CN219777671U - Experimental equipment for rock ore specimen identification analysis - Google Patents

Abstract

The utility model discloses experimental equipment for rock and mineral specimen identification and analysis, which comprises a device bottom plate, a first motor and a first device shell, wherein the first device shell is arranged at the top end of the device bottom plate, the first motor is arranged at the bottom end of one end of the first device shell, a positive and negative screw rod penetrating into the first device shell is arranged at the output end of the first motor, a connecting sliding plate is sleeved at both ends of the outer side of the positive and negative screw rod, one end of the connecting sliding plate is hinged with a mounting plate, a fourth motor is arranged at one end of the top end of the mounting plate, a rotating plate is arranged at the output end of the fourth motor, and a fifth device shell is uniformly arranged at one end of the rotating plate. According to the utility model, the fourth device shell is driven to rotate by the third motor, and when the fourth device shell rotates to a set position, the first motor drives the positive and negative screw rod to rotate and drives the mounting plate to rise, so that the device can store samples when in use.

Description

Experimental equipment for rock ore specimen identification analysis

Technical Field

The utility model relates to the technical field of rock and mineral identification experimental equipment, in particular to experimental equipment for rock and mineral specimen identification analysis.

Background

The method has the advantages that the method is characterized in that the method is provided with rich mineral resources in China, the existence of the mineral resources plays an important role in the economic development and the national enhancement of China, so that a solid material foundation is laid for the economic development by analyzing and identifying the rock and ore and then collecting the rock and ore, the development of geological work is accelerated, and the basic work in the geological work is the analysis and identification of the rock and ore.

The experimental equipment used in the current market has certain limitations, for example, the existing experimental equipment is not provided with a mechanism special for placing the specimen, and is easy to confuse with other specimens; meanwhile, the conventional experimental equipment cannot be used for placing some common instruments required by identification, and the situation that the instruments cannot be found in the identification process easily occurs, so that the conventional experimental equipment has certain limitations.

Disclosure of Invention

The utility model aims to provide experimental equipment for rock and mineral specimen identification and analysis, which aims to solve the problem that the prior experimental equipment for rock and mineral specimen identification and analysis is provided in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an experimental facilities of rock ore deposit sample appraisal analysis, includes device bottom plate, first motor and first device shell, first device shell is installed on the top of device bottom plate, and the bottom of first device shell one end installs first motor, first motor output installs the positive and negative lead screw that runs through to the inside of first device shell, and positive and negative lead screw outside both ends all overlap and be equipped with the handing-over slide, the one end of handing-over slide articulates there is the mounting panel, the fourth motor is installed to the one end on mounting panel top, and the output of fourth motor installs the revolving plate, the one end of revolving plate evenly installs the fifth device shell, and one side of fifth device shell installs the third motor, the third motor output installs the fourth device shell that runs through to the inside of fifth device shell, and the bottom that the revolving plate one end was kept away from to the fourth device shell articulates there is the apron, the through-hole has been seted up to the one end on first device shell top, and the one end that the first device shell top is close to the through-hole installs the detection frame, the inside top that keeps away from detection frame one end has the third device shell, and the third device shell is installed on the one end, and the third device shell is installed to the third device shell, and the third device shell is installed to the second motor top, the second device shell is kept away from the first end and the first end is kept away from the first gear and the top of the first device shell is installed on the first end.

Preferably, the two ends of the first device shell are provided with first sliding grooves, and the first guiding rods are vertically arranged in the first sliding grooves.

Preferably, the outside of the first guide rod is sleeved with a sliding block connected with the mounting plate, and the sliding block is in sliding connection with the first guide rod.

Preferably, the toothed plate bottom is provided with a second chute penetrating into the toothed plate, and a second guide rod connected with the bottom inside the third device shell is arranged inside the second chute.

