CN115939798B

CN115939798B - Graphene grounding device

Info

Publication number: CN115939798B
Application number: CN202310223387.6A
Authority: CN
Inventors: 陈莹丽; 邓承器; 宋强; 张远鑫; 吴媚
Original assignee: Jiangtian Technology Co ltd
Current assignee: Jiangtian Technology Co ltd
Priority date: 2023-03-09
Filing date: 2023-03-09
Publication date: 2023-05-23
Anticipated expiration: 2043-03-09
Also published as: CN115939798A

Abstract

The invention relates to the technical field of grounding devices, in particular to a graphene grounding device which comprises a graphene grounding rod, a mounting structure, a positioning structure, a stabilizing structure, a clamping structure, a sealing structure, an earth boring structure, a buffer structure and a sealing ring; the connecting ends of the graphene grounding rods are aligned and connected through the matching of the positioning structure and the mounting structure, so that abrasion among the core rods is reduced; the connection between the graphene grounding bars is more stable through the stabilizing structure, and the connection between the graphene grounding bars is tighter through the tightening structure, so that the breakage of the core rod of the graphene grounding bars due to vibration in the process of descending the ground is avoided; the graphene grounding rod connector is sealed through the sealing structure, moisture in soil is prevented from entering the interface of the graphene grounding rod, the elasticity between the mounting structures is reduced through the buffer structure when the clamping structure is used, and the sealing effect is better.

Description

Graphene grounding device

Technical Field

The invention relates to the technical field of grounding devices, in particular to a graphene grounding device.

Background

The grounding device is also called an integrated grounding device, and is used for connecting an electric device or other objects with the ground, wherein the electric device or other objects are electrically connected with the ground, the metal object which is directly contacted with the ground to realize the electric connection is a grounding electrode, the grounding device can be a manual grounding electrode or a natural grounding electrode, and the grounding electrode can be endowed with a certain electric function, such as system grounding, protection grounding or signal grounding, and the like, and the graphene grounding device is commonly used in some industrial electricity.

However, when two or more traditional graphene grounding rods are connected, the traditional graphene grounding rods are often connected through bolts, so that reserved hole sites between the core rods are inconvenient to find, and the traditional graphene grounding rods are troublesome to install; meanwhile, after the connected graphene grounding rod is driven into the ground, the graphene grounding rod is easy to break due to vibration of the connecting part, so that the graphene grounding rod material is wasted; moisture and inorganic salt in soil are easy to react with the connected bolts, the rusting of the bolts is serious, the graphene grounding rod is easy to fall off, and the service life of the graphene grounding rod is shortened; traditional beat into the soil horizon with graphite alkene earth bar through the electric hammer, soil horizon resistance is great, influences graphite alkene earth bar degree of depth ground connection.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a graphene grounding device.

The technical scheme adopted for solving the technical problems is as follows: the graphene grounding device comprises a graphene grounding rod, wherein a mounting structure is arranged on the graphene grounding rod, a positioning structure is arranged on the mounting structure, a stabilizing structure is arranged on the mounting structure, a clamping structure is arranged on the stabilizing structure, a sealing structure is arranged on the clamping structure, an earth boring structure is arranged on the mounting structure, a buffer structure is arranged on the mounting structure, and a sealing ring is arranged on the mounting structure;

the mounting structure comprises a connecting core rod, wherein the connecting core rod is arranged at one end of a graphene grounding rod, the other end of the graphene grounding rod is provided with a connecting outer rod, a mounting ring is fixed on the graphene grounding rod where the connecting core rod is located, a mounting sleeve is arranged at the end part of the graphene grounding rod where the connecting outer rod is located, the connecting core rod is in sliding connection with the connecting outer rod, a connecting ring is arranged at the end part of the mounting sleeve, the connecting ring is in sliding connection with the inside of the mounting ring, four clamping grooves of a circumferential array are arranged at the outer side of the connecting ring, four first clamping blocks of the circumferential array are arranged inside the mounting ring, the first clamping blocks are in sliding connection with the clamping grooves, a first spring is arranged on one side of the first clamping blocks, the first spring is fixed in the inside of the mounting ring, a deflector rod is fixed on one side of the first clamping blocks, the deflector rod is in sliding connection with the mounting ring, a mounting cover is arranged on one side of the mounting ring at the top of the deflector rod, and the mounting cover is in sliding connection with the mounting ring; the mounting structure further comprises a guide rod, wherein the guide rod is vertically arranged with the deflector rod, the deflector rod is connected with the guide rod in a sliding manner, and two ends of the guide rod are fixed in the mounting ring; the positioning structure comprises positioning plates, four positioning plates divide the area between the inner wall of the mounting sleeve and the outer wall of the connecting outer rod into four positioning grooves, four positioning blocks are arranged on the mounting ring, the positioning blocks are connected with the positioning grooves in a sliding mode, limiting grooves are formed in the positioning blocks, the limiting grooves are connected with limiting columns in a sliding mode, and the limiting columns are fixed to the inner wall of the mounting sleeve.

