CN219120292U - Place steady mine geology measuring device - Google Patents

Abstract

The utility model relates to the technical field of mine geological measuring devices, and provides a mine geological measuring device capable of being stably placed, which comprises a mounting frame, a detecting piece and a plurality of supporting components, wherein the detecting piece is movably arranged on the mounting frame, and can be lifted relative to the mounting frame; the installation rack comprises a plurality of support assemblies, wherein the support assemblies are arranged on the outer side of the installation rack along the circumferential direction at intervals, each support assembly comprises a support connecting piece and a ground grabbing mechanism, one end of each support connecting piece is connected with the installation rack, the ground grabbing mechanism is movably connected with the other end of each support connecting piece, and the support assemblies are used for supporting the installation rack. According to the mine geological measuring device with stable placement, the plurality of support assemblies are arranged to jointly support the mounting frame, and the height of the ground grabbing mechanism is adjustable when the ground grabbing mechanism grabs the ground, so that the mounting frame can be adjusted to be in a horizontal state by adjusting the height of the ground grabbing mechanism, and the defect that the existing mine geological measuring device is difficult to horizontally place on an uneven mine, and large errors are generated in measured data is effectively overcome.

Description

Place steady mine geology measuring device

Technical Field

The utility model relates to the technical field of mine geological measuring devices, in particular to a mine geological measuring device capable of being stably placed.

Background

The mine geological measurement is a basic working method in mineral screening and exploration, and is a basic means for systematically observing the geology of a working area or a found mining area, measuring a geological map with a certain proportion, finding out the characteristics of the geological structure, the mineral formation and the occurrence of geological conditions, and providing enough data basis for the subsequent mining or exploration work. The geological measurement of the mine is important, and the measurement error is too large, so that inaccurate knowledge of the geological condition of the mine can be caused, the subsequent production can be seriously and adversely affected, and even casualties can be caused.

The conventional mine geological measuring device is generally difficult to horizontally place on an uneven mine, and large errors can be generated in measured data.

Disclosure of Invention

The utility model provides a mine geological measuring device which is stable to place, and aims to overcome the defect that in the prior art, the mine geological measuring device is difficult to place horizontally on an uneven mine, so that larger errors are generated in measured data.

The utility model provides a mine geological measuring device with stable placement, which comprises:

a mounting frame;

the detection piece is movably arranged on the mounting frame and can move up and down relative to the mounting frame;

the support assembly comprises a support connecting piece and a ground grabbing mechanism, wherein one end of the support connecting piece is connected with the mounting frame, the ground grabbing mechanism is movably connected with the other end of the support connecting piece, the ground grabbing mechanism is used for grabbing the ground, and the support assembly is used for supporting the mounting frame.

According to the mine geological measuring device with stable placement, which is provided by the utility model, the mine geological measuring device with stable placement further comprises a moving mechanism, wherein the moving mechanism is arranged at the bottom of the mounting frame;

the support connecting piece is hinged with the mounting frame, and the support assembly can be overturned and moved to a folding state or an unfolding state relative to the mounting frame; in the folded state, the ground grabbing mechanism is turned over and closed to the outer side of the mounting frame; in the unfolded state, the ground grabbing mechanism is unfolded in a turnover mode to be far away from the mounting frame, and in the vertical direction, the ground grabbing mechanism is located on the lower side of the moving mechanism.

According to the mine geological measuring device with stable placement, the ground grabbing mechanism comprises the ground drilling operation piece and the ground drilling piece, the ground drilling piece is movably connected with the support connecting piece, the ground drilling operation piece is connected with the ground drilling piece, and the ground drilling operation piece can be operated to drive the ground drilling piece to move relative to the support connecting piece so that the ground drilling piece can be pricked into the ground.

According to the mine geological measuring device with stable placement, the ground grabbing mechanism further comprises an auxiliary piece, the auxiliary piece is connected with the ground drilling piece, and the auxiliary piece can synchronously move with the ground drilling piece to be pricked into the ground.

According to the mine geological measuring device with stable placement, the earth-boring part comprises the earth-boring rod, the auxiliary part comprises a plurality of auxiliary drill rods, and the auxiliary drill rods are arranged at intervals around the earth-boring rod and are connected with the earth-boring rod.

