CN212872610U - High-voltage direct-current detection device and detection system for buried metal pipeline - Google Patents
High-voltage direct-current detection device and detection system for buried metal pipeline Download PDFInfo
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- CN212872610U CN212872610U CN202020705373.XU CN202020705373U CN212872610U CN 212872610 U CN212872610 U CN 212872610U CN 202020705373 U CN202020705373 U CN 202020705373U CN 212872610 U CN212872610 U CN 212872610U
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- buried metal
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Abstract
The utility model belongs to the technical field of buried pipeline detection, in particular to a buried metal pipeline high-voltage direct current detection device and a detection system; the high-voltage direct-current detection device for the buried metal pipeline comprises a test box, a magnetism gathering ring and a transmission line, wherein a Hall sensor is installed in the test box, the magnetism gathering ring is provided with a fracture, the fracture is located in the test box, and the Hall sensor is located at the fracture of the magnetism gathering ring and is in clearance fit with the magnetism gathering ring; the magnetic gathering ring is sleeved outside the metal pipeline; the transmission line is connected with the Hall sensor and used for outputting signals of the Hall sensor. The utility model discloses a gather magnetic ring and hall sensor's design, can the immediate survey bury ground metal pipeline and whether have the electric current to flow through to and the accurate measurement electric current size possesses the high accuracy measurement.
Description
Technical Field
The utility model belongs to the technical field of buried pipeline detects, concretely relates to bury ground metal pipeline high voltage direct current detection device and detecting system.
Background
With the rapid development of energy demand and economy, the rapid construction of high-voltage/extra-high-voltage direct-current transmission lines, urban subways and pipeline engineering, the interference of direct-current traction systems such as high-voltage/extra-high-voltage direct-current transmission line grounding electrode single-stage operation and urban subways on buried metal pipelines is more and more serious. The direct current interference of the grounding electrode, a direct current traction system and the like often have the characteristics of large ground current, uncertain discharge time and the like, the buried metal pipeline is a good metal conductor, and large current flows in and out from the pipeline in the twinkling of an eye, so that the pipeline is damaged by corrosion, leakage, explosion, equipment burning, electric shock and casualties of people, large deviation of pipeline protection potential and the like. Therefore, effective current sensing of buried metal pipelines is an important measure in relation to the safe operation of the pipeline.
There have been some detection methods for current detection in buried metal pipelines. For example, patent document No. CN201583583U discloses a stray current detection device for a buried gas pipeline, which includes a power supply, three copper sulfate reference electrodes, two wiring piles and a single chip system, wherein the three copper sulfate reference electrodes are placed at 120 degrees near the buried gas pipeline, and the two wiring piles are welded on the buried gas pipeline; the three copper sulfate reference electrodes and the two wiring piles are respectively connected to the single chip microcomputer system through leads. For another example, patent document No. CN208654224U discloses a device for detecting stray current of buried metal pipeline, in which a main controller is connected to a data conversion module, an output terminal of a data acquisition module is connected to an input terminal of the data conversion module, an output terminal of the data conversion module is connected to the main controller, a GPS time service module, a data storage module, a power module, an alarm module, an ethernet module is connected to the main controller, the ethernet module is connected to a PC, the data acquisition module acquires the stray current data of the buried metal pipeline, the stray current data is transmitted to the main controller through the data conversion module, the main controller stores the data and transmits the data to the PC through the ethernet module, and the PC combines an EMD method to process the data.
However, the above-mentioned acquisition device for the pipeline current signal cannot be applied to a large-diameter pipeline, and the detection accuracy is not high.
SUMMERY OF THE UTILITY MODEL
Based on the above-mentioned not enough that exists among the prior art, the utility model provides a bury ground metal pipeline high voltage direct current detection device and detecting system.
In order to achieve the purpose of the utility model, the utility model adopts the following technical scheme:
a high-voltage direct-current detection device for a buried metal pipeline comprises a test box, a magnetic gathering ring and a transmission line, wherein a Hall sensor is installed in the test box, the magnetic gathering ring is provided with a fracture, the fracture is located in the test box, and the Hall sensor is located at the fracture of the magnetic gathering ring to be in clearance fit with the magnetic gathering ring; the magnetic gathering ring is sleeved outside the metal pipeline; the transmission line is connected with the Hall sensor and used for outputting signals of the Hall sensor.
Preferably, the magnetism gathering ring comprises a magnetism gathering ring core and an anti-corrosion sheath wrapped outside the magnetism gathering ring core.
Preferably, the magnetic gathering ring core is an annular structure formed by winding a plurality of layers of metal strips.
