CN210400346U - Geological disaster displacement automatic monitoring equipment - Google Patents

Abstract

The utility model discloses a geological disasters displacement automatic monitoring equipment, including the automatic monitoring equipment body, the automatic monitoring equipment body includes the cavity protection pipe and the cable joint who is connected with the cavity protection pipe, the movable sleeve is equipped with one side and is the protective housing that the opening set up on the cavity protection pipe, sets up the first groove that one side set up for the opening on the top inner wall of protective housing, and top one side fixed mounting of cavity protection pipe has first triangle piece, and one side that first triangle piece is close to the cable joint is established to the inclined plane, and one side movable contact that cable joint was kept away from to first triangle piece has the second triangle piece. The utility model relates to a rationally, convenient operation, the quick cable of being convenient for is connected with cable joint, and labour saving and time saving is convenient for protect cable joint, and is convenient for take off the protective housing fast and installs the cable, avoids causing the phenomenon of cable separation at the in-process cable joint that uses and external striking, is favorable to using.

Description

Geological disaster displacement automatic monitoring equipment

Technical Field

The utility model relates to an automatic monitoring equipment technical field especially relates to a geological disasters displacement automatic monitoring equipment.

Background

According to the general outline of the existing foreign research, in the aspect of realizing the landslide deep displacement monitoring method, a drilling inclination method is mainly adopted at home and abroad, namely, an inclinometer for embedding an inclinometer is adopted in a drilling hole to monitor the sliding part of a deep landslide body, the sliding horizontal displacement, the sliding speed and the intermittent sliding condition of the landslide body are monitored, the deep relative displacement deformation is the advance of the surface displacement deformation, the deep relative displacement deformation and the surface displacement deformation are closely related, the landslide stability can be predicted in advance by monitoring the deep relative displacement deformation, and the method is disclosed by a retrieval notice number: CN203657775U3 discloses a geological disaster displacement automatic monitoring device, which comprises: a hollow protection tube, a communication interface circuit, an acceleration sensor, a magnetic sensor, a cable and a power supply, wherein the outer side of the hollow protection tube is provided with a rubber protection layer, one end of the hollow protection tube is provided with a hanging head, the other end of the hollow protection tube is provided with a lower sealing head, the outer wall of one end of the hollow protection tube is provided with an upper guide, the outer wall of the other end of the hollow protection tube is provided with a lower guide, the cable is in conductive connection with the communication interface circuit, the acceleration sensor, the magnetic sensor, the DC power converter and the power supply, one end of the cable penetrates through the hanging head and is connected with the cable connector arranged outside the hollow protection tube, the deep displacement change of the landslide and the torsion azimuth change of the inclinometer tube can be automatically monitored at the same time, the landslide sliding direction and the landslide sliding strength scale are determined, and the landslide disaster forecasting and forecasting parameters are important parameters, the similar monitoring methods and instruments used at home and abroad do not have the performance of simultaneously monitoring the deep displacement direction and the torsion angle direction of the inclinometer.