According to the mine geological measuring device with stable placement, which is provided by the utility model, the mine geological measuring device with stable placement further comprises a horizontal detecting piece, and the horizontal detecting piece is arranged on the mounting frame.

According to the mine geological measuring device with stable placement, the mine geological measuring device with stable placement further comprises a lifting assembly, the lifting assembly comprises a fixing frame, a lifting operation piece and a moving piece, the fixing frame is connected with the fixing frame, the detecting piece is in sliding connection with the fixing frame, the lifting operation piece is arranged on the fixing frame and is connected with the detecting piece, a groove is formed in the moving piece, one end of the lifting operation piece stretches into the groove, the lifting operation piece is operated to drive the moving piece to move in a lifting mode, and the moving piece drives the detecting piece to move in a lifting mode.

According to the mine geological measuring device with stable placement, the lifting assembly further comprises the limiting piece, the limiting piece is arranged on the fixing frame and is in a limiting state and a non-limiting state, and in the limiting state, the limiting piece prevents the detecting piece from lifting; in the non-limiting state, the lifting operation piece is operated to drive the moving piece to move up and down, and the moving piece drives the detecting piece to move up and down.

According to the mine geological measuring device with stable placement, which is provided by the utility model, the mine geological measuring device with stable placement further comprises a rotating assembly, the rotating assembly comprises the rotating operation piece and the transmission piece, the rotating operation piece is arranged on the mounting frame, the rotating operation piece is connected with the detection piece through the transmission piece, and the rotating operation piece is operated to drive the detection piece to rotate.

According to the mine geological measuring device with stable placement, the rotary assembly further comprises the rotary connecting piece, the rotary connecting piece is rotationally connected with the rotary operating piece and the detecting piece, and the detecting piece can be lifted to drive the rotary operating piece to be lifted synchronously.

According to the mine geological measuring device with stable placement, the plurality of support assemblies are arranged to jointly support the mounting frame, and the height of the ground grabbing mechanism is adjustable when the ground grabbing mechanism grabs the ground, so that the mounting frame can be adjusted to be in a horizontal state by adjusting the height of the ground grabbing mechanism, and the defect that the existing mine geological measuring device is difficult to horizontally place on an uneven mine, and large errors are generated in measured data is effectively overcome.

Drawings

In order to more clearly illustrate the utility model or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the utility model, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a mine geological measuring device with stable placement according to an embodiment of the present utility model;

fig. 2 is a schematic diagram of a partial enlarged structure of a mine geological measuring device with stable placement according to an embodiment of the present utility model.

Reference numerals:

1: a mounting frame; 11: a mounting plate; 12: a column;

2: a detecting member; 21: scale marks; 22: a sampling groove; 23: a blade;

3: a support assembly; 31: a support connection; 32: a ground grabbing mechanism; 321: an earth boring operation member; 322: an earth boring element; 323: an auxiliary member;

4: a moving mechanism; 5: a lifting assembly; 51: a fixing frame; 511: penetrating a cylinder; 52: lifting the operating member; 521: a second rotary handle; 522: a first shaft; 523: a second shaft; 524: a third shaft; 53: a moving member; 531: a groove;

6: a limiting piece; 61: a gear lever; 62: a spring;

7: a rotating assembly; 71: rotating the operating member; 711: a third rotary handle; 712: a rotating rod; 72: a transmission member; 721: a gear; 73: a rotary connector; 731: a sleeve; 732: and (5) connecting a rod.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present utility model, 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.

The stationary mine geological survey apparatus of the present utility model is described below with reference to fig. 1 and 2.

As shown in fig. 1 and 2, the utility model provides a mine geological measuring device with stable placement, which comprises a mounting frame 1, a detecting piece 2 and a plurality of supporting components 3, wherein the detecting piece 2 is movably arranged on the mounting frame 1, and the detecting piece 2 can move up and down relative to the mounting frame 1; the outside of mounting bracket 1 is located along circumference interval to a plurality of supporting component 3, and every supporting component 3 all includes support connecting piece 31 and grabs ground mechanism 32, and the one end of support connecting piece 31 is connected with mounting bracket 1, grabs ground mechanism 32 and the other end swing joint of support connecting piece 31, grabs ground mechanism 32 and is used for grabbing the ground, and supporting component 3 is used for supporting mounting bracket 1.

