CN218938272U - Rotatable mineral sample testing mechanism - Google Patents

Abstract

The utility model discloses a rotatable mineral sample testing mechanism, wherein a U-shaped frame is positioned in a box body, the U-shaped frame is rotationally connected with the right side surface of the box body through a transmission shaft, the right end of the transmission shaft is exposed out of the box body and is provided with a first gear, the lower end of the right side surface of the box body is provided with a motor, the output end of the motor is provided with a second gear, a first clamping disk and a second clamping disk are symmetrically arranged in the U-shaped frame up and down, the first clamping disk is rotationally connected with the U-shaped frame through a connecting shaft, a third gear is arranged at one end of the connecting shaft exposed out of the U-shaped frame, the outer surface of the upper end surface of the U-shaped frame is provided with an electric push rod I, a rack is arranged on a piston rod of the electric push rod I, the lower end surface of the U-shaped frame is provided with an electric push rod II, the clamping disk is rotationally connected with a detection head driving mechanism, and a detection head is positioned in the box body. The utility model has the advantages that: the position of the mineral sample can be flexibly adjusted, the position of the detection head can be adjusted, and the testing efficiency is greatly improved.

Description

Rotatable mineral sample testing mechanism

Technical Field

The utility model relates to the technical field of testers, in particular to a rotatable mineral sample testing mechanism.

Background

The existing mineral sample detection mechanism mainly comprises a box body, a tray and a detection head, when the mineral sample is detected, the mineral sample is placed on the tray in the box body, the position of the mineral sample to be detected on the tray is relatively fixed, the detection head cannot comprehensively detect all parts of the mineral sample, the placement position of the mineral sample needs to be manually and frequently adjusted, and only the time consumption of the mineral sample test is long.

Disclosure of Invention

The utility model aims to solve the technical problem and provides a rotatable mineral sample testing mechanism which can flexibly adjust the position of a mineral sample, can adjust the position of a detection head and greatly improve the testing efficiency.

In order to solve the technical problems, the technical scheme provided by the utility model is as follows: the utility model provides a rotatable mineral sample testing mechanism, includes box, positioning mechanism and detection head, positioning mechanism includes U type frame, presss from both sides tight dish first and presss from both sides tight dish second, U type frame is located the box, U type frame passes through the transmission shaft and rotates with the box right flank and be connected, the transmission shaft right-hand member exposes the box, and is equipped with gear one, box right flank lower extreme is equipped with the motor, be equipped with gear two on the output of motor, gear two and gear one meshing, the symmetry is equipped with tight dish first and tight dish second of clamp from top to bottom in the U type frame, it is connected with U type frame rotation through the connecting axle to press from both sides tight dish first, be equipped with gear three on the one end that the connecting axle exposes U type frame, U type frame up end surface is equipped with electric putter one, be equipped with the rack on the piston rod of electric putter one, rack and gear three meshing, the terminal surface is equipped with electric putter second under the U type frame, piston rod and U type frame sliding connection, it is connected with electric putter's piston rod rotation terminal surface, be equipped with the tight dish second and the detection head on the box, detection head is located the detection head, detection head is internal to drive.

Further, actuating mechanism includes electric putter three, electric putter four and spout, the spout sets up at the box up end, box up end corresponds the department with the spout position and is equipped with the fluting, sliding connection has the slider in the spout, the spout openly is equipped with electric putter three, electric putter's piston rod is connected with the slider, the slider up end is equipped with electric putter four, electric putter four's piston rod and slider sliding connection, and expose from the fluting, electric putter four's piston rod is connected with the detection head.

Further, the motor is arranged on the upper end face of the supporting plate, and a reinforcing block is arranged between the supporting plate and the box body.

Further, a control box is arranged on the side face of the box body.

