CN112985877A - Rock ore sample parameter measuring device for geological exploration - Google Patents

Abstract

The invention relates to the geological exploration field, in particular to a rock ore sample parameter measuring device for geological exploration, which comprises a cylinder body, wherein one end of the cylinder body is movably connected with a sampling assembly, the outer wall of the cylinder body is fixedly connected with a measuring assembly, the outer wall of the cylinder body is connected with an interaction assembly in an inserted manner, and the other end of the cylinder body is fixedly connected with a storage assembly. The device is favorable for outdoor long-term use through the arrangement of the movable support and the solar panel, and the dependence on the battery is reduced.

Description

Rock ore sample parameter measuring device for geological exploration

Technical Field

The invention relates to the field of geological exploration, in particular to a rock ore specimen parameter measuring device for geological exploration.

Background

The geological exploration is to survey and research 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 foundation parameters, find an industrially significant mineral deposit in mineral product general survey, provide mineral product reserves and geological data required by mine construction design for finding out the mineral product quality and quantity and the technical conditions of mining and utilization, and investigate and research geological conditions such as rocks, strata, structures, mineral products, hydrology, landforms and the like in a certain area.

Geological exploration generally needs to investigate the mineral distribution condition and the formation time on site, the dependence on the personal ability of workers in the process is large, and the workers with insufficient experience are prone to errors, so a rock ore sample parameter measuring device for geological exploration is provided.

Disclosure of Invention

The invention aims to provide a rock ore sample parameter measuring device for geological exploration, which aims to solve the problems in the background technology.

In order to achieve the purpose, the rock ore sample parameter measuring device for geological exploration comprises a barrel, wherein one end of the barrel is movably connected with a sampling assembly, the outer wall of the barrel is fixedly connected with a measuring assembly, the outer wall of the barrel is connected with an interaction assembly in an inserted manner, and the other end of the barrel is fixedly connected with a storage assembly;

the sampling component comprises a motor, a rotating shaft, a cutting disc and an outer protective sleeve, wherein the motor is fixedly connected with one end of the inner part of the barrel, the rotating shaft is connected with one end of the motor in a rotating mode, the cutting disc is connected with one end of the rotating shaft in a threaded mode, and the outer protective sleeve is inserted into the surface of the outer wall of the cutting disc in a inserting mode.

Preferably: the measuring component comprises a box body, a second motor, a second rotating shaft, a disc, a sliding groove, a positioning block, a positioning knob and a laser scanning panel, the outer wall of the barrel is fixedly connected with the box body, the second motor is fixedly connected with the inside of the barrel, the second rotating shaft is rotatably connected with the second rotating shaft, the second rotating shaft extends into the disc which is fixedly connected with the inside of the box body, three groups of sliding grooves are uniformly formed in the upper edge of the disc, the positioning block is connected to the inside of the sliding groove in a sliding mode, one end of the positioning block is in threaded connection with the positioning knob, the two groups of laser scanning panels are fixedly connected with the inside of the box body, an operator can perform preliminary measurement on a rock ore sample in advance under the outdoor condition through the arrangement of the measuring component, and.

Preferably: mutual subassembly is including outer mutual groove, apron, charging wire, movable support and solar panel, outer mutual groove has been seted up to the outer wall of barrel, the outer wall in outer mutual groove is pegged graft and is had the apron, the one end in outer mutual groove is pegged graft and is had the charging wire, the one end fixedly connected with movable support of charging wire, the upper end of movable support is rotated and is connected with solar panel, conveniently fills for the device is whole can and with inside data file direction outside through setting up of mutual subassembly.

Preferably: the storage assembly comprises a storage chamber, a separation frame, a movable plate and an outer sealing cover, the storage chamber is formed in one end, away from the sampling assembly, of the barrel, the separation frame is inserted in the middle of the inner wall of the storage chamber in an inserted mode, the movable plate is rotatably connected to the surface of the separation frame, the outer sealing cover is connected to one end, away from the sampling assembly, of the barrel in a threaded mode, and the cut sample plate can be stored and carried to a laboratory through the storage assembly in a simple and convenient mode to perform precise chemical measurement.

Preferably: the inside of cutting dish rotates and is connected with the cutting piece, the one end of cutting piece and the one end fixed connection of pivot, the size of outer protective sheath and the size looks adaptation of cutting dish make the structure of device more stable.

Preferably: the top of box body is pegged graft and is had the lid, the size of spout and the size looks adaptation of locating piece can fix the sample at the upper surface of disc to a certain extent through the setting of locating piece to it is fixed with the locating piece through the location knob.

Preferably: the lower end of the positioning knob is sleeved with a rectangular clamping block, vertical stripes are uniformly distributed on the lower surface of the rectangular clamping block, the rectangular clamping block is connected with the positioning block in a sliding mode through the positioning knob, and the size of the upper surface of the sliding groove is matched with the size of the stripes on the lower surface of the rectangular clamping block, so that the positioning block can be stably stopped inside the sliding groove.