Specifically, the stabilizing structure comprises a contact block, four contact blocks of a circumferential array are arranged outside a mounting sleeve, the cross section of the contact block is of a trapezoid structure, the contact block is in sliding connection with the mounting sleeve, a push rod is arranged on one side of the contact block, the push rod is in sliding connection with the mounting sleeve, one end of the push rod is in sliding connection with the inside of a positioning plate, a first rolling shaft is arranged at the end of the push rod and is in rolling connection with the inside of a sliding groove, the sliding groove is arranged in the connecting rod, one end of the connecting rod is rotationally connected to a rotating shaft, the rotating shaft is fixed in the inside of the positioning plate, a second rolling shaft is rotationally connected to the second rolling shaft, the sliding rod is in sliding connection with the inside of an outer connecting rod, the end of the sliding rod is in sliding connection with the inside of a mounting hole, and the mounting hole is arranged on a connecting core rod; the stabilizing structure further comprises a limiting rod, one end of the limiting rod is fixed to one side of the contact block, the limiting rod is in sliding connection with the mounting sleeve, the other end of the limiting rod is arranged inside the positioning plate, the limiting rod is in sliding connection with the positioning plate, a second spring is arranged on one side of the limiting rod, and the second spring is fixed to the inside of the positioning plate.

Specifically, the clamping structure comprises a mounting plate, the mounting plate is fixed in one side of connecting rod, rotate between mounting plate and the pivot and be connected, be equipped with first connecting axle on the mounting plate, the outside of first connecting axle rotates the one end that is connected with first connecting strip, the other end of first connecting strip rotates and is connected with the second connecting axle, the second connecting axle is fixed in the tip of second connecting strip, second connecting strip sliding connection is in the inside of locating plate, sliding connection between second connecting strip and the installation cover, be equipped with the third connecting axle on the second connecting strip, the last one end that is connected with the third connecting strip that rotates of third connecting axle, the other end rotation of third connecting strip is connected in the outside of fourth connecting axle, the fourth connecting axle is fixed in the tip of tightening rod, sliding connection between tightening rod and the installation cover, the other end of tightening rod is fixed in the bottom of go-between.

Specifically, one end of the sealing ring is fixed in the mounting sleeve, and the other end of the sealing ring is connected in the mounting ring in a sliding manner; the sealing structure comprises a propping block, the propping block is arranged at the end part of the second connecting strip, the propping block is in sliding connection with the mounting sleeve, the section of the propping block is of a trapezoid structure, one side of the propping block is propped against an extrusion ring, the extrusion ring is in sliding connection with the mounting sleeve, and the extrusion ring is arranged at the bottom end of the sealing ring.

Specifically, the earth boring structure includes the drill bit, the drill bit is fixed with four circumference array's first fixed blocks, the cross-section of first fixed block is L shape structure, the drill bit inboard of first fixed block bottom is equipped with four parallel arrangement's second fixed blocks, the bottom of installation cover is equipped with four stoppers of circumference array, sliding connection between stopper and the first fixed block, sliding connection between stopper and the second fixed block, sliding connection between stopper and the drill bit, the bottom sliding connection of stopper has the second fixture block, sliding connection between second fixture block and the second fixed block, the one end sliding connection of second fixture block is in the inside of drill bit, the end fixing of second fixture block has the connecting block, sliding connection between connecting block and the drill bit, one side of connecting block is equipped with the third spring, one end of third spring is fixed in the inside of drill bit, one side of connecting block is fixed with the son rope, four the one end of son rope all is connected in the one end of mother rope, mother rope sliding connection in the inside of mother rope, sliding connection is in the other end of mother rope, sliding connection in mother rope's cover, sliding connection in mother rope's external connection.

Specifically, the buffer structure comprises a buffer ring, one side of the buffer ring is arranged on the mounting sleeve, the other side of the buffer ring is attached to the mounting ring, one side of the buffer pad is attached to the positioning plate, and the other side of the buffer pad is fixed to the mounting ring.

The beneficial effects of the invention are as follows:

(1) According to the graphene grounding device, the mounting structure is arranged on the graphene grounding rods, the positioning structure is arranged on the mounting structure, so that the connecting ends of the two graphene grounding rods are aligned and connected through the positioning structure, the connection deviation between the core rods is avoided, the connection is more stable, the two or more graphene grounding rods are connected through the mounting structure, the mounting is rapid and stable, the contact area between the graphene grounding rods is enlarged, the connecting effect of the core rods is better, the core rods are prevented from shaking, the abrasion between the core rods is reduced, and the service life of the graphene grounding rods is prolonged.

(2) According to the graphene grounding device, the stabilizing structure is arranged on the mounting structure, the clamping structure is arranged on the mounting structure, so that connection between the graphene grounding rods is more stable through the stabilizing structure, connection between the two graphene grounding rods is more compact through the clamping structure, breakage of the core rod in the grounding process of the graphene grounding rods due to vibration is avoided, and stability and working efficiency of the graphene grounding rods in grounding are improved.

