CN219244610U - Hydrologic monitoring rod utilizing rotary lever recycling equipment - Google Patents

Abstract

The utility model relates to a hydrological monitoring rod utilizing a rotating lever recycling device, which comprises a vertical rod, a triangular bracket, a rotating rod, a traction piece and hydrological monitoring equipment, wherein the vertical rod is fixed on the shore of a water area, two end points of the triangular bracket are fixed on the upper part of the vertical rod, the other end point of the triangular bracket is rotationally connected with the rotating rod, one end of the rotating rod is fixedly provided with the traction piece, the end of the rotating rod is detachably and fixedly connected with the triangular bracket, and the other end of the rotating rod is provided with the hydrological monitoring equipment. The utility model has the advantages that: the lever principle is skillfully utilized, so that the hydrologic monitoring equipment above the water surface can very conveniently return to the shore, and the debugging and maintenance difficulty of the hydrologic monitoring equipment is greatly reduced.

Description

Hydrologic monitoring rod utilizing rotary lever recycling equipment

Technical Field

The utility model relates to the technical field of hydrologic monitoring of river channels or lakes and reservoirs, in particular to a hydrologic monitoring rod utilizing a rotary lever recycling device.

Background

In the hydrologic monitoring process of river or lake reservoir, the static pressure level gauge with low cost measures and calculates the liquid level height through measuring the liquid pressure of submerged probe, installs troublesome in the use, and maintenance work load is big, is blocked up easily in the deepwater area and loses efficacy, therefore generally adopts radar level gauge more. In the measurement principle of the radar level gauge, the echo needs to be detected, so the radar level gauge must extend to the position right above the water surface, and although the installation of the radar level gauge is simpler, the maintenance of the radar level gauge right above the water surface is very troublesome, and the maintenance personnel is often required to perform the operation of launching water. At present, the traditional hydrologic monitoring rod is characterized in that a radar liquid level meter is fixed at the tail end of a simple cross rod, the other end of the cross rod is fixed to a vertical rod through a flange, and therefore a worker needs to go down to take a ladder to drive the radar liquid level meter during maintenance, or the whole cross rod is hoisted back to the shore through a crane for detaching the flange of the cross rod. Therefore, how to reduce the difficulty and cost of debugging and maintenance of hydrologic monitoring equipment is a technical problem to be solved.

Disclosure of Invention

In order to solve the problems, the utility model aims to provide the hydrologic monitoring rod by using the rotating lever recycling equipment, which skillfully uses the lever principle to enable the hydrologic monitoring equipment above the water surface to conveniently return to the shore, thereby greatly reducing the debugging and maintenance difficulty of the hydrologic monitoring equipment.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides an utilize rotatory lever recovery plant's hydrologic monitoring pole, includes pole setting, tripod, rotary rod, tractive spare and hydrologic monitoring equipment, the pole setting is fixed in waters bank, the both ends point of tripod is fixed in the upper portion of pole setting, another extreme point with the rotary rod rotates to be connected, the one end of rotary rod is fixed tractive spare and this end with the tripod can dismantle fixed connection, the other end installation of rotary rod hydrologic monitoring equipment.

More preferably, the rotary rod is a telescopic rod, and comprises a fixing part and a telescopic part, the middle part of the fixing part is rotationally connected with the tripod, the tail end of the fixing part is fixed with the traction piece and the end of the traction piece is detachably and fixedly connected with the tripod, the front end of the fixing part is connected with the telescopic part, the length of the telescopic part is adjustable, and the hydrologic monitoring equipment is fixed at the tail end of the telescopic part.

More preferably, the hydrologic monitoring rod further comprises a solar panel, a storage battery and an electric cabinet, wherein the solar panel and the electric cabinet are both fixed on the vertical rod, the solar panel and the storage battery are both connected with the electric cabinet, hydrologic monitoring equipment is connected with the electric cabinet, and the storage battery supplies power for equipment on the hydrologic monitoring rod.

