Grounding installation structure, grounding protection device, and grounding equipment

Abstract

This application discloses a grounding installation structure, a grounding protection device, and a grounding equipment, relating to the field of grounding protection technology. The grounding installation structure is used to install on a structure to be grounded and includes an installation component and a paint-breaking conductive component. The installation component has a threaded body for threaded engagement with a pre-drilled hole in the structure to be grounded, and the installation component is rotatable and adjustable. The paint-breaking conductive component is located on the installation component, and has a paint-breaking conductive body on the side facing the structure to be grounded. The paint-breaking conductive component can rotate under the action of the installation component, and the paint-breaking conductive body breaks through the paint surface of the structure to be grounded, connecting to the conductive part located in the inner layer of the paint surface of the structure to be grounded. The above-mentioned grounding installation structure, through the cooperation of the installation component and the paint-breaking conductive component, achieves efficient and convenient grounding without damaging the overall anti-corrosion coating, solving the problems of complex procedures, low efficiency, and insufficient grounding reliability caused by masking and applying conductive paint in the prior art.

Description

Technical Field

[0001] This application relates to the field of grounding protection technology, and in particular to a grounding installation structure, grounding protection device, and grounding equipment. Background Technology

[0002] In the high and low voltage power storage industry, grounding protection is an essential design feature for the safe operation of products. Especially in special environments such as those with atmospheric pollution and coastal areas, the corrosion resistance of the product surface is crucial.

[0003] Traditional grounding protection methods typically require breaking the entire anti-corrosion coating on the surface to achieve conductivity; however, this approach conflicts significantly with anti-corrosion requirements. Currently, a common solution on the market is to use a masking process, where the area requiring grounding is masked before powder coating, and then conductive paint is applied. However, this method has many problems, such as the inconvenience of removing the sticker, low efficiency of manual application, and difficulty in automating the entire process, which is not conducive to mass production. Utility Model Content

[0004] The purpose of this application is to provide a grounding installation structure that, through the cooperation of the installation components and the paint-breaking conductive parts, achieves efficient and convenient grounding conduction without damaging the overall anti-corrosion coating. This solves the problems of complex procedures, low efficiency, and insufficient grounding reliability caused by masking and applying conductive paint in the prior art. Another purpose of this application is to provide a grounding protection device and grounding equipment.

[0005] To achieve the above objectives, this application provides a grounding installation structure for installation on a structure to be grounded, comprising:

[0006] The mounting assembly includes a threaded body for engaging with a pre-drilled hole in the structure to be grounded, and the mounting assembly is rotatable and adjustable.

[0007] A paint-breaking conductive component is provided on the mounting assembly. The paint-breaking conductive component has a paint-breaking conductive body on the side facing the structure to be grounded. The paint-breaking conductive component can rotate under the action of the mounting assembly. The paint-breaking conductive body breaks through the paint surface of the structure to be grounded and conducts electricity with the conductive part located in the inner layer of the paint surface of the structure to be grounded.

[0008] In some embodiments, the installation component includes:

[0009] The fixed mounting component is provided with the threaded body, and the paint-breaking conductive component can rotate under the rotation of the fixed mounting component;

[0010] An adjustment component is installed and movably mounted on the fixed mounting component. The adjustment component and the fixed mounting component have a first sealing position. After the adjustment component is movable, it forms a second sealing position with the structure to be grounded. The paint-breaking conductive component is located in the sealed space formed by the first sealing position and the second sealing position.

[0011] In some embodiments, the grounding mounting structure further includes:

[0012] A first seal is disposed on the mounting adjustment member, the first seal being used to form a seal between the mounting adjustment member and the fixed mounting member at a first sealing position; and / or,

[0013] A second seal is provided on the mounting adjustment member, and the second seal is used to form a seal between the mounting adjustment member and the structure to be grounded at a second sealing position.

[0014] In some embodiments, the grounding mounting structure further includes:

[0015] Solid gel is provided on the mounting adjustment component. The solid gel can be squeezed and deformed by the reaction force of the paint breaking conductor under the action of the mounting adjustment component, and the gel is released to cover the scratched area of ​​the paint surface of the structure to be grounded.

[0016] The flow area of ​​the gel is confined within the sealed space formed by the first sealing position and the second sealing position.

[0017] In some embodiments, the fixing component includes a threaded body and a connecting body coaxially arranged, wherein the diameter of the connecting body is larger than the diameter of the threaded body;

[0018] In the axial direction of the fixed mounting component, the side of the connecting body facing the threaded body is provided with a first pushing surface, which is used to drive the paint-breaking conductive component to rotate under the action of friction.

[0019] In some embodiments, the mounting adjustment member includes a threaded hole body and a mounting hole body coaxially disposed thereon, wherein the diameter of the mounting hole body is larger than the diameter of the threaded hole body;

[0020] The connecting body is threadedly engaged with the threaded hole body;

[0021] A space for storing the solid gel is formed between the connector and the mounting hole;

[0022] In the axial direction of the mounting adjustment component, a second pushing surface is provided on the side of the threaded hole facing the mounting hole. The second pushing surface is used to drive the solid gel to be squeezed and deformed by the reaction force of the paint breaking conductor.

[0023] In some embodiments, the solid gel can form a conductor within the sealed space that enables the conductive portion of the structure to be grounded and the broken paint conductive element to conduct electricity; or,

[0024] The solid gel can form a conductive body within the sealed space that enables the conductive parts of the structure to be grounded, the broken paint conductive parts, and the fixed mounting parts to conduct electricity; or,

[0025] The solid gel can form a conductive material in the sealed space that enables the paint-damaged conductive component and the fixed installation component to conduct electricity.

