CN212256561U - Wind profile radar data acquisition equipment - Google Patents

Abstract

The utility model discloses a wind profile radar data acquisition device, which comprises a receiving end and a transmitting end, the receiving end is wirelessly connected with the transmitting end and comprises a first host computer control module and a first slave computer module, the first host control module is connected with the first slave module, the first slave module comprises a first inner chip, a storage module, a first ARM processor, a first signal analyzer, a first photomultiplier, a first signal comparator and a first bus plug-in board, the first inner chip, the storage module, the first ARM processor, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively arranged on the first bus plug-in board, the first inner chip, the storage module, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively connected with the first ARM processor through a first bus plug-in board. The utility model discloses simple structure, easy to use, the utility model discloses but the wide application is in the collection equipment field.

Description

Wind profile radar data acquisition equipment

Technical Field

The utility model relates to an acquisition equipment field especially relates to a wind profile radar data acquisition equipment.

Background

The wind profile radar data acquisition equipment is vertical atmosphere detection equipment which can automatically acquire wind direction and wind speed data of layers with different heights at high altitude and return the data, the change rule of the wind speed in the vertical direction has very important significance for wind energy assessment of a wind power plant, most of the existing wind profile radar data acquisition equipment are remote control equipment, workers are required to control and acquire and return the data, the structure is too complex, and the wind profile radar data acquisition equipment is not easy to use.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model aims at providing a wind profile radar data acquisition equipment, simple structure and easily installation.

The utility model adopts the technical proposal that: the receiving end is wirelessly connected with the sending end and comprises a first host control module and a first slave module, the first host control module is connected with the first slave module, the first slave module comprises a first inner chip, a storage module, a first ARM processor, a first signal analyzer, a first photomultiplier, a first signal comparator and a first bus plug-in board, the first inner chip, the storage module, the first ARM processor, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively installed on the first bus plug-in board, and the first inner chip, the storage module, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively connected with the first ARM processor through the first bus plug-in board.

Further, the sending end comprises a second host control module and a second slave module, the second host control module is connected with the second slave module, the second slave module comprises a second inner chip, a second ARM processor, a second signal analyzer, a second photomultiplier, a second signal comparator and a second bus plug-in board, the second inner chip, the second ARM processor, the second signal analyzer, the second photomultiplier and the second signal comparator are respectively installed on the second bus plug-in board, and the second inner chip, the second signal analyzer, the second photomultiplier and the second signal comparator are respectively connected with the second ARM processor through the second bus plug-in board.

Further, the first host control module, the first slave module, the second host control module and the second slave control module are respectively provided with a USB3.0 interface, the first host control module and the first slave module are connected through the USB3.0 interface, and the second host control module and the second slave module are connected through the USB3.0 interface.

Further, the receiving end still includes first power module, first power module is connected with first host computer control module and first bus plug-in board respectively, the sending end still includes second power module, second power module is connected with second host computer control module and second bus plug-in board respectively.

Further, the receiving end also comprises a network module, and the network module is connected with the first host control module.

Furthermore, a peripheral interface is further arranged on the first bus plug-in board, and the peripheral interface is connected with the first ARM processor through the first bus plug-in board.

Further, still be equipped with first heat dissipation module on the first slave module, first heat dissipation module installs on first bus plug-in board, first heat dissipation module is connected with first ARM treater through first bus plug-in board, still be equipped with second heat dissipation module on the second slave module, second heat dissipation module installs on second bus plug-in board, second heat dissipation module passes through second bus plug-in board and is connected with the second ARM treater.

The utility model has the advantages that: the receiving terminal is handled according to the rule of predetermineeing of instruction and is gathered data control to first signal analyzer, first photomultiplier, first signal comparator by first ARM after receiving the instruction to control the data that the sending terminal feedback was gathered, the utility model discloses simple structure, easy to use.

Drawings

Fig. 1 is the utility model discloses a wind profile radar data acquisition equipment's block diagram.