Preferably, the top of apron articulates there is the cardboard, fourth device shell top is close to apron one end and installs the dead lever that runs through the cardboard, and the fixture block is installed to dead lever top.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the fourth device shell is driven to rotate by the third motor, and when the fourth device shell rotates to a set position, the first motor drives the positive and negative screw rod to rotate and drives the mounting plate to ascend, so that the device can store a sample when in use;

2. according to the utility model, the second motor drives the gear to drive the second device shell to lift, so that the second device shell can be lifted to store materials when the device is used, and the phenomenon of confusion is not easy to occur.

Drawings

FIG. 1 is a schematic view of a front cross-sectional structure of the present utility model;

FIG. 2 is a schematic diagram of a front view structure of the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

fig. 4 is an enlarged view of the portion B of fig. 1 according to the present utility model.

In the figure: 1. a device base plate; 2. a first motor; 3. a first device housing; 4. a mounting plate; 5. a first guide bar; 6. a first chute; 7. a second guide bar; 8. a second motor; 9. a gear; 10. a toothed plate; 11. a second device housing; 12. a third device housing; 13. a through hole; 14. a detection frame; 15. a fourth device housing; 16. a third motor; 17. a rotating plate; 18. a fourth motor; 19. a fifth device housing; 20. a slide block; 21. a connecting slide plate; 22. a positive and negative screw rod; 23. a second chute; 24. a cover plate; 25. a clamping plate; 26. a clamping block; 27. and a fixing rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the implementations described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, an embodiment of an experimental apparatus for identifying and analyzing a rock sample is provided in the present utility model: the experimental equipment for rock and mineral specimen identification and analysis comprises a device bottom plate 1, a first motor 2 and a first device shell 3, wherein the first device shell 3 is arranged at the top end of the device bottom plate 1, first sliding grooves 6 are formed in two ends of the interior of the first device shell 3, first guide rods 5 are vertically arranged in the first sliding grooves 6, sliding blocks 20 connected with a mounting plate 4 are sleeved on the outer sides of the first guide rods 5, and the sliding blocks 20 are in sliding connection with the first guide rods 5;

the bottom end of one end of the first device shell 3 is provided with a first motor 2, the output end of the first motor 2 is provided with a positive and negative screw rod 22 penetrating into the first device shell 3, two ends of the outer side of the positive and negative screw rod 22 are sleeved with a connecting sliding plate 21, one end of the connecting sliding plate 21 is hinged with a mounting plate 4, one end of the top end of the mounting plate 4 is provided with a fourth motor 18, the output end of the fourth motor 18 is provided with a rotating plate 17, one end of the rotating plate 17 is uniformly provided with a fifth device shell 19, one side of the fifth device shell 19 is provided with a third motor 16, the output end of the third motor 16 is provided with a fourth device shell 15 penetrating into the fifth device shell 19, and the bottom end of the fourth device shell 15 far away from one end of the rotating plate 17 is hinged with a cover plate 24;

the top end of the cover plate 24 is hinged with a clamping plate 25, a fixing rod 27 penetrating through the clamping plate 25 is arranged at one end, close to the cover plate 24, of the top end of the fourth device shell 15, a clamping block 26 is arranged at the top end of the fixing rod 27, a through hole 13 is formed in one end, close to the through hole 13, of the top end of the first device shell 3, a detection frame 14 is arranged at one end, close to the through hole 13, of the top end, far from the detection frame 14, of the first device shell 3, a third device shell 12 is arranged at one end, far from the detection frame 14, of the top end, inside the third device shell 12, far from the detection frame 14, of the top end, close to the detection frame 14, of the second motor 8, a gear 9 is arranged at the output end of the second motor 8, and one end of the gear 9 is meshed with a toothed plate 10;

the second chute 23 penetrating into the toothed plate 10 is arranged at the bottom end of the toothed plate 10, the second guide rod 7 connected with the bottom end inside the third device housing 12 is arranged inside the second chute 23, and the second device housing 11 penetrating through the top end of the first device housing 3 is arranged at one end, far away from the second motor 8, of the toothed plate 10.