[0026] In some embodiments, the interior of the connector includes an operating hole and a connecting hole arranged coaxially. The operating hole is used to cooperate with an operating tool to rotate the fixed mounting component, and the connecting hole is used to connect to a grounding structure to achieve conductivity between the fixed mounting component and the grounding structure.

[0027] This application also provides a grounding protection device, installed on a structure to be grounded, including a grounding structure and the aforementioned grounding installation structure, wherein the grounding installation structure is disposed on the structure to be grounded, and the grounding structure is disposed on the grounding installation structure.

[0028] This application also provides a grounding device, including a structure to be grounded and the above-mentioned grounding protection device, wherein the grounding protection device is installed on the structure to be grounded.

[0029] Compared to the aforementioned background technology, the grounding installation structure provided in this application is used to install on a structure to be grounded. The grounding installation structure mainly includes an installation component and a paint-breaking conductive component. The installation component is provided with a threaded body, which is used to engage with the pre-drilled hole of the structure to be grounded. The installation component can be rotated and adjusted. The paint-breaking conductive component is provided on the installation component. The side of the paint-breaking conductive component facing the structure to be grounded has a paint-breaking conductive body. The paint-breaking conductive component can rotate under the action of the installation component. The paint-breaking conductive body breaks through the paint surface of the structure to be grounded and conducts electricity with the conductive part located in the inner layer of the paint surface of the structure to be grounded.

[0030] In the high and low voltage power storage industry, grounding protection is a crucial element in ensuring the safe operation of equipment. However, traditional grounding protection methods often require damaging the overall anti-corrosion coating on the equipment surface. For example, this involves masking the areas requiring grounding before powder coating and then applying conductive paint. While this method achieves grounding, it has several problems: First, the masking and conductive paint application processes are complex, require manual operation, are inefficient, and are difficult to automate. Second, manual application of conductive paint can easily lead to uneven coating thickness, creating pits and affecting the reliability of grounding. Furthermore, the masking process is prone to omissions, resulting in on-site rework and increasing production and time costs.

[0031] To address the aforementioned problems, this application provides an innovative grounding installation structure. This grounding installation structure mainly includes an installation component and a paint-breaking conductive element. The installation component has a threaded body that engages with a pre-drilled hole in the structure to be grounded, allowing the installation component to be securely installed on the structure through rotational adjustment. This threaded engagement design not only improves the ease of installation but also ensures a stable connection between the grounding installation structure and the structure to be grounded.

[0032] A paint-breaking conductive element is located on the mounting assembly, with a paint-breaking conductive body on the side facing the structure to be grounded. Driven by the movement of the mounting assembly, the paint-breaking conductive element rotates, breaking through the paint surface of the structure to be grounded, thus directly establishing conductivity with the conductive portion located within the paint surface. This design cleverly avoids the complex procedures of pre-masking and subsequent application of conductive paint required in traditional methods, achieving grounding conductivity directly during installation and significantly improving grounding efficiency.

[0033] Regarding the application scenarios of grounding installation structures, as an interface structure installed on the structure to be grounded, the grounding installation structure provides the conditions for external conductive grounding. By further installing a conductive grounding structure, the structure to be grounded can achieve reliable grounding. This grounding installation structure not only simplifies the grounding process but also improves the reliability of grounding. At the same time, due to its simple installation process, it can effectively reduce errors from manual operation, lower production costs, and improve production efficiency.

[0034] Based on the above structural and process descriptions, it can be seen that the grounding installation structure has at least the following beneficial effects: Through the cooperation of the installation components and the paint-breaking conductive parts, the grounding installation structure achieves efficient and convenient grounding without damaging the overall anti-corrosion coating, solving the problems of complex procedures, low efficiency, and insufficient grounding reliability caused by masking and applying conductive paint in the prior art. Attached Figure Description

[0035] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only embodiments of this application. For those skilled in the art, other drawings can be obtained based on the provided drawings without creative effort.

[0036] Figure 1 This is a schematic diagram of the grounding installation structure and the structure to be grounded provided in the embodiments of this application;

[0037] Figure 2 A schematic diagram of the grounding device provided in the embodiments of this application;

[0038] Figure 3 This is a schematic diagram of the grounding installation structure and grounding structure provided in the embodiments of this application;

[0039] Figure 4 A schematic diagram of the grounding installation structure, grounding structure, and structure to be grounded provided in the embodiments of this application;

[0040] Figure 5 An exploded view of the grounding protection device and the structure to be grounded provided in the embodiments of this application;

[0041] Figure 6 A schematic diagram of the paint-breaking conductive component provided in the embodiments of this application;

[0042] Figure 7 A schematic diagram of the fixing and mounting component provided in the embodiments of this application;

[0043] Figure 8 A schematic diagram of the installation adjustment component provided in the embodiments of this application;

[0044] Figure 9 This is a schematic diagram of the installation adjustment component, the first seal, the second seal, and the solid gel provided in the embodiments of this application.

[0045] in:

[0046] Grounding equipment 10000

[0047] Grounding protection device 1000

[0048] Grounding installation structure 100

[0049] Install component 1

[0050] Fixed mounting component 101, threaded body 1011, connecting body 1012, operating hole 10121, connecting hole 10122, first pushing surface 1013, first friction body 1014.

[0051] Mounting adjustment component 102, threaded hole body 1021, mounting hole body 1022, second pushing surface 1023.

