CN219474735U

CN219474735U - Storm flood water level detection equipment under mountain area complex environment

Info

Publication number: CN219474735U
Application number: CN202223264718.0U
Authority: CN
Inventors: 董林垚; 杜俊; 范仲杰; 许文涛; 刘纪根; 张超; 张宏雅; 杨嘉慧
Original assignee: Changjiang River Scientific Research Institute Changjiang Water Resources Commission; Yangtze Ecology and Environment Co Ltd
Current assignee: Changjiang River Scientific Research Institute Changjiang Water Resources Commission; Yangtze Ecology and Environment Co Ltd
Priority date: 2022-12-07
Filing date: 2022-12-07
Publication date: 2023-08-04
Anticipated expiration: 2032-12-07

Abstract

The utility model provides a device for detecting the water level of storm flood in a complex mountain area, which comprises a base plate for stably supporting the whole device; the middle part of the top end of the base plate is fixedly connected with an installation support sliding rod for supporting the top part; the bottom end of the base plate is provided with a base fixing mechanism for supporting and fixing the base plate; the outer side of the mounting support sliding rod is provided with a flood water level and impact force detection mechanism for detecting the flood water level and impact force of the flood; an electric box is fixedly arranged on one side of the top end of the mounting support sliding rod; the top end of the installation support sliding rod is fixedly provided with a monitor for video monitoring. The equipment is convenient for installing and fixing the detection equipment, is favorable for improving the stability of the fixing of the detection equipment, is favorable for preventing the device from inclining due to larger impact force, is convenient for detecting the impact force generated by flood while detecting the water level of the flood, and is convenient for detecting the rising speed of the flood while detecting the impact force generated by the flood.

Description

Storm flood water level detection equipment under mountain area complex environment

Technical Field

The utility model relates to the technical field of storm flood level detection, in particular to storm flood level detection equipment in a complex mountain area environment.

Background

Flood is a water flow phenomenon caused by natural factors such as storm, flash ice and snow melting, storm tide and the like, wherein the water quantity of rivers, lakes and seas is rapidly increased or the water level is rapidly increased. When heavy rain or snow melt occurs in the river basin to generate runoffs, the runoffs are collected at the outlet section of the river channel according to the distance, when the nearby runoffs arrive, the river flow starts to increase, the water level rises correspondingly, when most of high-strength surface runoffs are collected at the outlet section, the river flow increases to the maximum value, namely the peak flood flow, the corresponding highest water level is called the peak flood level, and when the surface runoffs of the river basin and the water stored in the ground, the surface soil and the river network flow and the water level flow out of the outlet section for a certain time after the heavy rain stops, the river flow and the water level fall back to the original state, and the whole process connection curve of the flood from rising to peak top to falling is called the flood process line, and the total water quantity flowing out is called the total flood quantity.

Most of the existing storm flood level detection equipment can only detect the height of the flood level through simple buoyancy plates and monitoring equipment, and cannot detect the rising speed of the flood and the impact force generated in the rising process of the flood, so that countermeasures cannot be timely taken when the flood is discharged.

In addition, the surface at the riverbed is mostly buried directly to current storm flood water level detection equipment base, and when the impact force that rises of flood was too big, the earth of burying on the base can be impacted away, and the base loses earth and fixes and can lead to detection equipment to take place the slope, and then leads to the empting of whole detection equipment, leads to equipment unable normal work.

Disclosure of Invention

The utility model aims to provide a device for detecting the level of storm flood in a complex mountain area, which can detect the rising speed of the flood and the impact force generated in the rising process of the flood, thereby ensuring that countermeasures are taken when the flood is discharged in time; moreover, the base fixing mechanism is adopted to reliably fix the whole detection equipment on the riverbed, so that the stability of the equipment base is improved, the detection equipment is convenient to install and fix, the stability of the detection equipment fixing is improved, the service life of the detection equipment is prolonged, and the inclination of the device caused by larger impact force is prevented.

In order to achieve the above object, the object of the present utility model is achieved as follows: a kind of mountain area complex environment storm flood water level detection equipment, it includes the bed plate used for carrying on the steady support to the whole apparatus;

the middle part of the top end of the base plate is fixedly connected with an installation support sliding rod for supporting the top part;

the bottom end of the base plate is provided with a base fixing mechanism for supporting and fixing the base plate;

the outer side of the mounting support sliding rod is provided with a flood water level and impact force detection mechanism for detecting the flood water level and impact force of the flood;

an electric box is fixedly arranged on one side of the top end of the installation support sliding rod;

the top end of the installation support sliding rod is fixedly provided with a monitor for video monitoring.

