CN211877186U

CN211877186U - Water level detector for hydraulic engineering

Info

Publication number: CN211877186U
Application number: CN202020730668.2U
Authority: CN
Inventors: 刘莹; 王国林
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-06
Filing date: 2020-05-06
Publication date: 2020-11-06
Anticipated expiration: 2030-05-06

Abstract

The utility model provides a water level detector for hydraulic engineering relates to hydraulic engineering technical field, including the bottom flotation pontoon, device support, electric motor, the photovoltaic board, top support and device main part, bottom flotation pontoon outside fixed surface is connected with device support, the nested electric motor that is provided with all around in the device support bottom outside, fixedly connected with photovoltaic board is shown at device support top, device support top fixed surface is connected with top support, the inboard fixedly connected with device main part in top support top, the device main part includes the wind speed detector, the signal lamp, storage battery, servo motor, draw the cylinder, along the exhibition steel wire, the detector that contacts to the earth. Spacing arch is and leaks hopper-shaped, and spacing protruding inboard is provided with the rubber gasket, and spacing arch and along the exhibition steel wire be the joint setting, when along the exhibition steel wire when sinking or retrieve, can contact with the rubber gasket along the exhibition steel wire to will follow the unnecessary moisture in exhibition steel wire surface and extrude, thereby make the inside drying more of device.

Description

Water level detector for hydraulic engineering

Technical Field

The utility model relates to a hydraulic engineering technical field, more specifically relates to a water level detector technical field.

Background

The hydraulic engineering is an engineering built for controlling and allocating surface water and underground water in the nature to achieve the purpose of removing harm and benefiting, also called water engineering, water is a valuable resource essential for human production and life, but the naturally existing state of the hydraulic engineering does not completely meet the requirement of human, only the hydraulic engineering is built to control water flow, prevent flood disasters and adjust and distribute water quantity to meet the requirement of people on water resources in life and production, the hydraulic engineering needs to build different types of hydraulic buildings such as dams, dikes, spillways, water gates, water inlets, channels, crossing tanks, rafts, fishways and the like to achieve the aim, the water level of the hydraulic engineering needs to be updated regularly, most detection equipment is difficult to work in the river channel flow field due to the geographical properties of the hydraulic engineering, so that the depth of underwater silt is known, and the depth detection is generally performed manually or the underwater silt is floated on the water surface for detection, causing trouble in use, etc.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that proposes in the above-mentioned background art to provide a water level detector for hydraulic engineering.

In order to achieve the above object, the utility model provides a following technical scheme: a water level detector for hydraulic engineering comprises a bottom buoy, a device support, an electric motor, a photovoltaic plate, a top support and a device main body, wherein the surface of the outer side of the bottom buoy is fixedly connected with the device support;

the device main body comprises a wind speed detector, a signal lamp, a storage battery pack, a servo motor, a traction roller, an edge-unfolding steel wire, a ground contact detector, a limiting bulge and an infrared detector, wherein the wind speed detector is rotatably connected above the device main body, the signal lamp is fixedly connected to the periphery of the tail end of the top of the device main body, the storage battery pack is fixedly connected to the middle part of the inner side of the device main body, the servo motor is fixedly connected to the right side of the middle part of the inner side of the device main body and is positioned below the storage battery pack, one side of the servo motor is movably connected with the traction roller through a rotating shaft, the edge-unfolding steel wire is wound on the surface of the outer side of the traction roller, the ground contact detector is clamped and connected to the surface of the bottom of, and the infrared detector is positioned above the limiting bulge.

Preferably, the protrusions are arranged on the outer side surface of the unfolding steel wire at intervals, and the protrusions are matched with the infrared detector.

Preferably, spacing arch is leaks hopper-shaped, and spacing protruding inboard is provided with the rubber gasket, and just spacing arch is the joint setting with along the exhibition steel wire.

Preferably, one side of the electric motor is rotatably connected with the paddle through a rotating shaft, and the electric motor is obliquely arranged.

Preferably, the infrared detector is in the shape of a ring.

Preferably, the device main part is internally and fixedly connected with a signal receiving end, the signal receiving end is in signal connection with an external control terminal, and the signal receiving end is electrically connected with the electric motor, the photovoltaic panel, the wind speed detector, the signal lamp, the storage battery, the servo motor, the ground contact detector and the infrared detector.

