CN113781748B - Movable landslide collapse disaster monitoring device - Google Patents

Abstract

The invention discloses a movable landslide collapse disaster monitoring device which structurally comprises a monitoring head, a supporting upright post and a movable bottom plate, wherein the lower end of the monitoring head is fixedly arranged at the top of the supporting upright post, the movable bottom plate is welded at the lower end of the supporting upright post, the ejecting block is used for telescopic extrusion in a spring pipe sleeve to improve the firmness of magnetic adsorption between the ejecting block and a magnetic block, a distance measuring mechanism is driven to rotate after a rotating shaft rotates to avoid angular deviation of the distance measuring mechanism, an abutting piece is elastically supported up and down through four extruding rods on the outer side, vibration damping and buffering are carried out between the distance measuring head and a protective shell, the top of a telescopic supporting rod is extruded at the bottom of an outer frame, the outer side of a linkage plate rotates on a hinged shaft, the hinged shaft moves up and down on a guide rod while rotating, slight up and down movement and buffering are carried out between a supporting rod and the outer frame at the moment, the distance measuring mechanism on the inner side of the outer frame is prevented from greatly shaking, and therefore the accuracy of real-time monitoring data of the distance measuring mechanism is improved.

Description

Movable landslide collapse disaster monitoring device

Technical Field

The invention relates to the field of disaster monitoring, in particular to a movable landslide collapse disaster monitoring device.

Background

In-process that the calamity of collapsing the mountain landslide monitored, need adopt laser range finder, place laser range finder on the spacious position of mountain side, carry out real-time supervision to the distance between mountain and the distancer, change data through real-time distance, can reach the mountain and whether there is the possibility that vibrations produced landslide and collapse, but because the angle of the monitoring head on the laser range finder can rotate the regulation, receive the influence of strong wind on the spacious position easily, the monitoring head on the laser range finder can receive vibrations, and vibrations can make the monitoring head adjust fixed angle and change, and laser range finder wholly receives after vibrations, produce great rocking, the laser range finder carries out the effect of buffering to the monitoring head of self relatively poor, make the monitoring head take place great error to the distance of mountain monitoring, lead to real-time monitoring's data accuracy to descend.

Disclosure of Invention

The technical scheme adopted by the invention for realizing the technical purpose is as follows: this movable landslide disaster monitoring device that collapses, its structure includes monitoring head, support post, removal bottom plate, monitoring head lower extreme fixed mounting is at the support post top to the welding of support post lower extreme has the removal bottom plate, monitoring head includes adjustment mechanism, turn button, block mechanism, buffer gear, adjustment mechanism medial extremity with be equipped with block mechanism to the turn button adopts clearance fit to run through inside adjustment mechanism, the turn button is fixed mutually with block mechanism outside end, the adjustment mechanism bottom is fixed mutually with the buffer gear top.

As a further improvement of the invention, the adjusting mechanism comprises an outer frame, a rotating shaft, magnetic blocks, spring pipe sleeves and ejector blocks, wherein the inner side end of the outer frame is provided with a clamping mechanism, the rotating shaft is fixed with the outer side end of the clamping mechanism, the rotating shaft penetrates through the outer frame, the magnetic blocks are welded on the inner wall of the outer frame, the lower ends of the ejector blocks are arranged in the spring pipe sleeves in a clearance fit mode, the spring pipe sleeves are welded on the outer side of the rotating shaft and abut against the magnetic blocks, the bottom of the outer frame is fixed with the top of the buffering mechanism, the three spring pipe sleeves and the three ejector blocks are distributed on the upper end of the rotating shaft in an arc shape at equal intervals, and the ejector blocks are made of iron and can perform magnetic adsorption with the magnetic blocks.

As a further improvement of the invention, the clamping mechanism comprises a distance measuring mechanism, a sliding shaft, a sliding rail and four clamping blocks, the distance measuring mechanism is arranged on the inner side of the outer frame, the middle end of the outer side of the distance measuring mechanism is fixed with the rotating shaft, the middle end of the bottom of the distance measuring mechanism is provided with the sliding shaft, the sliding shaft is slidably mounted in the sliding rail, the sliding rail is arranged at the lower end of the inner part of the outer frame, the clamping blocks are welded on the inner side of the sliding rail, the clamping blocks are clamped and connected with the outer side of the sliding shaft, the clamping blocks are made of hard rubber and are arranged in seven groups, and four clamping blocks are respectively arranged on the outer side of the sliding shaft.