(3) According to the graphene grounding device, the sealing structure is arranged on the mounting structure, the buffer structure is arranged on the mounting structure, so that the connection port of the graphene grounding rod is conveniently sealed through the sealing structure, moisture in soil is prevented from entering the connection port of the graphene grounding rod, the elasticity between the mounting structures is conveniently reduced through the buffer structure when the clamping structure is used, the mounting structure is connected more tightly, and the sealing effect is better.

(4) According to the graphene grounding device, the ground drilling structure is arranged on the mounting structure, so that the ground drilling structure can be conveniently mounted on any mounting structure, the mounting is convenient, the dismounting and the replacement are convenient, the graphene grounding rod can well drill deep soil through the ground drilling structure, and the grounding effect of the graphene grounding rod is further better.

Drawings

The invention will be further described with reference to the drawings and examples.

Fig. 1 is a schematic overall structure of a preferred embodiment of a graphene grounding device according to the present invention;

FIG. 2 is a schematic view of the connection structure of the mounting ring and the mounting sleeve of the present invention;

FIG. 3 is a schematic view of the connection structure of the stabilizing structure, earth boring structure and mounting sleeve of the present invention;

FIG. 4 is a schematic diagram illustrating a connection structure between a limiting block and a second clamping block according to the present invention;

FIG. 5 is a schematic diagram of a connection structure between a stopper and a first fixing block according to the present invention;

FIG. 6 is an enlarged schematic view of the portion A shown in FIG. 1;

FIG. 7 is an enlarged schematic view of the B-section structure shown in FIG. 1;

FIG. 8 is an enlarged schematic view of the structure of the portion C shown in FIG. 3;

FIG. 9 is an enlarged schematic view of the structure of the portion D shown in FIG. 3;

FIG. 10 is an enlarged schematic view of the E-section structure shown in FIG. 3;

FIG. 11 is an enlarged schematic view of the F portion structure shown in FIG. 3;

fig. 12 is an enlarged schematic view of the G portion structure shown in fig. 8.

In the figure: 1. a graphene grounding rod; 2. a mounting structure; 201. connecting the core rod; 202. a mounting ring; 203. connecting an outer rod; 204. a mounting sleeve; 205. a connecting ring; 206. a clamping groove; 207. a first clamping block; 208. a first spring; 209. a deflector rod; 210. a mounting cover; 211. a guide rod; 3. a positioning structure; 301. a positioning plate; 302. a positioning groove; 303. a positioning block; 304. a limit groove; 305. a limit column; 4. a stabilizing structure; 401. a touch block; 402. a push rod; 403. a limit rod; 404. a second spring; 405. a first roller; 406. a connecting rod; 407. a rotating shaft; 408. a chute; 409. a second roller; 410. a slide bar; 411. a mounting hole; 5. a clamping structure; 501. a mounting plate; 502. a first connecting shaft; 503. a first connecting bar; 504. a second connecting shaft; 505. a second connecting bar; 506. a third connecting shaft; 507. a third connecting bar; 508. a fourth connecting shaft; 509. a tightening rod; 6. a sealing structure; 601. abutting blocks; 602. ring extrusion; 7. an earth boring structure; 701. a drill bit; 702. a first fixed block; 703. a second fixed block; 704. a limiting block; 705. a second clamping block; 706. a connecting block; 707. a third spring; 708. a sub-rope; 709. connecting sleeves; 710. a parent rope; 711. a connection cover; 8. a buffer structure; 801. a buffer ring; 802. a cushion pad; 9. and (3) sealing rings.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1-12, the graphene grounding device comprises a graphene grounding rod 1, wherein a mounting structure 2 is arranged on the graphene grounding rod 1, a positioning structure 3 is arranged on the mounting structure 2, a stabilizing structure 4 is arranged on the mounting structure 2, a tightening structure 5 is arranged on the stabilizing structure 4, a sealing structure 6 is arranged on the tightening structure 5, an earth-boring structure 7 is arranged on the mounting structure 2, a buffer structure 8 is arranged on the mounting structure 2, and a sealing ring 9 is arranged on the mounting structure 2;