The base fixing mechanism comprises a first drill rod, wherein the first drill rod is positioned at one end of the middle part of the inner side of the base plate and is rotationally connected with one end of the middle part of the inner side of the base plate; one end of the outer top end of the first drill rod is connected with a connecting trapezoidal gear rod in a meshed manner, and the middle part of the bottom end of the connecting trapezoidal gear rod is connected with a spiral adjusting rod in a meshed manner; the bottom end of one end of the connecting trapezoidal gear rod is connected with a second drill rod in a meshed manner, the outer side of the spiral adjusting rod is connected with a sliding block in a sliding manner, and the bottom end of the outer side of the sliding block is connected with a bending fixing rod in a rotating manner; the two sides of the first drill rod and the second drill rod are connected with a first adjusting gear rod in a meshed mode, one side of the first adjusting gear rod is connected with a second adjusting gear rod in a meshed mode, the outer sides of the bottom ends of the second adjusting gear rod and the first adjusting gear rod are connected with a transverse supporting inserting plate in a meshed mode, the outer sides of the transverse supporting inserting plate are connected with a transverse clamping plate in a sliding mode, and one side of the transverse clamping plate is fixedly connected with a vertical inserting plate.

The flood water level and impact force detection mechanism comprises a first installation floating plate, wherein the first installation floating plate is positioned in the middle of the bottom end of the outer side of the installation support sliding rod and is in sliding connection with the middle of the bottom end of the outer side of the installation support sliding rod; the inner sides of the two ends of the first installation floating plate are fixedly connected with arc-shaped connecting blocks, the inner sides of the arc-shaped connecting blocks are rotationally connected with arc-shaped hanging blocks, and the bottom ends of the arc-shaped hanging blocks are fixedly connected with first buoyancy balls; the middle parts of the two sides of the first buoyancy ball are rotationally connected with a connecting push plate, one end of the inner side of the connecting push plate is rotationally connected with a second buoyancy ball, the top end of the second buoyancy ball is rotationally connected with the other end of the first installation floating plate through an arc hanging block, and one end of the middle part of the connecting push plate is clamped with a limiting screw rod; one end fixedly connected with third reset spring in the middle part of the first installation floating plate, one end fixedly connected with of third reset spring bulldozes the clamp splice, bulldozes the outside sliding connection of one end and the spacing screw rod of clamp splice, and the middle part fixedly connected with fixed stay scute on connection push pedal top.

The top end of the other end of the mounting support sliding rod is fixedly connected with a fixing supporting plate, the middle part of the inner side of the fixing supporting plate is fixedly connected with a first reset spring, one end of the first reset spring is fixedly connected with a fixing clamping block, and the inner side of the fixing clamping block is rotationally clamped with the top end of the outer side of the limiting screw rod; one end of the top end of the fixed supporting plate is rotationally connected with a pushing block, and one end of the pushing block is fixedly connected with the top end of the limit screw; the top end of the pushing and pressing block is provided with a rotary table, the inner side of the rotary table is fixedly connected with the top end of the outer side of the limit screw, one end of the pushing and pressing block is clamped with a butt joint sliding rod, and one end of the butt joint sliding rod is clamped with a connection sensing piece; the outer side of one end of the butt joint sliding rod is connected with a signal transmission electric plate in a sliding manner, and the bottom end of the signal transmission electric plate is fixedly connected with the top end of the electric box; an impact force sensor is fixedly connected to the middle of the top end of the signal transmission electric plate, the top end of the impact force sensor is connected with an impact hammer in a sliding manner, and one end of the impact hammer is rotationally clamped with the outer side of the top end of the limit screw; the middle part of the outer side of the turntable is fixedly connected with an impact ball; the other end sliding connection at the middle part of the first installation floating plate has a spacing slide bar, the top of spacing slide bar and the one end fixed connection at the middle part of the electronic box bottom, the one end sliding connection in butt joint slide bar outside has a second reset spring, and the second reset spring is located the one end of signal transmission electric plate.

The outer side of the arc-shaped connecting block is fixedly connected with a clamp positioning cavity; the middle parts of the two sides of the arc-shaped hanging block are fixedly connected with a rotating shaft block; the outside sliding connection of third reset spring has first shrink to accomodate the chamber.

The size of the inner side of the first shrinkage accommodating cavity is matched with the size of the outer side of the third reset spring, the size of the outer side of the pushing clamping block is matched with the size of the outer side of the first shrinkage accommodating cavity, and one end of the pushing clamping block is fixedly connected with a spiral hole ring.