Preferably: the outer mutual groove divide into data output groove and charging groove again, the size of apron and the size looks adaptation in outer mutual groove, through the daily use that mutual groove makes things convenient for the device outward, and the use in mutual groove is safer outward through the setting up of apron.

Preferably: the movable support comprises support legs and a rod body, the support legs are evenly distributed at the bottom of the rod body, one ends of the support legs are connected with one ends of the rod body in a rotating mode, a rectangular groove which is vertical to the support leg in size matching is formed in the bottom of the outer wall of the rod body, and charging wires are fixedly connected to the outer wall of the rod body so as to charge the device and facilitate long-term use of the device.

Preferably: the size of apotheca and the inner wall size looks adaptation of barrel, the inner wall of apotheca still bonds there is the buffering floorcloth, the size of activity board and the size looks adaptation of separate shelf, the inner wall of apotheca still set up with the arc spout of activity board one end size looks adaptation, through the upset of activity board can be further with the inside separation of apotheca to multiunit sample collection.

Compared with the prior art, the invention has the beneficial effects that:

1. assemble the cutting disc to the one end of barrel, take off outer protective sheath, the starter motor makes the inside cutting disc of cutting disc rotate through the pivot and is used for cutting the stratum under outdoor conditions, makes the stratum sample more quick simple and convenient under outdoor conditions.

2. The rock stratum model after will gathering is put into the inside of box body, scan the sample that the disc surface was placed through the laser scanning panel, the data that will obtain after the scanning passes through the bluetooth, the data output groove that wiFi or outer interaction groove department contained transmits to external equipment such as cell-phone through the mode of data line, again with scanning data transmission to high in the clouds, the relevant information of file acquisition sample in the contrast database, make the experience requirement to the worker further descend in the geological survey, make things convenient for the investigation of many people different directions simultaneously, the work efficiency has been accelerated to the edgewise.

3. The inside of apotheca is put into to the sample after the collection, helps separating the different samples of multiunit through separate shelf and fly leaf, helps the integration of outdoor sample reconnaissance, and the device helps outdoor long-term use through being provided with of movable support and solar panel, has reduced the dependence to the battery.

4. The rotary shaft is arranged through the storage assembly, so that the rock ore is collected, measured, stored and carried integrally, the daily work of workers in the exploration industry is facilitated, and the sample plate after cutting is conveniently brought into a laboratory to be subjected to precise chemical measurement.

Drawings

FIG. 1 is a schematic elevation view of a rock and ore specimen parameter measuring device for geological exploration, according to the present invention;

FIG. 2 is a schematic top view of a device for measuring parameters of a rock ore specimen for geological exploration according to the present invention;

FIG. 3 is a schematic view of the internal structure of a measuring assembly of the rock and ore specimen parameter measuring device for geological exploration;

FIG. 4 is a schematic structural diagram of a part of an interactive component of the rock and ore specimen parameter measuring device for geological exploration;

FIG. 5 is a schematic view of a part of the storage assembly of the device for measuring parameters of a rock ore specimen for geological exploration;

FIG. 6 is a schematic structural diagram of a peripheral component of a positioning block of the device for measuring parameters of a rock ore specimen for geological exploration.

In the figure:

1. a barrel; 2. a sampling assembly; 21. a motor; 22. a rotating shaft; 23. cutting the disc; 24. an outer protective sheath; 3. a measurement assembly; 31. a box body; 32. a second motor; 33. a second rotating shaft; 34. a disc; 35. a chute; 36. positioning blocks;

37. positioning a knob; 38. a laser scanning panel; 4. an interaction component; 41. an outer interaction slot; 42. a cover plate; 43. a charging wire; 44. a movable support; 45. a solar panel; 5. a storage assembly; 51. a storage chamber; 52. a spacer; 53. a movable plate; 54. and an outer sealing cover.

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 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.

Referring to fig. 1-6, which are a preferred embodiment of the present invention, a rock and ore sample parameter measuring device for geological exploration includes a cylinder 1, one end of the cylinder 1 is movably connected with a sampling assembly 2, the outer wall of the cylinder 1 is fixedly connected with a measuring assembly 3, the outer wall of the cylinder 1 is connected with an interaction assembly 4 in an inserting manner, and the other end of the cylinder 1 is fixedly connected with a storage assembly 5;

sampling subassembly 2 includes motor 21, pivot 22, cutting dish 23 and outer protective sheath 24, and the inside one end fixedly connected with motor 21 of barrel 1, the one end of motor 21 are rotated and are connected with pivot 22, and the one end threaded connection of pivot 22 has cutting dish 23, and the outer wall surface of cutting dish 23 is pegged graft and is had outer protective sheath 24