As a further improvement of the invention, the distance measuring mechanism comprises a protective shell, distance measuring heads, extrusion rods and contact pieces, wherein the distance measuring heads are installed in the protective shell, the outer side ends of the extrusion rods are welded with the inner wall of the protective shell, the inner side ends of the extrusion rods are provided with the contact pieces, the contact pieces are in contact with the outer sides of the distance measuring heads, the protective shell is arranged on the inner side of the outer frame, the middle ends of the outer sides of the protective shell are fixed with the rotating shaft, and the four extrusion rods are spring extrusion rods.

As a further improvement of the invention, the buffer mechanism comprises a support shell, a telescopic support rod and two vibration reduction linkage mechanisms, wherein the middle end inside the support shell is welded with the bottom of the telescopic support rod, the top of the telescopic support rod is welded at the middle end of the bottom of the outer frame, the lower end of the vibration reduction linkage mechanism is arranged inside the support shell, the top of the vibration reduction linkage mechanism is fixed with the outer side of the bottom of the outer frame, and the two vibration reduction linkage mechanisms are respectively arranged at two sides between the support shell and the telescopic support rod.

As a further improvement of the invention, the vibration reduction linkage mechanism comprises a support rod, a linkage plate, articulated shafts, guide rods and a limiting frame, wherein the lower end of the support rod is articulated with one end of the linkage plate, the articulated shafts are arranged at the other end of the linkage plate, the upper ends of the guide rods penetrate through the inside of the articulated shafts in a clearance fit mode, the articulated shafts are arranged inside the limiting frame, the outer side ends of the limiting frame are welded inside the supporting shell, the number of the guide rods is four, and the guide rods are arranged in groups and are respectively arranged at the front ends and the rear ends of the articulated shafts at the two sides.

The invention has the beneficial effects that:

1. through the kicking block in the inside extrusion that stretches out and draws back of spring pipe box, improve magnetic adsorption's fastness between kicking block and the magnetic path, the pivot has driven ranging mechanism after rotating and has rotated, the block can carry out the block after to sliding shaft sliding positioning, improve the inside block ability of sliding shaft at the slide rail, thereby carry out the angle fixed to ranging mechanism bottom, avoid ranging mechanism to take place the angular deviation, elastic support about four extrusion stems in the outside carry out to the contact, to carrying out the damping buffering between range finding head and the protective housing, improve the accuracy of test distance data between range finding head and the massif.

2. The bottom of outer frame extrudees the flexible bracing piece top of the inside middle-end of support shell, and the linkage plate outside rotates on the articulated shaft, and the articulated shaft is guided to move from top to bottom on the guide bar when the pivoted, carries out slight removal buffering from top to bottom between this moment branch and the outer frame, avoids the inside range finding mechanism of outer frame to take place great rocking to range finding mechanism improves real-time supervision's data accuracy.

Drawings

Fig. 1 is a schematic structural diagram of a movable landslide collapse disaster monitoring device according to the present invention.

Fig. 2 is a schematic structural diagram of a monitoring head according to the present invention.

Fig. 3 is a schematic structural diagram of an operating state of an adjusting mechanism according to the present invention.

FIG. 4 is a schematic structural diagram of an engaging mechanism according to the present invention.

Fig. 5 is a schematic diagram of an internal structure of a distance measuring mechanism according to the present invention.

Fig. 6 is a schematic view of an internal structure of a buffer mechanism according to the present invention.

Fig. 7 is a schematic top perspective view of a vibration damping linkage according to the present invention.

In the figure: the device comprises a monitoring head-1, a supporting upright post-2, a movable bottom plate-3, an adjusting mechanism-11, a rotating button-12, a clamping mechanism-13, a buffer mechanism-14, an outer frame-111, a rotating shaft-112, a magnet-113, a spring pipe sleeve-114, a top block-115, a distance measuring mechanism-131, a sliding shaft-132, a sliding rail-133, a clamping block-134, a protective shell-31 a, a distance measuring head-31 b, an extrusion rod-31 c, a collision sheet-31 d, a supporting shell-141, a telescopic supporting rod-142, a vibration reduction linkage mechanism-143, a supporting rod-43 a, a linkage plate-43 b, a hinge shaft-43 c, a guide rod-43 d and a limiting frame-43 e.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example 1:

as shown in figures 1 to 5:

the invention discloses a movable landslide collapse disaster monitoring device which structurally comprises a monitoring head 1, a supporting upright post 2 and a movable bottom plate 3, wherein the lower end of the monitoring head 1 is fixedly arranged at the top of the supporting upright post 2, the movable bottom plate 3 is welded at the lower end of the supporting upright post 2, the monitoring head 1 comprises an adjusting mechanism 11, a rotating button 12, a clamping mechanism 13 and a buffer mechanism 14, the clamping mechanism 13 is arranged at the inner end of the adjusting mechanism 11, the rotating button 12 penetrates through the adjusting mechanism 11 in a clearance fit mode, the rotating button 12 is fixed with the outer end of the clamping mechanism 13, and the bottom of the adjusting mechanism 11 is fixed with the top of the buffer mechanism 14.

