CN216012193U - High steep slope surface on-line monitoring device - Google Patents

Abstract

The utility model relates to the technical field of slope surface monitoring equipment, and discloses an online monitoring device for a high and steep slope surface, which comprises two fixing plates, wherein the tops of the two fixing plates are fixedly connected with supporting components, the tops of the fixing plates are fixedly connected with fixing components which are positioned on the back surfaces of the supporting components and meshed with the supporting components, the top of the supporting component on the left side is fixedly connected with a fixing frame, the inside of the fixing frame is fixedly connected with a monitoring component, and the upper side wall and the lower side wall of the fixing frame are fixedly connected with traction components. This steep domatic on-line monitoring device of height possesses advantages such as suitability height, has solved traditional steep domatic general mode of looking over through the manual work and has monitored domatic, not only consumes the manpower, can't in time discover in addition domatic not hard up, can produce the landslide phenomenon when domatic emergence is not hard up, and the rock under the landing not only injures the pedestrian of crossing by a crashing object easily but also causes the problem of destruction to the road easily.

Description

High steep slope surface on-line monitoring device

Technical Field

The utility model relates to the technical field of slope monitoring equipment, in particular to an online monitoring device for a high and steep slope.

Background

The slope surface is a slope with a regular form formed by slope type manual excavation according to a certain slope rate; the concept of high and steep slopes differs from the view of geotechnical engineering boundary at home and abroad, but in two aspects of general strength 'high' and 'steep', a rock side slope which is formed by manual excavation according to a certain slope rate and slope type and has a slope height of thirty meters or a soil side slope with a slope height of more than twenty meters is called a high and steep slope by a scholarly.

Traditional high steep slope is generally through the mode that artifical looking over comes to monitor domatic, not only expends the manpower, can't in time discover in addition that domatic not hard up, can produce the landslide phenomenon when domatic emergence is not hard up, and the rock under the landing not only smashes the pedestrian of crossing of hurting easily but also causes the destruction to the road easily, so proposes a high steep slope on-line monitoring device and solves the above-mentioned problem of proposing.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Aiming at the defects of the prior art, the utility model provides the high-steep slope surface online monitoring device which has the advantages of high applicability and the like, and solves the problems that the traditional high-steep slope surface is generally monitored in a manual checking mode, the manpower is consumed, the slope surface looseness cannot be found in time, the landslide phenomenon can be generated when the slope surface is loosened, and the falling rocks easily injure pedestrians passing by the road and damage the road.

(II) technical scheme

The technical scheme for solving the technical problems is as follows: the utility model provides a steep domatic on-line monitoring device of height, includes two fixed plates, two the equal fixedly connected with supporting component in top of fixed plate, the top fixedly connected with of fixed plate be located the supporting component back and with the fixed subassembly of supporting component engaged with, the left side the top fixedly connected with mount of supporting component, the inside fixedly connected with monitoring subassembly of mount, the equal fixedly connected with of the upper and lower both sides wall of mount pulls the subassembly, the right side the inside of supporting component is provided with the tensile subassembly that one end extends to the supporting component top, two pull the relative one side of subassembly all with one end extend to the mount inside and with tensile subassembly fixed connection's movable block swing joint, the top fixedly connected with signal transmitter of mount.

The utility model has the beneficial effects that:

this steep domatic on-line monitoring device of height, when needs use, earlier to the fixed subassembly of outside pulling, make it leave the contact with supporting component, the cancellation is fixed to supporting component, come to rotate two supporting component according to domatic angle immediately, it is when being the level with ground when the movable block is adjusted with the mount and all relative, can loosen fixed subassembly, make it fix supporting component, then fix on domatic through two fixed plates, can accomplish the device's installation, when domatic emergence is not hard up, because the skew takes place for the position of movable block, through monitoring components and signal transmitter, can give the surveillance center with the signal transmission, the staff of being convenient for monitors, thereby the effect that the suitability is high has been realized.

On the basis of the technical scheme, the utility model can be further improved as follows.

Further, the supporting component comprises a supporting block fixedly installed at the top of the fixing plate, a bearing is fixedly connected inside the supporting block, two ends of the bearing are fixedly connected with supporting rods extending to the outer sides of the supporting block, an installation block is fixedly connected to the front side of each supporting rod, and a first crown gear is fixedly connected to the back side of each supporting rod.