Detailed Description

The utility model provides a wind profile radar data acquisition device, which comprises a receiving end and a sending end, wherein the receiving end is wirelessly connected with the sending end, the receiving end comprises a first host control module and a first slave module, the first host control module is connected with the first slave module, the first slave module comprises a first inner chip, a storage module, a first ARM processor, a first signal analyzer, a first photomultiplier, a first signal comparator and a first bus plug-in board, the first inner chip, the storage module, the first ARM processor, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively arranged on the first bus plug-in board, the first inner chip, the storage module, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively connected with the first ARM processor through a first bus plug-in board.

Specifically, the first signal analyzer adopts a signal analyzer with a gating function and is used for inputting a signal decomposer, the first bus plug-in board is used for installing each module and parts, the first photomultiplier is used for converting collected weak optical signals into electric signals and processing the electric signals through a subsequent circuit, the signal comparator is used for comparing input signals and outputting the signals according to preset rules so as to control the circuit, the first inner core chip stores interface chip programs and is used for controlling a transmission interface, the first ARM processor is used as a controller and comprises a collection program, and the storage module can adopt a 64GB SD flash memory card and can be used for storing configuration information of the program, such as collection frequency and the like.

Further as a preferred embodiment of the system, the sending end includes a second master control module and a second slave module, the second master control module is connected to the second slave module, the second slave module includes a second internal chip, a second ARM processor, a second signal analyzer, a second photomultiplier, a second signal comparator and a second bus card, the second internal chip, the second ARM processor, the second signal analyzer, the second photomultiplier and the second signal comparator are respectively installed on the second bus card, and the second internal chip, the second signal analyzer, the second photomultiplier and the second signal comparator are respectively connected to the second ARM processor through the second bus card.

Specifically, the second internal chip, the second ARM processor, the second signal analyzer, the second photomultiplier, the second signal comparator and the second bus card are consistent with the first internal chip, the first signal analyzer, the first photomultiplier, the first signal comparator and the first bus card in function, the first signal analyzer and the second signal analyzer adopt a signal analyzer of the JD748B model, the first photomultiplier and the second photomultiplier adopt a photomultiplier of the H7422 model, and the first signal comparator and the second signal comparator adopt a signal comparator of the DSC-18 model.

As a preferred embodiment of the present system, the first host control module, the first slave control module, the second host control module, and the second slave control module are respectively provided with a USB3.0 interface, the first host control module and the first slave control module are connected by a USB3.0 interface, and the second host control module and the second slave control module are connected by a USB3.0 interface.

As a further preferred embodiment of the present system, the receiving end further includes a first power supply module, the first power supply module is connected to the first host control module and the first bus plug-in board, the transmitting end further includes a second power supply module, and the second power supply module is connected to the second host control module and the second bus plug-in board, respectively.

Specifically, the first power supply module and the second power supply module may be rechargeable batteries, or may adopt a solar power supply system to provide electric energy for the radar collection device.

Further as a preferred implementation of the system, the receiving end further includes a network module, and the network module is connected to the first host control module.

Specifically, the network module is used for receiving an external remote control instruction by a receiving end.

Further, as a preferred embodiment of the system, the first bus plug-in board is further provided with a peripheral interface, and the peripheral interface is connected with the first ARM processor through the first bus plug-in board.

Specifically, the peripheral interface may include an interface for connecting to other storage devices or sensors, and may also be a video and audio information interface, etc. to implement further functions.

Further, as a preferred embodiment of the present system, a first heat dissipation module is further disposed on the first slave module, the first heat dissipation module is mounted on the first bus plug-in board, the first heat dissipation module is connected to the first ARM processor through the first bus plug-in board, a second heat dissipation module is further disposed on the second slave module, the second heat dissipation module is mounted on the second bus plug-in board, and the second heat dissipation module is connected to the second ARM processor through the second bus plug-in board.

Specifically, the heat dissipation module may be a plurality of small fans, and receive the electric energy from the power supply module to dissipate heat of the receiving end and the transmitting end of the entire device.

