CN110608725A

CN110608725A - Water level wireless remote measurement flow monitoring terminal

Info

Publication number: CN110608725A
Application number: CN201910725646.9A
Authority: CN
Inventors: 杨丰; 贺桂玲; 杨建军; 杨益民
Original assignee: Shaanxi Heng Rui Tt&c System Co Ltd
Current assignee: Shaanxi Heng Rui Tt&c System Co Ltd
Priority date: 2019-08-07
Filing date: 2019-08-07
Publication date: 2019-12-24

Abstract

The invention provides a water level wireless remote measuring flow monitoring terminal, which comprises: the monitoring system comprises a support, a monitoring terminal and side legs; the pillar is of a cylindrical structure, the electric cabinet and the monitoring terminal are mounted on the upper portion of the pillar through the hoop, and the electric cabinet is located above the monitoring terminal; the photovoltaic cell panel bracket is arranged above the electric cabinet in a welding mode; the wireless remote flow monitoring device has the advantages that the structural design is reasonable, the monitoring terminal is provided with electric power support in a wind power generation and solar power generation complementary mode, the influence of weather and environment on power generation equipment is reduced, the overall length of the telescopic rod can be flexibly adjusted through expansion and contraction, the wireless remote flow monitoring device is suitable for different installation places, the supporting angle of the side leg can be flexibly adjusted through sliding of the sliding seat, the installation requirements of different installation points are met, and therefore problems and defects in the existing device are effectively solved.

Description

Water level wireless remote measurement flow monitoring terminal

Technical Field

The invention relates to the technical field of water level monitoring, in particular to a water level wireless remote measurement flow monitoring terminal.

Background

The water level is the height of the water surface of a water body at a certain place from a standard base level. There are two types of standard basal planes: the first is an absolute base plane, which refers to a certain sea level specified by the country and used as an elevation zero point, and elevations of other places all use the sea level as a starting point. China specifies a yellow sea surface as an absolute surface. The other is a hypothetical base, which refers to a level base that is temporarily assumed for calculating the water level or elevation of the hydrographic station. The position below the lowest point of the riverbed is often used as the elevation starting point of the station. Often there is no national level point near the station or it is used without conditions at one time.

The water level monitoring equipment commonly used comprises a water gauge and a water level gauge. The water gauge is a traditional and effective direct observation device. And in actual measurement, the water level is obtained by adding the water gauge zero elevation into the reading on the water gauge. The water level meter is an instrument made by utilizing the principle that a floater, pressure, sound waves and the like can provide water surface fluctuation change information. The water level gauge can directly draw a water level change process line. The water level process line recorded by the water level gauge is checked by using the records of other items observed at the same time.

Ultrasonic wave fluviograph, radar fluviograph are simultaneously through installing support fixed mounting in the water top, and the current installing support that is used for installing the fluviograph needs the stock of corresponding distance of installation according to the bank apart from the distance of water, has certain limitation during the use to current installing support only relies on a pillar to install and support, and the supporting effect is relatively poor, and the installation fastness is comparatively general.

In view of this, research and improvement are carried out to solve the existing problems, and a water level wireless telemetering flow monitoring terminal is provided, aiming at achieving the purposes of solving the problems and improving the practical value through the technology.

Disclosure of Invention

The invention aims to provide a water level wireless remote measurement flow monitoring terminal, which aims to solve the problems and the defects that the ultrasonic water level meter and the radar water level meter which are provided in the background technology are fixedly arranged above a water body through an installation support, the existing installation support for installing the water level meter needs to install a long rod with a corresponding distance according to the distance from a bank to the water body, certain limitation exists during use, and the existing installation support is installed and supported only by one support column, so that the supporting effect is poor, and the installation firmness is relatively general.

