CN217083882U - Hydraulic engineering water level intelligent monitoring equipment - Google Patents

Abstract

The utility model discloses a hydraulic engineering water level intelligent monitoring equipment relates to water level monitoring equipment technical field, including hollow measuring stick, the surface cover of hollow measuring stick has gliding kickboard from top to bottom, and the inside sliding connection of hollow measuring stick has the slider, and laser sensor is installed to the inside top surface of hollow measuring stick, and the top welding of hollow measuring stick has the roof, and surface mounting has the measuring cabinet on the roof, and the outside right flank of measuring cabinet installs audible-visual annunciator. The kickboard can carry out the oscilaltion along with the change of water level, and the kickboard that carries out the oscilaltion can drive the inside slider of hollow measuring stick in step and slide from top to bottom, and laser sensor can monitor the interval between laser sensor and the slider to can be accurate measure out water level data is indirect, and the water level data that measure out can be real-time show out at the LED display screen, and when the water level reachd the warning water level, can also carry out acousto-optic warning voluntarily.

Description

Hydraulic engineering water level intelligent monitoring equipment

Technical Field

The utility model relates to a water level monitoring equipment technical field especially relates to a hydraulic engineering water level intelligent monitoring equipment.

Background

The water conservancy project is a project built for controlling and allocating surface water and underground water in the nature to achieve the purposes of removing harm and benefiting, is also called as water project, water level monitoring is an indispensable link in the detection work of the water conservancy project, and the water level monitoring work is mainly used for monitoring the water depth of water bodies intercepted by the water conservancy projects such as dams and the like.

At present, most of water level monitoring modes are manual water level monitoring through observing scales on a measuring mark post, the monitoring modes are difficult to display accurate data of water level in time, and when the water level reaches a warning water level, alarming is difficult to carry out, so that a hydraulic engineering water level intelligent monitoring device is provided, and the technical problem provided by the water level intelligent monitoring device is solved.

SUMMERY OF THE UTILITY MODEL

The utility model provides a hydraulic engineering water level intelligent monitoring equipment is in order to solve the water level monitoring mode of the prior art that above-mentioned background art provided, is difficult to in time show out the accurate data of water level to when the water level to the warning water level, be difficult to the problem of reporting to the police.

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

the utility model provides a hydraulic engineering water level intelligent monitoring equipment, includes hollow measuring stick, the surface cover of hollow measuring stick has gliding kickboard from top to bottom, the inside sliding connection of hollow measuring stick has the slider, laser sensor is installed to the inside top surface of hollow measuring stick, the top welding of hollow measuring stick has the roof, surface mounting has the measuring cabinet on the roof, the outside right flank mounting of measuring cabinet has audible-visual annunciator.

Furthermore, a through groove is formed in the right side face of the hollow measuring rod, the sliding block is located on the inner side of the floating plate, and the right end of the sliding block penetrates through the through groove and is welded with the right side face of the inner side of the floating plate.

Furthermore, the laser sensor is located right above the sliding block, and a reflecting plate matched with the laser sensor for use is welded on the upper surface of the sliding block.

Furthermore, a conical scraper is installed at the bottom of the floating plate through a screw, the conical scraper is sleeved on the outer surface of the hollow measuring rod, and scales are carved on the front surface of the hollow measuring rod.

Furthermore, the inside of measuring cabinet installs battery, singlechip and wireless transceiver module, the outside top of measuring cabinet is installed the photovoltaic board, the outside front surface of measuring cabinet has inlayed the LED display screen.

Further, the LED display screen, the audible and visual alarm, the photovoltaic panel, the single chip microcomputer, the laser sensor and the wireless transceiver module are all connected with the storage battery through wires.

Furthermore, the LED display screen, the audible and visual alarm, the laser sensor and the wireless transceiver module are all connected with the single chip microcomputer through wires.