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

The utility model discloses a concrete embodiment as follows:

referring to fig. 1, a wind profile radar data acquisition device comprises a receiving end and a sending end, wherein the receiving end is in wireless connection with the sending end, the receiving end comprises a first host control module, a first power supply module, a network module and a first slave module, the first host control module is connected with the first slave module, the first slave module comprises a first inner chip, a storage module, a peripheral interface, a first heat dissipation module, a first ARM processor, a first signal analyzer, a first photomultiplier, a first signal comparator and a first bus plug-in board, the network module is connected with the first host control module, the first power supply module is respectively connected with the first host control module and the first bus plug-in board, and the first inner chip, the storage module, the peripheral interface, the first heat dissipation module, the first ARM processor, the first signal analyzer, The first photomultiplier and the first signal comparator are respectively installed on a first bus plug-in board, the first inner chip, the storage module, the peripheral interface, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively connected with the first ARM processor through the first bus plug-in board, the sending end comprises a second host control module, a second power supply module and a second slave module, the second host control module is connected with the second slave module, the second slave module comprises a second inner chip, a second heat dissipation module, a second ARM processor, a second signal analyzer, a second photomultiplier, a second signal comparator and a second bus plug-in board, the second power supply module is respectively connected with the second host control module and the second bus plug-in board, and the second inner chip, the second heat dissipation module, the second ARM processor, the second heat dissipation module, And the second inner chip, the second signal analyzer, the second photomultiplier and the second signal comparator are respectively connected with the second ARM processor through the second bus plug-in board.

While the preferred embodiments of the present invention have been described, the present invention is not limited to the embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention, and such equivalent modifications or substitutions are intended to be included within the scope of the present invention as defined by the appended claims.

Claims (7)

1. A wind profile radar data acquisition device, comprising: the receiving end is wirelessly connected with the sending end and comprises a first host control module and a first slave module, the first host control module is connected with the first slave module, the first slave module comprises a first inner chip, a storage module, a first ARM processor, a first signal analyzer, a first photomultiplier, a first signal comparator and a first bus plug-in board, the first inner chip, the storage module, the first ARM processor, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively installed on the first bus plug-in board, and the first inner chip, the storage module, the first signal analyzer, the first photomultiplier and the first signal comparator are respectively connected with the first ARM processor through the first bus plug-in board.

2. The wind profile radar data acquisition device according to claim 1, wherein the transmitting end comprises a second master control module and a second slave module, the second master control module is connected with the second slave module, the second slave module comprises a second internal chip, a second ARM processor, a second signal analyzer, a second photomultiplier, a second signal comparator and a second bus card, the second internal chip, the second ARM processor, the second signal analyzer, the second photomultiplier and the second signal comparator are respectively mounted on the second bus card, and the second internal chip, the second signal analyzer, the second photomultiplier and the second signal comparator are respectively connected with the second ARM processor through the second bus card.

3. The wind profile radar data collection device of claim 2, wherein the first master control module, the first slave control module, the second master control module and the second slave control module are respectively provided with a USB3.0 interface, the first master control module and the first slave module are connected through the USB3.0 interface, and the second master control module and the second slave module are connected through the USB3.0 interface.

4. The wind profile radar data collection device of claim 3, wherein the receiving end further comprises a first power supply module, the first power supply module is connected with the first host control module and the first bus plug-in board respectively, the transmitting end further comprises a second power supply module, and the second power supply module is connected with the second host control module and the second bus plug-in board respectively.

5. The wind profile radar data collection device of claim 4, wherein said receiving end further comprises a network module, said network module being connected to said first host control module.

6. The wind profile radar data collection device of claim 5, wherein a peripheral interface is further disposed on the first bus board, and the peripheral interface is connected to the first ARM processor through the first bus board.

7. The wind profile radar data collection device of claim 6, wherein said first slave module further comprises a first heat dissipation module, said first heat dissipation module is mounted on a first bus card, said first heat dissipation module is connected to said first ARM processor via said first bus card, said second slave module further comprises a second heat dissipation module, said second heat dissipation module is mounted on a second bus card, said second heat dissipation module is connected to said second ARM processor via said second bus card.

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