the installation structure 2 comprises a connecting mandrel 201, the connecting mandrel 201 is arranged at one end of a graphene grounding rod 1, the other end of the graphene grounding rod 1 is provided with a connecting outer rod 203, a mounting ring 202 is fixed on the graphene grounding rod 1 where the connecting mandrel 201 is arranged, an installation sleeve 204 is arranged at the end part of the graphene grounding rod 1 where the connecting outer rod 203 is arranged, the connecting mandrel 201 is in sliding connection with the connecting outer rod 203, a connecting ring 205 is arranged at the end part of the installation sleeve 204, the connecting ring 205 is in sliding connection with the inside of the mounting ring 202, four clamping grooves 206 in a circumferential array are arranged at the outer side of the connecting ring 205, four first clamping blocks 207 in a circumferential array are arranged inside the mounting ring 202, the first clamping blocks 207 are in sliding connection with the clamping grooves 206, a first spring 208 is arranged on one side of the first clamping blocks 207, the first spring 208 is fixed in the inside of the mounting ring 202, a deflector 209 is fixedly connected with the mounting ring 202 in a sliding manner, the top end of the mounting ring 202 is provided with a mounting cover 210, and the mounting ring 210 is slidably connected with the mounting cover 210; the mounting structure 2 further comprises a guide rod 211, wherein the guide rod 211 is vertically arranged with the deflector rod 209, the deflector rod 209 is in sliding connection with the guide rod 211, and two ends of the guide rod 211 are fixed in the mounting ring 202; the positioning structure 3 comprises a positioning plate 301, the four positioning plates 301 equally divide the area between the inner wall of the mounting sleeve 204 and the outer wall of the connecting outer rod 203 into four positioning grooves 302, the mounting ring 202 is provided with four positioning blocks 303, the positioning blocks 303 are slidably connected with the positioning grooves 302, the positioning blocks 303 are provided with limiting grooves 304, the limiting grooves 304 are slidably connected with limiting columns 305, and the limiting columns 305 are fixed on the inner wall of the mounting sleeve 204; namely: when two graphene grounding bars 1 are required to be connected, after the sealing ring 9 is installed, the positioning block 303 is slid into the positioning groove 302 separated by the positioning plate 301, at the moment, the connecting mandrel 201 is slid into the connecting outer bar 203, the limiting groove 304 and the limiting column 305 are arranged, so that the deviation of the positioning block 303 is effectively avoided, meanwhile, the stability between the connecting mandrel 201 and the connecting outer bar 203 is increased, after the connecting mandrel 201 is slid into the connecting outer bar 203, the connecting ring 205 on the mounting sleeve 204 is slid into the mounting ring 202, the connecting ring 205 firstly abuts against the first clamping block 207, the first spring 208 is contracted, when the clamping groove 206 of the connecting ring 205 is contacted with the first clamping block 207, the first spring 208 is reset, the first clamping block 207 is slid into the clamping groove 206, the connection between the mounting ring 202 and the mounting sleeve 204 is realized, when the connection is required to be released, the mounting cover 210 is slid, the rod 209 is further shifted, the rod 209 drives the first clamping groove 206 to slide out, the mounting ring 202 is detached from the mounting sleeve 204, meanwhile, the connection between the connecting rod 201 and the connecting outer bar 203 is released, and the sliding stability of the rod 211 is improved; the connecting ends of the two graphene grounding bars 1 are aligned and connected through the positioning structure 3, so that connection deviation between the core rods is avoided, meanwhile, connection is more stable, the two or more graphene grounding bars 1 are connected through the mounting structure 2, installation is rapid and stable, the contact area between the graphene grounding bars 1 is enlarged, the connecting effect of the core rods is better, meanwhile, the core rods are prevented from shaking, abrasion between the core rods is reduced, and the service life of the graphene grounding bars 1 is prolonged.

Specifically, the stabilizing structure 4 includes a contact block 401, four contact blocks 401 of a circumferential array are disposed outside the mounting sleeve 204, a cross section of the contact block 401 is a trapezoid structure, the contact block 401 is slidably connected with the mounting sleeve 204, a push rod 402 is disposed on one side of the contact block 401, the push rod 402 is slidably connected with the mounting sleeve 204, one end of the push rod 402 is slidably connected with the inside of the positioning plate 301, a first roller 405 is disposed at an end of the push rod 402, the first roller 405 is in rolling connection with the inside of a chute 408, the chute 408 is disposed inside a connecting rod 406, one end of the connecting rod 406 is rotatably connected with a rotating shaft 407, the rotating shaft 407 is fixed in the inside of the positioning plate 301, a second roller 409 is in rolling connection with the inside of the chute 408, a slide rod 410 is rotatably connected with the second roller 409, the slide rod 410 is slidably connected with the inside of the connecting outer rod 203, an end of the slide rod 410 is slidably connected with the inside of the mounting hole 411, and the mounting hole 411 is disposed on the connecting rod 201; the stabilizing structure 4 further comprises a limiting rod 403, one end of the limiting rod 403 is fixed on one side of the contact block 401, the limiting rod 403 is connected with the mounting sleeve 204 in a sliding mode, the other end of the limiting rod 403 is arranged in the positioning plate 301, the limiting rod 403 is connected with the positioning plate 301 in a sliding mode, a second spring 404 is arranged on one side of the limiting rod 403, and the second spring 404 is fixed in the positioning plate 301.