Although above-mentioned patent can automatic monitoring landslide deep displacement change and inclinometer pipe simultaneously twist reverse the position change, it still has some not enoughly, because cable joint and hanging head expose in the outside, it is not convenient for protect cable joint and hanging head, hit the phenomenon that causes cable joint to damage and separate with the cable easily because of the mistake collision in the in-process of using, and then the influence is used, and cable joint is not convenient for quick and is connected with the cable, what have now generally is to connect the cable joint on cable joint through bolt or wire rope cooperation, waste time and energy, and cause loaded down with trivial details, can not satisfy the user demand, consequently, we have proposed a geological disasters displacement automatic monitoring equipment and be used for solving above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the shortcomings existing in the prior art and providing a geological disaster displacement automatic monitoring equipment.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an automatic monitoring device for geological disaster displacement comprises an automatic monitoring device body, wherein the automatic monitoring device body comprises a hollow protection pipe and a cable joint connected with the hollow protection pipe, a protective shell with one side provided with an opening is movably sleeved on the hollow protection pipe, a first groove with one side provided with an opening is arranged on the inner wall of the top of the protective shell, a first triangular block is fixedly installed on one side of the top of the hollow protection pipe, one side of the first triangular block, which is close to the cable joint, is provided with an inclined plane, one side of the first triangular block, which is far away from the cable joint, is movably contacted with a second triangular block, one side of the second triangular block, which is far away from the first triangular block, is provided with an inclined plane, a T-shaped pull rod is fixedly installed on the top of the second triangular block, the top of the T-shaped pull rod extends to the upper part of the protective shell, the spring is movably sleeved on the T-shaped pull rod, one side of the cable joint, which is far away from the hollow protection tube, is provided with an arc-shaped groove, a cable is arranged in the arc-shaped groove, the top and the bottom of the cable are respectively provided with a T-shaped clamping plate, the top of the cable joint is provided with a first through hole, the inner wall of one side of the first through hole is provided with two rectangular grooves, the ends, which are far away from each other, of the two T-shaped clamping plates extend into the corresponding rectangular grooves respectively, two positioning rods are fixedly arranged between the inner walls of the top and the bottom of the rectangular grooves, the same moving rod is slidably sleeved on the two positioning rods in the same rectangular groove, one end of the moving rod is fixedly arranged with one side of the inner part of the corresponding T-shaped clamping plate, one end, which is far away from the corresponding T-shaped clamping plate, extends into the first, fixed mounting has same rectangular block between the both sides inner wall of first through-hole, the rectangular block rotates the cover and establishes on two screw rods, the carriage release lever thread bush is established on the screw rod that corresponds, fixed mounting has two installation poles between the both sides inner wall of first through-hole, the rectangular block is located between two installation poles, the bottom of the screw rod that is located the below in two screw rods and the top of the installation pole that is located the below in two installation poles rotate the installation, another installation pole cover is established on another screw rod, the top of another screw rod extends to cable joint's top, fixed cover is equipped with the T shape insulating boot that is located cable joint top on another screw rod.

Preferably, a sliding groove with one side being arranged as an opening is formed in the inner wall of the bottom of the protective shell, a sliding block is fixedly mounted on one side of the bottom of the hollow protective tube, and the sliding block is connected with the corresponding sliding groove in a sliding mode.

Preferably, a rectangular hole is formed in the inner wall of the top of the first groove, and the side wall of the rectangular hole is in sliding connection with the outer side of the T-shaped pull rod.

Preferably, the top of the moving rod is provided with a threaded hole, and the threaded hole is in threaded connection with the corresponding screw.

Preferably, a circular hole is formed in the top of the rectangular block, a bearing is fixedly sleeved in the circular hole, and an inner ring of the bearing is fixedly sleeved with the outer sides of the two screw rods.

Preferably, the anti-skid rubber is fixedly bonded on one side of each T-shaped clamping plate close to each other.

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

through the hollow protection tube, the protection shell, the installation rod, the cable joint, the first groove, the first triangular block, the second triangular block, the T-shaped pull rod, the spring, the first through hole, the rectangular groove, the positioning rod, the moving rod, the screw rod, the rectangular block and the T-shaped clamp plate are matched with the T-shaped insulation sleeve, when the protection shell needs to be taken down from the hollow protection tube to install the cable, the T-shaped pull rod is pulled upwards to drive the second triangular block to move upwards and compress the spring, when the second triangular block is staggered with the first triangular block, the protection shell is pulled away from the hollow protection tube to be taken down from the hollow protection tube, then the cable is placed between the two T-shaped clamp plates and is contacted with the inner wall of one side of the arc-shaped groove away from the opening of the arc-shaped groove, the T-shaped insulation sleeve is rotated forwards to drive the other screw rod fixedly connected with the T-shaped insulation sleeve to rotate, the screw rod drives the T-shaped clamp, the T-shaped clamp plate moves the corresponding anti-slip rubber sheet to clamp the cable tightly, so that the cable is fixed, when the protective shell is required to be sleeved on the hollow protective tube, the sliding groove is aligned with the sliding block, the protective shell is pushed to the direction close to the hollow protective tube to drive the second triangular block to move through the T-shaped pull rod and extrude the second triangular block and the first triangular block, the extruding force drives the second triangular block to move upwards and compress the spring, when the second triangular block is staggered with the first triangular block, the elastic force of the spring drives the second triangular block to move downwards and contact one side of the first triangular block, so that the protective shell is fixed.

