CN221262730U - Fast-assembling formula ion earthing pole - Google Patents

Abstract

The utility model discloses a quick-assembled ion grounding electrode, and relates to the technical field of grounding equipment and related accessories thereof. The utility model comprises a main grounding electrode, wherein an extension grounding electrode is arranged at the bottom of the main grounding electrode, a bottom grounding electrode is arranged at the bottom of the extension grounding electrode, and first sealing gaskets are adhered to two sides of the inner walls of the bottoms of the main grounding electrode and the extension grounding electrode; the butt joint assembly comprises an I-shaped ring and a clamping ring, through grooves are formed in two sides of the bottom of the outer wall of the I-shaped ring, the clamping ring is sleeved above the outer wall of the I-shaped ring, and the first spring is located between the clamping ring and the top of the I-shaped ring; the sealing component comprises a second fixing plate and a telescopic rod, and a third spring is sleeved outside the outer wall of the telescopic rod. According to the utility model, through the butt joint assembly and the sealing assembly, a worker can conveniently and rapidly complete the installation and the disassembly of the main grounding electrode, the extension grounding electrode and the grounding electrode, the working efficiency is high, and two groups of second sealing gaskets can be rapidly clamped at the two sides of the first sealing gasket, so that the sealing effect is improved.

Description

A quick-install ion grounding electrode

Technical Field

The utility model belongs to the technical field of grounding equipment and related accessories, in particular to a quick-install ion grounding electrode.

Background technique

The ion grounding electrode is a device with excellent conductive properties. It can play an effective role in lightning protection in buildings, and is also widely used in equipment grounds, AC and DC working places, and safety protection places in the communications industry, power systems, military facilities, transportation systems and other industries. Compared with traditional ion grounding electrodes, the quick-install ion grounding electrode can be assembled and changed in length according to needs at the construction site, which is also convenient for subsequent maintenance.

After searching, the publication number CN218300283U and the application date 2022.09.19 discloses a quick-install ion grounding electrode, wherein a detachable grounding electrode is installed at the bottom of the main grounding electrode, and a bottom grounding electrode is installed at the bottom of the detachable grounding electrode. Connecting rods are symmetrically installed on both sides of the top of the detachable grounding electrode and the bottom grounding electrode, and fixed seats are installed at the positions of the connecting rods at the bottoms of the main grounding electrode and the detachable grounding electrode. A conductive wire is installed on the outside of the main grounding electrode, and a copper busbar is installed on the outer end of the conductive wire. A top cover is installed on the upper part of the main grounding electrode, and a bottom cover is installed on the bottom of the bottom grounding electrode. Water conduction holes are equidistantly opened inside the bottom cover, and a quick-release structure is arranged between the connecting rod and the fixed seat.

However, it still has the following disadvantages in actual use:

1. The above-mentioned quick-install ion grounding electrode is disassembled and connected by pulling the pull button to make the locking rod cooperate with the locking hole. However, since this method is pulled outward, it is impossible for a single person to complete the installation, resulting in low efficiency of disassembly and installation, and time-consuming and labor-intensive.

2. The above-mentioned quick-install ion grounding electrode enhances the sealing effect through the sealing ring and the sealing sleeve when in use, and the sealing ring needs to be stuck in the center position of the sealing sleeve. Due to the large friction between the sealing ring and the sealing sleeve, the resistance is increased during installation and removal, which is time-consuming and labor-intensive, and the installation and removal cannot be completed quickly.

Utility Model Content

The purpose of the utility model is to provide a quick-install ion grounding electrode, which can facilitate the staff to quickly complete the installation and disassembly of the main grounding electrode, the extended grounding electrode and the ground grounding electrode through the docking assembly and the sealing assembly, saving time and improving work efficiency. It can also quickly clamp the two sets of second sealing pads on the outer wall of the movable plate on both sides of the first sealing pad, which is convenient for the staff to quickly install and improve the sealing effect.

