CN220016791U - High side slope deformation monitoring device - Google Patents

Abstract

The utility model provides a high side slope deformation monitoring devices, includes monitor and concrete pier, still includes: the base is detachably connected with the concrete column pier; a fastening mechanism for stabilizing the connection between the concrete column pier and the base; a lifting mechanism for changing the height of the monitor; and a protective cover for protecting the monitor. The setting of fastening mechanism makes this device adapt to the deformation monitoring work under the high slope state more, and the staple bolt is connected with the base, makes base and concrete column mound be connected inseparabler, and the supporting leg articulates in the staple bolt bottom, and the supporting leg supports peripheral topography staple bolt and more stably is difficult for taking place the skew, can keep normal operating condition equally when bad weather, and this device also conveniently dismantles simultaneously, can carry out quick turnover with the part other than the concrete column mound after dismantling. The monitor can be placed at the height convenient to monitor through the height adjustment, and the monitor can adapt to the monitoring environment through the height adjustment because the height of the high slope is higher and the height needs to be adjusted to acquire different visual fields during the monitoring.

Description

High side slope deformation monitoring device

Technical Field

The utility model relates to the technical field of high slope deformation monitoring instruments, in particular to a high slope deformation monitoring device.

Background

In high slope deformation monitoring, the external deformation monitoring is mostly observed by adopting an intersection method and a polar coordinate method. Along with the rapid development of the foundation construction of China, engineering design faces more complex geological conditions to a certain extent, so that the influence and the change trend of the slope geological conditions on the stability are required to be considered when the slope design is carried out.

The patent with the publication number of CN216558889U discloses a high side slope deformation monitoring device, which comprises a protection box, the through-hole has been seted up to the upper end of protective housing, the right side of protective housing is equipped with drive assembly, the inside drive assembly that is equipped with in the left and right sides of protective housing, the inside lifting assembly that is equipped with in the left and right sides of protective housing, the inside of protective housing is equipped with the mounting bracket, one side of mounting bracket is equipped with monitoring device body, and second bearing and the equal fixed connection of third bearing are inside the downside of protective housing. However, the fixing device is not stable and is easy to influence bad weather to monitor at a higher position.

Disclosure of Invention

The utility model aims to overcome the defects of the conditions, and aims to provide a high slope deformation monitoring device which can stably monitor a high slope with larger inclination, can keep a normal working state in bad weather and can be quickly disassembled and circulated.

The utility model provides a high side slope deformation monitoring devices, includes monitor and concrete pier, its characterized in that still includes: the base is detachably connected with the concrete column pier; a fastening mechanism for stabilizing the connection between the concrete column pier and the base; a lifting mechanism for changing the height of the monitor; and a protective cover protecting the monitor.

Further, a plurality of embedded bolts are embedded in the top of the concrete pier, mounting holes corresponding to the embedded bolts are formed in the bottom of the base, and the embedded bolts penetrate into the mounting holes.

Further, fastening mechanism includes two anchor clamps, two sets of anchor clamps and a plurality of supporting leg, the anchor clamps press from both sides tightly the concrete pier, the anchor clamps articulate in the anchor clamps top, the supporting leg articulate in the anchor clamps bottom.

Further, the two anchor ears are connected with the first nut through the first bolt.

Further, the front end of the clamp is provided with a clamping plate, the clamping plate is tightly attached to the side wall of the base, and the clamping plate is connected with the base through a second bolt.

Further, elevating system includes first lift bottom plate, second lift bottom plate, lift post, two connecting plates and backup pad, first lift bottom plate and second lift bottom plate sliding connection in base lateral wall and lift post, lift post bottom rigid coupling in the base top, the lift post lateral wall is equipped with spout and a plurality of through-holes, two the connecting plate rigid coupling respectively in first lift bottom plate and second lift bottom plate top, the backup pad rigid coupling in the top of connecting plate.