[0052] Paint-breaking conductive component 2, paint-breaking conductive body 201, second friction body 202

[0053] First sealing element 3

[0054] Second seal 4

[0055] Solid gel 5

[0056] 200m structure to be grounded

[0057] Preparing hole 6

[0058] Cutting the trajectory 7

[0059] Grounding structure 300

[0060] Grounding screw 8

[0061] Grounding terminal harness 9. Detailed Implementation

[0062] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.

[0063] To enable those skilled in the art to better understand the present application, the present application will be further described in detail below with reference to the accompanying drawings and specific embodiments.

[0064] Please refer to Figure 1 , Figure 1 This is a schematic diagram of the grounding installation structure and the structure to be grounded provided in the embodiments of this application.

[0065] like Figure 1 The diagram illustrates the installation relationship between the grounding mounting structure 100 and the structure to be grounded 200 in the grounding protection device 1000. The grounding mounting structure 100 is installed on the structure to be grounded 200 and serves as an interface structure, connecting the structure to be grounded 200 to the external ground.

[0066] Please refer to Figure 2 , Figure 2 This is a schematic diagram of a grounding device provided in an embodiment of this application.

[0067] like Figure 2 The diagram illustrates the installation relationship between the grounding protection device 1000 and the structure 200 to be grounded in the grounding equipment 10000. (In conjunction with...) Figure 1 As can be seen, the grounding installation structure 100 is installed on the basis of the structure to be grounded 200, and the grounding structure 300 is connected by the formed interface structure. The grounding structure 300 is grounded, and at the same time, the grounding structure 300 is connected to the grounding installation structure 100, so the structure to be grounded 200 is grounded.

[0068] Please refer to Figure 3 , Figure 3 This is a schematic diagram of the grounding installation structure and grounding structure provided in the embodiments of this application.

[0069] like Figure 3As shown, the exploded structure of the grounding installation structure 100 and the grounding structure 300 is illustrated. The exploded state is the opposite of the connected state of the grounding installation structure 100 and the grounding structure 300. Therefore, the connected structure of the grounding installation structure 100 and the grounding structure 300 can also be understood.

[0070] Please refer to Figure 4 , Figure 4 This is a schematic diagram of the grounding installation structure, grounding structure, and structure to be grounded provided in the embodiments of this application.

[0071] like Figure 4 As shown, the connection structure of the grounding installation structure 100, the structure to be grounded 200 and the grounding structure 300 is illustrated. The grounding structure 300 is connected to the ground (not shown in the figure), and at the same time, the grounding structure 300 is connected to the grounding installation structure 100. Therefore, the structure to be grounded 200 is connected to the ground.

[0072] Please continue to refer to this. Figures 1 to 4 and refer to Figures 5 to 7 ,in, Figure 5 This is an exploded view of the grounding protection device and the structure to be grounded provided in the embodiments of this application. Figure 6 This is a schematic diagram of the paint-breaking conductive component provided in an embodiment of this application. Figure 7 This is a schematic diagram of the fixing device provided in the embodiment of this application.

[0073] In a first specific embodiment, the grounding installation structure 100 provided in this application is used to be installed on the structure 200 to be grounded. The grounding installation structure 100 mainly includes an installation component 1 and a paint-breaking conductive component 2. The installation component 1 is provided with a threaded body 1011, which is used to thread into the pre-drilled hole 6 of the structure 200 to be grounded. The installation component 1 can be rotated and adjusted. The paint-breaking conductive component 2 is provided on the installation component 1. The side of the paint-breaking conductive component 2 facing the structure 200 to be grounded is provided with a paint-breaking conductive body 201. The paint-breaking conductive component 2 can rotate under the action of the installation component 1. The paint-breaking conductive body 201 breaks through the paint surface of the structure 200 to be grounded and conducts to the conductive part located in the inner layer of the paint surface of the structure 200 to be grounded.

[0074] like Figure 5 As shown, the scratch trajectory 7 is the mark formed by the paint-breaking conductor 201 scratching the paint surface of the structure to be grounded 200.

[0075] In the high and low voltage power storage industry, grounding protection is a crucial element in ensuring the safe operation of equipment. However, traditional grounding protection methods often require damaging the overall anti-corrosion coating on the equipment surface. For example, this involves masking the areas requiring grounding before powder coating and then applying conductive paint. While this method achieves grounding, it has several problems: First, the masking and conductive paint application processes are complex, require manual operation, are inefficient, and are difficult to automate. Second, manual application of conductive paint can easily lead to uneven coating thickness, creating pits and affecting the reliability of grounding. Furthermore, the masking process is prone to omissions, resulting in on-site rework and increasing production and time costs.

[0076] To address the aforementioned problems, this application provides an innovative grounding installation structure 100. This grounding installation structure 100 mainly includes an installation component 1 and a paint-breaking conductive component 2. The installation component 1 has a threaded body 1011, which threadedly engages with a pre-drilled hole 6 in the structure to be grounded 200, allowing the installation component 1 to be securely installed on the structure to be grounded 200 through rotational adjustment. This threaded engagement design not only improves the ease of installation but also ensures a stable connection between the grounding installation structure 100 and the structure to be grounded 200.

[0077] The paint-breaking conductive component 2 is located on the mounting assembly 1, and a paint-breaking conductive body 201 is provided on the side facing the structure 200 to be grounded. Driven by the movement of the mounting assembly 1, the paint-breaking conductive component 2 can rotate, breaking through the paint surface of the structure 200 to be grounded via the paint-breaking conductive body 201, thereby directly establishing a connection with the conductive portion located within the paint surface. This design cleverly avoids the complex procedures of pre-masking and subsequent application of conductive paint required in traditional methods, achieving grounding connection directly during installation and greatly improving grounding efficiency.

