wall of the heating box, and the outer wall of the heating module is attached to the primary crushing roller.

In order to prevent air from flowing, it is preferable that the stable working geological sampling and crushing device of the utility model is characterized in that a group of air transmission holes are formed at the bottom of the lifting plate, one end of each air transmission hole is communicated with an external air supply device through a hose, and the lifting plate is in a concentric circular ring shape.

In order to prevent excessive discharging, it is preferable that, as a stable working geological sampling crushing device of the utility model, the bottom of the heating box is communicated with a conveying pipe, the inner wall of the conveying pipe is rotatably provided with a supporting inclined plate through a hinge, the outer side of the conveying pipe is in threaded connection with an adjusting bolt, one end of the adjusting bolt is welded with a supporting spring, and one end of the supporting spring, which is far away from the adjusting bolt, is welded at the bottom of the supporting inclined plate.

In order to improve the crushing effect of the device, the geological sampling crushing device with stable work is preferably used as the geological sampling crushing device with stable work, the bottom of the conveying pipeline is communicated with the sampling box, the inner wall of the sampling box, close to the top, is welded with the crushing shell, the inner side of the crushing shell is rotatably embedded with the complete crushing roller group, and one side of the complete crushing roller is rotatably arranged on the external driving device through the connecting rod.

In order to improve the crushing precision of the device, the geological sampling crushing device with stable work is preferably used, the inner wall of the crushing shell is attached to the outer wall of the complete crushing roller, the bottom of the crushing shell is welded with the screen, the screen and the complete crushing roller are attached to each other, and the recovery box is arranged right below the screen in a sliding mode.

In order to improve the convenience of the device, it is preferable that the geological sampling and crushing device with stable work is provided with a water supply valve communicated with the inner wall of the heating box, and one end of the water supply valve is communicated with an external water supply device through a hose.

The utility model provides a geological sampling and crushing device capable of working stably. The method has the following beneficial effects:

(1) this stabilize geology sample reducing mechanism of working through heating module and ventilative net, can realize the preliminary drying to the ore, has guaranteed that the ore can not take place the phenomenon of agglomeration after smashing, avoids the ore powder to adhere to the device inner wall simultaneously, has improved the crushing ejection of compact effect of device.

(2) This steady operation geology sample reducing mechanism through gas transmission hole and feed water valve, can avoid the inner wall siltation ore deposit powder and moisture of the device, and the sampling is inaccurate and the wading of a writing brush rusts when leading to reuse, has reduced the device's reuse deployment time.

Drawings

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

FIG. 2 is a cross-sectional view of the damper spring according to the present invention;

fig. 3 is a rear view of the present invention.

In the figure: 1. a heating box; 2. a water supply valve; 3. a gas transmission hole; 4. a lifting plate; 5. a heating module; 6. a threaded rod; 7. a primary crushing roller; 8. adjusting the bolt; 9. a sampling box; 10. supporting the inclined plate; 11. a support spring; 12. a delivery conduit; 13. crushing the shell; 14. screening a screen; 15. a complete crushing roller; 16. a recovery box; 17. a lifting motor; 18. a heat insulation plate; 19. a breathable net; 20. a cover plate; 401. a lifting slide block; 402. and fixing the connecting rod.

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.

Examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

Referring to fig. 1-3, the present invention provides a technical solution: a geological sampling and crushing device with stable work comprises a heating box 1, wherein a group of preliminary crushing rollers 7 are arranged on the inner side of the heating box 1 in a rotating mode through connecting rods, one side of each preliminary crushing roller 7 is arranged on an external driving device in a rotating mode through the connecting rods, a cover plate 20 is embedded in the top of the heating box 1, a heat insulation plate 18 is welded at the top axis of the cover plate 20, a breathable net 19 is embedded in the inner side of the cover plate 20, a lifting motor 17 is fixedly arranged at the inner side axis of the heat insulation plate 18 through bolts, a threaded rod 6 is arranged at the output end of the lifting motor 17 in a rotating mode through a rotating shaft, a lifting plate 4 is sleeved at one end of the threaded rod 6, a fixed connecting rod 402 is embedded in the inner side of the lifting plate 4, a group of lifting slide blocks 401 are welded on the outer wall of the lifting slide blocks 401 and are arranged on the inner side of the heating box 1 in a sliding mode through sliding grooves, and heating modules 5 are welded on the inner wall of the heating box 1 close to the bottom, and the outer wall of the heating module 5 is attached to the preliminary crushing roller 7.

In this embodiment: through heat insulating board 18, can realize the thermal-insulated protection to elevator motor 17, avoid elevator motor 17 long-term work in high temperature environment, lead to its life-span to reduce, through lifter plate 4, can realize the stable extrusion to the ore, guarantee at preliminary crushing roller 7's crushing efficiency, through heating module 5, can heat the ore in advance, prevent because ore humidity is great, lead to ore powder agglomeration to adhere to heating cabinet 1 inner wall.

Specifically, a group of air delivery holes 3 are formed in the bottom of the lifting plate 4, one ends of the air delivery holes 3 are communicated with an external air supply device through hoses, and the lifting plate 4 is in a concentric circular ring shape.

In this embodiment: through gas transmission hole 3, can carry the hot gas flow of heating module 5 to the bottom, avoid the inside ore deposit powder of device to adhere to the inboard of dry this device prevents inside rust.

Specifically, the bottom intercommunication of heating cabinet 1 is provided with pipeline 12, and the inner wall of pipeline 12 is provided with support swash plate 10 through hinge rotation, and pipeline 12's outside threaded connection has adjusting bolt 8, and adjusting bolt 8's one end welding is provided with supporting spring 11, and supporting spring 11 keeps away from adjusting bolt 8's one end welding and sets up in the bottom department of supporting swash plate 10.