In order to achieve the purpose, the invention provides a water level wireless telemetering flow monitoring terminal, which is achieved by the following specific technical means:

a wireless telemetering flow monitoring terminal for water level comprises: the device comprises a support column, an electric cabinet, a monitoring terminal, a hoop, a photovoltaic cell panel bracket, a photovoltaic cell panel, a wind driven generator, a wind driven bird dispeller, a support, a telescopic rod, a connecting plate, a locking knob, a sliding seat, side legs, a connecting rod and a base; the pillar is of a cylindrical structure, the electric cabinet and the monitoring terminal are mounted on the upper portion of the pillar through the hoop, and the electric cabinet is located above the monitoring terminal; the photovoltaic cell panel support is installed above the electric cabinet in a welding mode, and the photovoltaic cell panel is installed on the inner side of the photovoltaic cell panel support in an inserting mode and fixed through bolts; the wind driven generator is arranged above the rear side of the electric cabinet through a bolt, and the wind driven bird repeller is fixedly arranged at the top end of the wind driven generator through a bolt; the support is arranged on the outer wall of the pillar in a welding mode, and the telescopic rod is arranged on the support in a hinged mode; the connecting plate is arranged on the outer walls of the support and the telescopic rod in a welding mode; the locking knob is arranged at the extending end of the telescopic rod in a threaded screwing mode; the sliding seat is sleeved on the lower part of the strut, and the top ends of the side legs are arranged on the sliding seat in a hinged mode; the base is arranged at the bottom of the side leg in a hinged mode; one end of the connecting rod is installed at the bottom of the pillar in a hinged mode, and the other end of the connecting rod is installed on the outer wall of the side supporting leg in a hinged mode.

As a further optimization of the technical scheme, the water level wireless telemetering flow monitoring terminal is a DATA-9201 type monitoring terminal and is electrically connected with a storage battery in an electric cabinet.

As a further optimization of the technical scheme, the water level wireless remote measurement flow monitoring terminal is characterized in that a wind-solar complementary controller and a storage battery are installed in an electric cabinet, and the wind-solar complementary controller is electrically connected with a photovoltaic cell panel and a wind driven generator.

As a further optimization of the technical scheme, the water level wireless remote measurement flow monitoring terminal comprises a telescopic rod which is a multi-section rectangular tubular telescopic rod, wherein a locking knob is arranged at the extending end of each telescopic rod and penetrates through the outer part of the telescopic rod.

As a further optimization of the technical scheme, the water level wireless remote measurement flow monitoring terminal is characterized in that hinged supports are welded to the lower ends of the support and the telescopic rod, and the telescopic rod is hinged to the support through the hinged supports to form a rotary folding device.

As a further optimization of the technical scheme, the water level wireless remote measurement flow monitoring terminal is characterized in that the connecting plate is of a triangular plate-shaped structure, and the support and the telescopic rod are fixedly connected through the connecting plate and the bolts.

As a further optimization of the technical scheme, the water level wireless telemetering flow monitoring terminal is characterized in that the sliding seat is of a cylindrical structure, three hinged supports distributed in an annular array shape are arranged on the outer wall of the sliding seat, and the sliding seat is installed on a support in a sleeved mode and is provided with a sliding device.

As a further optimization of the technical scheme, the water level wireless remote measurement flow monitoring terminal provided by the invention has the advantages that the base is of a disc-shaped structure, a plurality of circular holes distributed in an annular array are formed in the base, and the base is arranged on the side support leg in a hinged manner to form a rotating device.

Due to the application of the technical scheme, compared with the prior art, the invention has the following advantages:

1. the monitoring terminal is a DATA-9201 type monitoring terminal, the monitoring terminal is electrically connected with a storage battery in an electric cabinet, a wind-solar complementary controller and the storage battery are installed in the electric cabinet, the wind-solar complementary controller is electrically connected with a photovoltaic cell panel and a wind driven generator, electric power support is provided for the monitoring terminal through a wind power generation and solar power generation complementary mode, the power generation efficiency is high, the influence of weather and environment on power generation equipment is reduced, energy is saved, the environment is protected, and energy consumption is reduced.

2. The telescopic rod is a multi-section rectangular tubular telescopic rod, the extending end of each section of telescopic rod is provided with the locking knob, the locking knobs penetrate through the outer part of the telescopic rod, the lower ends of the end parts of the support and the telescopic rod are respectively provided with the hinged support in a welding mode, the telescopic rod is hinged with the support through the hinged supports to form the rotary folding device, the whole length of the telescopic rod can be flexibly adjusted through stretching, the telescopic rod is suitable for different installation places, the limitation in use is reduced, different use requirements are met through rotary folding of the telescopic rod, the whole size is reduced, and transportation is facilitated.

