CN217008335U - Hydrology monitoring facilities based on thing networking - Google Patents

Abstract

The utility model provides hydrological monitoring equipment based on the Internet of things, and belongs to the technical field of hydrological monitoring. This hydrology monitoring facilities based on thing networking includes basic subassembly and protection component. Basic subassembly includes stand, cat ladder, grid board, monitoring instrument, solar panel and camera, seted up flutedly on the stand, the cat ladder the grid board the monitoring instrument solar panel with the camera is all fixed on the outer wall of stand, during the use, speedtransmitter gives the electric jar to the signal transmission, and the electric jar work, the piston rod of electric jar stretch out and support in the inner wall of recess, under the effect of the frictional force between the tailpiece of the piston rod portion of electric jar and the recess inner wall, reaches the effect of slowing down the slider, and the slider finally stops on the slide rail, effectually prevents that the operator from being bruised, is provided with protection component on this hydrology monitoring facilities, has improved the security of operator's work.

Description

Hydrology monitoring facilities based on thing networking

Technical Field

The utility model relates to the field of hydrological monitoring, in particular to hydrological monitoring equipment based on the Internet of things.

Background

The hydrological monitoring system is suitable for hydrological departments to carry out real-time monitoring on hydrological parameters such as rivers, lakes, reservoirs, channels, underground water and the like, and the monitoring content comprises the following steps: water level, flow rate, rainfall, evaporation, silt, slush, soil moisture, water quality, and the like. The hydrological monitoring system adopts a wireless communication mode to transmit monitoring data in real time, so that the working efficiency of a hydrological department can be greatly improved.

At present, the hydrology monitoring facilities based on thing networking that has now need the operator to climb when needs overhaul hydrology monitoring facilities, but does not set up protection machanism on the hydrology monitoring facilities, has reduced the security of operator's work.

SUMMERY OF THE UTILITY MODEL

In order to make up for the defects, the utility model provides hydrological monitoring equipment based on the Internet of things, and aims to solve the problem that when the hydrological monitoring equipment needs to be overhauled, an operator needs to climb, but a protection mechanism is not arranged on the hydrological monitoring equipment, so that the working safety of the operator is reduced.

The utility model is realized by the following steps:

the utility model provides hydrological monitoring equipment based on the Internet of things.

The basic component comprises a stand column, a ladder stand, a grid plate, a monitoring instrument, a solar panel and a camera, wherein a groove is formed in the stand column, the ladder stand is provided with the grid plate, the monitoring instrument is fixed on the outer wall of the stand column, and the monitoring instrument is fixed on the outer wall of the stand column.

The protection component comprises a slide rail, a slide block, a lifting ring, a box body, an electric cylinder, a second storage battery and a speed sensor, wherein the slide rail is fixed in the groove, the slide block is arranged on the slide rail in a sliding mode, the lifting ring is fixed on the outer wall of the slide block, the box body is fixed on the slide block, the electric cylinder and the second storage battery are all fixed in the inner wall of the box body, the speed sensor is fixed on the outer wall of the slide block, the speed sensor and the electric cylinder are all connected with the second storage battery in an electric mode, and the speed sensor and the electric cylinder are connected together in an electric mode.

In one embodiment of the utility model, the base assembly further comprises a connecting plate fixed to a lower surface of the pillar.

In one embodiment of the utility model, the foundation assembly further comprises uprights fixed between the grid plates.

In an embodiment of the utility model, the solar panel includes a solar panel body, a first storage battery and a bracket, one end of the bracket is fixed on the outer wall of the upright column, the other end of the bracket is fixed on the outer wall of the solar panel body, the first storage battery is fixed on the outer wall of the solar panel body, and the monitoring instrument, the solar panel body and the camera are all electrically connected together with the first storage battery.

In an embodiment of the present invention, the camera includes a cross bar and a camera body, one end of the cross bar is fixed to the upper end of the upright, and the camera body is fixed to the cross bar.

In an embodiment of the present invention, the shielding assembly further includes a guide sleeve, the guide sleeve is fixed on the box body, and a piston rod of the electric cylinder slidably penetrates through the guide sleeve.

In one embodiment of the utility model, the guard assembly further comprises a lobe fixed to a piston rod end of the electric cylinder.