The inner side of the fixed clamping block is fixedly connected with a rotary connection arc groove, the outer side of the first reset spring is slidably connected with a second shrinkage accommodating cavity, and the butt joint sliding rod is slidably connected in a limiting sliding cavity groove of the signal transmission electric plate.

The outside sliding connection of horizontal support picture peg has the slip to accomodate the location chamber groove, the size and the size phase-match of the inside size and the size of location chamber groove are accomodate to the horizontal support picture peg outside.

The inside size of slider and the outside size of spiral regulation pole phase-match, the top fixedly connected with rotation regulation button of first drilling rod, the outside swivelling joint who connects trapezoidal gear pole has the swivel chamber.

The utility model has the following beneficial effects:

1. by adopting the water level detection equipment, the rising speed of the flood and the impact force generated in the rising process of the flood can be detected, so that countermeasures are ensured to be made in time when the flood is discharged; moreover, the base fixing mechanism is adopted to reliably fix the whole detection equipment on the riverbed, so that the stability of the equipment base is improved, the detection equipment is convenient to install and fix, the stability of the detection equipment fixing is improved, the service life of the detection equipment is prolonged, and the inclination of the device caused by larger impact force is prevented.

2. Through the base fixing mechanism, when in use, the base fixing mechanism arranged at the bottom of the equipment base plate and the bottom of the base plate is buried at the position of the appointed river bed, so that the first drill rod, the spiral adjusting rod and the second drill rod are deeply buried at the bottom of the river bed, after the buried soil is compacted, the rotating button fixedly connected with the top end of the first drill rod is rotated, the spiral adjusting rod and the second drill rod which are in meshed connection with the middle part and one end of the bottom end of the connecting trapezoidal gear rod are driven to rotate simultaneously through the connecting trapezoidal gear rod which is in meshed connection with the top end of the outer side of the first drill rod, the first adjusting gear rod which is in meshed connection with the first adjusting gear rod is driven to rotate by the rotating first drill rod and the second drill rod, the second adjusting gear rod which is in meshed connection with the first adjusting gear rod is synchronously driven to rotate by the rotating first adjusting gear rod, thereby drive the earth of being connected with first regulation gear pole and second regulation gear pole meshing lateral bracing picture peg to the outside slip card of horizontal cardboard bottom to the river bed in, synchronous by rotatory spiral regulation pole drive outside sliding connection's slider gliding promotion slider outside bottom rotate the buckling fixation pole of connection take place buckling card to the earth of river bed bottom in, the area of contact of equipment base and river bed bottom that increases is favorable to improving the steadiness of equipment base, has played the be convenient for install fixedly to the detection equipment, is favorable to improving the fixed steadiness of detection equipment, is favorable to improving the life of detection equipment, is favorable to preventing that the impact force is great to lead to the device to take place the slope.

3. When in use, when river water rises due to heavy rain, the first buoyancy ball and the second buoyancy ball which are connected with the first installation floating plate are driven to rise simultaneously, so that the first installation floating plate rises along the limit sliding rod and simultaneously drives the limit screw which is in sliding connection with one end of the middle part of the other end of the first installation floating plate to rotate, the rotating limit screw rotates through the turntable fixedly connected with the outer top end to drive the impact ball fixedly connected with the outer side of the turntable to strike one end of the impact sensor under the action of centrifugal force, the impact force sensed by the impact sensor is transmitted into the receiver arranged in the electric box through the transmission module, the impact force generated by the rising of the water level is analyzed, the push block fixedly connected with the top end of the limit screw is synchronously pushed to slide and clamped onto the connection sensing piece when the one end of the limit screw is rotated onto the butt sliding rod, the connection sensing piece receives the butt-joint signal and transmits the received signal into the rotating speed analyzer through the transmission device, the rotating speed of the rotary hammer is calculated according to the recorded time when the rotating speed of the rotary hammer is increased to the rotary hammer, the impact force of the impact ball is driven to rotate towards the first end of the impact ball through the transmission module, the impact force sensor drives the impact ball to rotate towards the first end of the arc-shaped connection ball to rotate around the first end of the impact ball when the impact ball is fixedly connected with the first impact ball, the received impact force is transmitted to a receiver installed in the electric box to analyze the impact force generated by rising of the flood, so that the impact force generated by the flood is conveniently detected while the water level of the flood is detected, the emergency is conveniently and timely prevented, and the rising speed of the flood is conveniently detected while the impact force generated by the flood is detected.

Drawings

The utility model is further described below with reference to the drawings and examples.

Fig. 1 is a schematic structural view of a front view in cross section of the present utility model.

Fig. 2 is a schematic structural view of an enlarged view of the portion a of the present utility model.