The utility model provides a water level detector for hydraulic engineering has following beneficial effect:

1. the water level detector for the hydraulic engineering is provided with an electric motor, one side of the electric motor is rotationally connected with paddles through a rotating shaft, the electric motor is arranged in an inclined mode, when the water level detector is used, a bottom buoy is placed on water firstly, then the bottom buoy is suspended on the water through self buoyancy, then the device converts solar energy into electric energy through a photovoltaic panel, the electric energy is stored in a storage battery pack, then an external control terminal sends a command to a signal receiving end to control the device, the movement of the device is controlled by controlling the electric motors at different positions to work in a coordinated mode, when the device reaches a specified position, a servo motor works to drive a traction roller, so that the device sinks towards the water along an unfolding steel wire and a ground contact detector, bulges are arranged at intervals along the outer side surface of the unfolding steel wire, the bulges and the infrared detector are arranged in a matched mode, the water depth can be known by scanning and, and the servo motor can stop work after the detector that contacts the earth to learn final depth of water, and when needing to change the position and detect, at first retrieve the detector that contacts the earth, then remove to other places through electric motor and paddle, make the device can carry out the quick detection to the water level through this kind of setting.

2. Secondly, still be provided with spacing arch, spacing arch is and leaks hopper-shaped, and spacing protruding inboard is provided with the rubber gasket, and spacing arch and be the joint setting along the exhibition steel wire, when sinking or when retrieving along the exhibition steel wire, can contact with the rubber gasket along the exhibition steel wire to will extrude along the unnecessary moisture in exhibition steel wire surface, thereby make the inside drying more of device.

Drawings

Fig. 1 is a schematic view of the overall front cross-sectional structure of the present invention.

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

Fig. 3 is a schematic structural diagram of the infrared detector of the present invention.

Fig. 4 is a schematic structural diagram of a in fig. 1 according to the present invention.

In FIGS. 1-4: 1-bottom buoy, 2-device support, 201-electric motor, 202-photovoltaic panel, 203-top support, 3-device body, 301-wind speed detector, 302-signal lamp, 303-storage battery, 304-servo motor, 305-traction roller, 3051-extending steel wire, 3052-ground contact detector, 3053-limiting protrusion and 3054-infrared detector.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 4, in an embodiment of the present invention, a water level detector for hydraulic engineering includes a bottom buoy 1, a device bracket 2, an electric motor 201, a photovoltaic panel 202, a top bracket 203, and a device body 3, wherein the surface of the outer side of the bottom buoy 1 is fixedly connected to the device bracket 2, the electric motor 201 is nested around the outer side of the bottom of the device bracket 2, the top of the device bracket 2 is fixedly connected to the photovoltaic panel 202, the surface of the top of the device bracket 2 is fixedly connected to the top bracket 203, and the inner side of the top bracket 203 is fixedly connected to the device body 3;

the device main body 3 comprises a wind speed detector 301, a signal lamp 302, a storage battery pack 303, a servo motor 304, a traction roller 305, an edge-unfolding steel wire 3051, a ground-contact detector 3052, a limit bulge 3053 and an infrared detector 3054, the wind speed detector 301 is rotatably connected above the device main body 3, the signal lamp 302 is fixedly connected around the top end of the device main body 3, the storage battery pack 303 is fixedly connected at the middle part of the inner side of the device main body 3, the servo motor 304 is fixedly connected at the right side of the middle part of the inner side of the device main body 3 and positioned below the storage battery pack 303, the traction roller 305 is movably connected at one side of the servo motor 304 through a rotating shaft, the edge-unfolding steel wire 3051 is wound on the outer side surface of the traction roller 305, the ground-contact detector 3052 is clamped and arranged on the bottom surface of the edge, the internal surface of the device body 3 is fixedly connected with an infrared detector 3054, and the infrared detector 3054 is positioned above the limiting protrusion 3053.

In this embodiment, spacing arch 3053 is and leaks hopper-shaped, and spacing arch 3053 inboard is provided with the rubber packing piece, and spacing arch 3053 with be the joint setting along exhibition steel wire 3051.

In this embodiment, the infrared detector 3054 has a ring shape.

In this embodiment, the signal receiving end is fixedly connected to the inside of the device main body 3, and the signal receiving end is in signal connection with the external control terminal, and the signal receiving end is in electrical connection with the electric motor 201, the photovoltaic panel 202, the wind speed detector 301, the signal lamp 302, the storage battery pack 303, the servo motor 304, the ground contact detector 3052 and the infrared detector 3054, so that the control terminal can wirelessly output and control the wind speed detector.

In this embodiment, one side of the electric motor 201 is rotatably connected with paddles through a rotating shaft, and the electric motor 201 is arranged obliquely, when in use, the bottom buoy 1 is placed on water, then the bottom buoy 1 is suspended on water through self buoyancy, then the device converts solar energy into electric energy through the photovoltaic panel 202, and stores the electric energy in the storage battery pack 303, then the external control terminal sends a command to the signal receiving end to control the device, at first, the movement of the device is controlled by controlling the electric motor 201 at different positions to work in coordination, when the device reaches a specified position, the servo motor 304 works to drive the traction roller 305, so that the water along the extension steel wire 3051 and the ground-contact detector 3052 sink underwater, and since the protrusions are arranged on the outer side surface of the extension steel wire 3051 at intervals, the protrusions are arranged in a matching manner with the infrared detector 3054, and the number of the protrusions sinking can be known by scanning and calculating the infrared detector 3054, after the ground contact detector 3052 touches the ground, the servo motor 304 can stop working, so that the final water depth can be known, and when the position needs to be changed for detection, the ground contact detector 3052 is recovered firstly, and then the electric motor 201 and the paddle move to other places, so that the device can quickly detect the water level through the arrangement.