The adjusting mechanism 11 includes an outer frame 111, a rotating shaft 112, magnetic blocks 113, a spring pipe sleeve 114 and a top block 115, the inner side end of the outer frame 111 is provided with a clamping mechanism 13, the rotating shaft 112 is fixed with the outer side end of the clamping mechanism 13, the rotating shaft 112 penetrates through the outer frame 111, the magnetic blocks 113 are welded on the inner wall of the outer frame 111, the lower end of the top block 115 is installed inside the spring pipe sleeve 114 in a clearance fit mode, the spring pipe sleeve 114 is welded on the outer side of the rotating shaft 112, the top block 115 abuts against the magnetic blocks 113, the bottom of the outer frame 111 is fixed to the top of the buffer mechanism 14, the spring pipe sleeve 114 and the top block 115 are respectively provided with three parts and are distributed on the upper end of the rotating shaft 112 in an arc-shaped equal distance mode, the top block 115 is made of iron and can perform magnetic adsorption with the magnetic blocks 113, the outer jacking capacity of the top block 115 is improved through a spring inside the spring pipe sleeve 114, and accordingly firmness of the magnetic adsorption between the top block 115 and the magnetic blocks 113 is improved, and angular deviation of the rotating shaft 112 is avoided.

Wherein, block mechanism 13 includes ranging mechanism 131, sliding shaft 132, slide rail 133, block 134, ranging mechanism 131 establishes at outer frame 111 inboardly to ranging mechanism 131 outside middle-end is fixed mutually with pivot 112, ranging mechanism 131 bottom middle-end is equipped with sliding shaft 132, sliding shaft 132 slidable mounting is inside at slide rail 133 to slide rail 133 is established at the inside lower extreme of outer frame 111, the inboard welding of slide rail 133 has block 134, block 134 is connected with the outside block of sliding shaft 132, block 134 adopts the ebonite material, is equipped with seven groups, and every group has four, is located four ends in the sliding shaft 132 outside respectively, does benefit to and carries out the block with the position after sliding shaft 132 rotates to fix a position the block with the angle after ranging mechanism 131 bottom rotates, avoid ranging mechanism 131 to take place the angle skew.

Wherein, ranging mechanism 131 includes protective housing 31a, range finding head 31b, extrusion stem 31c, conflict piece 31d, protective housing 31a internally mounted has range finding head 31b to the end is welded mutually with protective housing 31a inner wall to the extrusion stem 31c outside, extrusion stem 31c medial extremity is equipped with and supports contact 31d, it is inconsistent with the range finding head 31b outside to support contact 31d, protective housing 31a is established at outer frame 111 inboard, and protective housing 31a outside middle-end is fixed mutually with pivot 112, extrusion stem 31c is equipped with four altogether, and for the spring extrusion stem, can carry out the elastic extrusion, thereby will support contact 31d and carry out closely contradicting with range finding head 31b, improve the fastness of range finding head 31b location monitoring.

The specific use mode and function of the embodiment are as follows:

in the invention, the rotating knob 12 is rotated to drive the rotating shaft 112 to rotate, in the rotating process of the rotating shaft 112, the ejector block 115 and the magnetic block 113 are magnetically adsorbed, so that the rotating shaft 112 is angularly fixed, the ejector block 115 is telescopically extruded inside the spring tube sleeve 114, so that the ejector block 115 is telescopic to improve the firmness of magnetic adsorption between the ejector block 115 and the magnetic block 113, the rotating shaft 112 drives the distance measuring mechanism 131 to rotate after rotating, at this time, the sliding shaft 132 at the lower end of the distance measuring mechanism 131 slides inside the sliding rail 133, the sliding shaft 132 can be clamped after being slidably positioned through the clamping block 134, the clamping capacity of the sliding shaft 132 inside the sliding rail 133 is improved, so that the bottom of the distance measuring mechanism 131 is angularly fixed, the angle deviation of the distance measuring mechanism 131 is avoided, in the distance measuring process of the distance measuring head 31b, the abutting contact piece 31d is elastically supported up and down through the four outer extrusion rods 31c, so that the abutting piece 31d abuts against the distance measuring head 31b, and the protective shell 31a buffer is reduced, and the accuracy of the distance measuring data between the distance measuring head 31b and a mountain is improved.