In this embodiment, the detecting member 2 is used for performing geological measurement, and the detecting member 2 can be moved up and down relative to the mounting frame 1 so that the detecting member 2 can be inserted into an underground soil layer to perform geological measurement work; the plurality of support members 3 support the mounting frame 1 in common. The ground grabbing mechanism 32 is movably connected with the support connecting piece 31, and when the ground grabbing mechanism 32 grabs the ground, the height of the ground grabbing mechanism 32 can be adjusted by adjusting the relative connection position of the ground grabbing mechanism 32 and the support connecting piece 31. When the mine geological measuring device with stable placement of the embodiment is placed on the mine floor, the height of each ground grabbing mechanism 32 is adjusted according to the concave-convex condition of the floor, and the mounting frame 1 can be adjusted to be in a horizontally placed state.

According to the mine geological measuring device with stable placement, the plurality of support assemblies 3 are arranged to jointly support the mounting frame 1, the ground grabbing mechanism 32 is movably connected with the support connecting piece 31, and the height of the ground grabbing mechanism 32 during ground grabbing is adjustable, so that the mounting frame 1 can be adjusted to be in a horizontal state by adjusting the height of the ground grabbing mechanism 32, and the defect that the conventional mine geological measuring device is difficult to horizontally place on an uneven mine, and large errors are caused in measured data is effectively overcome.

Specifically, the mine geological measuring device with stable placement further comprises a moving mechanism 4, and the moving mechanism 4 is arranged at the bottom of the mounting frame 1; the support connecting piece 31 is hinged with the mounting frame 1, and the support assembly 3 can be overturned relative to the mounting frame 1 to a folded state or an unfolded state; in the folded state, the ground grabbing mechanism 32 is turned over and closed to the outer side of the mounting frame 1; in the unfolded state, the ground grasping mechanism 32 is unfolded to be away from the mount 1, and in the vertical direction, the ground grasping mechanism 32 is located on the lower side of the moving mechanism 4.

In the embodiment, the moving mechanism 4 is arranged, so that the mine geological measuring device which is stably placed is convenient to move; in the folded state, the ground grabbing mechanism 32 is turned over and close to the outer side of the mounting frame 1, so that the ground grabbing mechanism 32 is convenient to store, and the moving mechanism 4 is convenient to drive the mounting frame 1 to move; in the unfolded state, the ground grabbing mechanism 32 is turned over and unfolded to be far away from the mounting frame 1 so as to support the mounting frame 1, the ground grabbing mechanism 32 is located on the lower side of the moving mechanism 4, the moving mechanism 4 can be prevented from contacting the ground, the moving mechanism 4 is prevented from moving, and the mounting frame 1 is supported more stably and reliably.

In one particular embodiment, the movement mechanism 4 comprises a plurality of universal wheels.

In a specific embodiment, the mounting frame 1 comprises two mounting plates 11 and a plurality of upright posts 12, the two mounting plates 11 are arranged in parallel at intervals, the two mounting plates 11 are connected through the plurality of upright posts 12, the detecting element 2 penetrates through the two mounting plates 11, and in a folded state, the ground grabbing mechanism 32 can be turned over to rest on the mounting plate 11 below.

Further, in this embodiment, the mounting frame 1 is in a horizontal state, that is, when the mine geological measuring device with stable placement is in a horizontal state, the two mounting plates 11 are arranged at intervals up and down, and the two mounting plates 11 are both in a horizontal state.

In a specific embodiment, the support connection member 31 includes two support rods, wherein one end of one support rod is hinged to the mounting frame 1, the other end of the support rod is integrally connected to one end of the other support rod, the other end of the other support rod is connected to the ground grabbing mechanism 32, the two support rods form a V-shaped structure, and an included angle between the two support rods is greater than 90 °.