In order to solve the above technical problems, the utility model is achieved through the following technical solutions:

The utility model discloses a quick-install ion grounding electrode, comprising a main grounding electrode, an extended grounding electrode is installed at the bottom of the main grounding electrode, a bottom grounding electrode is installed at the bottom of the extended grounding electrode, first sealing pads are bonded on both sides of the bottom inner walls of the main grounding electrode and the extended grounding electrode, docking components are arranged at the bottom of the outer walls of the main grounding electrode and the extended grounding electrode, and sealing components are arranged at the top of the inner walls of the extended grounding electrode and the bottom grounding electrode; the docking components comprise an I-shaped ring and a clamping ring, through grooves are arranged on both sides of the bottom of the outer wall of the I-shaped ring, a clamping ring is sleeved on the upper part of the outer wall of the I-shaped ring, and the outer wall of the I-shaped ring is A first spring is sleeved on the top, a pressure ring is welded on the bottom end of the inner wall of the clamping ring, and the first spring is located between the pressure ring and the top of the I-shaped ring; the sealing assembly includes a second fixed plate and a telescopic rod, and telescopic rods are installed at the center positions of the front and rear end faces of the second fixed plate, and a third spring is sleeved on the outer side of the outer wall of the telescopic rod. The cross-section of the I-shaped ring is in the shape of an "I", and the bottom edge of the pressure ring is inclined to facilitate squeezing and pushing the second protrusion, which drives the pressure ring to move under the action of the elastic properties of the first spring, and the outer wall of the second fixed plate is fixed on the inner wall of the extended grounding electrode or the bottom grounding electrode.

Furthermore, a top cover is installed on the top of the main grounding electrode, a bottom cover is installed on the bottom of the bottom grounding electrode, a conductive mechanism is arranged on one side of the outer wall of the main grounding electrode, a plurality of drainage holes are opened on the bottom cover, and the conductive mechanism includes a conductive wire and a copper busbar.

Furthermore, a first fixing plate is fixedly connected to the inner side of the inner wall of the through groove, and a connecting rod is installed in the through hole on the inner wall of the first fixing plate.

Furthermore, one end of the connecting rod passes through a through hole on one end surface of the first fixed plate and is connected to the first protrusion, and the other end of the connecting rod passes through a through hole on the other end surface of the first fixed plate and is connected to the second protrusion. The first protrusion and the second protrusion are connected by the connecting rod to play a connecting role.

Furthermore, a second spring is sleeved on the outer side of the outer wall of the connecting rod, and the second spring is located between the first fixing plate and the second protrusion. The elastic performance of the second spring drives the first protrusion to move, and the outer walls of the first protrusion and the second protrusion are both semicircular heads.

Furthermore, a movable plate is installed at the telescopic end of the telescopic rod, and a pressure block is welded at the bottom of the outer wall of the movable plate. The other end of the pressure block passes through the through hole on the inner wall of the extended grounding electrode or the bottom grounding electrode, and the movable plate is driven to move under the elastic performance of the third spring.

Furthermore, second sealing gaskets are bonded to the top of the outer wall of the movable plate from top to bottom in sequence, and adjacent second sealing gaskets are located outside the first sealing gaskets. Two groups of second sealing gaskets are provided, and can cooperate with the first sealing gaskets to play a sealing role.

The utility model has the following beneficial effects:

1. The utility model provides a docking assembly, and the elastic performance of the first spring drives the clamping ring and the pressure ring on its inner wall to move, so as to achieve the suppression and release of the second protrusion, and drives the first protrusion to move under the elastic performance of the second spring, thereby achieving the limiting effect of the clamping groove on the outer wall of the extended grounding electrode and the bottom grounding electrode, so that the staff can quickly complete the installation and disassembly of the main grounding electrode, the extended grounding electrode and the ground grounding electrode, saving time and high work efficiency, and solving the problem that the above-mentioned quick-install ion grounding electrode is used to pull the pull button to make the locking rod and the locking hole cooperate to complete the disassembly, and this method is pulled outward, so a single person cannot complete the installation, resulting in low efficiency of disassembly and installation, and time-consuming and labor-intensive problems.