Compared with the prior art, the utility model discloses the beneficial effect who realizes:

the floating plate capable of sliding up and down is arranged outside the hollow measuring rod and floats on the water surface, so that the floating plate can lift up and down along with the change of the water level, and the floating plate which can go up and down can synchronously drive the slide block in the hollow measuring rod to go up and down, when the slide block goes up and down, because the laser sensor is arranged right above the sliding block and can monitor the distance between the laser sensor and the sliding block, therefore, under the condition that the distance between the laser sensor and the river bed is known, the water level height can be indirectly obtained by subtracting the distance between the laser sensor and the sliding block, so that the water level data can be accurately measured by the mode, and the measured water level data can be displayed on an LED display screen in real time, and when the water level reaches the warning water level, sound and light alarm can be automatically carried out.

Drawings

Fig. 1 is a schematic view of the overall external structure of the present invention.

Fig. 2 is a schematic view of the overall internal structure of the present invention.

Fig. 3 is a partially enlarged view of a portion a of fig. 2 according to the present invention.

Fig. 4 is a schematic top view of the floating plate of the present invention.

In FIGS. 1-4: 1-hollow measuring rod, 101-through groove, 2-floating plate, 3-conical scraper, 4-scale, 5-top plate, 6-measuring cabinet, 7-LED display screen, 8-audible and visual alarm, 9-photovoltaic plate, 10-storage battery, 11-single chip microcomputer, 12-laser sensor, 13-sliding block, 14-reflecting plate and 15-wireless transceiver module.

Detailed Description

Please refer to fig. 1 to 4:

the utility model provides a hydraulic engineering water level intelligent monitoring equipment, including hollow measuring stick 1, the surface cover of hollow measuring stick 1 has the kickboard 2 that can slide from top to bottom, the inside sliding connection of hollow measuring stick 1 has slider 13, the top surface of the inside of hollow measuring stick 1 is installed laser sensor 12, the top welding of hollow measuring stick 1 has roof 5, the surface mounting has measuring cabinet 6 on the roof 5, the right flank outside measuring cabinet 6 is installed audible-visual annunciator 8;

specifically, a storage battery 10, a single chip microcomputer 11 and a wireless transceiver module 15 are installed inside a measuring cabinet 6, a photovoltaic panel 9 is installed at the top outside the measuring cabinet 6, an LED display screen 7 is embedded on the front surface outside the measuring cabinet 6, the LED display screen 7, an audible and visual alarm 8, the photovoltaic panel 9, the single chip microcomputer 11, a laser sensor 12 and the wireless transceiver module 15 are all connected with the storage battery 10 through wires, and the LED display screen 7, the audible and visual alarm 8, the laser sensor 12 and the wireless transceiver module 15 are all connected with the single chip microcomputer 11 through wires;

the photovoltaic panel 9 can convert solar energy into electric energy and transmit the electric energy to the storage battery 10 for storage, and the storage battery 10 can provide electric power for the LED display screen 7, the audible and visual alarm 8, the single chip microcomputer 11, the laser sensor 12 and the wireless transceiving module 15;

according to the above, the right side surface of the hollow measuring rod 1 is provided with the through groove 101, the slider 13 is positioned on the inner side of the floating plate 2, the right end of the slider 13 penetrates through the through groove 101 and is welded with the right side surface of the inner side of the floating plate 2, the laser sensor 12 is positioned right above the slider 13, and the upper surface of the slider 13 is welded with the reflecting plate 14 matched with the laser sensor 12;

specifically, the floating plate 2 floats on the water surface, so that the floating plate 2 can be lifted up and down outside the hollow measuring rod 1 along with the change of the water level, and when the floating plate 2 is lifted up and down, the sliding block 13 can be synchronously driven to slide up and down;