Preferably, the cross section of the multilayer metal strip is a square with the side length of 1-5 cm.
Preferably, the magnetism gathering ring core comprises a first ring part and a second ring part, one end of the first ring part is connected with one end of the second ring part through a detachable connecting piece, and the other end of the first ring part and the other end of the second ring part form a fracture of the magnetism gathering ring.
Preferably, the magnetism gathering ring is flexible, and the magnetism gathering ring core is made of soft magnetic materials. The magnetic gathering ring core is made of soft magnetic materials with high saturation magnetic induction intensity and low iron loss, mainly nickel-iron alloy with the nickel content of 30-90%, and can also be made of soft magnetic materials such as iron-silicon alloy, iron-aluminum alloy, iron-silicon-aluminum alloy, iron-cobalt alloy or soft magnetic ferrite.
As a preferred scheme, the test box comprises a box body and a box cover covering the box body, wherein an installation frame is arranged in the box body and used for installing the Hall sensor; two side walls of the box body are respectively provided with an insertion hole for inserting the magnetism gathering ring. The magnetic gathering ring enters the test box through the openings on the two sides, and the interference of external electromagnetic waves except the magnetic gathering ring can be prevented.
As a preferred scheme, a transmission line in the box body is further arranged in the box body, the box cover is provided with a waterproof connector, and the transmission line in the box body is connected with the waterproof connector and the Hall sensor.
Preferably, the test box is filled with epoxy resin.
Preferably, the test box is externally provided with a graphene anticorrosive layer. The test box is coated with graphene anticorrosive paint, and the graphene coating with conductivity has certain electromagnetic shielding and interference preventing capabilities besides the corrosion resistance.
The utility model also provides a bury ground metal pipeline high voltage direct current detecting system, including as above arbitrary scheme bury ground metal pipeline high voltage direct current detection device, still including the test stake that is located ground, the test stake passes through transmission line and is connected with hall sensor.
Compared with the prior art, the utility model, beneficial effect is:
(1) the utility model can measure whether current flows through the buried metal pipeline in real time and accurately measure the current through the buried metal pipeline by the design of the magnetic gathering ring and the Hall sensor, and has high-precision measurement;
(2) the utility model adopts the metal strip winding magnetic gathering ring to measure the magnetic field variation of the buried metal pipeline with super large diameter; the strip winding magnetism-gathering ring is flexible and can be wound and processed randomly according to the size of a pipeline, namely, the magnetism-gathering ring can be flexibly bent and installed;
(3) the graphene anticorrosive coating designed outside the test box of the utility model has the capability of corrosion resistance and electromagnetic interference resistance;
(4) the buried measuring element has high-specification waterproof and anticorrosion capabilities.
Drawings
Fig. 1 is a schematic structural diagram of a buried metal pipeline high-voltage direct-current detection system according to a first embodiment of the present invention;
fig. 2 is a schematic structural diagram of the inside of a buried metal pipeline high-voltage direct-current detection device according to a first embodiment of the present invention;
fig. 3 is a schematic partial structure view of a magnetic gathering ring according to a first embodiment of the present invention;
fig. 4 is a schematic structural diagram of a buried metal pipeline high-voltage direct-current detection device of the second embodiment of the present invention.
Detailed Description
In order to more clearly illustrate the embodiments of the present invention, the following description will explain embodiments of the present invention with reference to the accompanying drawings. It is obvious that the drawings in the following description are only examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be obtained from these drawings without inventive effort. In addition, directional terms referred to in the following examples, for example: up, down, left, right, front or rear, etc., are simply directions with reference to the drawings. Accordingly, the directional terminology is used for purposes of illustration and is in no way limiting.
The first embodiment is as follows:
as shown in fig. 1-3, the high-voltage direct current detection device for the buried metal pipeline of the present embodiment includes a test box 1, a magnetic focusing ring 2 and a transmission line 3. Install hall sensor 102 in the test box 1, gather magnetic ring 2 and stretch into in the test box 1 and match with hall sensor 102, transmission line 3 is used for hall sensor to connect the test stake, and the test stake is located ground, installs the power that can be for hall sensor power supply and carries out data storage, processing, the module of transmission in the test stake.
The high-voltage direct current detection device for the buried metal pipeline is applied to detection of the detected buried metal pipeline 4. The buried metal pipeline is a common steel pipeline or a pipeline made of other materials.