Specifically, the tightening structure 5 includes a mounting plate 501, the mounting plate 501 is fixed on one side of the connecting rod 406, the mounting plate 501 is rotationally connected with the rotating shaft 407, a first connecting shaft 502 is provided on the mounting plate 501, one end of the first connecting rod 503 is rotationally connected with the outside of the first connecting shaft 502, the other end of the first connecting rod 503 is rotationally connected with a second connecting shaft 504, the second connecting shaft 504 is fixed on the end of the second connecting rod 505, the second connecting rod 505 is slidingly connected with the inside of the positioning plate 301, the second connecting rod 505 is slidingly connected with the mounting sleeve 204, a third connecting shaft 506 is provided on the second connecting rod 505, one end of the third connecting rod 507 is rotationally connected with the third connecting shaft 506, the other end of the third connecting rod 507 is rotationally connected with the outside of the fourth connecting shaft 508, the fourth connecting shaft 508 is fixed on the end of the tightening rod 509, the tightening rod 509 is slidingly connected with the mounting sleeve 204, and the other end of the tightening rod 509 is fixedly connected with the bottom end of the tightening rod 205; namely: when the connected graphene grounding rod 1 is placed under the ground, soil in a soil layer presses the contact block 401, the contact block 401 slides to drive the push rod 402 to slide, meanwhile, the limiting rod 403 slides, the second spring 404 compresses, the push rod 402 slides to push the connecting rod 406 to rotate around the rotating shaft 407, at the moment, the first roller 405 rolls in the sliding groove 408, the second roller 409 rolls in the sliding groove 408 because of the change of the position of the connecting rod 406, meanwhile, the second roller 409 pushes the sliding rod 410 to slide in the connecting outer rod 203, the connecting outer rod 203 slides into the mounting hole 411 preset by the connecting core rod 201, the connection between the connecting core rod 201 and the connecting outer rod 203 is further stable, meanwhile, the connecting rod 406 rotates to drive the mounting disc 501 to rotate, the mounting disc 501 rotates to change the position of the first connecting shaft 502, the first connecting shaft 502 further pushes the first connecting rod 503 to move, the angle of the first connecting rod 503 changes to push the second connecting shaft 504, the second connecting shaft 504 further pushes the second connecting rod 505 to slide, and when the second connecting rod 505 slides in the connecting rod 203, the position of the third connecting shaft 506 further changes, the third connecting shaft 506 is further, the third connecting rod 506 is further pulled by the third connecting rod 506 is further, the third connecting rod 205 is further pulled by the third connecting rod 506 is further tightly connected with the mounting ring 509, and the third connecting rod 509 is further tightly connected by the sliding, and the connecting ring 509 is tightly pulled by the third connecting rod 509, and further tightly pulled by the connecting ring 509 is further pulled by the third connecting rod 509, and tightly and connected by the connecting ring is further pulled by the connecting rod ring and the connecting rod ring roll; the connection between the graphene grounding bars 1 is more stable through the stabilizing structure 4, the connection between the two graphene grounding bars 1 is more compact through the tightening structure 5, breakage of the graphene grounding bars 1 due to vibration in the grounding process is avoided, and stability and working efficiency of the graphene grounding bars 1 in the grounding process are improved.

Specifically, one end of the sealing ring 9 is fixed in the mounting sleeve 204, and the other end of the sealing ring 9 is slidably connected in the mounting ring 202; the sealing structure 6 comprises a supporting block 601, the supporting block 601 is arranged at the end part of the second connecting strip 505, the supporting block 601 is in sliding connection with the mounting sleeve 204, the section of the supporting block 601 is of a trapezoid structure, one side of the supporting block 601 is abutted against an extruding ring 602, the extruding ring 602 is in sliding connection with the mounting sleeve 204, and the extruding ring 602 is arranged at the bottom end of the sealing ring 9.

Specifically, the earth-boring structure 7 includes a drill bit 701, the drill bit 701 is fixed with four first fixing blocks 702 in circumferential array, the cross section of the first fixing blocks 702 is in an L-shaped structure, four second fixing blocks 703 arranged in parallel are arranged inside the drill bit 701 at the bottom end of the first fixing blocks 702, four limiting blocks 704 in circumferential array are arranged at the bottom end of the mounting sleeve 204, the limiting blocks 704 are slidably connected with the first fixing blocks 702, the limiting blocks 704 are slidably connected with the second fixing blocks 703, the limiting blocks 704 are slidably connected with the drill bit 701, the bottom ends of the limiting blocks 704 are slidably connected with second clamping blocks 705, one ends of the second clamping blocks 705 are slidably connected with the inside of the drill bit 701, the end parts of the second clamping blocks 705 are fixedly connected with connecting blocks 706, one side of the connecting blocks 706 is provided with a third spring 707, one end of the third spring is fixedly connected with the inside of the drill bit 701, one side of the third spring 706 is fixedly connected with one end of the auxiliary rope 708, the four auxiliary ropes 708 are slidably connected with one end of the connecting blocks 710, one end of the auxiliary rope 708 is slidably connected with one end of the connecting block 710 is slidably connected with one end of the female cap 710, and the other end of the auxiliary rope is slidably connected with one end 710 of the connecting cap 711; namely: when a drill bit 701 needs to be installed, cutting a graphene grounding rod 1 at the bottom end of an installation sleeve 204 to obtain a proper length, sliding a limiting block 704 at the bottom end of the installation sleeve 204 into the drill bit 701, rotating the installation sleeve 204, rotating the limiting block 704, simultaneously rotating the limiting block 704 into an interlayer of a first fixing block 702 and a second fixing block 703, when the limiting block 704 firstly abuts against the second clamping block 705, compressing a third spring 707, sliding a connecting block 706, when the second clamping block 705 slides to a hole reserved in the limiting block 704, resetting the third spring 707, further driving the connecting block 706 to slide, simultaneously sliding the second clamping block 705 into the inside of the limiting block 704, when the drill bit 701 needs to be disassembled, buckling a connecting cover 711 at the position of the drill bit 701, pulling a parent rope 710 to slide in the inside of a connecting sleeve 709, pulling four child ropes 708 to slide, pulling the connecting block 706 and the second clamping block 705 to compress the third spring 707, and when the second clamping block 705 slides out of the inside of the limiting block 704, rotating the drill bit 701, and then disassembling the drill bit 701 from the bottom end of the installation sleeve 204; be convenient for install on arbitrary mounting structure 2 with boring ground structure 7, simple to operate, convenient to detach changes, makes graphene ground rod 1 better bore deep soil through boring ground structure 7, and then makes graphene ground rod 1's earthing effect better.