the laser sensor 12 can emit laser to the reflecting plate 14 above the sliding block 13, the reflecting plate 14 reflects the laser back to the laser sensor 12, so that the laser sensor 12 can measure the distance between the laser sensor 12 and the sliding block 13, the measured data can be sent to the singlechip 11, after the singlechip 11 receives the data, under the condition that the distance between the laser sensor 12 and the riverbed is known, the distance between the laser sensor 12 and the sliding block 13 can be subtracted, the water level height can be indirectly calculated, thus, by adopting the mode, the water level data can be accurately measured, the singlechip 11 can display the measured water level data on an LED display screen in real time, meanwhile, the singlechip 11 can also send the water level data to a data receiving terminal through the wireless transceiver module 15, and when the water level is monitored, if the water level reaches the warning water level, the singlechip 11 can automatically turn on the audible and visual alarm 8 so as to give an audible and visual alarm;

specifically, a conical scraper 3 is installed at the bottom of the floating plate 2 through a screw, the conical scraper 3 is sleeved on the outer surface of the hollow measuring rod 1, and a scale 4 is carved on the front surface of the hollow measuring rod 1;

under the circumstances of outage, also can measure the water level through scale 4 on the hollow measuring stick 1, circular cone scraper 3 can slide from top to bottom along with kickboard 2 goes on, and when kickboard 2 descends, circular cone scraper 3 just can be scraped its below and attached to the mud of 1 surface of hollow measuring stick to avoid mud to influence the definition of scale 4.

Claims (7)

1. The utility model provides a hydraulic engineering water level intelligent monitoring equipment, includes hollow measuring stick (1), its characterized in that:

the utility model discloses a hollow measuring rod, including hollow measuring rod (1), laser sensor (12), roof (5) are welded to the top welding of hollow measuring rod (1), the surface cover of hollow measuring rod (1) has about gliding kickboard (2), the inside sliding connection of hollow measuring rod (1) has slider (13), laser sensor (12) are installed to the inside top surface of hollow measuring rod (1), surface mounting has measuring cabinet (6) on roof (5), the outside right flank mounting of measuring cabinet (6) has audible-visual annunciator (8).

2. The hydraulic engineering water level intelligent monitoring equipment of claim 1, characterized in that: a through groove (101) is formed in the right side face of the hollow measuring rod (1), the sliding block (13) is located on the inner side of the floating plate (2), and the right end of the sliding block (13) penetrates through the through groove (101) and is welded with the right side face of the inner side of the floating plate (2).

3. The hydraulic engineering water level intelligent monitoring equipment of claim 1, characterized in that: the laser sensor (12) is located right above the sliding block (13), and a reflecting plate (14) matched with the laser sensor (12) for use is welded on the upper surface of the sliding block (13).

4. The hydraulic engineering water level intelligent monitoring equipment of claim 1, characterized in that: the bottom of the floating plate (2) is provided with a conical scraper (3) through a screw, the conical scraper (3) is sleeved on the outer surface of the hollow measuring rod (1), and a scale (4) is carved on the front surface of the hollow measuring rod (1).

5. The hydraulic engineering water level intelligent monitoring equipment of claim 1, characterized in that: the measuring cabinet is characterized in that a storage battery (10), a single chip microcomputer (11) and a wireless transceiver module (15) are arranged inside the measuring cabinet (6), a photovoltaic panel (9) is arranged at the top of the outside of the measuring cabinet (6), and an LED display screen (7) is embedded on the front surface of the outside of the measuring cabinet (6).

6. The hydraulic engineering water level intelligent monitoring equipment of claim 5, characterized in that: the LED display screen (7), the audible and visual alarm (8), the photovoltaic panel (9), the single chip microcomputer (11), the laser sensor (12) and the wireless transceiver module (15) are all connected with the storage battery (10) through wires.

7. The hydraulic engineering water level intelligent monitoring equipment of claim 5, characterized in that: the LED display screen (7), the audible and visual alarm (8), the laser sensor (12) and the wireless transceiving module (15) are all connected with the single chip microcomputer (11) through wires.

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