Example 2:

as shown in fig. 6 to 7:

the buffer mechanism 14 includes a support shell 141, a telescopic support rod 142, and a vibration damping linkage mechanism 143, the middle end inside the support shell 141 is welded to the bottom of the telescopic support rod 142, the top of the telescopic support rod 142 is welded to the middle end of the bottom of the outer frame 111, the lower end of the vibration damping linkage mechanism 143 is disposed inside the support shell 141, the top of the vibration damping linkage mechanism 143 is fixed to the outer side of the bottom of the outer frame 111, the two vibration damping linkage mechanisms 143 are disposed, and are respectively disposed on two sides between the support shell 141 and the telescopic support rod 142, so as to facilitate the buffer and vibration damping effects between the telescopic support rod 142 and the outer frame 111, and reduce the shaking generated when the outer frame 111 encounters strong wind.

The vibration reduction linkage mechanism 143 includes a supporting rod 43a, a linkage plate 43b, a hinge shaft 43c, a guide rod 43d, and a limiting frame 43e, wherein the lower end of the supporting rod 43a is hinged to one end of the linkage plate 43b, the other end of the linkage plate 43b is provided with the hinge shaft 43c, the upper end of the guide rod 43d is inserted into the hinge shaft 43c in a clearance fit manner, the hinge shaft 43c is disposed inside the limiting frame 43e, the outer end of the limiting frame 43e is welded inside the supporting shell 141, the number of the guide rods 43d is four, and the two guide rods are a group and are respectively disposed at the front and rear ends of the hinge shaft 43c at two sides, so that the hinge shaft 43c can vertically slide on the guide rod 43d, thereby vertically guiding the linkage plate 43b and slightly moving and buffering the supporting rod 43a and the outer frame 111.

The specific use mode and function of the embodiment are as follows:

in the invention, when strong wind occurs, the distance measuring mechanism 131 is easy to shake, the bottom of the outer frame 111 extrudes the top of the telescopic support rod 142 at the middle end in the support shell 141, the support rod 43a also moves downwards in the extrusion process, the linkage plate 43b is linked, the outer side of the linkage plate 43b rotates on the hinge shaft 43c, the hinge shaft 43c moves up and down on the guide rod 43d in a guiding way while rotating, the limit frame 43e is used for limiting the up-and-down movement distance, the linkage plate 43b is used for carrying out up-and-down linkage buffer support on the support rod 43a, and at the moment, the support rod 43a and the outer frame 111 are buffered by slight up-and-down movement, so that the distance measuring mechanism 131 inside the outer frame 111 is prevented from shaking greatly, and the accuracy of real-time monitoring data is improved by the distance measuring mechanism 131.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims (1)

1. The utility model provides a movable landslide disaster monitoring devices that collapses, its structure includes monitoring head (1), support post (2), removes bottom plate (3), monitoring head (1) lower extreme fixed mounting is at support post (2) top to support post (2) lower extreme welding has removal bottom plate (3), its characterized in that:

the monitoring head (1) comprises an adjusting mechanism (11), a rotating button (12), a clamping mechanism (13) and a buffering mechanism (14), wherein the clamping mechanism (13) is arranged at the inner side end of the adjusting mechanism (11), the rotating button (12) penetrates through the inside of the adjusting mechanism (11) in a clearance fit mode, the rotating button (12) is fixed with the outer side end of the clamping mechanism (13), and the bottom of the adjusting mechanism (11) is fixed with the top of the buffering mechanism (14);

the adjusting mechanism (11) comprises an outer frame (111), a rotating shaft (112), magnetic blocks (113), a spring pipe sleeve (114) and a top block (115), the inner side end of the outer frame (111) is provided with a clamping mechanism (13), the rotating shaft (112) is fixed with the outer side end of the clamping mechanism (13), the rotating shaft (112) penetrates through the outer frame (111), the magnetic blocks (113) are welded on the inner wall of the outer frame (111), the lower end of the top block (115) is installed inside the spring pipe sleeve (114) in a clearance fit mode, the spring pipe sleeve (114) is welded on the outer side of the rotating shaft (112), the top block (115) abuts against the magnetic blocks (113), and the bottom of the outer frame (111) is fixed with the top of the buffer mechanism (14);