Specifically, the buffer structure 8 includes a buffer ring 801, one side of the buffer ring 801 is mounted on the mounting sleeve 204, the other side of the buffer ring 801 is attached to the mounting ring 202, one side of the buffer pad 802 is attached to the positioning plate 301, and the other side of the buffer pad 802 is fixed to the mounting ring 202; namely: when the second connecting strip 505 slides, the abutting block 601 is driven to slide, the abutting block 601 slides to push the extruding ring 602 to slide, when the mounting structure 2 is connected, the extruding ring 602 slides to extrude the sealing ring 9 between the mounting sleeve 204 and the mounting ring 202, so that the sealing is tight, the buffer ring 801 and the buffer pad 802 are made of elastic materials, when the buffer ring 202 and the mounting sleeve 204 are extruded, the joint is tight, moisture in soil is prevented from entering the interface of the graphene grounding rod 1, the elasticity between the mounting structure 2 when the fastening structure 5 is reduced through the buffer structure 8, the connection of the mounting structure 2 is tight, and the sealing effect is better.

When the graphene grounding rod is used, when two graphene grounding rods 1 are required to be connected, after the sealing ring 9 is installed, the positioning block 303 is slid into the positioning groove 302 separated by the positioning plate 301, at the moment, the connecting core rod 201 is slid into the connecting outer rod 203, the limiting groove 304 and the limiting post 305 are arranged, so that the deviation of the positioning block 303 is effectively avoided, meanwhile, the stability between the connecting core rod 201 and the connecting outer rod 203 is improved, after the connecting core rod 201 is slid into the connecting outer rod 203, the connecting ring 205 on the mounting sleeve 204 is slid into the mounting ring 202, the connecting ring 205 firstly abuts against the first clamping block 207, the first spring 208 is contracted, when the clamping groove 206 of the connecting ring 205 is contacted with the first clamping block 207, the first spring 208 is reset, the first clamping block 207 is slid into the clamping groove 206, the connection between the mounting ring 202 and the mounting sleeve 204 is realized, when the connection is required to be released, the mounting cover 210 is slid, the driving rod 209 is pulled out of the clamping groove 206, the mounting ring 202 can be detached from the mounting sleeve 204, and meanwhile, the connecting rod 201 and the guide rod 211 are connected with the connecting rod 203 are released; the connecting ends of the two graphene grounding bars 1 are aligned and connected through the positioning structure 3, so that connection deviation between the core rods is avoided, meanwhile, the connection is more stable, the two or more graphene grounding bars 1 are connected through the mounting structure 2, the mounting is rapid and stable, the contact area between the graphene grounding bars 1 is enlarged, the connecting effect of the core rods is better, meanwhile, the core rods are prevented from shaking, abrasion between the core rods is reduced, and the service life of the graphene grounding bars 1 is prolonged;

when the connected graphene grounding rod 1 is placed under the ground, soil in a soil layer presses the contact block 401, the contact block 401 slides to drive the push rod 402 to slide, meanwhile, the limiting rod 403 slides, the second spring 404 compresses, the push rod 402 slides to push the connecting rod 406 to rotate around the rotating shaft 407, at the moment, the first roller 405 rolls in the sliding groove 408, the second roller 409 rolls in the sliding groove 408 because of the change of the position of the connecting rod 406, meanwhile, the second roller 409 pushes the sliding rod 410 to slide in the connecting outer rod 203, the connecting outer rod 203 slides into the mounting hole 411 preset by the connecting core rod 201, the connection between the connecting core rod 201 and the connecting outer rod 203 is further stable, meanwhile, the connecting rod 406 rotates to drive the mounting disc 501 to rotate, the mounting disc 501 rotates to change the position of the first connecting shaft 502, the first connecting shaft 502 further pushes the first connecting rod 503 to move, the angle of the first connecting rod 503 changes to push the second connecting shaft 504, the second connecting shaft 504 further pushes the second connecting rod 505 to slide, and when the second connecting rod 505 slides in the connecting rod 203, the position of the third connecting shaft 506 further changes, the third connecting shaft 506 is further, the third connecting rod 506 is further pulled by the third connecting rod 506 is further, the third connecting rod 205 is further pulled by the third connecting rod 506 is further tightly connected with the mounting ring 509, and the third connecting rod 509 is further tightly connected by the sliding, and the connecting ring 509 is tightly pulled by the third connecting rod 509, and further tightly pulled by the connecting ring 509 is further pulled by the third connecting rod 509, and tightly and connected by the connecting ring is further pulled by the connecting rod ring and the connecting rod ring roll; the connection between the graphene grounding bars 1 is more stable through the stabilizing structure 4, the connection between the two graphene grounding bars 1 is more compact through the tightening structure 5, breakage of the core rod of the graphene grounding bar 1 due to vibration in the grounding process is avoided, and stability and working efficiency of the graphene grounding bars 1 in the grounding connection are improved;

