CN218600545U - Positioning structure of sliding type inclinometer - Google Patents

Abstract

The utility model discloses a location structure of slidingtype inclinometer, including cable frame, deviational survey probe, test cable, installed part and reading appearance. The utility model discloses a, through setting up the cable frame, the deviational survey probe, the cooperation of test cable and installed part is used, can be used to monitor the deformation of massif landslide, be used for ground deep ground displacement measurement's precision instrument specially, the inside that the locating piece can follow the cavity removes to the deviational survey probe, thereby make the fixed of deviational survey probe and installed part, thrust unit's use, can make the locating piece shift out from the inside of deviational survey probe, realize the separation of deviational survey probe and installed part, but possess quick assembly disassembly deviational survey probe's advantage, the location structure of this slidingtype deviational survey instrument, it needs to carry out the dismouting through the instrument to have solved current deviational survey probe, it is comparatively troublesome, screw and thread groove are twisted for a long time and move, can make the thread groove cause the damage easily, make the problem that fixed effect weakens.

Description

Positioning structure of sliding type inclinometer

Technical Field

The utility model belongs to the technical field of the massif reconnaissance, especially, relate to a location structure of slidingtype inclinometer.

Background

The sliding inclinometer comprises an inclinometer probe, test cables and other equipment matched software, can be used for monitoring the deformation of landslide, is a precision measuring instrument specially used for measuring the displacement of a rock-soil deep foundation, because the ground landslide belongs to an oversize landslide, the sliding surface is deep, and the ground landslide is in a creeping stage, the requirements cannot be met due to the traditional exploration means, the high-precision monitoring can be carried out on the displacement of the deep part of the landslide through the sliding inclinometer, the inclinometer probe of the sliding inclinometer is usually screwed and fixed through the matching use of a screw and a thread groove, the disassembly and assembly are needed when the instrument is stored and used, the screw and the thread groove are screwed for multiple times, the abrasion can be caused to the thread groove, the fixing effect is weakened, and a user can disassemble and assemble the inclinometer probe through the tools, and the problems in the prior art are that: the inclinometer probe needs to be disassembled and assembled through a tool, which is troublesome, and the screw and the thread groove are twisted for a long time, so that the thread groove is easy to damage, the fixing effect is weakened, and the positioning structure of the sliding inclinometer is provided for solving the problems.

SUMMERY OF THE UTILITY MODEL

Problem to prior art exists, the utility model provides a location structure of slidingtype inclinometer possesses the advantage of quick assembly disassembly inclinometer probe, has solved current inclinometer probe and need carry out the dismouting through the instrument, and is comparatively troublesome, and screw and thread groove are twisted for a long time and are moved, can make the thread groove cause the damage easily, make the problem that fixed effect weakens.

The utility model discloses a realize like this, a location structure of slidingtype inclinometer, including cable rack, deviational survey probe, test cable and installed part, the cable rack is connected with the winding of test cable, installed part and test cable fixed connection, installed part and deviational survey probe plug-in connection, the equal fixedly connected with lug in top and the bottom of installed part, top the cavity has been seted up to the inside of lug, the bottom of cavity inner wall is provided with positioner, the top of cavity inner wall is provided with thrust unit.

As the utility model discloses it is preferred, positioner includes the locating piece, the surface of locating piece and the inside swing joint of cavity, the top fixedly connected with cooperation piece of locating piece, the left side fixedly connected with extension spring of cooperation piece bottom, the bottom of extension spring and the bottom fixed connection of cavity inner wall, the top of cooperation piece front side is rotated and is connected with the movable rod, and the locating piece can be followed the inside removal of cavity to the inside of deviational survey probe to can realize the front side of deviational survey probe and the inside fixed connection of installed part.

As the utility model discloses it is preferred, thrust unit includes the push rod, the inside swing joint of the surface of push rod and cavity, the left side of push rod front side is rotated with the right side of movable rod and is connected, the top fixedly connected with trapezoidal piece of push rod, the right side fixedly connected with reset spring of trapezoidal piece, reset spring's right side and the right side fixed connection of cavity inner wall can let the locating piece shift out from the inside of deviational survey probe to realize the front side of deviational survey probe and the inside break away from the contact of installed part.