Specifically, as shown in fig. 2, the test box 1 includes a test box housing 101, the test box housing 101 is a waterproof box made of engineering plastics, the magnetic gathering ring 2 enters the test box 1 through an opening 103 of the test box housing, and the hall sensor 102 is mounted in the test box 1 through a bracket. The hall sensor 102 is located at the midpoint of a fracture of the magnetic gathering ring 2, so as to be in clearance fit with the magnetic gathering ring 2. The interior of the test box 1 is encapsulated by epoxy resin, and only the transmission line 104 in the box is left out of the epoxy resin. The test box 1 further comprises a test box upper cover 105, the transmission line 104 in the test box is connected with one side of a waterproof plug 106 arranged on the test box upper cover, the test box upper cover 105 is fastened on the test box shell 101 through screws or other modes, so that the test box 1 is integrally installed and sealed, and the other side of the waterproof plug 106 is connected with a test line 3 positioned outside the test box.
In addition, the test box 1 is coated with graphene anticorrosive paint, the graphene coating with conductivity has certain electromagnetic shielding and anti-interference capabilities besides the anticorrosive performance, and the magnetic gathering ring enters the test box through the openings at the two sides, so that the interference of external electromagnetic waves except the magnetic gathering ring can be prevented.
The Hall sensor 102 of this embodiment is used for measuring the magnetic field signal of magnetic ring gathering, and the change of response magnetic field is converted into the signal of telecommunication, and Hall element's signal of telecommunication is converted into the voltage signal of-5 ~ 5V to Hall sensor's processing chip, and the resistance setting of the correction resistance on the signal rate of change accessible adjustment sensor circuit board is in the scope of 5 ~ 150mV/mT, and measurement accuracy can reach 0.1A magnitude, and the measured data is transmitted the host computer in the test stake through transmission line 3 and is carried out the record or send.
The magnetic gathering ring 2 is circular and annular, is used for being sleeved outside the detected buried metal pipeline 4, can be adjusted in size according to the detected pipeline 4, and has the inner diameter 1-10 cm larger than the outer diameter of the detected buried metal pipeline 4. As shown in fig. 3, the magnetism gathering ring 2 includes a magnetism gathering ring core 201 and a magnetism gathering ring sheath 202.
The magnetic gathering ring core 201 is made of soft magnetic materials with high saturation magnetic induction intensity and low iron loss, mainly nickel-iron alloy with nickel content of 30-90%, and can also be made of soft magnetic materials such as iron-silicon alloy, iron-aluminum alloy, iron-silicon-aluminum alloy, iron-cobalt alloy or soft magnetic ferrite. The manufacturing method is characterized in that the sensor is formed by winding metal strips in multiple layers, the cross section of the wound sensor is a square with the side length of 1-5cm, and the sensor is suitable for most Hall sensors.
The metal strip winding mode has the following advantages:
1. the manufacture is simple, and the magnet gathering rings with different diameters can be wound on underground conveying pipelines with different sizes.
2. The magnetic gathering ring produced by winding has flexibility, and is convenient to construct and install aiming at the existing pipeline; after winding, a 5 mm gap is reserved for placing the Hall sensor.
The magnetic gathering ring sheath 202 is wrapped outside the magnetic gathering ring core 201 to play a role in corrosion prevention, and is mainly made of plastics with better low-temperature resistance and aging resistance, such as polycarbonate, polytetrafluoroethylene and the like.
This embodiment still provides a bury ground metal pipeline high voltage direct current detection system, including the bury ground metal pipeline high voltage direct current detection device of this embodiment, still including the test stake that is located ground, the test stake passes through transmission line and is connected with hall sensor to the realization is to burying the current detection of ground metal pipeline.
Example two:
the buried metal pipeline high-voltage direct current detection device of the embodiment is different from the first embodiment in that: the magnetic gathering rings have different structures.
Specifically, as shown in fig. 4, the magnetic ring gathering core of the present embodiment is a split structure, and includes a first ring portion 2a and a second ring portion 2b, where the first ring portion 2a and the second ring portion 2b are both semicircular ring structures, one end of the first ring portion 2a is connected to one end of the second ring portion 2b through an installation buckle 5, and the other end of the first ring portion 2a and the other end of the second ring portion 2b enter the test box 10 through the test box housing openings on both sides, so as to form a fracture of the magnetic ring gathering core.
The high-voltage direct current detection device for the buried metal pipeline is small in diameter of the buried metal pipeline or the magnetic gathering ring is made of hard alloy, so that the buried metal pipeline is not flexible enough to stretch and sleeve. Optionally, the magnetic gathering ring is cut into two semicircular rings, two ends of the two semicircular rings are fixed by the installation buckle 5 which can be opened and closed, and the magnetic gathering ring installation buckle 5 can be opened or locked.
