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CN-224233398-U - High-voltage electric field energy taking device

CN224233398UCN 224233398 UCN224233398 UCN 224233398UCN-224233398-U

Abstract

The utility model discloses a high-voltage electric field energy taking device, which relates to the technical field of electric field energy taking and comprises an interdigital electrode array row, electrode outgoing lines and a product shell, wherein the electrode outgoing lines are arranged on the outer side of the interdigital electrode array row, and the product shell is arranged at the bottoms of the interdigital electrode array row and the electrode outgoing lines. The high-voltage electric field energy taking device can increase the total length and the coverage area of electrodes when a plurality of groups of interdigital electrode bodies are connected in series, so that the coupling effect with an external electric field is enhanced, the energy collecting efficiency is improved, the interdigital electrode bodies in series can increase the strength of output signals, the core principle of interdigital electrode electric field energy taking is that the electric field energy is converted into electric energy through the capacitive coupling effect by utilizing the potential difference generated between the interdigital electrode bodies by the external electric field.

Inventors

  • LIU CHUANBIN
  • ZHAO QIULIANG

Assignees

  • 中电新元(重庆)智能科技研究院有限公司

Dates

Publication Date
20260512
Application Date
20250604

Claims (6)

  1. 1. The high-voltage electric field energy taking device comprises an interdigital electrode array row (1), an electrode outgoing line (2) and a product shell (3), and is characterized in that: An electrode outgoing line (2) is arranged on the outer side of the interdigital electrode array row (1), and a product shell (3) is arranged at the bottoms of the interdigital electrode array row (1) and the electrode outgoing line (2) together; The interdigital electrode array row (1) comprises an interdigital electrode main body (11), a microelectrode array clamping groove (12) and an electrode acquisition module (13), an interdigital electrode metal layer (111) is sprayed on the surface of the interdigital electrode main body (11), and the electrode acquisition module (13) comprises an inserting plate type spring thimble (131) and a circuit board (132).
  2. 2. The high-voltage electric field energy taking device as claimed in claim 1, wherein the interdigital electrode bodies (11) are inserted into the microelectrode array clamping grooves (12), and two groups of interdigital electrode metal layers (111) are sprayed on one group of interdigital electrode bodies (11).
  3. 3. The high-voltage electric field energy taking device as claimed in claim 2, wherein the end part of the plugboard type spring thimble (131) is spliced in the microelectrode array clamping groove (12), and the end part of the plugboard type spring thimble (131) is contacted with the interdigital electrode metal layer (111) on the interdigital electrode main body (11).
  4. 4. A high-voltage electric field energy taking device as claimed in claim 1, characterized in that the interdigital electrode array row (1) and the electrode outgoing lines (2) are both installed inside the product housing (3).
  5. 5. The high-voltage electric field energy taking device as set forth in claim 3, wherein the interdigital electrode bodies (11) are distributed at equal intervals inside the microelectrode array clamping groove (12), and the microelectrode array clamping groove (12) and the electrode acquisition module (13) are distributed at equal intervals inside the product shell (3).
  6. 6. The high-voltage electric field energy taking device according to claim 5, wherein one ends of eight groups of electrode acquisition modules (13) are commonly connected in series on the electrode outgoing line (2), and twelve groups of interdigital electrode main bodies (11) are connected in series with one group of electrode acquisition modules (13).

Description

High-voltage electric field energy taking device Technical Field The utility model relates to the technical field of electric field energy taking, in particular to a high-voltage electric field energy taking device. Background The high-voltage electric field refers to a strong electric field environment generated by high voltage, the electric field intensity of the high-voltage electric field environment is obviously higher than that of a common electric field, and the high-voltage electric field energy taking is a technology for realizing electric energy conversion by coupling electric field energy around a high-voltage transmission line, so that an electric field energy taking device is needed. Along with the continuous development and the intellectualization of a power system, higher requirements are put forward on the monitoring and the maintenance of power equipment, the traditional power monitoring equipment generally depends on batteries or wired power supply, the problems of inconvenience in battery replacement and complex wiring exist, the traditional high-voltage electric field energy taking device is difficult to directly obtain energy from a high-voltage electric field, a continuous and stable power supply is provided for the power monitoring equipment, and the electric field energy taking device is more dependent on the traditional power supply. Disclosure of utility model The utility model aims to provide a high-voltage electric field energy taking device, which is used for solving the problem that the energy taking device in the current market, which is proposed by the background technology, is difficult to directly obtain energy from a high-voltage electric field. The high-voltage electric field energy taking device comprises an interdigital electrode array row, electrode outgoing lines and a product shell, wherein the electrode outgoing lines are arranged on the outer sides of the interdigital electrode array row, the product shell is arranged at the bottoms of the interdigital electrode array row and the electrode outgoing lines, the interdigital electrode array row comprises an interdigital electrode main body, a microelectrode array clamping groove and an electrode collecting module, an interdigital electrode metal layer is sprayed on the surface of the interdigital electrode main body, and the electrode collecting module comprises a plugboard type spring thimble and a circuit board. Preferably, the interdigital electrode bodies are inserted into the microelectrode array clamping grooves, and two groups of interdigital electrode metal layers are sprayed on one group of interdigital electrode bodies. Preferably, the end part of the plugboard type spring thimble is spliced in the microelectrode array clamping groove, and the end part of the plugboard type spring thimble is contacted with the interdigital electrode metal layer on the interdigital electrode main body. Preferably, the interdigital electrode array row and the electrode outgoing lines are both arranged inside the product shell. Preferably, the interdigital electrode bodies are distributed at equal intervals inside the microelectrode array clamping grooves, and the microelectrode array clamping grooves and the electrode acquisition modules are distributed at equal intervals inside the product shell. Preferably, one ends of the eight groups of electrode acquisition modules are connected in series on the electrode lead-out wire, and the twelve groups of interdigital electrode main bodies are connected in series with one group of electrode acquisition modules. Compared with the prior art, the high-voltage electric field energy taking device has the advantages that the interdigital electrode main bodies and the electrode acquisition modules in the product shell are connected in series, the electrode acquisition modules and the electrode outgoing lines are connected in series, so that when the interdigital electrode main bodies of a plurality of groups are connected in series, the total length and the coverage area of the electrodes can be increased, the coupling effect with an external electric field is enhanced, the energy collection efficiency is improved, the interdigital electrode main bodies can increase the strength of output signals, meanwhile, the conductive paths are increased, the impedance of the whole electrode is reduced, the loss in the energy transmission process is reduced, the energy transmission efficiency can be improved through the low-impedance design, more energy is effectively collected and utilized, the efficient energy conversion and utilization can be realized through the electric field energy taking scheme, the energy utilization efficiency of the interdigital electrode is improved, the electric field energy is converted into electric energy through the capacitive coupling effect by utilizing the potential difference generated between the interdigital electrode main bodies, and the energy collection effici