[0078] Regarding the application scenarios of the grounding installation structure 100, as an interface structure installed on the structure to be grounded 200, the grounding installation structure 100 provides the structure to be grounded 200 with external conductive grounding conditions. By further installing the conductive grounding structure 300, the structure to be grounded 200 can achieve reliable grounding. This grounding installation structure 100 not only simplifies the grounding process but also improves the reliability of grounding. At the same time, due to its simple installation process, it can effectively reduce errors from manual operation, lower production costs, and improve production efficiency.

[0079] Based on the above structural and process descriptions, it can be seen that the grounding installation structure 100 has at least the following beneficial effects: the grounding installation structure 100, through the cooperation of the installation component 1 and the paint-breaking conductive component 2, achieves efficient and convenient grounding conduction without damaging the overall anti-corrosion coating, solving the problems of complex procedures, low efficiency and insufficient grounding reliability caused by masking and applying conductive paint in the prior art.

[0080] It should be noted that this embodiment does not limit the way the mounting component 1 acts on the paint-breaking conductor 2. For example, the paint-breaking conductor 2 can be movably mounted on the mounting component 1, and the paint-breaking conductor 2 and the mounting component 1 can move in unison using friction or other specific locking conditions. The paint-breaking conductor 2 can also be fixedly mounted on the mounting component 1. Preferably, the paint-breaking conductor 2 is movably mounted, which facilitates processing, assembly, and replacement.

[0081] Please continue to refer to this. Figure 6 The paint-breaking conductor 2 has two sides, front and back. After the paint-breaking conductor 2 is installed on the mounting component 1, the first side of the paint-breaking conductor 2 faces the structure 200 to be grounded, and the second side of the paint-breaking conductor 2 faces away from the structure 200 to be grounded. The second side of the paint-breaking conductor 2 faces the mounting component 1.

[0082] In some cases, the first surface of the paint-breaking conductive component 2 is provided with a paint-breaking conductive body 201, and the second surface of the paint-breaking conductive component 2 is provided with a second friction body 202. Corresponding to the second friction body 202, the mounting assembly 1 is provided with a first friction body 1014. The paint-breaking conductive body 201 can break through the paint layer on the surface of the structure to be grounded 200, thereby contacting the conductive part of its inner layer and ensuring the reliability of grounding. Through the interaction between the first friction body 1014 and the second friction body 202, the paint-breaking conductive component 2 can rotate under the drive of the mounting assembly 1, thereby completing the function of paint-breaking and conduction.

[0083] Alternatively, both the first friction body 1014 and the second friction body 202 adopt a raised structure to increase the friction between the paint-breaking conductor 2 and the mounting assembly 1.

[0084] Alternatively, the paint-breaking conductor 201 may have a sharp, protruding structure to disrupt the surface treatment of the structure to be grounded 200.

[0085] It should be noted that regardless of the structural form of the paint-breaking conductor 201, its purpose is to locally modify the anti-corrosion coating on the equipment surface, avoid overall damage to the anti-corrosion coating, and thus greatly reduce the paint-breaking area and prevent corrosion through the paint-breaking conductor 201.

[0086] In some cases, the mounting assembly 1 includes a fixed mounting member 101, and a first friction body 1014 is disposed on the fixed mounting member 101; further, the fixed mounting member 101 is provided with a first pushing surface 1013, and the first friction body 1014 is located on the first pushing surface 1013.

[0087] In some embodiments, installation component 1 includes:

[0088] The fixed mounting component 101 is provided with a threaded body 1011, and the paint-breaking conductive component 2 can rotate under the rotation of the fixed mounting component 101;

[0089] The mounting adjustment component 102 is movably mounted on the fixed mounting component 101. The mounting adjustment component 102 and the fixed mounting component 101 have a first sealing position. After the mounting adjustment component 102 can move, it forms a second sealing position with the structure to be grounded 200. The paint-breaking conductive component 2 is located in the sealed space formed by the first sealing position and the second sealing position.

[0090] In this embodiment, the fixing mounting component 101 is a structure installed on the structure to be grounded 200, and it also drives the movement of the paint-breaking conductive component 2. The mounting adjustment component 102 is not directly related to the paint-breaking conductive component 2; its main function in this embodiment is to form a sealing protection.

[0091] Specifically, the mounting assembly 1 adopts a split structure, mainly including a fixed mounting component 101 and a mounting adjustment component 102. The fixed mounting component 101 has a threaded body 1011 for threaded engagement with the pre-drilled hole of the structure to be grounded 200, thereby achieving a secure installation of the grounding mounting structure 100. The paint-breaking conductive component 2 can rotate under the rotation of the fixed mounting component 101. This design ensures that the paint-breaking conductive component 2 can effectively break through the paint surface of the structure to be grounded 200, achieving grounding conductivity.

[0092] The mounting adjustment member 102 is movably mounted on the fixed mounting member 101. Its movement can include rotation, sliding, and other methods, all of which fall within the scope of this application. As a preferred embodiment, the mounting adjustment member 102 is rotatably mounted on the fixed mounting member 101. A first sealing position exists between the mounting adjustment member 102 and the fixed mounting member 101, and a second sealing position is formed between the mounting adjustment member 102 and the structure to be grounded 200 after the mounting adjustment member 102 is movable. The paint-breaking conductive member 2 is located within the sealed space formed by the first and second sealing positions.