Adopt above-mentioned further scheme's beneficial effect be, when the contact of second crown gear leaves with first crown gear, can rotate the installation piece.

Further, fixed subassembly is including being located the support block back and fixed mounting in the base at fixed plate top, the inside swing joint of base has both ends to all extend to the movable rod in the base outside, the positive fixedly connected with and the first crown gear engaged with second crown gear of movable rod, the outside fixedly connected with of movable rod is located the inside fixture block of base, the back fixedly connected with of fixture block is located the movable rod outside and one end extends to the first spring with the inside fixed connection of base, the back fixedly connected with handle of movable rod.

Adopt above-mentioned further scheme's beneficial effect is, when needs use, pull the handle backward earlier, the handle drives fixture block, movable rod and second crown gear in proper order and removes backward, and the first spring is extruded at the in-process that removes to the fixture block, and first spring atress contracts.

Further, the monitoring assembly comprises a laser ranging sensor fixedly installed inside the fixing frame, pressure sensors are fixedly connected to the upper side wall and the lower side wall of the inner cavity of the fixing frame, and the pressure sensors and the laser ranging sensor are electrically connected with the signal transmitter.

Adopt above-mentioned further scheme's beneficial effect is, when domatic emergence not hard up phenomenon, the movable block takes place the skew and contacts and extrude pressure sensor with pressure sensor, and laser rangefinder sensor also can sense and the movable block between the position change takes place, is extruded when the pressure sensor atress, and when laser rangefinder sensor received the sensing signal simultaneously, pressure sensor and laser rangefinder sensor passed through signal transmitter with information transmission to the surveillance center to the staff monitors.

Further, the traction assembly comprises two mounting plates which are fixedly mounted on the upper side and the lower side of the fixing frame, the outer sides of the mounting plates are fixedly connected with second springs, the opposite sides of the second springs are fixedly connected with supporting plates, and guide wheels are embedded in the opposite sides of the supporting plates.

Adopt above-mentioned further scheme's beneficial effect be, when the movable block takes place the skew, the movable block promotes guide pulley and backup pad and extrudees the second spring, when not taking place the landslide phenomenon, can prevent through the elasticity of two upper and lower second springs that the movable block from taking place the displacement or becoming flexible.

Further, the stretching assembly comprises a stretching rod movably connected to the right side and arranged inside the mounting block, one end of the stretching rod extends to the right side of the top of the mounting block, and the inside of the mounting block on the right side is in threaded connection with a threaded rod, one end of the threaded rod extends to be in contact with the stretching rod.

Adopt above-mentioned further scheme's beneficial effect be, when domatic angle changes, because the distance between movable block and the domatic has changed, can delay the distance between movable block and the domatic through pulling tensile pole, the threaded rod can be fixed the tensile pole after adjusting.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a left side sectional view of the support assembly of the present invention;

FIG. 3 is an elevational, cross-sectional view of the upper draft assembly of the present invention;

fig. 4 is an elevational, cross-sectional view of the right mounting block of the present invention.