Further, two protrusions are arranged on the side walls of two ends of the base, and the first lifting bottom plate and the second lifting bottom plate slide up and down between the protrusions.

Further, an opening is formed in the front end of the first lifting bottom plate, a cavity is formed in the opening in a concave mode, a positioning rack is arranged in the cavity and meshed with a rotating gear, a rotating button is fixedly connected above the rotating gear, and the top of the rotating button penetrates through the top of the first lifting bottom plate.

Further, the top of the second lifting bottom plate is fixedly connected with an inclined strut, the top of the inclined strut is fixedly connected with a sliding block, the sliding block slides in the sliding groove, an opening is also formed in the front end of the sliding block, and the positioning rack can penetrate through the through hole to enter the opening.

Further, a connecting seat is arranged at the top of the supporting plate, and the monitor is connected to the connecting seat.

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

(1) the setting of fastening mechanism makes this device adapt to the deformation monitoring work under the high side slope state more, and the staple bolt is connected with the base, makes base and concrete column mound be connected inseparabler, and the supporting leg articulates in the staple bolt bottom, and the supporting leg supports peripheral topography staple bolt and more stably is difficult for taking place the skew, can keep normal operating condition equally when bad weather, and this device also conveniently dismantles simultaneously, only need loosen the second bolt just can dismantle the base, can carry out the turnover fast with the part other than the concrete column mound after dismantling.

(2) The monitor can be placed at the height convenient to monitor through the height adjustment, and the monitor can adapt to the monitoring environment through the height adjustment after the monitoring environment changes due to the fact that the height of the high slope is higher and the height needs to be adjusted to acquire different visual fields during monitoring.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model. In the drawings:

fig. 1 is a schematic diagram of the overall structure of a high slope deformation monitoring device.

Fig. 2 is a schematic view of an elevating mechanism of a high slope deformation monitoring device.

Fig. 3 is a cross-sectional view of a first lifting base plate in a high slope deformation monitoring device.

Fig. 4 is a schematic view of a middle concrete pier of a high slope deformation monitoring device.

In the figure: 1. a monitor; 2. concrete column piers; 21. embedding bolts; 3. a base; 31. a protrusion; 4. a fastening mechanism; 41. a hoop; 42. a clamp; 421. a clamping plate; 43. support legs; 5. a lifting mechanism; 51. a first lifting base plate; 511. positioning a rack; 512. rotating the gear; 513. a rotating knob; 52. a second lifting base plate; 521. diagonal bracing; 522. a slide block; 53. lifting columns; 531. a chute; 532. a through hole; 54. a connecting plate; 55. a support plate; 551. a connecting seat; 56. a handle; 6. and a protective cover.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 4, a high slope deformation monitoring device includes a monitor 1 and a concrete pier 2, and further includes: a base 3 detachably connected to the concrete pier 2; a fastening mechanism 4 for fixing the connection between the concrete column pier 2 and the base 3; a lifting mechanism 5 for changing the height of the monitor 1; and a protective cover 6 protecting the monitor 1.

The monitor 1 is a high-definition camera or a GNSS receiver, and the concrete column pier 2 is a platform for placing monitoring equipment which is poured on a side slope in advance.

The embedded bolts 21 are embedded in the top of the concrete column pier 2, the embedded bolts 21 are positioned when the concrete column pier 2 is poured, the distance between the embedded bolts 21 after concrete solidification is guaranteed to be within an error allowable range, the installation holes corresponding to the embedded bolts 21 are formed in the bottom of the base 3, the embedded bolts 21 penetrate into the installation holes, convenience and quickness are achieved when the base 3 is installed, the height of the base 3 is higher than the length of the embedded bolts 21, and the base 3 is wide and thick, so that the device is more stable.

The fastening mechanism 4 includes two anchor ears 41, two sets of clamps 42, and three sets of support legs 43.