Working principle: when the device is used, the rotating plate 17 is driven by the fourth motor 18 to drive the fourth device shell 15 to rotate to a preset position, the fourth device shell 15 is driven by the third motor 16 to rotate, the forward and reverse screw rods 22 are driven by the first motor 2 to rotate when the fourth device shell 15 rotates to the preset position, the delivery slide plate 21 is driven to move when the forward and reverse screw rods 22 rotate, the mounting plate 4 is driven to move when the delivery slide plate 21 moves, the fourth motor 18 is driven to move upwards when the mounting plate 4 is driven to move upwards, the through holes 13 of the ejection through holes 13 of the fourth device shell 15 are driven to take samples in the fourth device shell 15 when the fourth motor 18 moves to the preset position, meanwhile, the detection frame 14 is used for observing and detecting the samples, the gear 9 is driven by the second motor 8 to drive the gear 9 to move when the forward and reverse screw rods 22 rotate, the second device shell 11 is driven to move from the inside of the third device shell 12 when the forward and reverse screw rods 22 move, the device can take samples out of the samples when the samples are required to be taken for detection and analysis, and the detection frame 14 can be used for detecting the samples, and all the samples can be detected and analyzed quickly.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides an experimental facilities of rock ore deposit sample identification analysis, includes device bottom plate (1), first motor (2) and first device shell (3), its characterized in that: the utility model discloses a detection device, including device bottom plate (1), first device shell (3) are installed on the top of device bottom plate (1), and first motor (2) are installed to the bottom of first device shell (3) one end, positive and negative lead screw (22) that run through to the inside of first device shell (3) are installed to first motor (2) output, and positive and negative lead screw (22) outside both ends all overlap and are equipped with handing-over slide (21), the one end of handing-over slide (21) articulates there is mounting panel (4), fourth motor (18) are installed to the one end on mounting panel (4) top, and the output of fourth motor (18) installs revolving plate (17), the one end of revolving plate (17) is evenly installed fifth device shell (19), and one side of fifth device shell (19) is installed third motor (16), fourth device shell (15) that run through to the inside of fifth device shell (19) are installed to third motor (16) output, and the bottom of fourth device shell (15) one end is kept away from revolving plate (17) end articulates there is apron (24), the one end is installed on the one end on the top of first device shell (3), and first device shell (13) is equipped with through-hole (13) and is kept away from first device shell (13) top end (13) and is installed on the top of first device shell (13), and second motor (8) are installed on the top that detects frame (14) one end was kept away from to inside third device shell (12), gear (9) are installed to the output of second motor (8), and the one end meshing of gear (9) has pinion rack (10), second device shell (11) that run through first device shell (3) top are installed to one end that second motor (8) were kept away from to pinion rack (10).

2. The experimental facility for rock and mineral specimen identification and analysis according to claim 1, wherein: the two ends of the inside of the first device shell (3) are provided with first sliding grooves (6), and the inside of each first sliding groove (6) is vertically provided with a first guide rod (5).

3. The experimental facility for rock and mineral specimen identification and analysis according to claim 2, wherein: the outside of the first guide rod (5) is sleeved with a sliding block (20) connected with the mounting plate (4), and the sliding block (20) is in sliding connection with the first guide rod (5).

4. The experimental facility for rock and mineral specimen identification and analysis according to claim 1, wherein: the bottom end of the toothed plate (10) is provided with a second chute (23) penetrating into the toothed plate (10), and a second guide rod (7) connected with the bottom end inside the third device shell (12) is arranged inside the second chute (23).

5. The experimental facility for rock and mineral specimen identification and analysis according to claim 1, wherein: the top of apron (24) articulates there is cardboard (25), dead lever (27) that run through cardboard (25) are installed near apron (24) one end on fourth device shell (15) top.

6. The experimental facility for rock and mineral specimen identification and analysis according to claim 5, wherein: a clamping block (26) is arranged at the top end of the fixing rod (27).