[0093] This sealed space design is one of the core innovations of this embodiment. Through the action of the installation adjustment member 102, the contact area between the paint-breaking conductive member 2 and the grounding structure 200 is sealed by the sealed space, thus achieving a sealing and protective effect. When the grounding structure 200 is in a harsh environment, this sealing design effectively improves corrosion resistance, preventing external environmental corrosion of the paint-breaking conductive member 2 and the conductive parts of the grounding structure 200, thereby extending the service life of the grounding installation structure 100 and improving its reliability. In some cases, the connecting body 1012 of the fixed mounting member 101 includes a smooth shaft section and a threaded section. The installation adjustment member 102 is threadedly engaged with the threaded section of the connecting body 1012, which is equivalent to the installation adjustment member 102 being rotatably mounted on the fixed mounting member 101. The first sealing position between the installation adjustment member 102 and the fixed mounting member 101 is located between the installation adjustment member 102 and the smooth shaft section of the connecting body 1012.

[0094] Please refer to Figure 8 and Figure 9 ,in, Figure 8 This is a schematic diagram of the installation adjustment component provided in an embodiment of this application. Figure 9 This is a schematic diagram of the installation adjustment component, the first seal, the second seal, and the solid gel provided in the embodiments of this application.

[0095] In some embodiments, the grounding mounting structure 100 further includes a first seal 3 disposed on the mounting adjustment member 102, the first seal 3 being used to form a seal between the mounting adjustment member 102 and the fixed mounting member 101 at a first sealing position.

[0096] In some embodiments, the grounding mounting structure 100 further includes a second seal 4 disposed on the mounting adjustment member 102, the second seal 4 being used to form a seal between the mounting adjustment member 102 and the structure 200 to be grounded at a second sealing position.

[0097] It should be noted that this embodiment does not limit the number of the first sealing element 3 and the second sealing element 4. For example, the number of the first sealing element 3 can be set to multiple, and the number of the second sealing element 4 can be set to multiple, thereby forming a more tight sealing effect, which should also fall within the scope of this embodiment.

[0098] In some cases, the mounting adjustment member 102 is provided with a first fixing groove and a second fixing groove, so as to realize the installation and fixing of the corresponding seal in the form of fixing groove.

[0099] In some cases, the mounting adjustment member 102 includes a threaded hole body 1021 and a mounting hole body 1022. The threaded hole body 1021 includes a smooth hole section and a threaded hole section. The threaded hole section of the threaded hole body 1021 is threadedly engaged with the threaded section of the connecting body 1012, allowing the mounting adjustment member 102 to rotate and be mounted on the fixed mounting member 101. A first fixing groove is provided in the smooth hole section of the threaded hole body 1021, and a first sealing member 3 is installed in the first fixing groove. The first sealing position between the mounting adjustment member 102 and the fixed mounting member 101 is located between the smooth hole section of the threaded hole body 1021 and the smooth shaft section of the connecting body 1012. The mounting hole body 1022 has an end face facing the structure to be grounded 200. A second fixing groove is provided in the end face of the mounting hole body 1022, and a second sealing member 4 is installed in the second fixing groove. When the mounting adjustment member 102 rotates to a position that contacts the structure to be grounded 200, a second sealing position is formed between the end face of the mounting hole body 1022 and the structure to be grounded 200.

[0100] Alternatively, the first seal 3 and the second seal 4 may be O-rings.

[0101] In some cases, continuing with the example of the mounting adjustment member 102 being screwed onto the fixed mounting member 101, the installation can be categorized into two states based on the position of the mounting adjustment member 102 on the fixed mounting member 101: completed tightening and incomplete tightening. In the incomplete tightening state, the distance between the mounting adjustment member 102 and the structure 200 to be grounded is insufficient to achieve a seal through the second sealing member 4, thus failing to form a seal at the second sealing position. In the completed tightening state, the distance between the mounting adjustment member 102 and the structure 200 to be grounded is zero or small enough to achieve a seal through the second sealing member 4, thus forming a seal at the second sealing position. In this case, the mounting adjustment member 102 is considered to be completed tightening on the fixed mounting member 101.

[0102] In some embodiments, the grounding mounting structure 100 further includes:

[0103] Solid gel 5 is provided on the installation adjustment component 102. The solid gel 5 can be squeezed and deformed by the reaction force of the paint breaking conductor 2 under the action of the installation adjustment component 102, and release the gel to cover the scratched area of ​​the paint surface of the structure to be grounded 200.

[0104] The flow area of ​​the gel is confined within the sealed space formed by the first sealing position and the second sealing position.

[0105] In this embodiment, the grounding installation structure 100 further incorporates a solid gel 5 design. This innovative structure provides additional corrosion protection for the grounding installation structure 100. The solid gel 5 is located on the installation adjustment member 102, and its unique release mechanism is closely related to the action of the installation adjustment member 102. The installation adjustment member 102 triggers the solid gel 5. Before triggering, the fixed installation member 101 has already completed the action of driving the paint-breaking conductive member 2. At this time, the positions of the fixed installation member 101 and the paint-breaking conductive member 2 remain stationary. Then, under the action of the installation adjustment member 102 on the solid gel 5, the solid gel 5 moves and is squeezed and deformed by the reaction force of the paint-breaking conductive member 2, releasing the gel. This process ensures that the gel can accurately cover the scratched area of ​​the paint surface of the structure to be grounded 200, thereby providing immediate corrosion protection for the scratched area while breaking the paint and conducting electricity.

[0106] The flow area of ​​the gel is strictly confined within a sealed space formed by the first and second sealing positions. This design not only ensures that the gel effectively covers the scratched area but also prevents disordered flow of the gel, avoiding potential interference with other components or areas. In this way, the release mechanism of the solid gel 5, combined with the sealed protective structure, forms a dual corrosion protection. On the one hand, the sealed space itself provides the first layer of corrosion protection for the area where the broken conductive element 2 and the grounding structure 200 operate; on the other hand, the coverage of the solid gel 5 further enhances the corrosion resistance of this area, effectively improving the reliability and durability of the grounding installation structure 100 in harsh environments.