More preferably, the hydrological monitoring rod further comprises a camera, which is fixed on the upright rod and connected with the electric cabinet.

More preferably, the hydrological monitoring rod further comprises a rain gauge fixed at the top end of the upright rod and connected with the electric cabinet.

More preferably, the hydrologic monitoring device is a radar level gauge.

More preferably, the pulling member is a pull rope.

More preferably, the electric control box comprises a solar controller, a telemetry terminal, a circuit breaker and a lightning protection device, wherein the solar controller is connected with the solar panel and the storage battery, the solar controller is connected with the telemetry terminal through the circuit breaker, and the telemetry terminal is in communication connection with the hydrologic monitoring equipment, the camera and the rain gauge; the lightning protection device is connected with the circuit breaker.

The utility model has the following beneficial effects:

according to the hydrologic monitoring rod utilizing the rotating lever recycling equipment, through ingenious design of the vertical rod, the triangular bracket and the rotating rod, hydrologic monitoring equipment right above the water surface can be easily returned to the shore through rotation of the rotating rod, debugging and maintenance personnel do not need to operate in the water, maintainability of the hydrologic monitoring equipment is greatly improved, and difficulty and cost of installation and maintenance are reduced.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of a tripod according to the present utility model;

FIG. 3 is a schematic view of a rotary rod fixing part according to the present utility model;

FIG. 4 is a schematic view of a telescoping portion of a rotary lever according to the present utility model;

FIG. 5 is a schematic view of a solar panel mount of the present utility model;

FIG. 6 is a schematic view of the recovery state of the present utility model;

fig. 7 is an electrical block diagram of the present utility model.

Reference numerals illustrate:

1. a vertical rod; 2. a tripod; 3. a rotating rod; 31. a fixing part; 311. a fixing hole; 32. a telescopic part; 321. an adjustment aperture; 4. a pulling member; 5. a hydrologic monitoring device; 6. a solar panel; 7. a storage battery; 8. an electric control box; 9. a camera; 10. a rain gauge; 100. a solar panel fixing frame; 101. a fixed rod; 102. a connecting sheet; 103. a rotating shaft; 104. an angle adjusting ring; 105. and (5) mounting a bracket.

Detailed Description

The utility model is described in further detail below with reference to the attached drawings and specific examples:

referring to fig. 1 to 4, a hydrological monitoring rod using a swivel lever recovery apparatus includes a vertical rod 1, a tripod 2, a swivel lever 3, a pulling member 4, a hydrological monitoring apparatus 5, a solar panel 6, a storage battery 7, an electric cabinet 8, a camera 9, and a rain gauge 10. The pole setting 1 is fixed in waters bank, the both ends point of tripod 2 is fixed in the upper portion of pole setting 1, another extreme point with rotary rod 3 rotates to be connected, the one end of rotary rod 3 is fixed pull piece 4 and this end with tripod 2 can dismantle fixed connection, the other end installation of rotary rod 3 hydrologic monitoring equipment 5, through rotary rod 3 stretches hydrologic monitoring equipment 5 to the surface of water of river course or lake storehouse directly over the monitoring hydrologic. The camera 9 is fixed on the upper part of the upright 1, and collects surrounding environment images, figures and the like. The rain gauge 10 is fixed at the top end of the vertical rod 1, the rain gauge 10 can adopt a tipping bucket rain gauge, the tipping bucket is used for measuring the water quantity of each turnover, and the turnover times in unit time are counted to obtain the rainfall. The hydrologic information generally includes real-time precipitation, evaporation, water level, flow, sand content, etc., which are measured by different devices, respectively, and in this embodiment, the hydrologic monitoring device is described in detail by taking a radar level gauge as an example, and monitors the water level by the radar level gauge. The hydrologic monitoring equipment 5 can be selected from devices with small storage batteries and wireless transmission modules, and can also be selected from devices which need external devices to supply power and provide data transmission, and only the devices are installed on the bank.