Specifically, the ground grabbing mechanism 32 includes an earth boring operation member 321 and an earth boring member 322, the earth boring member 322 is movably connected with the support connection member 31, the earth boring operation member 321 is connected with the earth boring member 322, and the earth boring operation member 321 is operated to drive the earth boring member 322 to move relative to the support connection member 31 so as to make the earth boring member 322 prick into the ground.

In this embodiment, through setting up boring the earth operating member 321 and boring the earth piece 322, be convenient for drive boring the earth piece 322 and remove, make boring the earth piece 322 and can prick ground more easily, it is more laborsaving, through adjusting the penetration depth of each boring the earth piece 322 to will place steady mine geology measuring device and adjust to the horizontality.

In one particular embodiment, the earth-boring manipulator 321 includes a first rotary handle, the earth-boring manipulator 322 includes an earth-boring rod having threads on a circumferential outer wall thereof, the earth-boring rod extending through the support link 31 and threadably coupled to the support link 31, and the earth-boring rod is driven to rotate by rotating the first rotary handle to move the earth-boring rod relative to the support link 31.

Specifically, the ground grabbing mechanism 32 further includes an auxiliary member 323, the auxiliary member 323 is connected to the ground penetrating member 322, and the auxiliary member 323 is movable synchronously with the ground penetrating member 322 to penetrate the ground.

In this embodiment, the auxiliary member 323 can move synchronously with the ground drilling member 322 to penetrate the ground, so that the ground grabbing effect of the ground grabbing mechanism 32 is better, and the support of the mounting frame 1 is more stable.

In one embodiment, the auxiliary element 323 includes a plurality of auxiliary drill rods spaced about and each connected to the earth-boring rod.

Further, in this embodiment, the auxiliary drill rod includes a drill section and a connection section, the drill section is parallel to the drill section, one end of the drill section is integrally formed with one end of the connection section, and the other end of the connection section is rotatably connected with the drill section.

Further, in the present embodiment, when the ground gripping mechanism 32 grips the ground, the ends of the earth-boring bar and the auxiliary drill bar facing the ground are pointed so that the earth-boring bar and the auxiliary drill bar can be more easily penetrated into the ground.

Specifically, place steady mine geology measuring device still includes level detection spare 2, and level detection spare 2 locates mounting bracket 1.

In this embodiment, through setting up level detection spare 2, can real-time detection place steady mine geology measuring device whether be in the horizontality, help promoting the measuring accuracy of detection spare 2.

In one embodiment, the level detecting member 2 comprises a bubble level, and has a simple structure and low cost.

Specifically, place steady mine geology measuring device still includes lifting unit 5, lifting unit 5 includes mount 51, lift operating piece 52 and moving part 53, mount 51 is connected with mounting bracket 1, detecting part 2 and mount 51 sliding connection, mount 51 is located to lift operating piece 52, moving part 53 is connected with detecting part 2, be equipped with recess 531 on the moving part 53, in the one end of lift operating piece 52 stretched into recess 531, the elevating movement of operating part 53 drivable moving part 53 of operation lift, moving part 53 drives detecting part 2 elevating movement.

In this embodiment, through setting up lifting unit 5, can drive detection piece 2 to go up and down to detection piece 2 goes deep into the underground and carries out the measurement work, and is more laborsaving.

In a specific embodiment, the lifting operation member 52 includes a second rotating handle 521, a first shaft lever 522, a second shaft lever 523 and a third shaft lever 524, the moving member 53 includes a bar-shaped lever, the fixing frame 51 is connected with the fixing frame 1, the fixing frame 51 has two penetrating cylinders 511, the detecting member 2 penetrates the bar-shaped lever and is rotationally connected with the bar-shaped lever, the bar-shaped lever is not perpendicular to the detecting member 2, the first shaft lever 522 is parallel to the third shaft lever 524, the second shaft lever 523 and the bar-shaped lever are perpendicular to the third shaft lever 524, the first shaft lever 522 is perpendicular to the detecting member 2, the first shaft lever 522 is rotationally connected with the fixing frame 51, one end of the first shaft lever 522 is connected with the second rotating handle 521, the other end of the first shaft lever 522 is connected with one end of the second shaft lever 523, one side of the bar-shaped lever 523 facing the third shaft lever 524 is provided with a groove 531, and the other end of the third shaft lever 524 extends into the groove 531; the second rotating handle 521 is rotated to drive the first shaft 522 to rotate, so that the third shaft 524 moves in the groove 531 through the third shaft 524 in a circular motion, and thus the bar and the detecting member 2 are driven to lift.