In the figure: 1. a fixing plate; 2. a support assembly; 201. a support block; 202. a bearing; 203. a support bar; 204. mounting blocks; 205. a first crown gear; 3. a fixing assembly; 301. a base; 302. a movable rod; 303. a second crown gear; 304. a clamping block; 305. a first spring; 306. a handle; 4. a fixed mount; 5. a monitoring component; 501. a laser ranging sensor; 502. a pressure sensor; 6. a traction assembly; 601. mounting a plate; 602. a second spring; 603. a support plate; 604. a guide wheel; 7. a stretching assembly; 701. a stretch rod; 702. a threaded rod; 8. a movable block; 9. a signal emitter.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the embodiment, as shown in fig. 1-4, an online monitoring device for steep and steep slope surface comprises two fixing plates 1, wherein the top of each fixing plate 1 is fixedly connected with a supporting component 2, each supporting component 2 comprises a supporting block 201 fixedly installed on the top of the fixing plate 1, a bearing 202 is fixedly connected inside the supporting block 201, a supporting rod 203 is fixedly connected inside the bearing 202, two ends of the supporting rod 203 extend to the outer side of the supporting block 201, a mounting block 204 is fixedly connected to the front of the supporting rod 203, a first crown gear 205 is fixedly connected to the back of the supporting rod 203, when a second crown gear 303 leaves contact with the first crown gear 205, the mounting block 204 can be rotated, a fixing component 3 which is located on the back of the supporting component 2 and engaged with the supporting component 2 is fixedly connected to the top of the fixing plate 1, the fixing component 3 comprises a base 301 which is located on the back of the supporting block 201 and fixedly installed on the top of the fixing plate 1, the inside of the base 301 is movably connected with a movable rod 302, two ends of the movable rod 302 extend to the outside of the base 301, the front of the movable rod 302 is fixedly connected with a second crown gear 303 engaged with the first crown gear 205, the outside of the movable rod 302 is fixedly connected with a clamping block 304 positioned inside the base 301, the back of the clamping block 304 is fixedly connected with a first spring 305 positioned outside the movable rod 302 and one end of the clamping block extends to the inside of the base 301, the back of the movable rod 302 is fixedly connected with a handle 306, when the movable rod 302 is needed to be used, the handle 306 is pulled backwards first, the clamping block 304, the movable rod 302 and the second crown gear 303 are sequentially driven by the handle 306 to move backwards, the clamping block 304 extrudes the first spring 305 in the moving process, the first spring 305 is stressed and contracted, the top of the left supporting component 2 is fixedly connected with a fixed frame 4, the inside of the fixed frame 4 is fixedly connected with a monitoring component 5, the monitoring component 5 comprises a laser ranging sensor 501 fixedly arranged inside the fixed frame 4, the upper side wall and the lower side wall of the inner cavity of the fixed frame 4 are both fixedly connected with a pressure sensor 502, the pressure sensor 502 and the laser ranging sensor 501 are both electrically connected with a signal emitter 9, when the slope surface is loosened, the movable block 8 deflects to contact with the pressure sensor 502 and extrude the pressure sensor 502, the laser ranging sensor 501 can also sense the position change between the movable block 8 and the pressure sensor 502, when the pressure sensor 502 is stressed and extruded and the laser ranging sensor 501 receives a sensing signal, the pressure sensor 502 and the laser ranging sensor 501 transmit information to a monitoring center through the signal emitter 9 so as to be monitored by a worker, the upper side wall and the lower side wall of the fixed frame 4 are both fixedly connected with traction components 6, each traction component 6 comprises two mounting plates 601 which are fixedly arranged at the upper side and the lower side of the fixed frame 4, and the outer sides of the two mounting plates 601 are both fixedly connected with second springs 602, the opposite sides of the two second springs 602 are fixedly connected with supporting plates 603, the opposite sides of the two supporting plates 603 are embedded with guide wheels 604, when the movable block 8 deviates, the movable block 8 pushes the guide wheels 604 and the supporting plates 603 to extrude the second springs 602, when the landslide phenomenon does not occur, the movable block 8 can be prevented from displacing or loosening by the elastic force of the two upper and lower second springs 602, the inside of the right side supporting component 2 is provided with a stretching component 7, one end of the stretching component 7 extends to the top of the supporting component 2, the stretching component 7 comprises a stretching rod 701 movably connected inside the right side mounting block 204, and the other end of the stretching rod 701 extends to the top of the right side mounting block 204, the internal thread of the right side mounting block 204 is connected with a threaded rod 702, one end of which is contacted with the stretching rod 701, when the angle of the slope surface changes, because the distance between the movable block 8 and the slope surface is changed, the distance between the movable block 8 and the slope surface can be delayed by pulling the stretching rod 701, threaded rod 702 can fix the tensile pole 701 after adjusting, two relative one sides of pulling subassembly 6 all extend to the mount 4 inside with one end and with tensile subassembly 7 fixed connection's movable block 8 swing joint, the top fixedly connected with signal transmitter 9 of mount 4.