In an embodiment of the present invention, the protection component further includes an electric quantity sensor and a buzzer, the electric quantity sensor and the buzzer are both fixed in an inner wall of the box body, the electric quantity sensor and the buzzer are both electrically connected with the second battery, and the electric quantity sensor and the buzzer are electrically connected together.

In one embodiment of the utility model, the base assembly further comprises angle steel fixed between the outer wall of the upright and the lower surface of the cross bar.

In one embodiment of the utility model, at least three electric cylinders are arranged in the box body, and the electric cylinders are distributed in the box body at equal intervals.

The beneficial effects of the utility model are: when the hydrological monitoring equipment based on the Internet of things is used, in the hydrological monitoring process by using the monitoring instrument, when the monitoring instrument, the solar panel and the camera need to be overhauled, an operator buckles a safety buckle ring on a safety belt on a hanging ring, then the operator can climb a ladder and climb onto a grid plate, the slide block synchronously moves upwards on the slide rail in the ascending process, when the operator falls down carelessly, the slide block synchronously moves downwards on the slide rail, when the speed sensor senses that the speed of the slide block downwards moves reaches a set maximum value, the speed sensor transmits a signal to the electric cylinder, the electric cylinder works, a piston rod of the electric cylinder extends out and abuts against the inner wall of the groove, the effect of reducing the speed of the slide block is achieved under the action of friction force between the end part of the piston rod of the electric cylinder and the inner wall of the groove, and the slide block finally stays on the slide rail, the effectual operator that prevents is hindered by the fall, is provided with protective assembly on this hydrology monitoring facilities, has improved the security of operator's work.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a hydrological monitoring device based on the internet of things according to an embodiment of the present invention;

fig. 2 is a schematic cross-sectional structure diagram of a hydrological monitoring device based on the internet of things according to an embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view of a base assembly according to an embodiment of the present invention;

FIG. 4 is a schematic cross-sectional view of a shield assembly according to an embodiment of the present invention;

fig. 5 is an enlarged view of the area a in fig. 4 according to an embodiment of the present invention.

In the figure: 100-a base component; 110-upright post; 120-a connecting plate; 130-a groove; 140-ladder stand; 150-upright stanchion; 160-a grid plate; 170-monitoring the instrument; 180-solar panel; 181-solar panel body; 182-a first battery; 183-bracket; 190-camera; 1901-cross bar; 1902-a camera body; 191-angle steel; 200-a guard assembly; 210-a slide rail; 220-a slide block; 230-a lifting ring; 250-a box body; 260-electric cylinder; 270-guide sleeve; 280-convex teeth; 290-a charge sensor; 291-second battery; 292-a buzzer; 293-speed sensor.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Examples

Referring to fig. 1-5, the present invention provides a technical solution: a hydrological monitoring device based on the Internet of things comprises a base assembly 100 and a protection assembly 200. The protection component 200 is arranged on the base component 100, and the protection component 200 is arranged on the hydrologic monitoring device, so that the working safety of an operator is improved.

Referring to fig. 1-3, the base assembly 100 includes a vertical column 110, a ladder 140, a grid plate 160, a monitoring instrument 170, a solar panel 180, and a camera 190, a groove 130 is formed in the vertical column 110, the ladder 140, the grid plate 160, the monitoring instrument 170, the solar panel 180, and the camera 190 are all fixed to an outer wall of the vertical column 110 by bolts, the base assembly 100 further includes an upright 150, the upright 150 is fixed between the grid plates 160 by bolts, the upright 150 enables the grid plate 160 to be more firmly fixed to the vertical column 110, the solar panel 180 includes a solar panel body 181, a first storage battery 182, and a bracket 183, one end of the bracket 183 is fixed to the outer wall of the vertical column 110 by bolts, and the other end of the bracket 183 is fixed to the outer wall of the solar panel body 181 by bolts.