As shown in fig. 1-6, the measuring assembly 3 includes a box 31, a second motor 32, a second rotating shaft 33, a disc 34, a sliding groove 35, a positioning block 36, a positioning knob 37 and a laser scanning panel 38, the outer wall of the barrel 1 is fixedly connected with the box 31, the inside of the barrel 1 is fixedly connected with the second motor 32, one end of the second motor 32 is rotatably connected with the second rotating shaft 33, the second rotating shaft 33 extends into the inside one end of the box 31 and is fixedly connected with the disc 34, three groups of sliding grooves 35 are uniformly formed on the upper side of the disc 34, the inside of the sliding grooves 35 is slidably connected with the positioning block 36, one end of the positioning block 36 is threadedly connected with the positioning knob 37, and the inside of the box 31 is.

Mutual subassembly 4 includes outer mutual groove 41, apron 42, charging wire 43, movable support 44 and solar panel 45, and outer mutual groove 41 has been seted up to the outer wall of barrel 1, and the outer wall in outer mutual groove 41 is pegged graft and is had apron 42, and the one end in outer mutual groove 41 is pegged graft and is had charging wire 43, and charging wire 43's one end fixedly connected with movable support 44, movable support 44's upper end rotation is connected with solar panel 45.

The storage assembly 5 comprises a storage chamber 51, a partition frame 52, a movable plate 53 and an outer sealing cover 54, the storage chamber 51 is arranged at one end of the cylinder 1 far away from the sampling assembly 2, the partition frame 52 is inserted in the middle of the inner wall of the storage chamber 51, the movable plate 53 is rotatably connected to the surface of the partition frame 52, and the outer sealing cover 54 is connected to one end of the cylinder 1 far away from the sampling assembly 2 in a threaded manner.

The inside of cutting disc 23 rotates and is connected with the cutting piece, and the one end of cutting piece and the one end fixed connection of pivot 22, the size of outer protective sheath 24 and the size looks adaptation of cutting disc 23.

The top of the box body 31 is inserted with a box cover, and the size of the sliding groove 35 is matched with that of the positioning block 36.

The lower extreme of location knob 37 has cup jointed the rectangle fixture block, and the lower surface evenly distributed of rectangle fixture block has vertical stripe, and the rectangle fixture block passes through location knob 37 and locating piece 36 sliding connection, and the upper surface size of spout 35 has the lower surface stripe size looks adaptation with the rectangle fixture block.

The outer interaction slot 41 is divided into a data output slot and a charging slot, and the size of the cover plate 42 is matched with that of the outer interaction slot 41.

The movable support 44 comprises support legs and a rod body, wherein the three groups of support legs are uniformly distributed at the bottom of the rod body, one ends of the support legs are respectively connected with one end of the rod body in a rotating mode, a rectangular groove which is vertical to the support leg in size matching is formed in the bottom of the outer wall of the rod body, and the outer wall of the rod body is fixedly connected with a charging wire 43.

The size of the storage chamber 51 is matched with the size of the inner wall of the barrel 1, the inner wall of the storage chamber 51 is further bonded with a buffer cloth liner, the size of the movable plate 53 is matched with the size of the separation frame 52, and the inner wall of the storage chamber 51 is further provided with an arc-shaped sliding groove matched with the size of one end of the movable plate 53.

Wherein, the one end that sampling component 2 was kept away from to the outer wall of barrel 1 is provided with anti-skidding line, and the start button setting of device is at the outer wall of barrel 1, and cutting disc 23, movable support 44 and solar panel 45 homoenergetic when the device is idle break away from with barrel 1, help depositing and carrying of device.

In this embodiment, during field investigation, the user assembles the cutting disc 23 to one end of the cylinder 1, takes off the outer protective sleeve 24, starts the motor 21 to rotate the cutting blade inside the cutting disc 23 through the rotating shaft 22 to cut the rock stratum under outdoor conditions, puts the collected rock stratum sample plate into the box 31, the laser scanning panel 38 scans the sample placed on the surface of the disc 34, the data obtained after scanning is transmitted to external devices such as a mobile phone and the like through a data line by a data output slot included in a bluetooth, WiFi or external interaction slot 41, and then the scanned data is transmitted to the cloud, the information related to the sample is obtained by comparing the files in the database, the collected sample is placed in the storage chamber 51, the separation of a plurality of groups of different samples is facilitated through the separation frame 52 and the movable plate 53, the integration of outdoor sample investigation is facilitated, and the device is facilitated to be used outdoors for a long time through the arrangement of the movable support 44 and the solar panel 45.

While the invention has been described in further detail in connection with specific embodiments thereof, it will be understood that the invention is not limited thereto, and that various other modifications and substitutions may be made by those skilled in the art without departing from the spirit of the invention, which should be considered to be within the scope of the invention as defined by the appended claims.