Fig. 3 is a schematic structural view of the horizontal clamping plate and the first drill rod in the disassembly perspective view.

Fig. 4 is a schematic structural view of a connection between a second buoyancy ball and a first buoyancy ball according to the present utility model.

Fig. 5 is a schematic structural view of a spacing screw of the present utility model.

In the figure: 1 base plate, 2 base fixing mechanism, 21 first drilling rod, 22 horizontal clamping plate, 23 horizontal supporting plugboard, 24 vertical plugboard, 25 connecting trapezoid gear rod, 26 spiral adjusting rod, 27 sliding block, 28 bending fixing rod, 29 second drilling rod, 210 first adjusting gear rod, 211 second adjusting gear rod, 3 mounting supporting sliding rod, 4 flood water level and impulse detecting mechanism, 41 first mounting floating plate, 42 arc connecting block, 43 arc hanging block, 44 first buoyancy ball 45 connecting push plate, 46 second buoyancy ball, 47 fixed supporting angle plate, 48 limit screw, 49 limit slide bar, 410 fixed support plate, 411 first reset spring, 412 fixed clamping block, 413 turntable, 414 impulse ball, 415 push block, 416 butt slide bar, 417 connecting induction piece, 418 signal transmission electric plate, 419 impulse inductor, 420 second reset spring, 421 impulse hammer, 422 third reset spring, 423 push clamping block, 5 electric box, 6 monitor.

Detailed Description

Embodiments of the present utility model will be further described with reference to the accompanying drawings.

Referring to fig. 1 to 5, a heavy rain flood water level detection device in a complex mountain area comprises a base plate 1 for stably supporting the whole device; the middle part of the top end of the base plate 1 is fixedly connected with an installation support sliding rod 3 for supporting a top part; the bottom end of the base plate 1 is provided with a base fixing mechanism 2 for supporting and fixing the base plate 1; the outer side of the mounting support sliding rod 3 is provided with a flood water level and impact force detection mechanism 4 for detecting the flood water level and the impact force of the flood; an electric box 5 is fixedly arranged on one side of the top end of the installation support sliding rod 3; the top end of the installation support sliding rod 3 is fixedly provided with a monitor 6 for video monitoring. Through adopting foretell water level detection equipment, be convenient for install fixedly to detection equipment, be favorable to improving the fixed steadiness of detection equipment, be favorable to improving detection equipment's life, be favorable to preventing that the impact force is great to lead to the device to take place the slope, be convenient for detect the impact force that the flood produced when detecting the flood water level, be convenient for in time make the prevention prevent emergency to take place, be convenient for detect the speed that the flood rises when detecting the flood and produce the impact force. In the concrete installation and use process, the base plate 1 is fixed through the fixed mechanism 2 of base and the fixed reliability between the riverbed, effectively prevent the water level detection equipment's that flood impacted and cause empty problem. The flood level and impulse detection means 4 can be used for detecting the impact force of the flood and the rising speed of the flood level when the flood arrives.

Further, the base fixing mechanism 2 comprises a first drill rod 21, the first drill rod 21 is located at one end of the middle portion of the inner side of the base plate 1 and is in rotary connection with one end of the middle portion of the inner side of the base plate 1, one end of the outer side top end of the first drill rod 21 is in meshed connection with a connecting trapezoidal gear rod 25, the middle portion of the bottom end of the connecting trapezoidal gear rod 25 is in meshed connection with a spiral adjusting rod 26, the bottom end of one end of the connecting trapezoidal gear rod 25 is in meshed connection with a second drill rod 29, the outer side of the spiral adjusting rod 26 is in sliding connection with a sliding block 27, the bottom end of the outer side of the sliding block 27 is in rotary connection with a bending fixing rod 28, two sides of the first drill rod 21 and the second drill rod 29 are in meshed connection with a first adjusting gear rod 210, one side of the first adjusting gear rod 210 is in meshed connection with a second adjusting gear rod 211, the outer side of the bottom end of the second adjusting gear rod 211 and the first adjusting gear rod 210 is in meshed connection with a transverse supporting plugboard 23, the outer side of the transverse supporting plugboard 23 is in sliding connection with a transverse plugboard 22, and one side of the transverse plugboard 22 is fixedly connected with a vertical plugboard 24. The base fixing mechanism 2 is mainly used for reliably installing and fixing the base plate 1, so that the base plate 1 can be reliably and fixedly installed on a corresponding river bed, and the problem of inclination of the base plate is prevented.

Further, the sliding block 27 and the screw adjusting rod 26 form a threaded transmission fit, and the sliding block 27 is driven to realize lifting action in the process of rotating the screw adjusting rod 26.