when the second connecting strip 505 slides, the abutting block 601 is driven to slide, the abutting block 601 slides to push the extruding ring 602 to slide, when the mounting structure 2 is connected, the extruding ring 602 slides to extrude the sealing ring 9 between the mounting sleeve 204 and the mounting ring 202, so that the sealing is tighter, the buffer ring 801 and the buffer pad 802 are made of elastic materials, when the extrusion of the mounting ring 202 and the mounting sleeve 204 is received, the bonding is tighter, moisture in soil is prevented from entering the interface of the graphene grounding rod 1, the elasticity between the mounting structure 2 when the tightening structure 5 is used is reduced through the buffer structure 8, the connection of the mounting structure 2 is tighter, and the sealing effect is better;

when a drill bit 701 needs to be installed, cutting a graphene grounding rod 1 at the bottom end of an installation sleeve 204 to obtain a proper length, sliding a limiting block 704 at the bottom end of the installation sleeve 204 into the drill bit 701, rotating the installation sleeve 204, rotating the limiting block 704, simultaneously rotating the limiting block 704 into an interlayer of a first fixing block 702 and a second fixing block 703, when the limiting block 704 firstly abuts against the second clamping block 705, compressing a third spring 707, sliding a connecting block 706, when the second clamping block 705 slides to a hole reserved in the limiting block 704, resetting the third spring 707, further driving the connecting block 706 to slide, simultaneously sliding the second clamping block 705 into the inside of the limiting block 704, when the drill bit 701 needs to be disassembled, buckling a connecting cover 711 at the position of the drill bit 701, pulling a parent rope 710 to slide in the inside of a connecting sleeve 709, pulling four child ropes 708 to slide, pulling the connecting block 706 and the second clamping block 705 to compress the third spring 707, and when the second clamping block 705 slides out of the inside of the limiting block 704, rotating the drill bit 701, and then disassembling the drill bit 701 from the bottom end of the installation sleeve 204; be convenient for install on arbitrary mounting structure 2 with boring ground structure 7, simple to operate, convenient to detach changes, makes graphene ground rod 1 better bore deep soil through boring ground structure 7, and then makes graphene ground rod 1's earthing effect better.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims

1. The graphene grounding device is characterized by comprising a graphene grounding rod (1), wherein a mounting structure (2) is arranged on the graphene grounding rod (1), a positioning structure (3) is arranged on the mounting structure (2), a stabilizing structure (4) is arranged on the mounting structure (2), a tightening structure (5) is arranged on the stabilizing structure (4), a sealing structure (6) is arranged on the tightening structure (5), an earth-boring structure (7) is arranged on the mounting structure (2), a buffer structure (8) is arranged on the mounting structure (2), and a sealing ring (9) is arranged on the mounting structure (2);

the installation structure (2) comprises a connecting mandrel (201), one end of a graphene grounding rod (1) is arranged at the connecting mandrel (201), the other end of the graphene grounding rod (1) is provided with a connecting outer rod (203), a mounting ring (202) is fixed on the graphene grounding rod (1) where the connecting mandrel (201) is located, an installation sleeve (204) is arranged at the end part of the graphene grounding rod (1) where the connecting outer rod (203) is located, the connecting mandrel (201) is in sliding connection with the connecting outer rod (203), a connecting ring (205) is arranged at the end part of the installation sleeve (204), the connecting ring (205) is in sliding connection with the inside of the mounting ring (202), four clamping grooves (206) of a circumferential array are arranged at the outer side of the connecting ring (205), four first clamping blocks (207) of the circumferential array are arranged inside the mounting ring (202), one side of each first clamping block (207) is provided with a first spring (208), one side of each first clamping block (207) is fixedly connected with one poking rod (209), one side of a mounting ring (202) at the top end of the deflector rod (209) is provided with a mounting cover (210), and the mounting cover (210) is in sliding connection with the mounting ring (202); the mounting structure (2) further comprises a guide rod (211), the guide rod (211) and the deflector rod (209) are vertically arranged, the deflector rod (209) is connected with the guide rod (211) in a sliding mode, and two ends of the guide rod (211) are fixed in the mounting ring (202);

the positioning structure (3) comprises positioning plates (301), four positioning plates (301) divide the area between the inner wall of the mounting sleeve (204) and the outer wall of the connecting outer rod (203) into four positioning grooves (302) in an equally dividing mode, four positioning blocks (303) are arranged on the mounting ring (202), the positioning blocks (303) are in sliding connection with the positioning grooves (302), limiting grooves (304) are formed in the positioning blocks (303), the limiting grooves (304) are in sliding connection with limiting columns (305), and the limiting columns (305) are fixed on the inner wall of the mounting sleeve (204);