As the utility model discloses preferred, the bottom of locating piece runs through lug, installed part and deviational survey probe in proper order and extends to the inside of deviational survey probe through the cavity, and the locating piece can shift out through the inside that the cavity removed to the deviational survey probe and follow the inside of deviational survey probe, realizes the dismouting of deviational survey probe and installed part.

As the utility model discloses it is preferred, the inside sliding connection of cooperation piece has the stopper, the bottom of stopper and the bottom fixed connection of cavity inner wall, the use of stopper play the effect of spacing support, make the cooperation piece drive the locating piece in the inside better removal of cavity, make the removal effect better.

As the utility model discloses preferred, the sliding surface at trapezoidal piece top is connected with dovetail groove and in close contact with, the top of cavity inner wall is seted up in the dovetail groove, and the use in dovetail groove makes trapezoidal piece drive the push rod and only can control the direction and remove, makes the push rod can normal use.

As the utility model discloses it is preferred, the shape of locating piece is square, the inside in close contact with of the surface of locating piece and deviational survey probe, the shape of locating piece be square and the surface of locating piece and the inside in close contact with of deviational survey probe, can make fixed effect more firm, avoid the front side of deviational survey probe to appear rocking in the inside of installed part.

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

1. the utility model discloses a set up the cable frame, the deviational survey probe, the cooperation of test cable and installed part is used, can be used to monitor the deformation of massif landslide, be used for ground deep ground displacement measurement's precision instrument specially, the inside that the locating piece can follow the cavity removes to the inside of deviational survey probe, thereby make the fixed of deviational survey probe and installed part, thrust unit's use can make the locating piece shift out from the inside of deviational survey probe, realize the separation of deviational survey probe and installed part, but possess quick assembly disassembly deviational survey probe's advantage.

2. The utility model discloses a set up positioner and thrust unit, when needs make deviational survey probe and installation separation accomodate, it removes to promote the push rod direction left through the manpower, the push rod can make the movable rod move left at the in-process that removes, the movable rod can clockwise rotation at the in-process that removes, the movable rod can make cooperation piece upwards direction remove and make locating piece rebound at the in-process that removes, thereby make the locating piece shift out from the inside of deviational survey probe, realize the separation of deviational survey probe and installed part, the in-process that the push rod moved left can make the trapezoidal piece move left and make reset spring produce the power of a deformation, after loosening the push rod, reset spring can give a same power of trapezoidal piece, make the trapezoidal piece drive the push rod and make the movable rod kick-back to the normal position, the cooperation piece can make the extension spring produce the power of a deformation at the in-process that removes, when loosening the push rod, the extension spring can give a same power of cooperation piece, make cooperation piece drive the locating piece kick-back to the inside of deviational survey probe shift out, realize the fixed of deviational survey probe and installed part.

Drawings

Fig. 1 is a schematic structural diagram provided in an embodiment of the present invention;

fig. 2 is a schematic perspective view of an inclinometer probe provided in an embodiment of the present invention;

fig. 3 is an enlarged view of a point a in fig. 2 according to an embodiment of the present invention;

fig. 4 is a detailed perspective view of a local structure provided in the embodiment of the present invention.

In the figure: 1. a cable rack; 2. an inclinometer probe; 3. testing the cable; 4. a mounting member; 5. a bump; 6. a cavity; 7. a positioning device; 701. positioning a block; 702. a matching block; 703. a tension spring; 704. a movable rod; 8. a pushing device; 801. a push rod; 802. a trapezoidal block; 803. a return spring; 9. a limiting block; 10. a trapezoidal groove.

Detailed Description

For further understanding the contents, features and effects of the present invention, the following embodiments will be illustrated in detail with reference to the accompanying drawings.