Further, in the concrete installation process, first, the base fixing mechanism 2 is buried in a designated position of the river bed, the first drill rod 21, the spiral adjusting rod 26 and the second drill rod 29 are deeply buried in the bottom of the river bed, and buried soil is compacted; then, rotate the rotatory button of first drilling rod 21 top fixed connection, through the connection trapezoidal gear pole 25 that is connected with the outside top meshing of first drilling rod 21 drive with connect trapezoidal gear pole 25 bottom middle part and one end meshing be connected spiral regulation pole 26 and second drilling rod 29 produce the rotation simultaneously, drive the first adjusting gear pole 210 rotation of meshing connection by rotatory first drilling rod 21 and second drilling rod 29, synchronous drive the second adjusting gear pole 211 rotation of meshing connection with first adjusting gear pole 210 by rotatory first adjusting gear pole 210, thereby drive the lateral bracing picture peg 23 that is connected with first adjusting gear pole 210 and second adjusting gear pole 211 meshing to slide to the outside of transverse clamping plate 22 and block into the earth of riverbed bottom, synchronous drive outside sliding connection's slider 27 gliding promotion slider 27 outside bottom rotation is connected buckling fixation pole 28 takes place buckling card to the earth of riverbed bottom, the contact area of equipment base and riverbed bottom is favorable to improving the steadiness of equipment base.

Further, the flood level and impulse force detection mechanism 4 comprises a first installation floating plate 41, wherein the first installation floating plate 41 is located in the middle of the outer bottom end of the installation support sliding rod 3 and is in sliding connection with the middle of the outer bottom end of the installation support sliding rod 3, and is used for driving the buoyancy ball to stably rise.

Further, the inner sides of the two ends of the first installation floating plate 41 are fixedly connected with an arc-shaped connecting block 42, the inner sides of the arc-shaped connecting blocks 42 are rotatably connected with an arc-shaped hanging block 43, and the arc-shaped hanging block 43 is used for limiting the rotating track of the buoyancy ball. The bottom fixedly connected with first buoyancy ball 44 of arc hanging piece 43, the middle part at first buoyancy ball 44 both sides rotates and is connected with connection push pedal 45, the inboard one end of connection push pedal 45 rotates and is connected with second buoyancy ball 46, the top of second buoyancy ball 46 is connected with the other end rotation of first installation floating plate 41 through arc hanging piece 43, the one end joint at connection push pedal 45 middle part has spacing screw 48 for detect the impact force that the flood produced under the state of storm.

Further, a third return spring 422 is fixedly connected to one end of the middle portion of the first installation floating plate 41, one end of the third return spring 422 is fixedly connected with a pushing clamping block 423, one end of the pushing clamping block 423 is slidably connected with the outer side of the limit screw 48 and used for limiting the rotation angle of the limit screw 48, and a fixed supporting angle plate 47 is fixedly connected to the middle portion of the top end of the connecting push plate 45 and used for fixing the first installation floating plate 41.

Further, the top end of the other end of the mounting support sliding rod 3 is fixedly connected with a fixing supporting plate 410, the middle part of the inner side of the fixing supporting plate 410 is fixedly connected with a first reset spring 411, one end of the first reset spring 411 is fixedly connected with a fixing clamping block 412, the inner side of the fixing clamping block 412 is rotationally clamped with the top end of the outer side of the limit screw 48, and the fixing clamping block is further used for limiting the rotation angle of the limit screw 48.

Further, one end of the top end of the fixed supporting plate 410 is rotatably connected with a pushing block 415, one end of the pushing block 415 is fixedly connected with the top end of one end of the limit screw 48, a turntable 413 is arranged at the top end of the pushing block 415, and the inner side of the turntable 413 is fixedly connected with the top end of the outer side of the limit screw 48 and used for installing and fixing the impact ball 414.

Further, the one end joint of bulldozing piece 415 has butt joint slide bar 416, the one end joint of butt joint slide bar 416 has connection induction piece 417 for record the revolution, the outside sliding connection of butt joint slide bar 416 one end has signal transmission electric plate 418, the bottom of signal transmission electric plate 418 and the top fixed connection of electronic box 5, the one end fixedly connected with impulsive force inductor 419 in the middle part of signal transmission electric plate 418 top, impulsive force inductor 419 is used for carrying out the response transmission to the impulsive force, the top sliding connection of impulsive force inductor 419 has impulsive hammer 421, the outside rotatory joint of one end and spacing screw 48 top of impulsive force 421, the middle part fixedly connected with impulsive force ball 414 in the outside of carousel 413 for detect the impulsive force that the flood produced, the other end sliding connection in the middle part of first installation floating plate 41 has spacing slide bar 49 for inject the track that first installation floating plate 41 goes up and down the gliding, the one end fixed connection in the middle part of spacing 49 bottom of electronic box 5, the one end sliding connection outside the impulsive force inductor 419 is used for carrying out the response transmission to the impulsive force, the one end sliding connection in the outside the slide bar 416 has the second reset spring 420, the reset spring 420 is located the outside the transmission slide bar 416.