The anchor ear 41 presss from both sides tight concrete pier 2 upper end, and two anchor ears 41 are connected with first nut through first bolt, through with first nut screw in the first bolt, make two anchor ears 41 fasten on concrete pier 2, restrict anchor ear 41's displacement.

The clamp 42 is hinged at the top of the anchor ear 41, the front end of the clamp 42 is provided with a clamp plate 421, the clamp plate 421 is tightly attached to the side wall of the base 3, the corresponding positions of the clamp plate 421 and the side wall of the base 3 are provided with bolt holes for connection, after the base 3 is placed on the embedded bolt 21, the clamp plate 421 is downwards moved to the position where the bolt holes coincide, the clamp plate 421 is connected with the base 3 through a second bolt, and the base 3 is further reinforced by the two clamp plates 421.

The supporting leg 43 articulates in staple bolt 41 bottom, because of the high side slope exists certain slope, and three supporting legs 43 support the peripheral topography of this device, through the support of supporting leg 43, make this device still can keep stable on the great high side slope of gradient, and the position of staple bolt 41 can further be guaranteed to supporting leg 43 simultaneously for base 3 is more stable to be fixed on concrete pier 2, can keep normal operating condition equally during bad weather.

The setting of fastening mechanism 4 makes this device adapt to the deformation monitoring work under the high side slope state more, also conveniently dismantles when having fastened this device, only need loosen the second bolt and just can dismantle base 3, can carry out the turnover fast with the part other than concrete pier 2 after dismantling.

The lifting mechanism 5 comprises a first lifting bottom plate 51, a second lifting bottom plate 52, a lifting column 53, two connecting plates 54 and a supporting plate 55, wherein the first lifting bottom plate 51 and the second lifting bottom plate 52 are slidably connected to the side wall of the base 3 and the lifting column 53, the bottom of the lifting column 53 is fixedly connected to the top of the base 3, a sliding groove 531 and a plurality of through holes 532 are formed in the side wall of the lifting column 53, the plurality of through holes 532 are vertically and uniformly arranged in the sliding groove 531, the two connecting plates 54 are fixedly connected to the tops of the first lifting bottom plate 51 and the second lifting bottom plate 52 respectively, and the supporting plate 55 is fixedly connected to the top of the connecting plate 54.

The two end side walls of the base 3 are respectively provided with two bulges 31, the first lifting bottom plate 51 and the second lifting bottom plate 52 slide up and down between the two bulges 31, and the bulges 31 limit the left-right displacement of the first lifting bottom plate 51 and the second lifting bottom plate 52 when lifting, so that the up-down movement is smoother.

The front end of the first lifting bottom plate 51 is internally provided with an opening, the opening is concave to form a cavity, a positioning rack 511 is arranged in the cavity, the positioning rack 511 is a strip-shaped plate with teeth on one side, the positioning rack 511 is meshed with a rotating gear 512, the rotating gear 512 is also arranged in the cavity, the cavity where the rotating gear 512 is located can accommodate the rotating gear 512 to rotate, other part of the cavity can accommodate the front and back movement of the positioning rack 511, a rotating button 513 is fixedly connected above the rotating gear 512, the top of the rotating button 513 penetrates through the top of the first lifting bottom plate 51, the rotating button 513 is driven to rotate by screwing, so that the positioning rack 511 is controlled to move forwards or backwards, the positioning rack 511 moves forwards to penetrate through a through hole 532, the position of the lifting device is fixed, the purpose of adjusting the height is achieved, the monitor 1 can be placed at the height convenient to monitor through the adjustment of the height, and different visual fields can be acquired through the adjustment of the height during the monitoring.

The top of the second lifting bottom plate 52 is fixedly connected with a diagonal bracing 521, the top of the diagonal bracing 521 is fixedly connected with a sliding block 522, the sliding block 522 slides in a sliding groove 531, the front end of the sliding block 522 is also provided with an opening, and the positioning rack 511 can pass through the through hole 532 to enter the opening, so that the first lifting bottom plate 51 and the second lifting bottom plate 52 are connected into a whole, and the support is more stable.