3. The sliding seat is of a cylindrical structure, three hinged supports distributed in an annular array form are arranged on the outer wall of the sliding seat, the sliding seat is arranged on the support in a sleeved mode and is arranged as a sliding device, the distribution area of the side legs is increased, the supporting effect is improved, the side legs are not prone to tilting or inclining, the supporting angle of the side legs can be flexibly adjusted through sliding of the sliding seat, and the mounting requirements of different mounting points are met.

4. The base is of a disc-shaped structure, a plurality of circular holes distributed in an annular array are formed in the base, the base is arranged on the side support leg in a hinged mode and is provided with the rotating device, the contact area of the base and a supporting surface is increased, the supporting effect is improved, and the base is convenient to install.

5. The wireless remote flow monitoring device has the advantages that the structural design is reasonable, the monitoring terminal is provided with electric power support in a wind power generation and solar power generation complementary mode, the influence of weather and environment on power generation equipment is reduced, the overall length of the telescopic rod can be flexibly adjusted through expansion and contraction, the wireless remote flow monitoring device is suitable for different installation places, the supporting angle of the side leg can be flexibly adjusted through sliding of the sliding seat, the installation requirements of different installation points are met, and therefore problems and defects in the existing device are effectively solved.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a rear side view of the present invention;

FIG. 3 is an enlarged schematic view of the structure at A of the present invention;

FIG. 4 is an enlarged view of the structure at B of the present invention;

fig. 5 is an enlarged schematic view of the structure at position C of the present invention.

In the figure: pillar 1, electric cabinet 2, monitor terminal 3, staple bolt 4, photovoltaic cell board support 5, photovoltaic cell board 6, aerogenerator 7, wind-force bird dispeller 8, support 9, telescopic link 10, connecting plate 11, locking knob 12, slide 13, collateral branch leg 14, connecting rod 15, base 16.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

It is to be noted that, in the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention.

Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Meanwhile, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "connected" and "connected" should be interpreted broadly, for example, as being fixedly connected, detachably connected, or integrally connected; the connection can be mechanical connection or electrical connection; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 5, the present invention provides a specific technical implementation of a water level wireless telemetering flow monitoring terminal:

a wireless telemetering flow monitoring terminal for water level comprises: the device comprises a support 1, an electric cabinet 2, a monitoring terminal 3, a hoop 4, a photovoltaic cell panel support 5, a photovoltaic cell panel 6, a wind driven generator 7, a wind driven bird dispeller 8, a support 9, an expansion link 10, a connecting plate 11, a locking knob 12, a sliding seat 13, side legs 14, a connecting rod 15 and a base 16; the pillar 1 is of a cylindrical structure, the electric cabinet 2 and the monitoring terminal 3 are installed on the upper portion of the pillar 1 through the hoop 4, and the electric cabinet 2 is located above the monitoring terminal 3; the photovoltaic cell panel bracket 5 is installed above the electric cabinet 2 in a welding mode, and the photovoltaic cell panel 6 is installed on the inner side of the photovoltaic cell panel bracket 5 in an inserting mode and fixed through bolts; the wind driven generator 7 is arranged above the rear side of the electric cabinet 2 through bolts, and the wind driven bird repeller 8 is fixedly arranged at the top end of the wind driven generator 7 through bolts; the support 9 is installed on the outer wall of the pillar 1 in a welding mode, and the telescopic rod 10 is installed on the support 9 in a hinged mode; the connecting plate 11 is arranged on the outer walls of the support 9 and the telescopic rod 10 in a welding mode; the locking knob 12 is installed at the extending end of the telescopic rod 10 in a threaded screwing mode; the sliding base 13 is sleeved on the lower part of the pillar 1, and the top ends of the side legs 14 are arranged on the sliding base 13 in a hinged mode; the base 16 is mounted at the bottom of the side leg 14 in a hinged manner; one end of the link 15 is hingedly mounted to the bottom of the column 1 and the other end of the link 15 is hingedly mounted to the outer wall of the side leg 14.

Specifically, the monitoring terminal 3 is a DATA-9201 type monitoring terminal, and the monitoring terminal 3 is electrically connected with a storage battery in the electric cabinet 2.