Further, the outer side of the arc-shaped connection block 42 is fixedly connected with a clamp positioning cavity, the middle parts of the two sides of the arc-shaped hanging block 43 are fixedly connected with a rotating shaft block, and the outer side of the third reset spring 422 is slidably connected with a first shrinkage accommodating cavity.

Further, the size of the inner side of the first shrinkage accommodating cavity is matched with the size of the outer side of the third return spring 422, the size of the outer side of the pushing clamping block 423 is matched with the size of the outer side of the first shrinkage accommodating cavity, and one end of the pushing clamping block 423 is fixedly connected with a spiral hole ring.

Further, the inner side of the fixed clamping block 412 is fixedly connected with a rotary connection arc slot, the outer side of the first return spring 411 is slidably connected with a second shrinkage accommodating cavity, and the docking slide rod 416 is slidably connected in a limiting sliding cavity slot of the signal transmission electric plate 418.

Further, the outer side of the transverse support plugboard 23 is slidably connected with a sliding storage positioning cavity groove, and the outer side of the transverse support plugboard 23 is matched with the inner side of the sliding storage positioning cavity groove.

Further, the size of the inner side of the sliding block 27 is matched with the size of the outer side of the screw adjusting rod 26, a rotary adjusting button is fixedly connected to the top end of the first drill rod 21, and a rotary cavity is rotatably connected to the outer side of the connecting trapezoidal gear rod 25.

The method for detecting the storm flood water level by adopting the storm flood water level detection equipment under the complex mountain area environment comprises the following steps:

step one: when in use, the base plate 1 of the equipment and the base fixing mechanism 2 arranged at the bottom end of the base plate 1 are buried at the designated riverbed position, so that the first drill rod 21, the spiral adjusting rod 26 and the second drill rod 29 are deeply buried at the riverbed bottom, after buried soil is compacted, the rotating button fixedly connected with the top end of the first drill rod 21 is rotated, the spiral adjusting rod 26 and the second drill rod 29 which are in meshed connection with the middle part and one end of the bottom end of the connecting trapezoidal gear rod 25 are driven to rotate simultaneously by the connecting trapezoidal gear rod 25 which is in meshed connection with the top end of the outer side of the first drill rod 21, the first adjusting gear rod 210 which is in meshed connection is driven to rotate by the rotating first drill rod 21 and the second drill rod 29, the first adjusting gear rod 210 which rotates synchronously drives the second adjusting gear rod 211 which is meshed with the first adjusting gear rod 210 to rotate, so that the transverse support plugboard 23 which is meshed with the first adjusting gear rod 210 and the second adjusting gear rod 211 is driven to slide and clamp to the soil at the bottom of the river bed to the outer side of the transverse clamping board 22, the sliding block 27 which is driven to slide and connect at the outer side by the rotating spiral adjusting rod 26 synchronously slides downwards to push the bending fixing rod 28 which is rotationally connected with the bottom end at the outer side of the sliding block 27 to bend and clamp to the soil at the bottom of the river bed, and the contact area between the base plate 1 and the bottom of the river bed is increased, and the stability of the equipment base is improved;

step two: when river water rises due to heavy rain, the first installation floating plate 41 and the first buoyancy ball 44 and the second buoyancy ball 46 connected with the first installation floating plate 41 are driven to rise simultaneously, so that the first installation floating plate 41 rises along the limit sliding rod 49 and simultaneously drives the limit screw 48 which is in sliding connection with one end of the middle part of the other end of the first installation floating plate 41 to rotate, the rotating limit screw 48 rotates through the turntable 413 fixedly connected with the top end of the outer side so as to drive the impact ball 414 fixedly connected with the outer side of the turntable 413 to strike one end of the impact sensor 419 under the action of centrifugal force, and the impact force sensed by the impact sensor 419 is transmitted into the receiver arranged in the electric box 5 through the transmission module to analyze the impact force generated by water level rising;

synchronously, when the pushing block 415 fixedly connected with the top end of one end of the limit screw 48 is screwed onto the butt joint slide bar 416, the butt joint slide bar 416 is pushed to slide and clamp onto the connection induction piece 417, the connection induction piece 417 receives a butt joint signal, the received signal is transmitted into the rotating speed analyzer through the transmitter, and the water level rising speed is calculated according to the recorded rotating speed and the recorded time;

