CN209821371U - Mobile single-probe radar wave flow measuring device - Google Patents

Abstract

The utility model discloses a portable single probe radar wave current surveying device relates to radar wave current surveying device field. The device comprises a flow measuring station, a support frame and a radar wave flow measuring device, wherein a partition wall is vertically arranged in the flow measuring station, pulleys A are arranged at the opposite positions of one side of the partition wall facing the outside and the support frame, and a steel cable is sleeved on the two opposite pulleys A; a contact net is also erected between the supporting frame and the current measuring station and is positioned above the steel cable; the radar wave flow measuring device comprises a pulley B arranged at the top of the device, and is arranged on the steel cable through the pulley B; the radar wave current measuring device is also provided with an electric pantograph which can be in contact with a contact network for supplying power. The utility model discloses be provided with two kinds of independent operating system that can complement each other again separately, under the condition that an operating system broke down, the radar wave current surveying device can be automatic through the operation of another kind of operating system.

Description

Mobile single-probe radar wave flow measuring device

Technical Field

The utility model relates to a radar wave current surveying device field, in particular to portable single probe radar wave current surveying device.

Background

With the rapid development of economic society in China, river hydrological prediction especially has very important function of testing main hydrological factors such as flow, water level and the like. The medium and small river hydrological stations are wide in distribution, wide in region and multiple in stations, and particularly due to the characteristics of high confluence speed of mountain stream rivers, steep rise and fall of flood and the like, the flow rate test is extremely difficult. The radar wave flow real-time on-line monitoring system is a new method and a new way for quickly and accurately measuring the flow velocity and the flow by fully utilizing the modern photoelectric and automatic control technology without directly contacting and disturbing the water flow structure, obtains better social and economic benefits and has good popularization and application values.

The traditional radar wave current measuring device generally adopts an operating system, and when power supply is interrupted due to power supply failure, the radar wave current measuring device stops working to guide workers to finish rush repair of the operating system. In addition, the traditional radar wave flow station has single function.

Disclosure of Invention

The utility model aims to provide a: the mobile single-probe radar wave flow measuring device is provided with two independent running systems which can be mutually supplemented, and under the condition that one running system is in failure, the radar wave flow measuring device can automatically run through the other running system. The utility model discloses a solar cell panel supplies power to be equipped with meteorological monitoring equipment such as hyetometer, anemometry appearance, utilize the excellent geographical position of survey station, carry out meteorological monitoring simultaneously.

The utility model adopts the technical scheme as follows:

the mobile single-probe radar wave flow measuring device comprises a flow measuring station, a support frame and a radar wave flow measuring device, wherein a partition wall is vertically arranged in the flow measuring station, pulleys A are arranged at the opposite positions of one side of the partition wall facing the outside and the support frame, and a steel cable is sleeved on the two opposite pulleys A; a contact net is also erected between the supporting frame and the current measuring station and is positioned above the steel cable; the radar wave flow measuring device comprises a pulley B arranged at the top of the device, and is arranged on the steel cable through the pulley B; the radar wave current measuring device is also provided with an electric pantograph which can be in contact with a contact network for supplying power.

The operation process of the radar wave flow measurement system comprises the following steps: firstly, field data acquisition: collecting required data including water level information, flow velocity information, starting point distance information and the like through a radar wave flow measuring device; the field flow calculation needs to input large section data in advance. And secondly, transmitting the field data to a data center server end through a wireless public network and the Internet. And thirdly, remote management software is arranged at the data center, field data is received within 7-24 hours, a user can inquire the hydrological characteristic value of each measured time on the network, display the flow velocity distribution diagram, confirm whether the measured flow data is normal or not, adjust the test layout scheme, adjust the flow velocity averaging algorithm, set the large section, the measured flow vertical line group and the like through the remote management software, and can remotely call and measure to obtain real-time flow data.

The first operation system of the utility model is that the storage battery collects and stores electric energy through the solar cell panel and provides driving force for the pulley A, so that the pulley A rotates to drive the steel cable to transmit; under the operation system, the clamping device on the pulley B on the radar wave current measuring device can fix the body of the radar wave current measuring device on the steel cable through the pulley B, so that the radar wave current measuring device and the steel cable do not generate relative displacement, and the movement of the radar wave current measuring device is completely realized by the matching of the steel cable and the pulley A.

The utility model discloses a second operation system does, and the battery passes through solar cell panel and collects the storage electric energy to for the contact net provides the electric energy, the electric bow that radar wave current surveying device carried through self, and obtain the electric energy with the contact net contact of electric bow, thereby after drive arrangement obtained the electric energy, drive radar wave current surveying device automatic operation on the cable wire.