The pulling member 4 is a pull rope, and preferably a hook ring is provided at an end of the rotating rod 3, and one end of the pulling member 4 is connected to the hook ring. When the hydrologic monitoring equipment 5 needs to be recovered or stretched out, the traction piece 4 is hung on a hanging hook ring of the rotating rod 3, and the rotating rod 3 is pulled by manpower to rotate, so that the hydrologic monitoring equipment 5 returns to the shore or stretches out to the water surface.

The rotary rod 3 is a telescopic rod, and comprises a fixing portion 31 and a telescopic portion 32, wherein the middle of the fixing portion 31 is rotationally connected with the tripod 2, the tail end of the fixing portion 31 is fixedly provided with the traction piece 4, the end of the traction piece is detachably and fixedly connected with the tripod 2, the front end of the fixing portion 31 is connected with the telescopic portion 32, the length of the telescopic portion 32 is adjustable, and the hydrologic monitoring equipment 5 is fixed at the tail end of the telescopic portion 32. In this embodiment, the fixing portion 31 may be fixedly connected to the tripod 2 by a bolt. The length adjustment mode of the telescopic part 32 can be that a fixed hole 311 is formed in the front end of the fixed part 31, a plurality of adjusting holes 321 are formed in the telescopic part 32, the length is adjustable through the connection of the adjusting holes 321 in different positions and the fixed hole 311 of the fixed part 31, and therefore the phenomenon that the shore is knocked when the hydrologic monitoring equipment 5 is retracted in a rotating mode can be prevented.

Referring to fig. 7, the solar panel 6 and the electric cabinet 8 are both fixed on the upright 1, and the solar panel 6 and the storage battery 7 are both connected with the electric cabinet 8. The electric cabinet 8 comprises a solar controller, a telemetering terminal, a circuit breaker and a lightning arrester, wherein the solar controller is connected with the solar panel 6 and the storage battery 7, the solar controller is connected with the telemetering terminal through the circuit breaker, and the telemetering terminal is in communication connection with the hydrologic monitoring equipment 5, the camera 9 and the rain gauge 10; the lightning protection device is connected with the circuit breaker. The telemetry terminal generally integrates functions of an RS485 interface, a POE network port, a switching value interface, a GPS positioning antenna and the like, supports wired and wireless network transmission, and remotely transmits various acquired information to a centralized control center or an upper platform. The battery 7 may preferably be placed by using a buried box, and then the buried box is buried under the ground.

The solar panel 6 is fixed to the upright by a solar panel fixing frame 100. Referring to fig. 5, the solar panel fixing frame 100 includes a fixing rod 101, a connecting piece 102, a rotating shaft 103, an angle adjusting ring 104, and a mounting bracket 105. The fixing rod 101 is connected with the connecting sheet 102, the tail end of the connecting sheet 102 is rotatably connected with the mounting bracket 105 through the rotating shaft 103, the angle adjusting ring 104 is welded on the mounting bracket 105, the connecting sheet 102 is provided with a threaded hole, the angle adjusting ring 104 is provided with a plurality of angle positioning holes, during installation, the solar panel 6 is fixed on the mounting bracket 105, the fixing rod 101 is fixed on the vertical rod 1 through the anchor ear, and 360-degree rotation can be carried out around the vertical rod 1 to align the direction of the solar noon time. The rotating shaft 103 is matched with the angle adjusting ring 104 to adjust the angle of the solar panel in the vertical direction so as to fully receive sunlight. After the mounting bracket 105 is turned to a proper angle, the angle of the solar panel 6 is fixed by passing a bolt through an angle positioning hole on the angle adjusting ring 104 and screwing the bolt into a threaded hole of the connecting piece 102.