The first storage battery 182 is fixed on the outer wall of the solar panel body 181 through a bolt, the monitoring instrument 170, the solar panel body 181 and the camera 190 are electrically connected with the first storage battery 182, the first storage battery 182 is convenient for supplying power to the monitoring instrument 170, the solar panel body 181 and the camera 190, the camera 190 comprises a cross rod 1901 and a camera body 1902, one end of the cross rod 1901 is fixed at the upper end of the upright column 110 through a bolt, the camera body 1902 is fixed on the cross rod 1901 through a bolt, the cross rod 1901 is convenient for installing and fixing the camera body 1902 on the upright column 110, the foundation component 100 further comprises an angle steel 191, the angle steel 191 is fixed between the outer wall of the upright column 110 and the lower surface of the cross rod 1901 through a bolt, the angle steel 191 enables the bearing capacity of the cross rod 1901 to be stronger, the monitoring instrument 170 and the camera 190 are electrically connected with the solar panel 180, the foundation component 100 further comprises a connecting plate 120, the connecting plate 120 is welded on the lower surface of the upright 110, and the connecting plate 120 facilitates the installation and fixation of the upright 110.

Referring to fig. 2, 4 and 5, the protection assembly 200 includes a slide rail 210, a slide block 220, a suspension ring 230, a box 250, an electric cylinder 260, a second storage battery 291 and a speed sensor 293, wherein the slide rail 210 is fixed in the groove 130 by bolts, the slide block 220 is slidably disposed on the slide rail 210, the suspension ring 230 is fixed on an outer wall of the slide block 220 by bolts, the box 250 is fixed on the slide block 220 by bolts, the electric cylinder 260 and the second storage battery 291 are both fixed in an inner wall of the box 250 by bolts, the electric cylinders 260 in the box body 250 are at least three, the electric cylinders 260 are equidistantly distributed in the box body 250, the end parts of the electric cylinders 260 are extruded through the inner wall of the extrusion groove 130, the sliding block 220 is rapidly fixed on the sliding rail 210, the protection assembly 200 further comprises a guide sleeve 270, the guide sleeve 270 is welded on the box body 250, a piston rod of the electric cylinder 260 slides to penetrate through the guide sleeve 270, and the guide sleeve 270 enables the piston rod of the electric cylinder 260 to move on the box body 250 more smoothly.

The protection assembly 200 further comprises a convex tooth 280, the convex tooth 280 is welded at the end part of the piston rod of the electric cylinder 260, the convex tooth 280 increases the roughness of the end part of the piston rod of the electric cylinder 260, a speed sensor 293 is fixed on the outer wall of the sliding block 220 through a bolt, the speed sensor 293 and the electric cylinder 260 are both electrically connected with a second storage battery 291, the speed sensor 293 is electrically connected with the electric cylinder 260, the protection assembly 200 further comprises an electric quantity sensor 290 and a buzzer 292, the electric quantity sensor 290 and the buzzer 292 are both fixed in the inner wall of the box body 250 through bolts, the electric quantity sensor 290 and the buzzer 292 are both electrically connected with the second storage battery 291, the electric quantity sensor 290 and the buzzer 292 are both electrically connected, the electric quantity sensor 290 facilitates real-time monitoring of the electric quantity in the second storage battery 291, when the electric quantity in the second storage battery 291 is smaller than a set value, the electric quantity sensor 290 transmits a signal to the buzzer 292, the buzzer 292 alarms to remind the operator to charge the second storage battery 291.

Specifically, this hydrology monitoring facilities based on thing networking's theory of operation: when the hydrologic monitoring device 170 is used, when the monitoring device 170, the solar panel 180 and the camera 190 need to be overhauled, an operator buckles a safety buckle on a safety belt on the hanging ring 230, then the operator can climb the ladder stand 140 and go up to the grid plate 160, the slide block 220 synchronously moves up and down on the slide rail 210 in the ascending process, when the operator falls down carelessly, the slide block 220 can synchronously move up and down on the slide rail 210, when the speed sensor 293 senses that the speed of the downward movement of the slide block 220 reaches a set maximum value, the speed sensor 293 transmits a signal to the electric cylinder 260, the electric cylinder 260 works, a piston rod of the electric cylinder 260 extends out and abuts against the inner wall of the groove 130, the effect of reducing the speed of the slide block 220 is achieved under the action of friction force between the end part of the piston rod of the electric cylinder 260 and the inner wall of the groove 130, and the slide block 220 finally stays on the slide rail 210, the effective operator that prevents is hindered by the fall, is provided with protective component 200 on this hydrology monitoring facilities, has improved the security of operator's work.