2. The utility model provides a sealing component, and drives the movable plate to move under the elastic performance of the third spring, so that the two sets of second sealing pads on the outer wall of the movable plate can be quickly clamped on both sides of the first sealing pad, which is convenient for the staff to quickly install and improve the sealing effect. It solves the problem that the above-mentioned quick-install ion grounding electrode enhances the sealing effect through the sealing ring and the sealing sleeve when in use, and the sealing ring needs to be clamped in the center position of the sealing sleeve. Due to the large friction between the sealing ring and the sealing sleeve, the resistance is increased during installation and disassembly, which is time-consuming and labor-intensive, and the installation and disassembly cannot be completed quickly.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the technical solutions of the embodiments of the utility model, the drawings required for describing the embodiments are briefly introduced below. Obviously, the drawings described below are only some embodiments of the utility model. For ordinary technicians in this field, other drawings can be obtained based on these drawings without creative work.

FIG1 is a schematic diagram of the structure of a quick-install ion grounding electrode;

FIG2 is a cross-sectional view of a quick-install ion grounding electrode;

FIG3 is a disassembled view of the main ground electrode, the extended ground electrode and the bottom ground electrode;

FIG4 is a disassembled view of the docking assembly;

FIG. 5 is a structural diagram of the sealing assembly.

In the accompanying drawings, the components represented by the reference numerals are listed as follows:

1. Main grounding electrode; 101. Extended grounding electrode; 102. Bottom grounding electrode; 103. Top cover; 104. Bottom cover; 105. First sealing gasket; 106. Conductive mechanism; 2. Docking assembly; 201. I-shaped ring; 202. Through groove; 203. Clamping ring; 204. Pressing ring; 205. First spring; 206. First fixed plate; 207. Connecting rod; 208. First protrusion; 209. Second protrusion; 2010. Second spring; 3. Sealing assembly; 301. Second fixed plate; 302. Telescopic rod; 303. Third spring; 304. Moving plate; 305. Pressing block; 306. Second sealing gasket.

Detailed ways

The technical solutions in the embodiments of the present invention will be described clearly and completely below in conjunction with the accompanying drawings in the embodiments of the present invention.

Please refer to Figures 1 to 5. The utility model is a quick-install ion grounding electrode, including a main grounding electrode 1, an extended grounding electrode 101 is installed at the bottom of the main grounding electrode 1, a bottom grounding electrode 102 is installed at the bottom of the extended grounding electrode 101, first sealing pads 105 are bonded on both sides of the bottom inner wall of the main grounding electrode 1 and the extended grounding electrode 101, a docking assembly 2 is provided at the bottom of the outer wall of the main grounding electrode 1 and the extended grounding electrode 101, and a sealing assembly 3 is provided at the top of the inner wall of the extended grounding electrode 101 and the bottom grounding electrode 102; the docking assembly 2 includes an I-shaped ring 201 and a snap ring 203, through grooves 202 are opened on both sides of the bottom of the outer wall of the I-shaped ring 201, a snap ring 203 is sleeved on the upper part of the outer wall of the I-shaped ring 201, and the outer wall of the I-shaped ring 201 is provided with a A first spring 205 is sleeved on the top, a pressure ring 204 is welded to the bottom end of the inner wall of the retaining ring 203, and the first spring 205 is located between the pressure ring 204 and the top of the I-shaped ring 201; the sealing assembly 3 includes a second fixed plate 301 and a telescopic rod 302, and the telescopic rod 302 is installed at the center position of the front and rear end faces of the second fixed plate 301, and a third spring 303 is sleeved on the outer side of the outer wall of the telescopic rod 302. The cross-section of the I-shaped ring 201 is in the shape of an "I", and the bottom edge of the pressure ring 204 is inclined to facilitate squeezing and pushing the second protrusion 209, which drives the pressure ring 204 to move under the action of the elastic performance of the first spring 205, and the outer wall of the second fixed plate 301 is fixed on the inner wall of the extended grounding electrode 101 or the bottom grounding electrode 102.