Specifically, the lifting assembly 5 further includes a limiting member 6, the limiting member 6 is disposed on the fixing frame 51, the limiting member 6 has a limiting state and a non-limiting state, and in the limiting state, the limiting member 6 prevents the lifting movement of the detecting member 2; in the non-limiting state, the lifting operation piece 52 is operated to drive the moving piece 53 to move up and down, and the moving piece 53 drives the detecting piece 2 to move up and down.

In this embodiment, through setting up locating part 6, avoided detecting part 2 to lead to detecting part 2's high unusual decline because of reasons such as self gravity, be in spacing state through setting up locating part 6, make detecting part 2 maintain at a fixed height, be convenient for measure the work, need not the manual work and maintain detecting part 2's high unchangeable, saved the manpower.

In a specific embodiment, the limiting member 6 includes a stop lever 61 and a spring 62, one end of the spring 62 is connected with the fixing frame 51, the other end of the spring 62 is connected with the stop lever 61, when the spring 62 is in a natural state, the limiting member 6 is in a limiting state, and at this time, the stop lever 61 blocks the lifting operation member 52 from moving, so as to prevent the detection member 2 from lifting; when the spring 62 is contracted or bent by an external force, and the stop lever 61 cannot stop the lifting operation member 52 from moving, the limiting member 6 is in an unlimited state, the lifting operation member 52 is operated to drive the moving member 53 to move up and down, and the moving member 53 drives the detecting member 2 to move up and down.

Specifically, the mine geological measuring device with stable placement further comprises a rotating assembly 7, the rotating assembly 7 comprises a rotating operation member 71 and a transmission member 72, the rotating operation member 71 is arranged on the mounting frame 1, the rotating operation member 71 is connected with the detecting member 2 through the transmission member 72, the rotating operation member 71 is operated, and the detecting member 2 can be driven to rotate.

In this embodiment, through setting up rotatory operating piece 71 and driving medium 72 for detecting piece 2 can rotate, so that adjust the orientation of detecting piece 2, make detecting piece 2 better accomplish the detection work, perhaps through rotatory, the elevating movement of collocation detecting piece 2 makes detecting piece 2 prick the ground more easily and carries out the measurement work, more laborsaving.

In a specific embodiment, the rotary operating member 71 includes a third rotary handle 711 and a rotary rod 712, the transmission member 72 includes two gears 721, the third rotary handle 711 is connected to one end of the rotary rod 712, the rotary rod 712 is slidably disposed on the mounting frame 1, the two gears 721 are sleeved on the rotary rod 712 and the detecting member 2 in a one-to-one correspondence manner, the two gears 721 are meshed, the third rotary handle 711 is rotated to rotate the rotary rod 712, and the detecting member 2 is rotated by transmission of the two gears 721.

In a specific embodiment, the detecting member 2 includes a detecting rod, the bottom of the detecting rod is a tip with a wide top and a narrow bottom, so that the detecting rod can be pricked into the ground more easily when lifted, and the peripheral outer wall of the tip is provided with an external thread, so that the detecting rod can be pricked into the ground more easily when lifted by rotation.

In one embodiment, graduation marks 21 are provided on the outer wall of the sensing element 2 for depth measurement.

In a specific embodiment, the outer wall of the detecting member 2 is provided with a plurality of sampling mechanisms with different heights, each sampling mechanism comprises a sampling groove 22 and a blade 23, the blade 23 is arranged on one side of the sampling groove 22, the blade 23 is provided with an inclined surface for guiding the sampling groove 22, when the detecting member 2 moves, the blade 23 scrapes off a soil sample, the soil sample falls into the sampling groove 22, and the collection of the soil sample is completed.

Specifically, the rotating assembly 7 further includes a rotating connecting piece 73, the rotating connecting piece 73 is rotationally connected with the rotating operating piece 71 and the detecting piece 2, and the detecting piece 2 is lifted and lowered, so that the rotating operating piece 71 can be driven to lift and lower synchronously.