the stabilizing structure (4) comprises a contact block (401), four contact blocks (401) in a circumferential array are arranged outside the mounting sleeve (204), the cross section of each contact block (401) is of a trapezoid structure, the contact blocks (401) are in sliding connection with the mounting sleeve (204), a push rod (402) is arranged on one side of each contact block (401), the push rod (402) is in sliding connection with the mounting sleeve (204), one end of each push rod (402) is in sliding connection with the inside of the corresponding positioning plate (301), a first roller (405) is arranged at the end of each push rod (402), the first roller (405) is in rolling connection with the inside of each sliding groove (408), each sliding groove (408) is arranged in the inside of each connecting rod (406), one end of each connecting rod (406) is in rolling connection with a rotary shaft (407), each rotary shaft (407) is fixed in the inside of the corresponding positioning plate (301), a second roller (409) is in rolling connection with the inside of each sliding groove (408), a sliding rod (410) is in rolling connection with the second roller (409), one end of each sliding rod (410) is in sliding connection with the sliding rod (203), and the sliding rod (410) is in the inside of the mounting hole (201) in a sliding connection hole (411); the stabilizing structure (4) further comprises a limiting rod (403), one end of the limiting rod (403) is fixed on one side of the contact block (401), the limiting rod (403) is connected with the mounting sleeve (204) in a sliding mode, the other end of the limiting rod (403) is arranged in the positioning plate (301), the limiting rod (403) is connected with the positioning plate (301) in a sliding mode, a second spring (404) is arranged on one side of the limiting rod (403), and the second spring (404) is fixed in the positioning plate (301);

the tightening structure (5) comprises a mounting disc (501), the mounting disc (501) is fixed on one side of a connecting rod (406), the mounting disc (501) is rotationally connected with a rotating shaft (407), a first connecting shaft (502) is arranged on the mounting disc (501), one end of a first connecting bar (503) is rotationally connected to the outside of the first connecting shaft (502), a second connecting shaft (504) is rotationally connected to the other end of the first connecting bar (503), the second connecting shaft (504) is fixed on the end part of a second connecting bar (505), the second connecting bar (505) is slidably connected to the inside of a positioning plate (301), the second connecting bar (505) is slidably connected with a mounting sleeve (204), a third connecting shaft (506) is arranged on the second connecting bar (505), one end of the third connecting bar (507) is rotationally connected to the outside of a fourth connecting shaft (508), the other end of the third connecting bar (507) is rotationally connected to the outside of the fourth connecting shaft (508), and the second connecting bar (505) is fixedly connected to the end part of the fourth connecting bar (509) and the end part of the connecting bar (509) is fixedly connected with the other end part of the connecting bar (509);

seal structure (6) are including supporting piece (601), the tip of second connecting strip (505) is located to piece (601), sliding connection between piece (601) and installation cover (204) support, the cross-section of piece (601) is trapezium structure, it has crowded ring (602) to support one side of piece (601) to contradict, sliding connection between crowded ring (602) and installation cover (204), the bottom of sealing washer (9) is located to crowded ring (602).

2. The graphene grounding device of claim 1, wherein: one end of the sealing ring (9) is fixed in the mounting sleeve (204), and the other end of the sealing ring (9) is connected in the mounting ring (202) in a sliding manner.

3. The graphene grounding device of claim 1, wherein: the earth boring structure (7) comprises a drill bit (701), four first fixing blocks (702) in circumferential arrays are fixed on the drill bit (701), the cross section of each first fixing block (702) is of an L-shaped structure, four second fixing blocks (703) which are arranged in parallel are arranged on the inner side of the drill bit (701) at the bottom end of each first fixing block (702), four limiting blocks (704) in circumferential arrays are arranged at the bottom end of each mounting sleeve (204), the limiting blocks (704) are in sliding connection with the first fixing blocks (702), the limiting blocks (704) are in sliding connection with the second fixing blocks (703), the bottom ends of the limiting blocks (704) are in sliding connection with second clamping blocks (705), one ends of the second clamping blocks (705) are in sliding connection with the inside of the drill bit (701), connecting blocks (706) are fixed on the end portions of the second clamping blocks (705), springs (706) are arranged between the limiting blocks (706) and the first side of each connecting block (706), one side of each connecting block (706) is fixedly connected with one side of each third spring (707), one end of each of the four sub ropes (708) is connected to one end of a parent rope (710), the parent rope (710) is slidably connected to the inside of the connecting sleeve (709), the other end of the parent rope (710) is connected to the connecting cover (711), and the connecting cover (711) is slidably connected to the outside of the drill bit (701).

4. The graphene grounding device of claim 1, wherein: the buffer structure (8) comprises a buffer ring (801), one side of the buffer ring (801) is installed on the installation sleeve (204), the other side of the buffer ring (801) is attached to the installation ring (202), one side of a buffer pad (802) is attached to the positioning plate (301), and the other side of the buffer pad (802) is fixed to the installation ring (202).