[0107] In some embodiments, the solid gel 5 can form a conductor in a sealed space.

[0108] In this embodiment, the solid gel 5 is designed not only to provide corrosion protection but also to conduct electricity, further enhancing the conductivity of the grounding installation structure 100. The solid gel 5 is a corrosion-resistant and conductive grease with excellent conductivity and corrosion resistance. In the sealed space, the solid gel 5 can deform and release under the action of the installation adjustment component 102, covering the scratched area of ​​the paint surface of the structure to be grounded 200, while simultaneously forming a conductor to ensure reliable grounding.

[0109] In some embodiments, the solid gel 5 can form a conductive body in a sealed space that enables the conductive portion of the structure to be grounded 200 and the paint-breaking conductive element 2 to conduct electricity.

[0110] In this embodiment, the solid gel 5 can form a conductor in the sealed space, enabling the conductive part of the structure to be grounded 200 to conduct with the paint-breaking conductive element 2. Compared with direct contact between the paint-breaking conductive element 2 and the structure to be grounded 200, this design provides a more stable conductive path, reduces contact resistance, and enhances the conductivity.

[0111] In some embodiments, the solid gel 5 can form a conductive body in a sealed space that enables the conductive portion of the structure to be grounded 200, the paint-breaking conductive element 2, and the fixed mounting element 101 to conduct electricity.

[0112] In this embodiment, the solid gel 5 not only connects the conductive portion of the structure 200 to be grounded with the paint-breaking conductive element 2, but also further establishes a conductive connection between the paint-breaking conductive element 2 and the fixed mounting element 101. This multi-point conductive design further optimizes the grounding path and improves the overall reliability of the grounding system. Especially under complex environmental conditions, it can effectively reduce the risk of grounding failure due to poor contact.

[0113] In some embodiments, the solid gel 5 can form a conductive material in a sealed space that enables the paint-breaking conductor 2 and the fixed mounting component 101 to conduct electricity.

[0114] In this embodiment, the solid gel 5 can form a conductor in the sealed space, enabling direct conductivity between the paint-breaking conductive element 2 and the fixed mounting element 101. This design further simplifies the grounding path, reduces the number of contact points in the conductive path, thereby reducing contact resistance and improving conductivity and grounding reliability.

[0115] In summary, the solid gel 5 design not only provides corrosion protection but also further enhances the conductivity of the grounding installation structure 100 through its electrical conductivity. This design enables the grounding installation structure 100 to maintain efficient and reliable grounding performance under complex environmental conditions, significantly improving the safety and stability of the grounding system.

[0116] In some embodiments, the fixing mounting member 101 includes a threaded body 1011 and a connecting body 1012 coaxially arranged, wherein the diameter of the connecting body 1012 is larger than the diameter of the threaded body 1011.

[0117] In the axial direction of the fixed mounting component 101, the connecting body 1012 is provided with a first pushing surface 1013 on the side facing the threaded body 1011. The first pushing surface 1013 is used to drive the paint breaking conductor 2 to rotate under the action of friction.

[0118] In this embodiment, this structural design cleverly utilizes the diameter difference to form a first pushing surface 1013 on the side of the connector 1012 facing the threaded body 1011. The presence of the first pushing surface 1013 provides an important physical basis for the interaction between the fixed mounting part 101 and the paint-breaking conductive part 2.

[0119] Specifically, the mechanism of the first pushing surface 1013 is based on the principle of friction. When the fixed mounting component 101 rotates during installation or use, friction is generated between the first pushing surface 1013 and the paint-breaking conductive component 2. This friction effectively drives the paint-breaking conductive component 2 to rotate, thereby realizing the paint-breaking function of the paint-breaking conductive component 2. This design not only simplifies the structure but also improves the stability and reliability of the movement of the paint-breaking conductive component 2, ensuring the efficiency and stability of the grounding mounting structure 100 in practical applications.

[0120] In some embodiments, the mounting adjustment member 102 includes a threaded hole body 1021 and a mounting hole body 1022 coaxially arranged, wherein the diameter of the mounting hole body 1022 is larger than the diameter of the threaded hole body 1021.

[0121] Among them, the connecting body 1012 is threadedly engaged with the threaded hole body 1021;

[0122] A space for storing solid gel 5 is formed between connector 1012 and mounting hole 1022;

[0123] In the axial direction of the mounting adjustment component 102, the threaded hole body 1021 is provided with a second pushing surface 1023 on the side facing the mounting hole body 1022. The second pushing surface 1023 is used to drive the solid gel 5 to be squeezed and deformed by the reaction force of the paint breaking conductor 2.

[0124] In this embodiment, this structural design not only provides a connection base for the installation adjustment component 102 to the fixed installation component 101, but also cleverly utilizes the diameter difference to form a space for storing the solid gel 5, as well as a key structure for releasing the solid gel 5—the second pushing surface 1023.

[0125] Specifically, the connector 1012 and the threaded hole 1021 are connected via a threaded engagement, thus connecting the mounting adjustment member 102 to the fixed mounting member 101. This threaded engagement not only ensures the stability of the mounting adjustment member 102 but also provides the basis for power transmission for its movement. The space between the connector 1012 and the mounting hole 1022 is designed as a region for storing the solid gel 5, and this space provides the necessary physical conditions for the release of the solid gel 5.