The working principle is as follows:

the first step is as follows: when the device is needed to be used, the handle 306 is pulled backwards, the handle 306 sequentially drives the fixture block 304, the movable rod 302 and the second crown gear 303 to move backwards, the fixture block 304 presses the first spring 305 in the moving process, the first spring 305 is stressed and contracted, when the second crown gear 303 leaves the contact with the first crown gear 205, the fixing of the mounting block 204 can be cancelled, the two mounting blocks 204 are rotated according to the slope angle, when the movable block 8 and the fixed frame 4 are adjusted to be horizontally opposite to the ground, the handle 306 is released, the first spring 305 rebounds, the mounting blocks 204 can be fixed, and then the two fixed plates 1 are fixed on the slope to complete the mounting of the device;

the second step is that: when domatic emergence is not hard up the phenomenon, movable block 8 takes place to squint and pressure sensor 502 and extrudees pressure sensor 502, laser rangefinder sensor 501 also can sense and the position between the movable block 8 changes, be extruded when pressure sensor 502 atress, when laser rangefinder sensor 501 received the sensing signal simultaneously, pressure sensor 502 and laser rangefinder sensor 501 pass through signal transmitter 9 with information transmission to the surveillance center, so that the staff monitors, thereby realized the high effect of suitability.

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. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a steep domatic on-line monitoring device of height, includes two fixed plates (1), its characterized in that: the top parts of the two fixing plates (1) are fixedly connected with a supporting component (2), the top of the fixed plate (1) is fixedly connected with a fixed component (3) which is positioned at the back of the supporting component (2) and is engaged with the supporting component (2), the top of the supporting component (2) at the left side is fixedly connected with a fixed frame (4), the inside of the fixed frame (4) is fixedly connected with a monitoring component (5), the upper side wall and the lower side wall of the fixed frame (4) are both fixedly connected with a traction component (6), the inside of the supporting component (2) on the right side is provided with a stretching component (7) of which one end extends to the top of the supporting component (2), the opposite sides of the two traction components (6) are both movably connected with a movable block (8) of which one end extends to the inside of the fixed frame (4) and is fixedly connected with the stretching component (7), the top of the fixed frame (4) is fixedly connected with a signal emitter (9).

2. The high steep slope surface on-line monitoring device according to claim 1, wherein: the supporting component (2) comprises a supporting block (201) fixedly installed at the top of the fixing plate (1), a bearing (202) is fixedly connected to the inside of the supporting block (201), two ends of the fixedly connected to the inside of the bearing (202) extend to supporting rods (203) on the outer side of the supporting block (201), a mounting block (204) is fixedly connected to the front side of the supporting rods (203), and a first crown gear (205) is fixedly connected to the back side of the supporting rods (203).

3. The high steep slope surface on-line monitoring device according to claim 2, wherein: fixed subassembly (3) including being located base (301) at supporting shoe (201) back and fixed mounting at fixed plate (1) top, the inside swing joint of base (301) has both ends and all extends to movable rod (302) in the base (301) outside, the positive fixedly connected with of movable rod (302) and first crown gear (205) second crown gear (303) of meshing mutually, the outside fixedly connected with of movable rod (302) is located inside fixture block (304) of base (301), the back fixedly connected with of fixture block (304) is located movable rod (302) outside and one end extends to first spring (305) with the inside fixed connection of base (301), the back fixedly connected with handle (306) of movable rod (302).

4. The high steep slope surface on-line monitoring device according to claim 1, wherein: monitoring subassembly (5) are including fixed mounting in inside laser range finding sensor (501) of mount (4), the equal fixedly connected with pressure sensor (502) of both sides wall about the inner chamber of mount (4), pressure sensor (502) all are connected with signal transmitter (9) electricity with laser range finding sensor (501).

5. The high steep slope surface on-line monitoring device according to claim 1, wherein: the traction assembly (6) comprises two mounting plates (601) which are fixedly mounted on the upper side and the lower side of the fixing frame (4), the outer sides of the mounting plates (601) are fixedly connected with second springs (602), the opposite sides of the second springs (602) are fixedly connected with supporting plates (603), and guide wheels (604) are embedded in the opposite sides of the supporting plates (603).

6. The high steep slope surface on-line monitoring device according to claim 2, wherein: the stretching assembly (7) comprises a stretching rod (701) movably connected to the right side inside the mounting block (204) and one end of the stretching rod extends to the right side of the top of the mounting block (204), and the right side inside the mounting block (204) is in threaded connection with a threaded rod (702) of which one end extends to be in contact with the stretching rod (701).

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