The working principle of the utility model is as follows:

firstly, referring to fig. 1, a vertical rod 1 is fixed on the shore of a water area, a hydrologic monitoring device 5 is installed on a rotary rod 3, the rotary rod 3 is rotatably connected with an a-frame 2, the tail end of the rotary rod 3 is fixed with the a-frame 2 through bolts, the a-frame 2 is installed on the vertical rod 1, a traction piece 4 is fixed on the rotary rod 3, and the installation of other devices is a conventional technology in the art and is not repeated herein;

secondly, referring to fig. 6, when the hydrologic monitoring device 5 needs to be maintained, the fixing bolt of the rotating rod 3 is loosened, the pulling piece 4 is slowly released, under the action of gravity, the rotating rod 3 naturally returns to the shore in cooperation with the lever principle, the hydrologic monitoring device 5 can hang down along with the rotation of the rotating rod 3, the hydrologic monitoring device 5 is hooked back to the shore by using the long rod with the hook, and an operator can debug and maintain the hydrologic monitoring device 5;

finally, after the maintenance of the hydrologic monitoring equipment 5 is finished, the pulling piece 4 is pulled down and tied on the base opening of the vertical rod 1, the rotary rod 3 and the triangular bracket 2 are locked by the fixing bolt, the task of extending the hydrologic monitoring equipment 5 to the position right above the water surface is completed, debugging maintenance personnel do not need to operate in the water, the maintainability of the hydrologic monitoring equipment 5 is greatly improved, and the maintenance cost and difficulty are reduced.

The foregoing description is only specific embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the present utility model and the accompanying drawings, or direct or indirect application in other related technical fields, are included in the scope of the present utility model.

Claims (8)

1. The utility model provides an utilize hydrologic monitoring pole of swivel lever recovery plant which characterized in that: including pole setting, tripod, rotary rod, tractive spare and hydrologic monitoring facilities, the pole setting is fixed in waters bank, the both ends point of tripod is fixed in the upper portion of pole setting, another extreme point with the rotary rod rotates to be connected, the one end of rotary rod is fixed tractive spare and this end with tripod can dismantle fixed connection, the other end installation of rotary rod hydrologic monitoring facilities.

2. A hydrological monitoring bar utilizing a swivel lever recovery apparatus as defined in claim 1, wherein: the rotary rod is a telescopic rod, and comprises a fixing part and a telescopic part, wherein the middle part of the fixing part is rotationally connected with the triangular bracket, the tail end of the fixing part is fixedly provided with a traction piece, the end of the traction piece is detachably and fixedly connected with the triangular bracket, the front end of the fixing part is connected with the telescopic part, the length of the telescopic part is adjustable, and the hydrologic monitoring equipment is fixed at the tail end of the telescopic part.

3. A hydrological monitoring bar utilizing a swivel lever recovery apparatus as defined in claim 1, wherein: still include solar panel, battery and electric cabinet, solar panel and electric cabinet are all fixed in the pole setting, solar panel and battery are all connected the electric cabinet, hydrologic monitoring equipment with the electric cabinet is connected, the battery is the equipment power supply on the hydrologic monitoring pole.

4. A hydrological monitoring bar utilizing a swivel lever recovery apparatus as defined in claim 3, wherein: still include the camera, it is fixed in the pole setting and with the electric cabinet is connected.

5. A hydrological monitoring bar utilizing a swivel lever recovery apparatus as defined in claim 3, wherein: the rain gauge is fixed at the top end of the vertical rod and is connected with the electric cabinet.

6. A hydrological monitoring bar utilizing a swivel lever recovery apparatus as defined in claim 3, wherein: the hydrologic monitoring equipment is a radar liquid level gauge.

7. A hydrological monitoring bar utilizing a swivel lever recovery apparatus as defined in claim 1, wherein: the pulling piece is a pull rope.

8. A hydrological monitoring bar utilizing a swivel lever recovery apparatus as defined in claim 3, wherein: the electric control box comprises a solar controller, a telemetry terminal, a circuit breaker and a lightning arrester, wherein the solar controller is connected with the solar panel and the storage battery, the solar controller is connected with the telemetry terminal through the circuit breaker, and the telemetry terminal is in communication connection with the hydrologic monitoring equipment, the camera and the rain gauge; the lightning protection device is connected with the circuit breaker.

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