the clamping mechanism (13) comprises a distance measuring mechanism (131), a sliding shaft (132), a sliding rail (133) and a clamping block (134), the distance measuring mechanism (131) is arranged on the inner side of the outer frame (111), the middle end of the outer side of the distance measuring mechanism (131) is fixed with the rotating shaft (112), the sliding shaft (132) is arranged at the middle end of the bottom of the distance measuring mechanism (131), the sliding shaft (132) is slidably mounted inside the sliding rail (133), the sliding rail (133) is arranged at the lower end of the inner side of the outer frame (111), the clamping block (134) is welded on the inner side of the sliding rail (133), and the clamping block (134) is connected with the outer side of the sliding shaft (132) in a clamping manner;

the distance measuring mechanism (131) comprises a protective shell (31 a), a distance measuring head (31 b), an extrusion rod (31 c) and a contact piece (31 d), the distance measuring head (31 b) is installed inside the protective shell (31 a), the outer side end of the extrusion rod (31 c) is welded with the inner wall of the protective shell (31 a), a contact piece (31 d) is arranged at the inner side end of the extrusion rod (31 c), the contact piece (31 d) is in contact with the outer side of the distance measuring head (31 b), the protective shell (31 a) is arranged inside the outer frame (111), and the middle end of the outer side of the protective shell (31 a) is fixed with the rotating shaft (112);

the buffer mechanism (14) comprises a support shell (141), a telescopic supporting rod (142) and a vibration reduction linkage mechanism (143), the middle end in the support shell (141) is welded with the bottom of the telescopic supporting rod (142), the top of the telescopic supporting rod (142) is welded at the middle end of the bottom of the outer frame (111), the lower end of the vibration reduction linkage mechanism (143) is arranged in the support shell (141), and the top of the vibration reduction linkage mechanism (143) is fixed with the outer side of the bottom of the outer frame (111);

the vibration reduction linkage mechanism (143) comprises a support rod (43 a), a linkage plate (43 b), a hinge shaft (43 c), a guide rod (43 d) and a limiting frame (43 e), the lower end of the support rod (43 a) is hinged to one end of the linkage plate (43 b), the hinge shaft (43 c) is arranged at the other end of the linkage plate (43 b), the upper end of the guide rod (43 d) penetrates through the inside of the hinge shaft (43 c) in a clearance fit mode, the hinge shaft (43 c) is arranged inside the limiting frame (43 e), and the outer end of the limiting frame (43 e) is welded inside the supporting shell (141);

the rotating knob (12) is rotated to drive the rotating shaft (112) to rotate, in the rotating process of the rotating shaft (112), the ejector block (115) and the magnetic block (113) are magnetically adsorbed, so that the rotating shaft (112) is angularly fixed, the ejector block (115) is used for telescopic extrusion in the spring pipe sleeve (114), so that the ejector block (115) is telescopic to improve the firmness of the magnetic adsorption between the ejector block (115) and the magnetic block (113), the rotating shaft (112) drives the distance measuring mechanism (131) to rotate after rotating, at the moment, a sliding shaft (132) at the lower end of the distance measuring mechanism (131) slides in a sliding rail (133), the sliding shaft (132) can be clamped after being slidably positioned by a clamping block (134), the clamping capacity of the sliding shaft (132) in the sliding rail (133) is improved, so that the bottom of the distance measuring mechanism (131) is angularly fixed, the distance measuring mechanism (131) is prevented from angular deviation, the distance measuring head (31 b) is abutted against a contact piece (31 d) to be elastically supported by four extrusion rods (31 c) at the outer side, and the distance measuring head (31 b) is accurately tested;

when strong wind occurs, the distance measuring mechanism (131) is easy to shake, at the moment, the bottom of the outer frame (111) extrudes the top of a telescopic supporting rod (142) at the middle end in the supporting shell (141), the supporting rod (43 a) can move downwards in the extrusion process, the linkage plate (43 b) is linked, the outer side of the linkage plate (43 b) rotates on the hinge shaft (43 c), the hinge shaft (43 c) moves up and down on the guide rod (43 d) in a guiding mode during rotation, the limiting frame (43 e) is used for limiting the up-down movement distance, the linkage plate (43 b) is used for buffering and supporting the supporting rod (43 a) in an up-down linkage mode, at the moment, the supporting rod (43 a) and the outer frame (111) are buffered in a slight up-down movement mode, the distance measuring mechanism (131) on the inner side of the outer frame (111) is prevented from shaking greatly, and therefore the data accuracy of real-time monitoring is improved by the distance measuring mechanism (131).

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