In the actual installation process, the installation buckle 5 is opened, one side of the magnetic gathering ring is separated from the test box 1, the whole set of device is sleeved into the steel pipeline, the magnetic gathering ring is inserted into the test box 1, and the installation buckle 5 is locked.
The mounting buckle of the present embodiment can also be replaced by other detachable connectors in the prior art, for example: the nut and nut may be matched, magnetically matched, etc., and reference may be made to the prior art, which is not described herein in detail.
The foregoing has been a detailed description of the preferred embodiments and principles of the present invention, and it will be apparent to those skilled in the art that variations may be made in the specific embodiments based on the concepts of the present invention, and such variations are considered as within the scope of the present invention.
Claims (10)
1. A high-voltage direct-current detection device for a buried metal pipeline is characterized by comprising a test box, a magnetism gathering ring and a transmission line, wherein a Hall sensor is installed in the test box, the magnetism gathering ring is provided with a fracture, the fracture is located in the test box, and the Hall sensor is located at the fracture of the magnetism gathering ring to be in clearance fit with the magnetism gathering ring; the magnetic gathering ring is sleeved outside the metal pipeline; the transmission line is connected with the Hall sensor and used for outputting signals of the Hall sensor.
2. The high-voltage direct-current detection device for the buried metal pipeline as recited in claim 1, wherein the magnetism gathering ring comprises a magnetism gathering ring core and an anti-corrosion sheath wrapped outside the magnetism gathering ring core.
3. The high-voltage direct current detection device for the buried metal pipeline according to claim 2, wherein the magnetic gathering ring core is of an annular structure formed by winding a plurality of layers of metal strips.
4. The high-voltage direct current detection device for the buried metal pipeline as claimed in claim 2, wherein the magnetism gathering ring core comprises a first ring portion and a second ring portion, one end of the first ring portion is connected with one end of the second ring portion through a detachable connecting piece, and the other end of the first ring portion and the other end of the second ring portion form a fracture of the magnetism gathering ring.
5. A buried metal pipeline high voltage direct current detection device as claimed in claim 2 or 3 or 4, wherein the magnetic gathering ring is flexible, and the magnetic gathering ring core is made of soft magnetic material.
6. The high-voltage direct current detection device for the buried metal pipeline according to claim 1, wherein the test box comprises a box body and a box cover covering the box body, an installation frame is arranged in the box body, and the installation frame is used for installing the Hall sensor; two side walls of the box body are respectively provided with an insertion hole for inserting the magnetism gathering ring.
7. The device for high-voltage direct current detection of the buried metal pipeline according to claim 6, wherein an in-box transmission line is further arranged in the box body, the box cover is provided with a waterproof connector, and the in-box transmission line connects the waterproof connector and the Hall sensor.
8. The buried metal pipeline high voltage direct current detection device according to claim 6 or 7, wherein epoxy resin is filled in the test box.
9. The high-voltage direct current detection device for the buried metal pipeline according to claim 1, wherein a graphene anticorrosive layer is arranged outside the test box.
10. A buried metal pipeline high-voltage direct current detection system is characterized by comprising the buried metal pipeline high-voltage direct current detection device as claimed in any one of claims 1 to 9 and further comprising a test pile located on the ground, wherein the test pile is connected with a Hall sensor through a transmission line.
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| CN202020705373.XU CN212872610U (en) | 2020-04-30 | 2020-04-30 | High-voltage direct-current detection device and detection system for buried metal pipeline |
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| CN202020705373.XU CN212872610U (en) | 2020-04-30 | 2020-04-30 | High-voltage direct-current detection device and detection system for buried metal pipeline |
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| Publication number | Priority date | Publication date | Assignee | Title |
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| CN111579846A (en) * | 2020-04-30 | 2020-08-25 | 浙江浙能天然气运行有限公司 | High-voltage direct-current detection device and detection system for buried metal pipeline |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN111579846A (en) * | 2020-04-30 | 2020-08-25 | 浙江浙能天然气运行有限公司 | High-voltage direct-current detection device and detection system for buried metal pipeline |
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Effective date of registration: 20231113 Address after: No. 1751 Binsheng Road, Binjiang District, Hangzhou City, Zhejiang Province, 310000 Patentee after: Zhejiang Provincial Natural Gas Development Co.,Ltd. Patentee after: ZHEJIANG ENERGY R & D INSTITUTE Co.,Ltd. Address before: Zheneng second building, 1751 Binsheng Road, Binjiang District, Hangzhou, Zhejiang 310000 Patentee before: ZHEJIANG ZHENENG NATURAL GAS OPERATION CO.,LTD. Patentee before: ZHEJIANG ENERGY R & D INSTITUTE Co.,Ltd. |