The structure of the present invention will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 4, the embodiment of the utility model provides a positioning structure of slidingtype inclinometer, including cable rack 1, deviational survey probe 2, test cable 3, installed part 4, lug 5, cavity 6, positioner 7, locating piece 701, cooperation piece 702, extension spring 703, movable rod 704, thrust unit 8, push rod 801, trapezoidal piece 802, reset spring 803, stopper 9 and trapezoidal groove 10, cable rack 1 is connected with test cable 3 winding, installed part 4 and test cable 3 fixed connection, installed part 4 and deviational survey probe 2 plug-in connection, the equal fixedly connected with lug 5 in top and bottom of installed part 4, cavity 6 has been seted up to the inside of top lug 5, the bottom of cavity 6 inner wall is provided with positioner 7, the top of cavity 6 inner wall is provided with thrust unit 8.

Referring to fig. 3, the positioning device 7 includes a positioning block 701, a surface of the positioning block 701 is movably connected with an inside of the cavity 6, a top of the positioning block 701 is fixedly connected with a matching block 702, a left side of a bottom of the matching block 702 is fixedly connected with a tension spring 703, a bottom of the tension spring 703 is fixedly connected with a bottom of an inner wall of the cavity 6, and a top of a front side of the matching block 702 is rotatably connected with a movable rod 704.

The scheme is adopted: the positioning block 701 is movable from inside the cavity 6 to inside the inclinometer probe 2, so that the front side of the inclinometer probe 2 can be fixedly connected to the inside of the mounting 4.

Referring to fig. 3, the pushing device 8 includes a push rod 801, a surface of the push rod 801 is movably connected with an inside of the cavity 6, a left side of a front side of the push rod 801 is rotatably connected with a right side of the movable rod 704, a trapezoidal block 802 is fixedly connected to a top of the push rod 801, a return spring 803 is fixedly connected to a right side of the trapezoidal block 802, and a right side of the return spring 803 is fixedly connected with a right side of an inner wall of the cavity 6.

Adopt above-mentioned scheme: the locating block 701 can be removed from the interior of the inclinometer probe 2, thereby enabling the front side of the inclinometer probe 2 to be removed from contact with the interior of the mounting 4.

Referring to fig. 1 and 3, the bottom of the locating block 701 extends through the protrusion 5, the mounting member 4 and the inclinometer probe 2 in sequence and into the inclinometer probe 2 through the cavity 6.

The scheme is adopted: the locating block 701 can move into the inclinometer probe 2 and move out of the inclinometer probe 2 through the cavity 6, so that the inclinometer probe 2 and the mounting piece 4 can be disassembled and assembled.

Referring to fig. 3, the inside of the fitting block 702 is slidably connected with a limiting block 9, and the bottom of the limiting block 9 is fixedly connected with the bottom of the inner wall of the cavity 6.

The scheme is adopted: the limiting block 9 is used for limiting and supporting, so that the matching block 702 drives the positioning block 701 to better move in the cavity 6, and the moving effect is better.

Referring to fig. 3, the top surface of the trapezoidal block 802 is slidably connected with a trapezoidal groove 10 and closely contacts with the trapezoidal groove 10, and the trapezoidal groove 10 is opened at the top of the inner wall of the cavity 6.

The scheme is adopted: the use of the trapezoidal groove 10 enables the trapezoidal block 802 to drive the push rod 801 to move only in the left and right directions, so that the push rod 801 can be normally used.

Referring to fig. 3, the positioning block 701 has a square shape, and the surface of the positioning block 701 is in close contact with the inside of the inclinometer probe 2.

Adopt above-mentioned scheme: the positioning block 701 is square, the surface of the positioning block 701 is in close contact with the inside of the inclinometer probe 2, so that the fixing effect is firmer, and the front side of the inclinometer probe 2 is prevented from shaking in the mounting part 4.