The utility model relates to a rationally, convenient operation, the quick cable of being convenient for is connected with cable joint, and labour saving and time saving is convenient for protect cable joint, and is convenient for take off the protective housing fast and installs the cable, avoids causing the phenomenon of cable separation at the in-process cable joint that uses and external striking, is favorable to using.

Drawings

Fig. 1 is a schematic structural view of an automatic geological disaster displacement monitoring device provided by the present invention;

fig. 2 is a schematic structural diagram of a part a of an automatic geological disaster displacement monitoring device provided by the present invention;

fig. 3 is a schematic structural diagram of a part B of the automatic geological disaster displacement monitoring device provided by the present invention.

In the figure: the cable connector comprises a hollow protection tube 1, a protection shell 2, a mounting rod 3, a cable connector 4, a first groove 5, a first triangular block 6, a second triangular block 7, a pull rod 8T-shaped, a spring 9, a first through hole 10, a rectangular groove 11, a positioning rod 12, a movable rod 13, a screw rod 14, a rectangular block 15, a clamping plate 16T-shaped and an insulating sleeve 17T-shaped.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, a geological disaster displacement automatic monitoring device comprises an automatic monitoring device body, the automatic monitoring device body comprises a hollow protection pipe 1 and a cable joint 4 connected with the hollow protection pipe 1, a protective shell 2 with one side being an opening is movably sleeved on the hollow protection pipe 1, a first groove 5 with one side being an opening is arranged on the inner wall of the top of the protective shell 2, a first triangular block 6 is fixedly installed on one side of the top of the hollow protection pipe 1, one side of the first triangular block 6 close to the cable joint 4 is arranged as an inclined plane, one side of the first triangular block 6 far away from the cable joint 4 is movably contacted with a second triangular block 7, one side of the second triangular block 7 far away from the first triangular block 6 is arranged as an inclined plane, a T-shaped pull rod 8 is fixedly installed on the top of the second triangular block 7, the top of the T-shaped pull rod 8 extends to the upper side of the protective shell 2, a spring 9 is fixedly installed between the inner wall of the top, the spring 9 is movably sleeved on the T-shaped pull rod 8, one side of the cable joint 4, which is far away from the hollow protection tube 1, is provided with an arc-shaped groove, a cable is arranged in the arc-shaped groove, the top and the bottom of the cable are both provided with T-shaped clamping plates 16, the top of the cable joint 4 is provided with a first through hole 10, one side inner wall of the first through hole 10 is provided with two rectangular grooves 11, the ends, which are far away from each other, of the two T-shaped clamping plates 16 respectively extend into the corresponding rectangular grooves 11, two positioning rods 12 are fixedly installed between the top inner wall and the bottom inner wall of the rectangular grooves 11, the two positioning rods 12 positioned in the same rectangular groove 11 are slidably sleeved with the same moving rod 13, one end of the moving rod 13 is fixedly installed with one side of the inner part of the corresponding T-shaped clamping plate 16, one end, which is far away from the corresponding T-shaped clamping plate 16, extends into, the screw threads of the two screw rods 14 are opposite in turning direction, the same rectangular block 15 is fixedly arranged between the inner walls at two sides of the first through hole 10, the rectangular block 15 is rotatably sleeved on the two screw rods 14, the moving rod 13 is in threaded sleeve connection with the corresponding screw rods 14, the two mounting rods 3 are fixedly arranged between the inner walls at two sides of the first through hole 10, the rectangular block 15 is positioned between the two mounting rods 3, the bottom end of the screw rod 14 positioned below in the two screw rods 14 is rotatably mounted with the top of the mounting rod 3 positioned below in the two mounting rods 3, the other mounting rod 3 is sleeved on the other screw rod 14, the top end of the other screw rod 14 extends to the upper part of the cable joint 4, and the T-shaped insulating sleeve 17 positioned above the cable joint 4 is fixedly sleeved on the other screw rod 14. Labour saving and time saving is convenient for protect cable joint 4, and is convenient for take off protective housing 2 fast and installs the cable, avoids causing the phenomenon of cable separation at the in-process cable joint 4 that uses and external striking, is favorable to using.