As shown in Figures 1 to 3, a top cover 103 is installed on the top of the main grounding electrode 1, a bottom cover 104 is installed on the bottom of the bottom grounding electrode 102, a conductive mechanism 106 is provided on one side of the outer wall of the main grounding electrode 1, and a plurality of drainage holes are opened on the bottom cover 104. The conductive mechanism 106 includes a conductive wire and a copper busbar.

As shown in Figures 3 to 4, a first fixing plate 206 is fixedly connected to the inner side of the inner wall of the through groove 202, and a connecting rod 207 is installed in the through hole on the inner wall of the first fixing plate 206. One end of the connecting rod 207 passes through the through hole on the end surface of one side of the first fixing plate 206 and is connected to the first protrusion 208, and the other end of the connecting rod 207 passes through the through hole on the end surface of the other side of the first fixing plate 206 and is connected to the second protrusion 209. The first protrusion 208 and the second protrusion 209 are connected by the connecting rod 207 to play a connecting role. A second spring 2010 is sleeved on the outer side of the outer wall of the connecting rod 207. The second spring 2010 is located between the first fixing plate 206 and the second protrusion 209. The first protrusion 208 is driven to move under the action of the elastic performance of the second spring 2010, and the outer walls of the first protrusion 208 and the second protrusion 209 are both semicircular heads.

As shown in Figures 3 and 5, a movable plate 304 is installed at the telescopic end of the telescopic rod 302, and a pressure block 305 is welded at the bottom of the outer wall of the movable plate 304. The other end of the pressure block 305 passes through the through hole on the inner wall of the extended grounding electrode 101 or the bottom grounding electrode 102, and the movable plate 304 is driven to move under the elastic performance of the third spring 303. Second sealing gaskets 306 are bonded to the top of the outer wall of the movable plate 304 from top to bottom in sequence, and adjacent second sealing gaskets 306 are located on the outside of the first sealing gasket 105. Two groups of second sealing gaskets 306 are provided, and can cooperate with the first sealing gasket 105 to play a sealing role.

A specific application of this embodiment is: when the staff uses the ion grounding electrode, it is necessary to first dock and install the assembled ion grounding electrode. First, the staff holds the main grounding electrode 1 with one hand and pushes the clamping ring 203 upward. At this time, the clamping ring 203 is forced to move upward and drives the pressure ring 204 to move upward. The upward movement of the pressure ring 204 squeezes the first spring 205, so that the external force of the second spring 2010, which is always in a compressed state, disappears, and then the second protrusion 209 can be ejected out of the through groove 202 under the elastic performance of the second spring 2010. The second protrusion 209 is connected to the first protrusion 208 through the connecting rod 207. Therefore, when the second protrusion 209 moves, the first protrusion 208 is driven to move under the action of the connecting rod 207, and the first protrusion 208 is moved into the through groove 202. Then, the top of the extended grounding electrode 101 is docked with the bottom of the main grounding electrode 1, and then the force on the clamping ring 203 is stopped. At this time, the clamping ring 203 is rebounded by the pressure ring 204 under the elastic performance of the first spring 205, and the pressure ring 204 is used to re-squeeze the second protrusion 209 located on the outside, and the second protrusion 209 is forced to move into the through slot 202 again, and under the action of the connecting rod 207, the first protrusion 208 is pushed out again, and the second spring 2010 is squeezed, so that the first protrusion 208 can be inserted into the slot on the outer wall of the extended grounding electrode 101, and it plays a role of limiting, completing the docking operation. When disassembling, the above operation can be repeated in the same way, and the bottom grounding electrode 102 can be docked at the bottom of the extended grounding electrode 101 in the same way. While performing the above operation, hold the extended grounding electrode 101 with the other hand, and press the front and rear pressing blocks 305 inward, and the pressing blocks The force 305 pushes the movable plate 304 to move inward under the limiting action of the telescopic rod 302 and squeezes the third spring 303. Then, as the movable plates 304 at the front and rear move inward, the movable plate 304 can be inserted into the main grounding electrode 1. Then the force on the pressing block 305 is stopped. At this time, the movable plate 304 will be ejected again under the elastic performance of the third spring 303, and the two second sealing pads 306 on the top of its outer wall can be stuck on both sides of the first sealing pad 105 on the inner wall of the main grounding electrode 1, thereby facilitating the installation of the staff and improving the sealing effect.