step three: when wind power occurs, storm wind blows lake water to beat on the first buoyancy ball 44 or the second buoyancy ball 46, the arc-shaped hanging block 43 fixedly connected with the top end of the first buoyancy ball 44 is driven to rapidly rotate around the arc-shaped connecting block 42 by a certain angle, so that the first buoyancy ball 44 drives the connecting push plate 45 rotatably connected with the outer side of the first buoyancy ball 44 to move to one end, thereby pushing the limit screw 48 of the clamp to rotate to one end by a certain angle, driving the impact hammer 421 fixedly connected with the top end of the limit screw 48 to rapidly impact the other end of the impact force sensor 419, and transmitting the received impact force into a receiver arranged in the electric box 5 to analyze the impact force generated by rising of flood;

when the limit screw 48 rotates towards one end, the pushing and pressing clamping block 423 of one end clamping is extruded and contracted back into the inner cavity of the inner side of the first installation floating plate 41 under the action of the third reset spring 422, the pushing and pressing clamping block 423 of the other end of the synchronous screw is tightly attached to the limit screw 48 under the action of the third reset spring 422, the fixed clamping block 412 of one end clamping is driven to contract into the fixed supporting plate 410 under the action of the first reset spring 411 after the top end of the synchronous limit screw 48 rotates by a certain angle, so that the fixed clamping block 412 of the other end clamping slides towards the outer side of the fixed supporting plate 410 under the action of the first reset spring 411, the top end of the fixed clamping block 412 tightly attached to the limit screw 48 is always clamped on a designated position, and the condition of water level rising is monitored by the monitor 6.

Claims

1. The utility model provides a storm flood water level detection equipment under mountain area complex environment which characterized in that: it comprises a base plate (1) for stably supporting the whole equipment;

the middle part of the top end of the base plate (1) is fixedly connected with an installation support sliding rod (3) for supporting the top part;

the bottom end of the base plate (1) is provided with a base fixing mechanism (2) for supporting and fixing the base plate (1);

the outer side of the mounting support sliding rod (3) is provided with a flood water level and impact force detection mechanism (4) for detecting the flood water level and the impact force of the flood;

an electric box (5) is fixedly arranged at one side of the top end of the installation support sliding rod (3);

the top end of the installation support sliding rod (3) is fixedly provided with a monitor (6) for video monitoring.

2. The apparatus for detecting the level of a storm flood in a complex mountain environment as claimed in claim 1, wherein: the base fixing mechanism (2) comprises a first drill rod (21), and the first drill rod (21) is positioned at one end of the middle part of the inner side of the base plate (1) and is rotationally connected with one end of the middle part of the inner side of the base plate (1); one end of the outer top end of the first drill rod (21) is connected with a connecting trapezoidal gear rod (25) in a meshed manner, and the middle part of the bottom end of the connecting trapezoidal gear rod (25) is connected with a spiral adjusting rod (26) in a meshed manner; the bottom end of one end of the connecting trapezoidal gear rod (25) is connected with a second drill rod (29) in a meshed manner, the outer side of the spiral adjusting rod (26) is connected with a sliding block (27) in a sliding manner, and the bottom end of the outer side of the sliding block (27) is connected with a bending fixing rod (28) in a rotating manner; the two sides of the first drill rod (21) and the two sides of the second drill rod (29) are connected with a first adjusting gear rod (210) in a meshed mode, one side of the first adjusting gear rod (210) is connected with a second adjusting gear rod (211), the outer sides of the bottom ends of the second adjusting gear rod (211) and the first adjusting gear rod (210) are connected with a transverse supporting inserting plate (23) in a meshed mode, the outer sides of the transverse supporting inserting plate (23) are connected with a transverse clamping plate (22) in a sliding mode, and one side of the transverse clamping plate (22) is fixedly connected with a vertical inserting plate (24).