In the utility model, a chute with one side arranged as an opening is arranged on the inner wall of the bottom of the protective shell 2, a slider is fixedly arranged on one side of the bottom of the hollow protective tube 1, the slider is connected with the corresponding chute in a sliding way, a rectangular hole is arranged on the inner wall of the top of the first groove 5, the side wall of the rectangular hole is connected with the outside of the T-shaped pull rod 8 in a sliding way, a threaded hole is arranged on the top of the moving rod 13, the threaded hole is connected with the corresponding screw 14 in a threaded way, a circular hole is arranged on the top of the rectangular block 15, a bearing is fixedly sleeved in the circular hole, the inner ring of the bearing is fixedly sleeved with the outside of the two screws 14, and one side of the two T-shaped clamping plates 16 which are close to each other is fixedly bonded with an anti-slip rubber sheet, the utility model has reasonable design and convenient operation, is convenient for connecting the cable with the, the phenomenon that the cable connector 4 is separated from the outside due to impact in the using process is avoided, and the use is facilitated.

The working principle is as follows: when the protective shell 2 is required to be taken down from the hollow protective tube 1 to install a cable, the T-shaped pull rod 8 is pulled upwards, the T-shaped pull rod 8 drives the second triangular block 7 to move upwards and compress the spring 9, when the second triangular block 7 is staggered with the first triangular block 6, the protective shell 2 is pulled in the direction away from the hollow protective tube 1, the protective shell 2 can be taken down from the hollow protective tube 1, then the cable is placed between the two T-shaped clamp plates 16, one end of the cable is in contact with the inner wall of one side, away from the opening, of the arc-shaped groove, the T-shaped insulating sleeve 17 is rotated forwards, the T-shaped insulating sleeve 17 drives the other screw 14 fixedly connected with the T-shaped insulating sleeve to rotate, the other screw 14 drives one screw 14 fixedly connected with the T-shaped insulating sleeve to rotate, under the action of the threaded hole formed in the top of the movable rod 13, the screw 14 rotates and simultaneously drives the corresponding movable rod 13 to move, the two moving rods 13 slide on the corresponding positioning rods 12 in the direction of approaching each other, the moving rods 13 drive the corresponding T-shaped clamping plates 16 to move in the direction of approaching the cable while moving, the T-shaped clamping plates 16 drive the corresponding anti-skid rubber sheets to move, and the two anti-skid rubber sheets move in the direction of approaching each other and clamp the cable, so that the cable is conveniently and quickly connected with the cable connector 4;