[0126] Along the axial direction of the mounting adjustment component 102, a second pushing surface 1023 is provided on the side of the threaded hole body 1021 facing the mounting hole body 1022. The mechanism of action of the second pushing surface 1023 is based on the reaction force of the paint-breaking conductive component 2. When the paint-breaking conductive component 2 rotates under the drive of the fixed mounting component 101, its reaction force acts on the second pushing surface 1023, thereby causing the solid gel 5 to be squeezed and deformed. This design allows the solid gel 5 to be precisely released and cover the scratched area of ​​the paint surface of the structure to be grounded 200 during the operation of the mounting adjustment component 102, thereby achieving anti-corrosion protection and conductivity.

[0127] In some embodiments, the interior of the connector 1012 includes an operating hole 10121 and a connecting hole 10122 arranged coaxially. The operating hole 10121 is used to cooperate with an operating tool to rotate the fixed mounting component 101, and the connecting hole 10122 is used to connect to the grounding structure 300 to realize the conduction between the fixed mounting component 101 and the grounding structure 300.

[0128] In this embodiment, the operating hole 10121 is designed to cooperate with an operating tool to rotate the fixing mounting component 101. This design allows for precise control of the rotation of the connector 1012 during installation, thereby driving the threaded body 1011 to tighten and achieving a secure connection between the fixing mounting component 101 and the structure to be grounded 200. Simultaneously, it drives the paint-breaking conductive component 2 to act on the structure to be grounded 200. This method of using the operating hole 10121 in conjunction with the operating tool not only improves the accuracy and convenience of installation but also ensures the stability and reliability of the installation process, avoiding errors and instabilities that may occur due to manual operation.

[0129] The connecting hole 10122 is designed to connect the grounding structure 300, enabling conductivity between the fixed mounting component 101 and the grounding structure 300. This design ensures the continuity and reliability of the grounding path, allowing the grounding current to be effectively conducted to the grounding structure 300 through the fixed mounting component 101, thereby achieving the grounding protection function. Through this structural design, the grounding mounting structure 100 not only offers high operational convenience during installation but also provides a stable physical connection for achieving the grounding function, ensuring the safety and effectiveness of the grounding system.

[0130] In some cases, the operating hole 10121 is an internal hexagonal socket. The connecting hole 10122 is an internal thread.

[0131] In some cases, the external part of the mounting adjustment element 102 is provided with a protrusion to facilitate gripping operation.

[0132] In one specific embodiment, the metal parts of the grounding mounting structure 100, such as the fixing mounting member 101, can be made of highly corrosion-resistant materials such as SUS304 stainless steel.

[0133] This application also provides a grounding protection device 1000, which is installed on a structure 200 to be grounded, including a grounding structure 300 and the aforementioned grounding installation structure 100. The grounding installation structure 100 is disposed on the structure 200 to be grounded, and the grounding structure 300 is disposed on the grounding installation structure 100.

[0134] In this embodiment, the grounding installation structure 100 serves as the core component of the grounding protection device 1000. Its design features include the synergistic effect of the fixed mounting component 101 and the paint-breaking conductive component 2, as well as the sealing of the mounting adjustment component 102 and the corrosion-resistant and conductive functions of the solid gel 5. These design details collectively ensure the reliability and durability of the grounding protection device 1000 in complex environments.

[0135] The grounding structure 300 serves as the grounding terminal of the grounding protection device 1000. Through its connection with the grounding installation structure 100, it enables effective conduction of the grounding current. This design not only simplifies the overall structure of the grounding protection device 1000 but also improves the installation efficiency and maintenance convenience of the grounding system.

[0136] In some cases, the design of the grounding structure 300 is further refined to include a grounding screw 8 and a grounding terminal harness 9. The grounding screw 8 is connected to the connection hole 10122 of the mounting bracket 101 to mount the grounding terminal harness 9 onto the mounting bracket 101. This design not only achieves a physical connection between the grounding structure 300 and the grounding mounting structure 100, but also forms a complete conductive path through the synergistic effect of the grounding screw 8 and the grounding terminal harness 9.

[0137] Specifically, the conduction path starts from the grounding terminal harness 9, connects to the fixing mounting part 101 via the grounding screw 8, and then achieves conduction with the structure to be grounded 200 via the paint-breaking conductive part 2. This path ensures that the grounding current can be smoothly conducted from the grounding terminal harness 9 to the structure to be grounded 200, thereby achieving reliable grounding protection.

[0138] The grounding screw 8 has an external thread, and the connecting hole 10122 has an internal thread. The grounding screw 8 and the connecting hole 10122 are connected by a threaded engagement.

[0139] Optionally, the conductive path may also include a conductor formed by the gel released from the solid gel 5. After being compressed and deformed in the sealed space, the solid gel 5 can cover the scratched area, such as the scratch trajectory 7, between the broken conductive element 2 and the structure to be grounded 200, and form a conductor. This conductor not only enhances the conductivity but also further reduces the contact resistance, improving the reliability and durability of the grounding system. In this way, the solid gel 5 not only provides corrosion protection but also optimizes the grounding path, ensuring the efficiency and stability of the grounding system.

[0140] This application also provides a grounding device 10000, including a structure 200 to be grounded and the aforementioned grounding protection device 1000, wherein the grounding protection device 1000 is installed on the structure 200 to be grounded.

[0141] In this embodiment, the grounding device 10000 includes not only the structure to be grounded 200, but also the aforementioned grounding protection device 1000. The grounding protection device 1000 is firmly connected to the structure to be grounded 200 through its grounding mounting structure 100, thereby realizing the grounding function of the grounding device 10000.