3. The apparatus for detecting the level of a storm flood in a complex mountain environment as claimed in claim 1, wherein: the flood water level and impulse force detection mechanism (4) comprises a first installation floating plate (41), wherein the first installation floating plate (41) is positioned in the middle of the bottom end of the outer side of the installation support sliding rod (3) and is in sliding connection with the middle of the bottom end of the outer side of the installation support sliding rod (3); the inner sides of the two ends of the first installation floating plate (41) are fixedly connected with arc-shaped connecting blocks (42), the inner sides of the arc-shaped connecting blocks (42) are rotatably connected with arc-shaped hanging blocks (43), and the bottom ends of the arc-shaped hanging blocks (43) are fixedly connected with first buoyancy balls (44); the middle parts of two sides of the first buoyancy ball (44) are rotationally connected with a connecting push plate (45), one end of the inner side of the connecting push plate (45) is rotationally connected with a second buoyancy ball (46), the top end of the second buoyancy ball (46) is rotationally connected with the other end of the first installation buoyancy plate (41) through an arc-shaped hanging block (43), and one end of the middle part of the connecting push plate (45) is clamped with a limiting screw rod (48); one end fixedly connected with third reset spring (422) at first installation floating plate (41) middle part, the one end fixedly connected with of third reset spring (422) bulldozes clamp splice (423), bulldozes the outside sliding connection of clamp splice (423) and spacing screw (48), and the middle part fixedly connected with fixed support scute (47) at connection push pedal (45) top.

4. A stormwater flood detection device in a complex mountain environment as claimed in claim 3, wherein: the top end of the other end of the mounting support sliding rod (3) is fixedly connected with a fixed supporting plate (410), the middle part of the inner side of the fixed supporting plate (410) is fixedly connected with a first reset spring (411), one end of the first reset spring (411) is fixedly connected with a fixed clamping block (412), and the inner side of the fixed clamping block (412) is rotationally clamped with the top end of the outer side of the limit screw (48); one end of the top end of the fixed supporting plate (410) is rotatably connected with a pushing block (415), and one end of the pushing block (415) is fixedly connected with the top end of the limit screw (48); a turntable (413) is arranged at the top end of the pushing block (415), the inner side of the turntable (413) is fixedly connected with the top end of the outer side of the limit screw (48), one end of the pushing block (415) is clamped with a butt joint sliding rod (416), and one end of the butt joint sliding rod (416) is clamped with a connection induction piece (417); the outer side of one end of the butt joint sliding rod (416) is connected with a signal transmission electric plate (418) in a sliding way, and the bottom end of the signal transmission electric plate (418) is fixedly connected with the top end of the electric box (5); an impact force sensor (419) is fixedly connected to the middle of the top end of the signal transmission electric plate (418), an impact hammer (421) is connected to the top end of the impact force sensor (419) in a sliding mode, and one end of the impact hammer (421) is rotationally clamped with the outer side of the top end of the limit screw (48); the middle part of the outer side of the turntable (413) is fixedly connected with an impulse ball (414); the other end sliding connection at the middle part of first installation floating plate (41) has spacing slide bar (49), and the one end fixed connection at the top of spacing slide bar (49) and electric box (5) bottom middle part, the one end sliding connection in butt joint slide bar (416) outside has second reset spring (420), and second reset spring (420) are located the one end of signal transmission electric plate (418).

5. A stormwater flood detection device in a complex mountain environment as claimed in claim 3, wherein: the outer side of the arc-shaped connecting block (42) is fixedly connected with a clamp positioning cavity; the middle parts of the two sides of the arc-shaped hanging block (43) are fixedly connected with a rotating shaft block; the outside sliding connection of third reset spring (422) has first shrink to accomodate the chamber.

6. The device for detecting the level of a storm flood in a complex mountain environment as claimed in claim 5 wherein: the size of the inner side of the first shrinkage accommodating cavity is matched with the size of the outer side of the third reset spring (422), the size of the outer side of the pushing clamping block (423) is matched with the size of the outer side of the first shrinkage accommodating cavity, and one end of the pushing clamping block (423) is fixedly connected with a spiral hole ring.

7. The device for detecting the level of a storm flood in a complex mountain environment as claimed in claim 4 wherein: the inner side of the fixed clamping block (412) is fixedly connected with a rotary connection arc groove, the outer side of the first reset spring (411) is slidably connected with a second shrinkage accommodating cavity, and the butt joint sliding rod (416) is slidably connected in a limiting sliding cavity groove of the signal transmission electric plate (418).

8. A stormwater flood detection device in a complex mountain environment as claimed in claim 2, wherein: the outside sliding connection of horizontal support picture peg (23) has the slip to accomodate the location chamber groove, the size and the size phase-match of the inside size and the size phase-match of location chamber groove are accomodate to the size and the size of the outside of horizontal support picture peg (23).

9. A stormwater flood detection device in a complex mountain environment as claimed in claim 2, wherein: the size of the inner side of the sliding block (27) is matched with the size of the outer side of the spiral adjusting rod (26), a rotary adjusting button is fixedly connected to the top end of the first drill rod (21), and a rotary cavity is rotatably connected to the outer side of the connecting trapezoidal gear rod (25).