In this embodiment, the rotary connection member 73 is rotatably connected to both the rotary operation member 71 and the detecting member 2, so that the rotary operation member 71 and the detecting member 2 can be lifted synchronously, and the detecting member 2 can still be driven to rotate by operating the rotary operation member 71 when lifted, so that the lifting of the rotary operation member 71 is not required to be controlled manually, and both hands are liberated.

In a specific embodiment, the rotary connector 73 includes a connecting rod 732 and two sleeves 731, and the rotary operating member 71 and the detecting member 2 are rotatably sleeved with one sleeve 731, and the two sleeves 731 are connected by the connecting rod 732.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. A mining geological survey device for stable placement, comprising:

a mounting frame;

the detection piece is movably arranged on the mounting frame and can move up and down relative to the mounting frame;

the support assembly comprises a support connecting piece and a ground grabbing mechanism, wherein one end of the support connecting piece is connected with the mounting frame, the ground grabbing mechanism is movably connected with the other end of the support connecting piece, the ground grabbing mechanism is used for grabbing the ground, and the support assembly is used for supporting the mounting frame.

2. The stationary mining geological survey according to claim 1, further comprising a moving mechanism provided at the bottom of the mounting frame;

the support connecting piece is hinged with the mounting frame, and the support assembly can be overturned and moved to a folding state or an unfolding state relative to the mounting frame; in the folded state, the ground grabbing mechanism is turned over and closed to the outer side of the mounting frame; in the unfolded state, the ground grabbing mechanism is unfolded in a turnover mode to be far away from the mounting frame, and in the vertical direction, the ground grabbing mechanism is located on the lower side of the moving mechanism.

3. The stationary mining geological survey system according to claim 1, wherein said ground grasping means comprises an earth boring operation member movably connected to said support connection member and an earth boring operation member connected to said earth boring member, said earth boring operation member being operable to drive said earth boring member to move relative to said support connection member to cause said earth boring member to penetrate the ground.

4. A stationary mine geological survey according to claim 3, wherein the grappling mechanism further comprises an auxiliary member connected to the earth-boring member, the auxiliary member being movable in synchronism with the earth-boring member to dig into the ground.

5. The stationary mining geological survey system according to claim 4 wherein said earth-boring member comprises an earth-boring rod, said auxiliary member comprises a plurality of auxiliary drill rods, a plurality of said auxiliary drill rods being spaced around and connected to said earth-boring rod.

6. The stationary mining geological survey according to claim 1, further comprising a level detecting member provided to the mounting frame.

7. The mine geology measuring device capable of being placed stably according to claim 1, further comprising a lifting assembly, wherein the lifting assembly comprises a fixing frame, a lifting operation piece and a moving piece, the fixing frame is connected with the fixing frame, the detecting piece is in sliding connection with the fixing frame, the lifting operation piece is arranged on the fixing frame, the moving piece is connected with the detecting piece, a groove is formed in the moving piece, one end of the lifting operation piece stretches into the groove, the lifting operation piece is operated to drive the moving piece to move in a lifting mode, and the moving piece drives the detecting piece to move in a lifting mode.

8. The stationary mine geological survey of claim 7, wherein said lifting assembly further comprises a stop member, said stop member being disposed on said fixed frame, said stop member having a stop position and a non-stop position, said stop member preventing lifting movement of said detection member in said stop position; in the non-limiting state, the lifting operation piece is operated to drive the moving piece to move up and down, and the moving piece drives the detecting piece to move up and down.

9. The stationary mining geological survey system according to claim 7, further comprising a rotating assembly, wherein the rotating assembly comprises a rotating operating member and a transmission member, the rotating operating member is provided on the mounting frame, the rotating operating member is connected with the detecting member through the transmission member, and the rotating operating member is operated to drive the detecting member to rotate.

10. The mining geological survey system according to claim 9, wherein the rotating assembly further comprises a rotating connecting member, the rotating connecting member is rotationally connected with the rotating operating member and the detecting member, and the detecting member is lifted and lowered to drive the rotating operating member to be lifted and lowered synchronously.

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