CN214540452U - Engineering investigation field acquisition system of continuous acquisition technology - Google Patents

Abstract

The utility model discloses an engineering investigation field acquisition system of continuous acquisition technology, which comprises a computation cluster and a server, wherein the computation cluster comprises an acquisition circuit, a continuous circuit, a microprocessor chip and a power circuit, and the acquisition circuit is connected with the microprocessor chip and is used for receiving field acquisition data; the continuous circuit is connected with the microprocessor chip and is used for sending a signal for acquiring the residual data of the same drilling hole or a signal for acquiring the data of another drilling hole to the microprocessor chip; the power circuit is connected with the acquisition circuit, the continuous circuit and the microprocessor chip and is used for providing power for each component; the server comprises a storage circuit, the storage circuit is connected with the acquisition circuit and used for storing field acquisition data generated by the acquisition circuit. The utility model discloses can carry out the continuous collection of surplus data in same drilling according to the actual work demand, also can carry out the continuous collection between a plurality of drilling, make things convenient for the later stage inquiry management of data.

Description

Engineering investigation field acquisition system of continuous acquisition technology

Technical Field

The utility model relates to an engineering investigation technical field, concretely relates to engineering investigation field collection system of continuous acquisition technique.

Background

The existing exploration field acquisition system needs related workers to arrange related hardware equipment and software equipment, and then manually stores and documents acquired field data, so that a large amount of data is irregularly sent and stored, the existing exploration field acquisition system is not beneficial to management and query of a large amount of data in the later period, and the performance requirement on a data transmission system is very high when the existing exploration field acquisition system is used.

SUMMERY OF THE UTILITY MODEL

In order to solve the shortcoming that exists among the above-mentioned prior art, the utility model provides an engineering investigation field collection system of continuous collection technique, concrete scheme is as follows:

the system comprises a computing cluster and a server, wherein the computing cluster comprises an acquisition circuit, a continuous circuit, a microprocessor chip and a power circuit, and the acquisition circuit is connected with the microprocessor chip and used for receiving field collected data; the continuous circuit is connected with the microprocessor chip and is used for sending a signal for acquiring the residual data of the same drilling hole or a signal for acquiring the data of another drilling hole to the microprocessor chip; the power circuit is connected with the acquisition circuit, the continuous circuit and the microprocessor chip and is used for providing power for each component;

the server comprises a storage circuit, and the storage circuit is connected with the acquisition circuit and used for storing the field acquisition data generated by the acquisition circuit.

Furthermore, the computing cluster further comprises a display device connected with the acquisition circuit and used for displaying the acquired field acquisition data.

Furthermore, the micro-processing chip comprises an identification unit, a statistical unit and a rechecking unit; the identification unit is connected with the acquisition circuit and is used for identifying the drill hole to which the field acquisition data belongs; the statistical unit is connected with the identification unit and is used for counting the items of field collected data belonging to the same drill hole in the identification unit; the rechecking unit is connected with the statistical unit and used for checking whether the field collected data in the statistical unit belong to the same drilling hole.

Further, the computing cluster and the server are connected through a wireless network system with a security device.

Further, the power supply circuit includes a rechargeable battery and a charging device connected to the rechargeable battery.

The beneficial effects of the utility model reside in that:

the utility model provides a pair of engineering investigation field collection system of continuous collection technique can carry out the continuous collection of surplus data in same drilling according to the actual work demand, also can carry out the continuous collection between a plurality of drilling, makes things convenient for the later stage inquiry management of data.

Drawings

Figure 1 is a schematic connection diagram of the present invention,

fig. 2 is a schematic connection diagram of other embodiments of the present invention.

Figure number and name: 1. the system comprises a computing cluster, 11, an acquisition circuit, 12, a continuous circuit, 13, a microprocessing chip, 131, an identification unit, 132, a statistical unit, 133, a rechecking unit, 14, a power circuit, 15, display equipment, 2, a server, 21, a storage circuit, 3, a wireless network system, 31 and safety equipment.

Detailed Description

In order to explain the technical content, structural features, achieved objects and functions of the present invention in detail, the following embodiments are described in detail with reference to the accompanying drawings.

Referring to fig. 1, the utility model discloses an engineering investigation field acquisition system of continuous acquisition technique, including calculating cluster 1 and server 2, calculating cluster 1 includes acquisition circuit 11, continuous circuit 12, microprocessor chip 13 and power supply circuit 14, and acquisition circuit 11 is connected with microprocessor chip 13 for receive field acquisition data; the continuous circuit 12 is connected with the microprocessor chip 13 and is used for sending a signal for acquiring the residual data of the same drilling hole or a signal for acquiring the data of another drilling hole to the microprocessor chip 13; the power circuit 14 is connected with the acquisition circuit 11, the continuous circuit 12 and the microprocessor chip 13 and is used for providing power for each component;

the server 2 comprises a storage circuit 21, and the storage circuit 21 is connected with the acquisition circuit 11 and used for storing the field acquisition data generated by the acquisition circuit 11.