In this embodiment: through supporting swash plate 10, can realize tentatively storing ore powder, avoid smashing 15 disposable feeds of cylinder completely too much, lead to unable repeated grinding to smash.

Specifically, the bottom intercommunication of pipeline 12 is provided with sampling box 9, and the inner wall of sampling box 9 is close to top department welding and is provided with crushing shell 13, and the inboard of crushing shell 13 is rotated and is inlayed and be equipped with a set of crushing roller 15 completely, and one side of crushing roller 15 completely passes through the connecting rod rotation and sets up in external drive device.

In this embodiment: through crushing shell 13, can realize supporting preliminary kibbling ore, avoid preliminary kibbling ore to roll and break away from the region of smashing cylinder 15 completely, and then lead to smashing incompletely.

Specifically, the inner wall of the crushing shell 13 is attached to the outer wall of the complete crushing roller 15, the bottom of the crushing shell 13 is welded with the screen 14, the screen 14 and the complete crushing roller 15 are attached to each other, and the recovery box 16 is slidably arranged right below the screen 14.

In this embodiment: through the screen 14, can realize the stable screening to ore powder, avoid not reaching the ore powder ejection of compact of smashing standard.

Specifically, a water supply valve 2 is disposed on the inner wall of the heating box 1 in a communicating manner, and one end of the water supply valve 2 is disposed on an external water supply device through a hose in a communicating manner.

In this embodiment: through water supply valve 2, can realize washing the device inboard, when avoiding using again, the ore powder of attached to the inner wall influences the sampling precision.

When in use, firstly the cover plate 20 and the lifting plate 4 are opened, the ore to be crushed is placed in the heating box 1, then the cover plate 20 is closed, the smoothness of the breathable net 19 is ensured, then the heating module 5 is started, the hot air flows upwards, the certain dryness of all the ore is ensured, then the lifting motor 17 and the primary crushing roller 7 are started, the lifting motor 17 drives the lifting plate 4 to extrude the ore through the threaded rod 6, the primary crushing roller 7 performs primary crushing on the ore, then the primary crushed ore drops onto the supporting inclined plate 10, when the certain weight is reached, the supporting inclined plate 10 inclines, the primary crushed ore drops into the crushing shell 13, finally the crushing is performed through the complete crushing roller 15, when the ore powder reaches the specified specification, the ore powder leaks out from the screen 14 and enters into the recovery box 16, the user can take out the device, when the device needs to be used again, the water supply valve 2 is opened firstly, so that the cleaning liquid washes the inner wall of the device, then the heating module 5 is opened, and hot air is blown to the bottom of the device through the air delivery hole 3, so that dust prevention and moisture prevention of siltation in the device are guaranteed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (6)

1. The utility model provides a steady operation geology sample reducing mechanism, includes heating cabinet (1), its characterized in that: the inner side of the heating box (1) is provided with a group of primary crushing rollers (7) in a rotating mode through a connecting rod, one side of each primary crushing roller (7) is arranged on an external driving device in a rotating mode through the connecting rod, a cover plate (20) is embedded at the top of the heating box (1), a heat insulation plate (18) is welded at the top axle center of the cover plate (20), a breathable net (19) is embedded in the inner side of the cover plate (20), a lifting motor (17) is fixedly arranged at the inner side axle center of the heat insulation plate (18) through bolts, a threaded rod (6) is arranged at the output end of the lifting motor (17) in a rotating mode through a rotating shaft, a lifting plate (4) is sleeved at one end of the threaded rod (6), a fixed connecting rod (402) is embedded in the inner side of the lifting plate (4), a group of lifting sliding blocks (401) are welded on the outer wall of the lifting plate (4), and the outer wall of the lifting blocks (401) is arranged at the inner side of the heating box (1) in a sliding mode through a sliding chute, the inner wall of the heating box (1) is provided with a heating module (5) close to the bottom in a welding mode, and the outer wall of the heating module (5) is attached to a primary crushing roller (7).

2. A steady-working geological sampling comminution apparatus as claimed in claim 1 in which: a group of air delivery holes (3) are formed in the bottom of the lifting plate (4), one ends of the air delivery holes (3) are communicated with an external air supply device through hoses, and the lifting plate (4) is in a concentric circular ring shape.

3. A steady-working geological sampling comminution apparatus as claimed in claim 1 in which: the bottom intercommunication of heating cabinet (1) is provided with pipeline (12), and the inner wall of pipeline (12) is provided with support swash plate (10) through hinge rotation to the outside threaded connection of pipeline (12) has adjusting bolt (8), the one end welding of adjusting bolt (8) is provided with supporting spring (11), and the one end welding that adjusting bolt (8) were kept away from in supporting spring (11) sets up in the bottom department of supporting swash plate (10).

4. A steady-working geological sampling comminution apparatus as claimed in claim 3 in which: the bottom intercommunication of pipeline (12) is provided with sampling box (9), and the inner wall of sampling box (9) is close to top department welding and is provided with crushing shell (13), the inboard of crushing shell (13) is rotated and is inlayed and is equipped with a set of crushing roller (15) completely, and the one side of crushing roller (15) completely passes through the connecting rod and rotates and set up in external drive device.

5. A steady working geological sampling comminution device as claimed in claim 4 in which: the inner wall of the crushing shell (13) is attached to the outer wall of the complete crushing roller (15), the bottom of the crushing shell (13) is welded with a screen (14), the screen (14) and the complete crushing roller (15) are attached to each other, and a recovery box (16) is arranged under the screen (14) in a sliding mode.

6. A steady-working geological sampling comminution apparatus as claimed in claim 1 in which: the inner wall of the heating box (1) is communicated with a water supply valve (2), and one end of the water supply valve (2) is communicated with an external water supply device through a hose.

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