Compared with the prior art, the utility model has the advantages that:

1. the motor rotates, the transmission shaft is driven to rotate through the meshing of the gear II and the gear I, and the transmission shaft drives the U-shaped frame to rotate, so that the mineral sample rotates in the vertical direction, manual overturning is not needed, and the comprehensiveness of detection is improved;

2. the piston rod of the first electric push rod stretches to drive the gear III to rotate, the gear III drives the clamping disc to rotate through the connecting shaft, and the clamping disc drives the ore sample to rotate in the horizontal direction, so that the comprehensiveness of detection is further improved;

3. the piston rod of the electric push rod III stretches out and draws back to drive the sliding block to move in the sliding groove, and the sliding block adjusts the position of the detection head above the horizontal through the electric push rod IV, so that the detection head can test a plurality of positions of a mineral sample, and the comprehensiveness of detection is improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

fig. 2 is a top view of the chute of the present utility model.

Reference numerals: 1. the box body, 2, the detection head, 3, U-shaped frame, 4, clamping disk one, 5, clamping disk two, 6, transmission shaft, 7, gear one, 8, motor, 9, gear two, 10, reinforcement block, 11, control box, 12, connecting axle, 13, gear three, 14, electric putter one, 15, rack, 16, electric putter two, 17, electric putter three, 18, electric putter four, 19, spout, 20, slider, 21, backup pad.

Detailed Description

The following description of the technical solutions in the embodiments of the present utility model will be clear and complete, and it is obvious that the described embodiments are only some embodiments of the present utility model, but not all embodiments. 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.

It should be noted that all directional indications such as up, down, left, right, front, and rear … … in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture such as that shown in the drawings, and if the specific posture is changed, the directional indication is changed accordingly.

Furthermore, descriptions such as those referred to as "first," "second," and the like, are provided for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implying an order of magnitude of the indicated technical features in the present disclosure. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The utility model will now be further described with reference to the accompanying drawings.

Referring to fig. 1, a first clamping disc 4 and a second clamping disc 5 are vertically symmetrically arranged in the U-shaped frame 3, the first clamping disc 4 is rotationally connected with the U-shaped frame 3 through a connecting shaft 12, an electric push rod II 16 is arranged on the lower end face of the U-shaped frame 3, a piston rod of the electric push rod II 16 is slidably connected with the U-shaped frame 3, and the second clamping disc 5 is rotationally connected with a piston rod of the electric push rod II 16.

And placing the mineral sample to be tested between the first clamping disk 4 and the second clamping disk 5, and extending a piston rod of the second electric push rod 16 to drive the second clamping disk 5 to move towards the first clamping disk 10, so that the second clamping disk 5 and the first clamping disk 4 clamp and fix the mineral sample together.

Referring to fig. 1, the U-shaped frame 3 is located in the case 1, the U-shaped frame 3 is rotatably connected with the right side surface of the case 1 through a transmission shaft 6, the right end of the transmission shaft 6 is exposed out of the case 1 and provided with a gear one 7, the lower end of the right side surface of the case 1 is provided with a motor 8, the output end of the motor 8 is provided with a gear two 9, and the gear two 9 is meshed with the gear one 7.

When the mineral sample needs to be overturned in the horizontal direction, and therefore other positions of the mineral sample are detected, the motor 8 rotates, the transmission shaft 6 is driven to rotate through the meshing of the gear II 9 and the gear I7, the transmission shaft 6 drives the U-shaped frame 3 to rotate, the mineral sample is further enabled to rotate in the vertical direction, and the position of the mineral sample towards the detection head 2 is adjusted.

Referring to fig. 1, the first clamping disc 4 is rotatably connected with the U-shaped frame 3 through a connecting shaft 12, a third gear 13 is arranged at one end of the connecting shaft 12 exposed out of the U-shaped frame 3, an electric push rod 14 is arranged on the outer surface of the upper end face of the U-shaped frame 3, a rack 15 is arranged on a piston rod of the electric push rod 14, and the rack 15 is meshed with the third gear 13.

When the mineral sample needs to be overturned in the vertical direction, and therefore other positions of the mineral sample are detected, a piston rod of the electric push rod I14 stretches out and draws back to drive the gear III 13 to rotate, the gear III 13 drives the clamping disc I4 to rotate through the connecting shaft 12, the clamping disc I4 drives the mineral sample to rotate in the horizontal direction, and the position of the mineral sample towards the detection head 2 is adjusted.