In this embodiment, spacing arch 3053 is and leaks hopper-shaped, and spacing arch 3053 inboard is provided with the rubber packing piece, and spacing arch 3053 with along exhibition steel wire 3051 be the joint setting, when along exhibition steel wire 3051 when sinking or retrieving, can contact with the rubber packing piece along exhibition steel wire 3051 to will follow the unnecessary moisture in exhibition steel wire 3051 surface and extrude, thereby make the inside drying more of device.

When the water level detector for hydraulic engineering is used, firstly, the bottom buoy 1 is placed on water firstly during use, then the bottom buoy 1 is suspended on water through self buoyancy, then the device converts solar energy into electric energy through the photovoltaic panel 202, the electric energy is stored in the storage battery pack 303, then an external control terminal sends a command to a signal receiving terminal to control the device, firstly, the electric motors 201 at different positions are controlled to work in coordination to control the movement of the device, when the device reaches a specified position, the servo motor 304 works to drive the traction roller 305, so that the water depth along the spreading steel wire 3051 and the ground-contact detector 3052 sinks underwater, and because the protrusions are arranged at intervals along the outer side surface of the spreading steel wire 3051, the protrusions are matched with the infrared detector 3054, the water depth can be known by scanning and calculating the number of the protrusions sinking through the infrared detector 3054, when the final water depth is known by stopping the operation of the servo motor 304 after the ground contact detector 3052 contacts the ground and the position needs to be changed for detection, the ground contact detector 3052 is first recovered and then moved to another place by the electric motor 201 and the blade.

The above is only the preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, without departing from the concept of the present invention, several modifications and improvements can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent.

Claims

1. The utility model provides a water level detector for hydraulic engineering, includes bottom flotation pontoon (1), device support (2), electric motor (201), photovoltaic board (202), top support (203) and device main part (3), bottom flotation pontoon (1) outside fixed surface is connected with device support (2), the nested electric motor (201) that is provided with all around in the device support (2) bottom outside, its characterized in that: the photovoltaic panel (202) is fixedly connected to the top surface of the device bracket (2), the top bracket (203) is fixedly connected to the top surface of the device bracket (2), and the device main body (3) is fixedly connected to the inner side of the top bracket (203);

the device main body (3) comprises a wind speed detector (301), a signal lamp (302), a storage battery pack (303), a servo motor (304), a traction roller (305), an edge-unfolding steel wire (3051), a ground contact detector (3052), a limiting protrusion (3053) and an infrared detector (3054), wherein the wind speed detector (301) is rotatably connected above the device main body (3), the signal lamp (302) is fixedly connected around the tail end of the top of the device main body (3), the storage battery pack (303) is fixedly connected in the middle of the inner side of the device main body (3), the servo motor (304) is fixedly connected on the right side of the middle of the inner side of the device main body (3), the servo motor (304) is positioned below the storage battery pack (303), the traction roller (305) is movably connected on one side of the servo motor (304) through a rotating shaft, the edge-, be provided with detector (3052) to touch ground along exhibition steel wire (3051) bottom surface joint, device main part (3) is inside all around fixedly connected with spacing arch (3053), and is connected with detector (3052) to touch ground along exhibition steel wire (3051), device main part (3) inside fixed surface is connected with infrared detector (3054), and infrared detector (3054) are located spacing arch (3053) top.

2. The water level detector for hydraulic engineering according to claim 1, characterized in that: the outer side surface of the steel wire (3051) is provided with bulges at intervals, and the bulges are matched with the infrared detector (3054).

3. The water level detector for hydraulic engineering according to claim 1, characterized in that: spacing arch (3053) are and leak hopper-shaped, and spacing arch (3053) inboard is provided with the rubber packing piece, and spacing arch (3053) is the joint setting with along exhibition steel wire (3051).

4. The water level detector for hydraulic engineering according to claim 1, characterized in that: electric motor (201) one side is rotated through the pivot and is connected with the paddle, and electric motor (201) is the slope setting.

5. The water level detector for hydraulic engineering according to claim 1, characterized in that: the infrared detector (3054) is ring-shaped.

6. The water level detector for hydraulic engineering according to claim 1, characterized in that: the device main part (3) is internally and fixedly connected with a signal receiving end, and the signal receiving end is in signal connection with an external control terminal.