The above are only preferred embodiments of the present invention and do not limit the present invention. Any modification to the technical solutions recorded in the aforementioned embodiments and any equivalent replacement of some of the technical features therein, any modification, equivalent replacement, and improvement made are all within the protection scope of the present invention.

Claims (7)

1. The utility model provides a fast-assembling formula ion earthing pole, includes main earthing pole (1), its characterized in that: an extension grounding electrode (101) is arranged at the bottom of the main grounding electrode (1), a bottom grounding electrode (102) is arranged at the bottom of the extension grounding electrode (101), first sealing gaskets (105) are adhered to two sides of the inner wall of the bottom of the main grounding electrode (1) and the two sides of the inner wall of the bottom of the extension grounding electrode (101), a butt joint assembly (2) is arranged at the bottoms of the outer walls of the main grounding electrode (1) and the extension grounding electrode (101), and sealing assemblies (3) are arranged at the top ends of the inner parts of the extension grounding electrode (101) and the bottom grounding electrode (102);

The butt joint assembly (2) comprises an I-shaped ring (201) and a clamping ring (203), through grooves (202) are formed in two sides of the bottom of the outer wall of the I-shaped ring (201), the clamping ring (203) is sleeved above the outer wall of the I-shaped ring (201), a first spring (205) is sleeved at the top of the outer wall of the I-shaped ring (201), a pressing ring (204) is welded at the bottom end of the inner wall of the clamping ring (203), and the first spring (205) is located between the pressing ring (204) and the top of the I-shaped ring (201);

The sealing assembly (3) comprises a second fixing plate (301) and a telescopic rod (302), the telescopic rod (302) is installed at the center positions of the front end face and the rear end face of the second fixing plate (301), and a third spring (303) is sleeved on the outer side of the outer wall of the telescopic rod (302).

2. The quick-assembly ion grounding electrode as defined in claim 1, wherein: the top cover (103) is installed at the top of main earthing pole (1), bottom lid (104) are installed to the bottom of bottom earthing pole (102), outer wall one side of main earthing pole (1) is provided with conductive mechanism (106).

3. The quick-assembly ion grounding electrode as defined in claim 1, wherein: the inner side of the inner wall of the through groove (202) is fixedly connected with a first fixing plate (206), and a connecting rod (207) is arranged in a through hole on the inner wall of the first fixing plate (206).

4. A quick-fit ion grounding electrode as defined in claim 3, wherein: one end of the connecting rod (207) penetrates through a through hole in the end face of one side of the first fixing plate (206) to be connected with the first bump (208), and the other end of the connecting rod (207) penetrates through a through hole in the end face of the other side of the first fixing plate (206) to be connected with the second bump (209).

5. The quick-fit ion grounding electrode as defined in claim 4, wherein: a second spring (2010) is sleeved outside the outer wall of the connecting rod (207), and the second spring (2010) is located between the first fixing plate (206) and the second protruding block (209).

6. The quick-assembly ion grounding electrode as defined in claim 1, wherein: the telescopic end of the telescopic rod (302) is provided with a movable plate (304), the bottom of the outer side wall of the movable plate (304) is welded with a pressing block (305), and the other end of the pressing block (305) penetrates through the through hole on the inner wall of the extended grounding electrode (101) or the bottom grounding electrode (102).

7. The quick-fit ion grounding electrode as defined in claim 6, wherein: and a second sealing gasket (306) is sequentially bonded to the top of the outer side wall of the moving plate (304) from top to bottom, and the adjacent second sealing gaskets (306) are all positioned on the outer sides of the first sealing gaskets (105).