Claims (10)

1. A rock ore sample parameter measuring device for geological exploration comprises a barrel body (1), wherein one end of the barrel body (1) is movably connected with a sampling assembly (2), the outer wall of the barrel body (1) is fixedly connected with a measuring assembly (3), the outer wall of the barrel body (1) is connected with an interaction assembly (4) in an inserting mode, and the other end of the barrel body (1) is fixedly connected with a storage assembly (5);

the method is characterized in that: the sampling component (2) comprises a motor (21), a rotating shaft (22), a cutting disc (23) and an outer protective sleeve (24), the motor (21) is fixedly connected with one end of the barrel body (1), the rotating shaft (22) is connected with one end of the motor (21) in a rotating mode, the cutting disc (23) is connected with one end of the rotating shaft (22) in a threaded mode, and the outer protective sleeve (24) is connected with the outer wall surface of the cutting disc (23) in an inserting mode.

2. The apparatus according to claim 1, wherein the apparatus comprises: the measuring component (3) comprises a box body (31), a second motor (32), a second rotating shaft (33), a disc (34), a chute (35), a positioning block (36), a positioning knob (37) and a laser scanning panel (38), the outer wall of the cylinder body (1) is fixedly connected with a box body (31), the interior of the cylinder body (1) is fixedly connected with a second motor (32), one end of the second motor (32) is rotationally connected with a second rotating shaft (33), one end of the second rotating shaft (33) extending into the box body (31) is fixedly connected with a disc (34), three groups of sliding grooves (35) are uniformly arranged on the upper edge of the disc (34), positioning blocks (36) are connected inside the sliding grooves (35) in a sliding manner, one end of the positioning block (36) is in threaded connection with a positioning knob (37), and two groups of laser scanning panels (38) are fixedly connected inside the box body (31).

3. The apparatus according to claim 1, wherein the apparatus comprises: mutual subassembly (4) are including outer mutual groove (41), apron (42), charging wire (43), movable support (44) and solar panel (45), outer mutual groove (41) have been seted up to the outer wall of barrel (1), the outer wall of outer mutual groove (41) is pegged graft and is had apron (42), the one end of outer mutual groove (41) is pegged graft and is had charging wire (43), the one end fixedly connected with movable support (44) of charging wire (43), the upper end of movable support (44) is rotated and is connected with solar panel (45).

4. The apparatus according to claim 1, wherein the apparatus comprises: the storage assembly (5) comprises a storage chamber (51), a separation frame (52), a movable plate (53) and an outer sealing cover (54), the storage chamber (51) is formed in one end, away from the sampling assembly (2), of the barrel body (1), the separation frame (52) is inserted in the middle of the inner wall of the storage chamber (51), the movable plate (53) is rotatably connected to the surface of the separation frame (52), and the outer sealing cover (54) is connected to one end, away from the sampling assembly (2), of the barrel body (1) in a threaded mode.

5. The apparatus according to claim 1, wherein the apparatus comprises: the inside of cutting dish (23) is rotated and is connected with the cutting piece, the one end of cutting piece and the one end fixed connection of pivot (22), the size of outer protective sheath (24) and the size looks adaptation of cutting dish (23).

6. The apparatus according to claim 2, wherein the apparatus comprises: the top of the box body (31) is inserted with a box cover, and the size of the sliding groove (35) is matched with that of the positioning block (36).

7. The apparatus according to claim 2, wherein the apparatus comprises: the lower end of the positioning knob (37) is sleeved with a rectangular fixture block, vertical stripes are uniformly distributed on the lower surface of the rectangular fixture block, the rectangular fixture block is connected with the positioning block (36) in a sliding mode through the positioning knob (37), and the size of the upper surface of the sliding groove (35) is matched with the size of the stripes on the lower surface of the rectangular fixture block.

8. The apparatus according to claim 3, wherein the apparatus comprises: the outer interaction groove (41) is divided into a data output groove and a charging groove, and the size of the cover plate (42) is matched with that of the outer interaction groove (41).

9. The apparatus according to claim 3, wherein the apparatus comprises: the movable support (44) comprises support legs and a rod body, the support legs are evenly distributed at the bottom of the rod body, one ends of the support legs are connected with one ends of the rod body in a rotating mode, a rectangular groove which is vertical to the support legs in size matching is formed in the bottom of the outer wall of the rod body, and charging wires (43) are fixedly connected to the outer wall of the rod body.

10. The apparatus according to claim 4, wherein the apparatus comprises: the size of the storage chamber (51) is matched with the size of the inner wall of the barrel body (1), the inner wall of the storage chamber (51) is further bonded with a buffer cloth liner, the size of the movable plate (53) is matched with the size of the separation frame (52), and the inner wall of the storage chamber (51) is further provided with an arc-shaped sliding groove matched with the size of one end of the movable plate (53).

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