Specifically, a wind-solar hybrid controller and a storage battery are installed in the electric cabinet 2, and the wind-solar hybrid controller is electrically connected with the photovoltaic cell panel 6 and the wind driven generator 7.

Specifically, the telescopic rod 10 is a multi-section rectangular tubular telescopic rod, the extending end of each section of telescopic rod is provided with a locking knob 12, and the locking knob 12 penetrates through the outside of the telescopic rod 10.

Specifically, hinged supports are welded to the lower ends of the support 9 and the telescopic rod 10, and the telescopic rod 10 is hinged to the support 9 through the hinged supports to form a rotary folding device.

Specifically, the connecting plate 11 is a triangular plate-shaped structure, and the support 9 and the telescopic rod 10 are fixedly connected through the connecting plate 11 and a bolt.

Specifically, the slide 13 is a cylindrical structure, three hinged supports distributed in an annular array are arranged on the outer wall of the slide 13, and the slide 13 is installed on the support 1 in a sleeved mode to form a sliding device.

Specifically, base 16 is discoid structure, and sets up the round hole that many places are the annular array form and distribute on the base 16 to base 16 sets up to rotary device on collateral branch leg 14 through articulated mode.

The method comprises the following specific implementation steps:

when the water level gauge is used, a proper installation mode is selected according to the installation requirements of an actual installation point, and when the water level gauge needs to be placed above a water body through the telescopic rod 10; firstly fixing a strut 1, adjusting the supporting angle of a side leg 14 by a sliding slide seat 13 according to the installation phantom of a mounting point, then clinging a base 16 to a supporting surface, fixing the strut by bolts, completing the installation of the strut 1, hoisting a telescopic rod 10, attaching the end part of the telescopic rod 10 to a support 9, then fixing the telescopic rod 10 by a bolt through a connecting plate 11, fixedly installing a water level gauge at the end part of the telescopic rod 10, extending the telescopic rod 10 to a certain length in a pulling mode, fixing the length of the telescopic rod 10 by a locking knob 12, and completing the integral installation. When the water level gauge is installed on the inner side of the observation well, the support 1 can be installed according to the steps, and the telescopic rod 10 does not need to be unfolded and extended.