The computing cluster 1 further includes a display device 15 connected to the acquisition circuit 11, and configured to display the acquired field acquisition data.

The microprocessor chip 13 includes an identification unit 131, a statistical unit 132, and a review unit 133; the identification unit 131 is connected with the acquisition circuit 11 and is used for identifying the drill hole to which the field acquisition data belongs; the statistical unit 132 is connected with the identification unit 131 and is used for counting the items of field collected data belonging to the same drilling hole in the identification unit 131; the review unit 133 is connected to the statistical unit 132, and is configured to review whether the field collected data in the statistical unit 132 belongs to the same borehole.

The working principle of the application is as follows:

the acquisition circuit receives field data (the field data items of each drill hole are recorded in the system, such as the most common field stratigraphic description, standard penetration experiment, geotechnical experiment data, water level observation data and the like), and the micro-processing chip collects the field acquisition data of the residual items of the drill holes through the acquisition circuit after statistics according to the identified drill holes (each drill hole has a unique number in the system); when the data acquisition of all the projects of one drilling hole is finished, the micro-processing chip collects field acquisition data of the next drilling hole through the acquisition circuit. The field acquisition may not be specific to a specific borehole, but a certain range may be selected in the system for acquisition, more than one borehole may be in the range, and the micro-processing chip may optionally collect field acquisition data in one borehole (except for the borehole for which all project data acquisition is completed) in the selected range.

As shown in fig. 2, the computing cluster 1 is connected to the server 2 through the wireless network system 3 with the security device 31, so that the field collected data can be safely and remotely transmitted to the storage circuit of the server, and the later query and management of the data are facilitated.

The power circuit 14 includes a rechargeable battery and a charging device (e.g., a solar charging module or a wireless charging module, not shown in the drawings) connected to the rechargeable battery, so as to prolong the working time of the system in the field survey operation and improve the applicability thereof.

In summary, the preferred embodiments of the present invention are only examples, and the scope of the present invention is not limited thereto, and all equivalent changes and modifications made in accordance with the scope of the present invention and the contents of the specification are within the scope covered by the present invention.

Claims (5)

1. An engineering investigation field acquisition system of continuous acquisition technology, comprising a computing cluster (1) and a server (2), characterized in that: the computing cluster (1) comprises an acquisition circuit (11), a continuous circuit (12), a microprocessor chip (13) and a power circuit (14), wherein the acquisition circuit (11) is connected with the microprocessor chip (13) and is used for receiving field collected data; the continuous circuit (12) is connected with the microprocessor chip (13) and is used for sending a signal for acquiring the residual data of the same drilling hole or a signal for acquiring the data of another drilling hole to the microprocessor chip (13); the power circuit (14) is connected with the acquisition circuit (11), the continuous circuit (12) and the microprocessor chip (13) and is used for providing power for each component;

the server (2) comprises a storage circuit (21), wherein the storage circuit (21) is connected with the acquisition circuit (11) and is used for storing the field acquisition data generated by the acquisition circuit (11).

2. The continuous acquisition technical field acquisition system for engineering surveys of claim 1, wherein: the computing cluster (1) further comprises a display device (15) connected with the acquisition circuit (11) and used for displaying the acquired field acquisition data.

3. The continuous acquisition technical field acquisition system for engineering surveys of claim 1, wherein: the microprocessor chip (13) comprises an identification unit (131), a statistic unit (132) and a rechecking unit (133); the identification unit (131) is connected with the acquisition circuit (11) and is used for identifying the drill hole to which field acquisition data belongs; the statistical unit (132) is connected with the identification unit (131) and is used for counting the items of field collected data belonging to the same drilling hole in the identification unit (131); the rechecking unit (133) is connected with the statistical unit (132) and is used for checking whether the field collected data in the statistical unit (132) belong to the same borehole.

4. The continuous acquisition technical field acquisition system for engineering surveys of claim 1, wherein: the computing cluster (1) is connected to the server (2) via a wireless network system (3) with a security device (31).

5. The continuous acquisition technical field acquisition system for engineering surveys of claim 1, wherein: the power supply circuit (14) includes a rechargeable battery and a charging device connected to the rechargeable battery.

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