Handles 56 are fixedly connected to the side walls of the two support plates 55, and the handles 56 are gripped to assist the operation of the lifting mechanism 5 when the height of the lifting mechanism 5 is changed.

The top of the supporting plate 55 is provided with a connecting seat 551, the connecting seat 551 is connected with a monitor 1, a conventional bolt connection is adopted when a GNSS receiver is connected, and a bottom welding or a threaded connection is adopted when a high-definition camera is connected.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. High side slope deformation monitoring devices, including monitor (1) and concrete pier (2), its characterized in that still includes:

a base (3) detachably connected to the concrete pier (2);

a fastening mechanism (4) for stabilizing the connection between the concrete column pier (2) and the base (3);

a lifting mechanism (5) for changing the height of the monitor (1); and

a protective cover (6) for protecting the monitor (1).

2. The high slope deformation monitoring device according to claim 1, wherein: the concrete column pier is characterized in that a plurality of embedded bolts (21) are embedded in the top of the concrete column pier (2), mounting holes corresponding to the embedded bolts (21) are formed in the bottom of the base (3), and the embedded bolts (21) penetrate into the mounting holes.

3. The high slope deformation monitoring device according to claim 2, wherein: fastening mechanism (4) include two staple bolt (41), two sets of anchor clamps (42) and a plurality of supporting leg (43), staple bolt (41) press from both sides tightly concrete pier (2), anchor clamps (42) articulate in staple bolt (41) top, supporting leg (43) articulate in staple bolt (41) bottom.

4. A high slope deformation monitoring device according to claim 3, wherein: the two anchor ears (41) are connected with a first nut through a first bolt.

5. The high slope deformation monitoring device according to claim 4, wherein: the front end of the clamp (42) is provided with a clamping plate (421), the clamping plate (421) is tightly attached to the side wall of the base (3), and the clamping plate (421) is connected with the base (3) through a second bolt.

6. The high slope deformation monitoring device according to claim 5, wherein: elevating system (5) are including first lift bottom plate (51), second lift bottom plate (52), lift post (53), two connecting plates (54) and backup pad (55), first lift bottom plate (51) and second lift bottom plate (52) sliding connection in base (3) lateral wall and lift post (53), lift post (53) bottom rigid coupling in base (3) top, lift post (53) lateral wall be equipped with spout (531) and a plurality of through-hole (532), two connecting plates (54) rigid coupling respectively in first lift bottom plate (51) and second lift bottom plate (52) top, backup pad (55) rigid coupling in the top of connecting plate (54).

7. The high slope deformation monitoring device of claim 6, wherein: the side walls at two ends of the base (3) are respectively provided with two protrusions (31), and the first lifting bottom plate (51) and the second lifting bottom plate (52) slide up and down between the two protrusions (31).

8. The high slope deformation monitoring device of claim 7, wherein: an opening is formed in the front end of the first lifting bottom plate (51), a cavity is formed in the opening in a concave mode, a positioning rack (511) is arranged in the cavity, the positioning rack (511) is meshed with a rotating gear (512), a rotating button (513) is fixedly connected above the rotating gear (512), and the top of the rotating button (513) penetrates through the top of the first lifting bottom plate (51).

9. The high slope deformation monitoring device of claim 8, wherein: the top of the second lifting bottom plate (52) is fixedly connected with a diagonal bracing (521), the top of the diagonal bracing (521) is fixedly connected with a sliding block (522), the sliding block (522) slides in the sliding groove (531), an opening is also formed in the front end of the sliding block (522), and the positioning rack (511) can penetrate through the through hole (532) to enter the opening.

10. The high slope deformation monitoring device of claim 9, wherein: the top of the supporting plate (55) is provided with a connecting seat (551), and the connecting seat (551) is connected with the monitor (1).