It should be noted that the specific model specifications of the monitoring instrument 170, the solar panel 180, the first storage battery 182, the camera 190, the electric cylinder 260, the electric quantity sensor 290, the second storage battery 291, the buzzer 292, and the speed sensor 293 need to be determined by type selection according to the actual specification of the device, and the specific type selection calculation method adopts the prior art in the field, and therefore details are not repeated.

The power supply and the principle of the monitoring instrument 170, the solar panel 180, the first storage battery 182, the camera 190, the electric cylinder 260, the electric quantity sensor 290, the second storage battery 291, the buzzer 292 and the speed sensor 293 are clear to those skilled in the art and will not be described in detail herein.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. Hydrology monitoring facilities based on thing networking, its characterized in that includes

The solar monitoring system comprises a base assembly (100), wherein the base assembly (100) comprises an upright column (110), a ladder (140), a grid plate (160), a monitoring instrument (170), a solar panel (180) and a camera (190), a groove (130) is formed in the upright column (110), the ladder (140), the grid plate (160), the monitoring instrument (170), the solar panel (180) and the camera (190) are all fixed on the outer wall of the upright column (110), and the monitoring instrument (170) and the camera (190) are both electrically connected with the solar panel (180);

the protection assembly (200), the protection assembly (200) comprises a slide rail (210), a slide block (220), a hanging ring (230), a box body (250), an electric cylinder (260), a second storage battery (291) and a speed sensor (293), the sliding rail (210) is fixed in the groove (130), the sliding block (220) is arranged on the sliding rail (210) in a sliding way, the hanging ring (230) is fixed on the outer wall of the sliding block (220), the box body (250) is fixed on the sliding block (220), the electric cylinder (260) and the second storage battery (291) are both fixed in the inner wall of the case (250), the speed sensor (293) is fixed on the outer wall of the sliding block (220), the speed sensor (293) and the electric cylinder (260) are electrically connected with the second storage battery (291), the speed sensor (293) and the electric cylinder (260) are electrically connected together.

2. The internet of things-based hydrological monitoring device of claim 1, wherein the base assembly (100) further comprises a connecting plate (120), the connecting plate (120) being fixed on a lower surface of the upright (110).

3. The internet of things-based hydrological monitoring device of claim 1, wherein the base assembly (100) further comprises uprights (150), the uprights (150) being fixed between the grid plates (160).

4. The Internet of things-based hydrological monitoring device of claim 1, wherein the solar panel (180) comprises a solar panel body (181), a first storage battery (182) and a bracket (183), one end of the bracket (183) is fixed on the outer wall of the upright column (110), the other end of the bracket (183) is fixed on the outer wall of the solar panel body (181), the first storage battery (182) is fixed on the outer wall of the solar panel body (181), and the monitoring instrument (170), the solar panel body (181) and the camera (190) are all electrically connected together with the first storage battery (182).

5. The Internet of things-based hydrological monitoring device according to claim 1, wherein the camera (190) comprises a cross bar (1901) and a camera body (1902), one end of the cross bar (1901) is fixed to the upper end of the upright post (110), and the camera body (1902) is fixed to the cross bar (1901).

6. The Internet of things-based hydrological monitoring device of claim 1, wherein the shield assembly (200) further comprises a guide sleeve (270), the guide sleeve (270) is fixed on the box body (250), and a piston rod of the electric cylinder (260) slidably penetrates through the guide sleeve (270).

7. The internet of things-based hydrological monitoring device of claim 1, wherein the shield assembly (200) further comprises a protruding tooth (280), the protruding tooth (280) being fixed at a piston rod end of the electric cylinder (260).

8. The internet of things-based hydrological monitoring device according to claim 1, wherein the protective assembly (200) further comprises a charge sensor (290) and a buzzer (292), the charge sensor (290) and the buzzer (292) are both fixed in an inner wall of the box body (250), the charge sensor (290) and the buzzer (292) are both electrically connected together with the second storage battery (291), and the charge sensor (290) and the buzzer (292) are both electrically connected together.

9. The Internet of things-based hydrological monitoring device of claim 5, wherein the base assembly (100) further comprises angle steel (191), the angle steel (191) being fixed between an outer wall of the column (110) and a lower surface of the cross bar (1901).

10. The Internet of things-based hydrological monitoring device of claim 1, wherein at least three electric cylinders (260) are provided in the box body (250), and the electric cylinders (260) are distributed in the box body (250) at equal intervals.

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