Furthermore, a solar cell panel, a rain gauge, a wind speed measuring instrument and the like are arranged at the top of the flow measuring station.

Furthermore, a storage battery is further arranged in the space on the inner side of the partition wall of the flow measuring station, an input end and an output end are arranged on the storage battery, the solar cell panel is connected with the input end through a line, and the rain gauge, the wind speed measuring instrument, the pulley A, the contact net and the like are connected with the output end through lines.

The utility model discloses gather required data through radar wave current surveying device, when including water level information, velocity of flow information and starting point apart from information etc, can also carry out the measurement of weather through the weather measuring device of peripheral hardware such as the pluviometer and the wind speed measuring instrument that set up on the test station. Since the test station is usually located on the shore, the test station is spacious around the shore, and is also the preferred location for climate measurement.

Furthermore, clamping devices are further arranged on two end faces of the pulley B of the radar wave flow measuring device.

Furthermore, a driving device connected with the pulley B is arranged in the radar wave current measuring device.

Furthermore, the pantograph comprises a horizontal support, a vertical support and a contact plate, one end of the horizontal support is arranged on the side face of the radar wave current measuring device, the other end of the horizontal support is connected with one end of the vertical support, and the other end of the vertical support is connected with the contact plate.

Furthermore, a pivot is arranged on the vertical support, and the vertical support can be bent at the pivot.

Furthermore, the flow measuring station is supported and fixed on the ground through the upright post, and the inlet of the flow measuring station is connected with the ground through the stairs.

To sum up, owing to adopted above-mentioned technical scheme, the beneficial effects of the utility model are that:

1. the utility model discloses portable single probe radar wave current surveying device is provided with two kinds of independent operating system that again can supply each other separately, and under the condition that an operating system broke down, radar wave current surveying device can be automatic through the operation of another kind of operating system.

2. The utility model discloses portable single probe radar wave current surveying device supplies power through solar cell panel to be equipped with meteorological monitoring equipment such as rain gauge, anemometry appearance, utilize the excellent geographical position of current surveying station, carry out meteorological monitoring simultaneously.

Drawings

The invention will now be described, by way of example, with reference to the accompanying drawings, in which:

fig. 1 is a schematic view of the present invention;

fig. 2 is a schematic view of the present invention;

in the figure, 1-flow measuring station, 11-partition wall, 12-pulley A, 13-storage battery, 131-output end, 132-input end, 14-rain gauge, 15-wind speed measuring instrument, 16-solar panel, 17-upright post, 18-stair, 2-support frame, 3-radar wave flow measuring device, 31-pulley B, 32-pantograph, 321-contact plate, 33-driving device, 4-steel cable and 5-contact net.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

It is noted that relational terms such as "first" and "second," and the like, may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The present invention will be described in detail with reference to fig. 1 and 2.

Example 1

A mobile single-probe radar wave flow measuring device, as shown in fig. 1 and 2, comprising a flow measuring station 1, a support frame 2 and a radar wave flow measuring device 3, wherein a partition wall 11 is vertically arranged inside the flow measuring station 1, pulleys a12 are respectively arranged at the opposite positions of the outward side of the partition wall 11 and the support frame 2, and a steel cable 4 is sleeved on the two opposite pulleys a 12; a contact net 5 is also erected between the support frame 2 and the current measuring station 1, and the contact net 5 is positioned above the steel cable 4; the radar wave flow measuring device 3 comprises a pulley B31 arranged at the top of the device, and the radar wave flow measuring device 3 is arranged on the steel cable 4 through a pulley B31; the radar wave current measuring device 3 is also provided with a pantograph 32, and the pantograph 32 can be in contact with the contact net 5 for supplying power.

Example 2

The present embodiment is different from embodiment 1 in that:

the top of the flow measuring station 1 is provided with a solar cell panel 16, a rain gauge 14, an air speed measuring instrument 15 and the like.

The inside space of the partition wall 11 of the current measuring station 1 is also provided with a storage battery 13, the storage battery 13 is provided with an input end 132 and an output end 131, the solar panel 16 is connected with the input end 132 through a line, and the rain gauge 14, the wind speed measuring instrument 15, the pulley A12, the contact net 5 and the like are connected with the output end 131 through lines.

Example 3

The present embodiment is different from embodiment 1 in that:

clamping devices are further arranged on two end faces of the pulley B31 of the radar wave flow measuring device 3.

The radar wave flow measuring device 3 is internally provided with a driving device 33 connected with a pulley B31.

The pantograph 32 includes a horizontal bracket, a vertical bracket and a contact plate 321, one end of the horizontal bracket is disposed on the side of the radar wave current measuring device 3, the other end of the horizontal bracket is connected with one end of the vertical bracket, and the other end of the vertical bracket is connected with the contact plate 321.