The utility model discloses a theory of operation:

when the inclination measuring probe 2 and the test cable 3 are special instruments for measuring the displacement of the rock foundation, when the inclination measuring probe 2 needs to be stored separately from the installation, the push rod 801 is pushed to move leftwards by manpower, the push rod 801 can enable the movable rod 704 to move leftwards in the moving process, the movable rod 704 can rotate clockwise in the moving process, the matching block 702 can move upwards and the positioning block 701 can move upwards in the moving process of the movable rod 704, so that the positioning block 701 can be moved out of the interior of the inclination measuring probe 2, the inclination measuring probe 2 and the installation piece 4 can be separated, the trapezoidal block 802 can move leftwards and the reset spring 803 can generate a deformation force in the leftward moving process of the push rod 801, after the push rod 801 is released, the reset spring 803 can provide the same force to the trapezoidal block 802, the trapezoidal block 802 drives the push rod 801 and the movable rod 704 to rebound to the original position, the matching block 702 can generate a deformation force in the moving process, the tension spring 703 can provide the same force to the matching block 702 when the push rod 801 is released, the matching block 702 can drive the inclination measuring probe 702 to move out of the installation piece 701, and the inclination measuring probe 701 and the installation piece 4 can be fixed.

In conclusion: this location structure of slidingtype inclinometer, through setting up cable tray 1, deviational survey probe 2, test cable 3, installed part 4, lug 5, cavity 6, positioner 7, locating piece 701, cooperation piece 702, extension spring 703, movable rod 704, thrust unit 8, push rod 801, trapezoidal piece 802, reset spring 803, the cooperation of stopper 9 and trapezoidal groove 10 is used, it needs to carry out the dismouting through the instrument to have solved current deviational survey probe, it is comparatively troublesome, screw and thread groove are twisted for a long time and are moved, can make the thread groove cause the damage easily, make the problem that fixed effect weakens.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

Claims (7)

1. The utility model provides a location structure of slidingtype inclinometer, includes cable frame (1), deviational survey probe (2), test cable (3) and installed part (4), cable frame (1) is connected with test cable (3) winding, installed part (4) and test cable (3) fixed connection, installed part (4) and deviational survey probe (2) plug-in connection, its characterized in that: the top and the bottom of installed part (4) are all fixedly connected with lug (5), the top cavity (6) has been seted up to the inside of lug (5), the bottom of cavity (6) inner wall is provided with positioner (7), the top of cavity (6) inner wall is provided with thrust unit (8).

2. The positioning structure of the sliding inclinometer according to claim 1, characterized in that: positioner (7) are including locating piece (701), the inside swing joint of the surface of locating piece (701) and cavity (6), the top fixedly connected with cooperation piece (702) of locating piece (701), left side fixedly connected with extension spring (703) of cooperation piece (702) bottom, the bottom of extension spring (703) and the bottom fixed connection of cavity (6) inner wall, the top of cooperation piece (702) front side is rotated and is connected with movable rod (704).

3. The positioning structure of a sliding inclinometer as claimed in claim 2, characterized in that: the pushing device (8) comprises a pushing rod (801), the surface of the pushing rod (801) is movably connected with the inside of the cavity (6), the left side of the front side of the pushing rod (801) is rotatably connected with the right side of the movable rod (704), a trapezoidal block (802) is fixedly connected to the top of the pushing rod (801), a reset spring (803) is fixedly connected to the right side of the trapezoidal block (802), and the right side of the reset spring (803) is fixedly connected with the right side of the inner wall of the cavity (6).

4. The positioning structure of the sliding inclinometer according to claim 2, characterized in that: the bottom of the positioning block (701) sequentially penetrates through the lug (5), the mounting piece (4) and the inclinometer probe (2) through the cavity (6) and extends into the inclinometer probe (2).

5. The positioning structure of the sliding inclinometer according to claim 2, characterized in that: the inside sliding connection of cooperation piece (702) has stopper (9), the bottom of stopper (9) and the bottom fixed connection of cavity (6) inner wall.

6. The positioning structure of the sliding inclinometer according to claim 3, characterized in that: the surface at the top of trapezoidal piece (802) sliding connection has dovetail groove (10) and in close contact with, dovetail groove (10) set up in the top of cavity (6) inner wall.

7. The positioning structure of a sliding inclinometer as claimed in claim 2, characterized in that: the positioning block (701) is square, and the surface of the positioning block (701) is in close contact with the interior of the inclinometer probe (2).

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