With reference to fig. 1-2, the chute 19 is arranged on the upper end surface of the box body 1, a slot is formed in the position, corresponding to the chute 19, of the upper end surface of the box body 1, a sliding block 20 is slidably connected in the chute 19, an electric push rod III 17 is arranged on the front surface of the chute 19, a piston rod of the electric push rod III 17 is connected with the sliding block 20, an electric push rod IV 18 is arranged on the upper end surface of the sliding block 20, a piston rod of the electric push rod IV 18 is slidably connected with the sliding block 20 and is exposed from the slot, and a piston rod of the electric push rod IV 18 is connected with the detection head 2.

The piston rod of the electric push rod III 17 stretches out and draws back to drive the sliding block 20 to move in the sliding groove 19, and the sliding block 20 adjusts the position of the detection head 2 above the horizontal through the electric push rod IV 18, so that the detection head 2 can test a plurality of positions of a mineral sample. The electric push rod four 18 positions the detection head 2 at an appropriate height.

The utility model and its embodiments have been described in a non-limiting manner, and the actual construction is not limited to the embodiments of the utility model as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present utility model.

Claims (4)

1. Rotatable ore sample testing mechanism, including box (1), positioning mechanism and detection head (2), its characterized in that: the positioning mechanism comprises a U-shaped frame (3), a first clamping disk (4) and a second clamping disk (5), wherein the U-shaped frame (3) is positioned in a box body (1), the U-shaped frame (3) is rotationally connected with the right side surface of the box body (1) through a transmission shaft (6), the right end of the transmission shaft (6) is exposed out of the box body (1), a first gear (7) is arranged, the lower end of the right side surface of the box body (1) is provided with a motor (8), the output end of the motor (8) is provided with a second gear (9), the second gear (9) is meshed with the first gear (7), the first clamping disk (4) and the second clamping disk (5) are vertically symmetrically arranged in the U-shaped frame (3), the first clamping disk (4) is rotationally connected with the U-shaped frame (3) through a connecting shaft (12), one end of the connecting shaft (12) exposed out of the U-shaped frame (3) is provided with a third gear (13), the outer surface of the upper end surface of the U-shaped frame (3) is provided with a first electric push rod (14), the first electric push rod (14) is meshed with the second electric push rod (16), the second electric push rod (16) is meshed with the second electric push rod (16) and the second electric push rod (16) is meshed with the second electric push rod (16), the clamping plate II (5) is rotationally connected with a piston rod of the electric push rod II (16), a detection head driving mechanism is arranged on the upper end face of the box body (1), the detection head (2) is located in the box body (1), and the detection head driving mechanism drives the detection head (2) to move.

2. A rotatable mineral sample testing mechanism in accordance with claim 1 wherein: the driving mechanism comprises an electric push rod III (17), an electric push rod IV (18) and a sliding groove (19), wherein the sliding groove (19) is formed in the upper end face of the box body (1), a groove is formed in the position, corresponding to the position of the sliding groove (19), of the upper end face of the box body (1), a sliding block (20) is connected in the sliding groove (19) in a sliding mode, the electric push rod III (17) is arranged on the front face of the sliding groove (19), a piston rod of the electric push rod III (17) is connected with the sliding block (20), the electric push rod IV (18) is arranged on the upper end face of the sliding block (20), a piston rod of the electric push rod IV (18) is connected with the sliding block (20) in a sliding mode, the piston rod of the electric push rod IV (18) is exposed from the groove, and the piston rod of the electric push rod IV (18) is connected with the detection head (2).

3. A rotatable mineral sample testing mechanism in accordance with any one of claims 1 to 2 wherein: the motor (8) is arranged on the upper end face of the supporting plate (21), and a reinforcing block (10) is arranged between the supporting plate (21) and the box body (1).

4. A rotatable mineral sample testing mechanism in accordance with claim 1 wherein: the side of the box body (1) is provided with a control box (11).

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