The vertical support is provided with a pivot, and the vertical support can be bent at the pivot.

Example 4

The operation process of the radar wave flow measurement system comprises the following steps: firstly, field data acquisition: collecting required data including water level information, flow velocity information, starting point distance information and the like through a radar wave flow measuring device 3; the field flow calculation needs to input large section data in advance. And secondly, transmitting the field data to a data center server end through a wireless public network and the Internet. And thirdly, remote management software is arranged at the data center, field data is received within 7-24 hours, a user can inquire the hydrological characteristic value of each measured time on the network, display the flow velocity distribution diagram, confirm whether the measured flow data is normal or not, adjust the test layout scheme, adjust the flow velocity averaging algorithm, set the large section, the measured flow vertical line group and the like through the remote management software, and can remotely call and measure to obtain real-time flow data.

Example 5

The first operation system of the utility model is that the storage battery 13 collects and stores electric energy through the solar panel 16 and provides driving force for the pulley A12, so that the pulley A12 rotates to drive the steel cable 4 to transmit; under the operation system, the clamping device on the pulley B31 on the radar wave current measuring device 3 can fix the body of the radar wave current measuring device 3 on the steel cable 4 through the pulley B31, so that the radar wave current measuring device 3 does not generate relative displacement with the steel cable 4, and the movement of the radar wave current measuring device 3 is completely realized by the matching of the steel cable 4 and the pulley A12.

The utility model discloses a second operation system does, and battery 13 passes through solar cell panel 16 and collects the storage electric energy to for contact net 5 provides the electric energy, radar wave current surveying device 3 is through the pantograph 32 that self carried, and comes the electric energy with pantograph 32 and contact net 5 contact, thereby after drive arrangement obtained the electric energy, drive radar wave current surveying device 3 automatic operation on cable wire 4.

The above description is only for the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art can be covered within the protection scope of the present invention without the changes or substitutions conceived by the inventive work within the technical scope disclosed by the present invention. Therefore, the protection scope of the present invention should be subject to the protection scope defined by the claims.

Claims (8)

1. Portable single probe radar wave current surveying device, its characterized in that: the device comprises a flow measuring station (1), a supporting frame (2) and a radar wave flow measuring device (3), wherein a partition wall (11) is vertically arranged in the flow measuring station (1), pulleys A (12) are arranged at opposite positions on one side, facing the outside, of the partition wall (11) and the supporting frame (2), and a steel cable (4) is sleeved on the two opposite pulleys A (12); a contact net (5) is further erected between the supporting frame (2) and the flow measuring station (1), and the contact net (5) is positioned above the steel cable (4); the radar wave flow measuring device (3) comprises a pulley B (31) arranged at the top of the device, and the radar wave flow measuring device (3) is arranged on the steel cable (4) through the pulley B (31); the radar wave current measuring device (3) is also provided with an electric bow (32), and the electric bow (32) can be in contact with the contact net (5) for supplying power.

2. The mobile single probe radar wave flow gauging device according to claim 1, wherein: the top of the flow measuring station (1) is provided with a solar cell panel (16), a rain gauge (14), an air speed measuring instrument (15) and the like.

3. The mobile single probe radar wave flow gauging device according to claim 2, wherein: still be provided with battery (13) in the inboard space of partition wall (11) of survey flow station (1), be equipped with input (132) and output (131) on battery (13), solar cell panel (16) meet with input (132) through the circuit, rain gauge (14), wind speed measuring instrument (15) and pulley A (12), contact net (5) etc. all are connected with output (131) through the circuit.

4. The mobile single probe radar wave flow gauging device according to claim 1, wherein: clamping devices are further arranged on two end faces of a pulley B (31) of the radar wave flow measuring device (3).

5. The mobile single probe radar wave flow gauging device according to claim 1, wherein: and a driving device (33) connected with the pulley B (31) is arranged in the radar wave flow measuring device (3).

6. The mobile single probe radar wave flow gauging device according to claim 1, wherein: the pantograph (32) comprises a horizontal support, a vertical support and a contact plate (321), one end of the horizontal support is arranged on the side face of the radar wave current measuring device (3), the other end of the horizontal support is connected with one end of the vertical support, and the other end of the vertical support is connected with the contact plate (321).

7. The mobile single probe radar wave flow gauging device according to claim 6, wherein: the vertical support is provided with a pivot, and the vertical support can be bent at the pivot.

8. The mobile single probe radar wave flow gauging device according to claim 1, wherein: the flow measuring station (1) is supported and fixed on the ground through an upright post (17), and the inlet of the flow measuring station (1) is connected with the ground through a stair (18).