when the protective shell 2 needs to be sleeved on the hollow protective tube 1, the sliding groove is aligned with the sliding block, the protective shell 2 is pushed in the direction close to the hollow protective tube 1, the protective shell 2 drives the second triangular block 7 to move through the T-shaped pull rod 8, when the inclined surface of the second triangular block 7 is contacted with the inclined surface of the first triangular block 6, the protective shell 2 is continuously pushed, so that the second triangular block 7 is continuously moved and is extruded with the first triangular block 6, the second triangular block 7 is driven to move upwards by the extrusion force and compresses the spring 9, when the second triangular block 7 is staggered with the first triangular block 6, the spring 9 in the compression state is reset, the elastic force of the spring 9 drives the second triangular block 7 to move downwards and is contacted with one side of the first triangular block 6, under the matching of the second triangular block 7 and the first triangular block 6, the protective shell 2 is fixed, so that the cable joint 4 is conveniently protected, and be convenient for take off the protective housing 2 fast and install the cable, avoid causing the phenomenon of cable separation at the in-process cable joint 4 that uses and external striking.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. The automatic geological disaster displacement monitoring equipment comprises an automatic monitoring equipment body, wherein the automatic monitoring equipment body comprises a hollow protection pipe (1) and a cable joint (4) connected with the hollow protection pipe (1), and is characterized in that a protective shell (2) with one side arranged for an opening is movably sleeved on the hollow protection pipe (1), a first groove (5) with one side arranged for the opening is formed in the inner wall of the top of the protective shell (2), a first triangular block (6) is fixedly installed on one side of the top of the hollow protection pipe (1), an inclined plane is formed on one side, close to the cable joint (4), of the first triangular block (6), a second triangular block (7) is movably contacted with one side, far away from the cable joint (4), of the first triangular block (7), an inclined plane is formed on one side, far away from the first triangular block (6), of the second triangular block (7), and a T-shaped pull rod (8) is fixedly installed on the top of the second triangular block (7), the top of the T-shaped pull rod (8) extends to the upper part of the protective shell (2), a spring (9) is fixedly arranged between the inner wall of the top of the protective shell (2) and the top of the second triangular block (7), the spring (9) is movably sleeved on the T-shaped pull rod (8), an arc-shaped groove is formed in one side, away from the hollow protective tube (1), of the cable joint (4), a cable is arranged in the arc-shaped groove, T-shaped clamping plates (16) are arranged at the top and the bottom of the cable, a first through hole (10) is formed in the top of the cable joint (4), two rectangular grooves (11) are formed in the inner wall of one side of the first through hole (10), one ends, away from each other, of the two T-shaped clamping plates (16) extend into the corresponding rectangular grooves (11) respectively, two positioning rods (12) are fixedly arranged between the inner wall of the top and the inner wall of the bottom of the rectangular grooves (11), the two positioning rods (, one end of a movable rod (13) is fixedly installed with one side inside a corresponding T-shaped clamping plate (16), one end of the movable rod (13), far away from the corresponding T-shaped clamping plate (16), extends into a first through hole (10), two screw rods (14) are arranged in the first through hole (10), one ends, close to each other, of the two screw rods (14) are fixedly connected, the thread turning directions of the two screw rods (14) are opposite, a same rectangular block (15) is fixedly installed between the inner walls of the two sides of the first through hole (10), the rectangular block (15) is rotatably sleeved on the two screw rods (14), the movable rod (13) is rotatably sleeved on the corresponding screw rod (14), two installation rods (3) are fixedly installed between the inner walls of the two sides of the first through hole (10), the rectangular block (15) is located between the two installation rods (3), the bottom end of one screw rod (14) below in the two screw rods (14) is rotatably installed with the top of the installation rod (3) below in the two installation rods (3, the other mounting rod (3) is sleeved on the other screw rod (14), the top end of the other screw rod (14) extends to the upper part of the cable joint (4), and a T-shaped insulating sleeve (17) positioned above the cable joint (4) is fixedly sleeved on the other screw rod (14).

2. The automatic geological disaster displacement monitoring equipment as claimed in claim 1, wherein a sliding groove with an opening at one side is formed on the inner wall of the bottom of the protective shell (2), a sliding block is fixedly installed at one side of the bottom of the hollow protective tube (1), and the sliding block is in sliding connection with the corresponding sliding groove.

3. A geological disaster displacement automatic monitoring equipment according to claim 1, characterized in that the top inner wall of the first groove (5) is opened with a rectangular hole, the side wall of which is connected with the outside of the T-shaped pull rod (8) in a sliding way.

4. A geological disaster displacement automatic monitoring equipment according to claim 1, characterized in that the top of the moving rod (13) is equipped with a threaded hole, and the threaded hole is connected with the corresponding screw (14) by screw thread.

5. A geological disaster displacement automatic monitoring equipment according to claim 1, characterized in that the top of the rectangular block (15) is provided with a circular hole, a bearing is fixedly sleeved in the circular hole, and the inner ring of the bearing is fixedly sleeved with the outer sides of the two screw rods (14).

6. A geological disaster displacement automatic monitoring equipment according to claim 1, characterized in that the side of two T-shaped clamping plates (16) close to each other is adhered with anti-skid rubber.

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