[0142] The design of the grounding protection device 1000 enables the grounding equipment 10000 to achieve efficient grounding conduction during installation. Furthermore, innovative designs such as sealed protection and solid gel 5 enhance the conductivity and corrosion resistance of the grounding path. This design not only improves the safety and reliability of the grounding equipment 10000 but also ensures the efficiency and stability of the grounding system by optimizing the grounding path.

[0143] The structural design of the grounding device 10000 enables its widespread application in high and low voltage power storage industries and other scenarios requiring reliable grounding. By installing the grounding protection device 1000 on the structure 200 to be grounded, the grounding device 10000 not only simplifies the installation and maintenance of the grounding system but also improves grounding efficiency, reduces grounding costs, and provides strong protection for the safe operation of the equipment.

[0144] It should be noted that many of the components mentioned in this application are general standard parts or components known to those skilled in the art, and their structure and principle can be learned by those skilled in the art through technical manuals or through conventional experimental methods.

[0145] It should be noted that in this specification, relational terms such as first and second are used only to distinguish one entity from several other entities, and do not necessarily require or imply any such actual relationship or order between these entities.

[0146] The grounding installation structure, grounding protection device, and grounding equipment provided in this application have been described in detail above. Specific examples have been used to illustrate the principles and implementation methods of this application. The descriptions of the embodiments above are only for the purpose of helping to understand the method and core ideas of this application. It should be noted that those skilled in the art can make several improvements and modifications to this application without departing from the principles of this application, and these improvements and modifications also fall within the protection scope of the claims of this application.

Claims

1. A grounding installation structure for installation on a structure to be grounded, characterized in that, include: The mounting assembly includes a threaded body for engaging with a pre-drilled hole in the structure to be grounded, and the mounting assembly is rotatable and adjustable. A paint-breaking conductive component is provided on the mounting assembly. The paint-breaking conductive component has a paint-breaking conductive body on the side facing the structure to be grounded. The paint-breaking conductive component can rotate under the action of the mounting assembly. The paint-breaking conductive body breaks through the paint surface of the structure to be grounded and conducts electricity with the conductive part located in the inner layer of the paint surface of the structure to be grounded.

2. The grounding installation structure according to claim 1, characterized in that, The installation components include: The fixed mounting component is provided with the threaded body, and the paint-breaking conductive component can rotate under the rotation of the fixed mounting component; An adjustment component is installed and movably mounted on the fixed mounting component. The adjustment component and the fixed mounting component have a first sealing position. After the adjustment component is movable, it forms a second sealing position with the structure to be grounded. The paint-breaking conductive component is located in the sealed space formed by the first sealing position and the second sealing position.

3. The grounding installation structure according to claim 2, characterized in that, Also includes: A first sealing element is disposed on the mounting adjustment element, and the first sealing element is used to form a seal between the mounting adjustment element and the fixed mounting element at a first sealing position; And / or, A second seal is provided on the mounting adjustment member, and the second seal is used to form a seal between the mounting adjustment member and the structure to be grounded at a second sealing position.

4. The grounding installation structure according to claim 2, characterized in that, Also includes: Solid gel is provided on the mounting adjustment component. The solid gel can be squeezed and deformed by the reaction force of the paint breaking conductor under the action of the mounting adjustment component, and the gel is released to cover the scratched area of ​​the paint surface of the structure to be grounded. The flow area of ​​the gel is confined within the sealed space formed by the first sealing position and the second sealing position.

5. The grounding installation structure according to claim 4, characterized in that, The fixing component includes a threaded body and a connecting body arranged coaxially, wherein the diameter of the connecting body is larger than the diameter of the threaded body; In the axial direction of the fixed mounting component, the side of the connecting body facing the threaded body is provided with a first pushing surface, which is used to drive the paint-breaking conductive component to rotate under the action of friction.

6. The grounding installation structure according to claim 5, characterized in that, The mounting adjustment component includes a threaded hole body and a mounting hole body arranged coaxially, wherein the diameter of the mounting hole body is larger than the diameter of the threaded hole body; The connecting body is threadedly engaged with the threaded hole body; A space for storing the solid gel is formed between the connector and the mounting hole; In the axial direction of the mounting adjustment component, a second pushing surface is provided on the side of the threaded hole facing the mounting hole. The second pushing surface is used to drive the solid gel to be squeezed and deformed by the reaction force of the paint breaking conductor.

7. The grounding installation structure according to claim 4, characterized in that, The solid gel can form a conductive body within the sealed space that enables the conductive parts of the structure to be grounded and the broken paint conductive parts to conduct electricity; or, The solid gel can form a conductive body within the sealed space that enables the conductive parts of the structure to be grounded, the broken paint conductive parts, and the fixed mounting parts to conduct electricity; or, The solid gel can form a conductive material in the sealed space that enables the paint-damaged conductive component and the fixed installation component to conduct electricity.

8. The grounding installation structure according to claim 5, characterized in that, The interior of the connector includes an operating hole and a connecting hole arranged coaxially. The operating hole is used to cooperate with the operating tool to rotate the fixed installation component, and the connecting hole is used to connect to the grounding structure to realize the conduction between the fixed installation component and the grounding structure.

9. A grounding protection device, installed on a structure to be grounded, characterized in that, It includes a grounding structure and a grounding installation structure as described in any one of claims 1 to 8, wherein the grounding installation structure is disposed on the structure to be grounded, and the grounding structure is disposed on the grounding installation structure.

10. A grounding device, characterized in that, It includes a structure to be grounded and a grounding protection device as described in claim 9, wherein the grounding protection device is installed on the structure to be grounded.

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