In summary, the following steps: according to the water level wireless remote measurement flow monitoring terminal, the monitoring terminal is a DATA-9201 type monitoring terminal, the monitoring terminal is electrically connected with a storage battery in an electric cabinet, a wind-solar complementary controller and the storage battery are installed in the electric cabinet, the wind-solar complementary controller is electrically connected with a photovoltaic cell panel and a wind driven generator, power support is provided for the monitoring terminal through a wind power generation and solar power generation complementary mode, the power generation efficiency is high, the influence of weather and environment on power generation equipment is reduced, energy is saved, the environment is protected, and energy consumption is reduced; the telescopic rod is a multi-section rectangular tubular telescopic rod, the extending end of each section of telescopic rod is provided with a locking knob, the locking knobs penetrate through the outside of the telescopic rod, hinged supports are welded at the lower ends of the end parts of the supports and the telescopic rod, the telescopic rod is hinged and connected with the supports through the hinged supports to form a rotary folding device, the whole length of the telescopic rod can be flexibly adjusted through stretching, the telescopic rod is suitable for different installation places, the limitation in use is reduced, different use requirements are met through rotary folding of the telescopic rod, the whole size is reduced, and transportation is facilitated; the sliding seat is of a cylindrical structure, three hinged supports distributed in an annular array form are arranged on the outer wall of the sliding seat, the sliding seat is arranged on the support in a sleeved mode and is arranged as a sliding device, the distribution area of the side legs is increased, the supporting effect is improved, the side legs are not prone to tilting and inclining, the supporting angle of the side legs can be flexibly adjusted through sliding of the sliding seat, and the mounting requirements of different mounting points are met; the base is of a disc-shaped structure, a plurality of circular holes distributed in an annular array are formed in the base, and the base is arranged on the side support leg in a hinged mode and is provided with the rotating device, so that the contact area between the base and the supporting surface is increased, the supporting effect is improved, and the mounting is convenient; through the improvement to the wireless telemetering measurement flow monitor terminal of water level, it is reasonable to have a structural design, provide electric power support for monitor terminal through wind power generation and the complementary form of solar energy power generation, it receives weather, the influence of environment to reduce power generation equipment, can adjust the holistic length of telescopic link in a flexible way through flexible, be applicable to different installation places, the support angle that can adjust the collateral branch leg in a flexible way through the slip of slide, satisfy the advantage of the installation demand of different installation points, thereby effectual problem appearing and not enough in having solved current device.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A wireless telemetering flow monitoring terminal for water level comprises: the device comprises a supporting column (1), an electric cabinet (2), a monitoring terminal (3), a hoop (4), a photovoltaic cell panel support (5), a photovoltaic cell panel (6), a wind driven generator (7), a wind driven bird dispeller (8), a support (9), a telescopic rod (10), a connecting plate (11), a locking knob (12), a sliding seat (13), side supporting legs (14), a connecting rod (15) and a base (16); the method is characterized in that: the support (1) is of a cylindrical structure, the electric cabinet (2) and the monitoring terminal (3) are installed on the upper portion of the support (1) through the hoop (4), and the electric cabinet (2) is located above the monitoring terminal (3); the photovoltaic cell panel support (5) is installed above the electric cabinet (2) in a welding mode, and the photovoltaic cell panel (6) is installed on the inner side of the photovoltaic cell panel support (5) in an inserting mode and fixed through bolts; the wind driven generator (7) is arranged above the rear side of the electric cabinet (2) through bolts, and the wind driven bird repeller (8) is fixedly arranged at the top end of the wind driven generator (7) through bolts; the support (9) is installed on the outer wall of the strut (1) in a welding mode, and the telescopic rod (10) is installed on the support (9) in a hinged mode; the connecting plate (11) is arranged on the outer walls of the support (9) and the telescopic rod (10) in a welding mode; the locking knob (12) is arranged at the extending end of the telescopic rod (10) in a threaded screwing mode; the sliding seat (13) is sleeved on the lower part of the strut (1), and the top ends of the side legs (14) are arranged on the sliding seat (13) in a hinged mode; the base (16) is arranged at the bottom of the side leg (14) in a hinged mode; one end of the connecting rod (15) is installed at the bottom of the pillar (1) in a hinged mode, and the other end of the connecting rod (15) is installed on the outer wall of the side leg (14) in a hinged mode.

2. The wireless telemetering flow monitoring terminal for water level according to claim 1, characterized in that: the monitoring terminal (3) is a DATA-9201 type monitoring terminal, and the monitoring terminal (3) is electrically connected with a storage battery in the electric cabinet (2).

3. The wireless telemetering flow monitoring terminal for water level according to claim 1, characterized in that: and a wind-solar complementary controller and a storage battery are installed in the electric cabinet (2), and the wind-solar complementary controller is electrically connected with the photovoltaic cell panel (6) and the wind driven generator (7).

4. The wireless telemetering flow monitoring terminal for water level according to claim 1, characterized in that: the telescopic rod (10) is a multi-section rectangular tubular telescopic rod, the extending end of each section of telescopic rod is provided with a locking knob (12), and the locking knob (12) penetrates through the outer part of the telescopic rod (10).

5. The wireless telemetering flow monitoring terminal for water level according to claim 1, characterized in that: the lower ends of the end parts of the support (9) and the telescopic rod (10) are respectively provided with a hinged support in a welding mode, and the telescopic rod (10) is hinged and connected with the support (9) through the hinged supports to form a rotary folding device.

6. The wireless telemetering flow monitoring terminal for water level according to claim 1, characterized in that: the connecting plate (11) is of a triangular plate-shaped structure, and the support (9) is fixedly connected with the telescopic rod (10) through the connecting plate (11) and a bolt.

7. The wireless telemetering flow monitoring terminal for water level according to claim 1, characterized in that: the sliding seat (13) is of a cylindrical structure, three hinged supports distributed in an annular array shape are arranged on the outer wall of the sliding seat (13), and the sliding seat (13) is installed on the support column (1) in a sleeved mode to form a sliding device.

8. The wireless telemetering flow monitoring terminal for water level according to claim 1, characterized in that: the base (16) is of a disc-shaped structure, a plurality of circular holes distributed in an annular array shape are formed in the base (16), and the base (16) is installed on the side supporting legs (14) in a hinged mode and is provided with a rotating device.