Molding machine distribution station anti-static grounding flow copper row assembly

Abstract

The utility model relates to copper bar assembly technical field discloses the forming machine distribution station anti -static grounding flow guide copper bar assembly, including forming machine distribution station main part, distribution butt joint pipe, the distribution butt joint pipe fixed connection is in the top outer wall of forming machine distribution station main part, the bottom outer wall fixed connection of forming machine distribution station main part has the first ground wire, the right -hand member fixed connection of first ground wire has the copper bar main part, be provided with adjusting mechanism on the copper bar main part, be provided with auxiliary mechanism on adjusting mechanism, adjusting mechanism includes the rotating column, the rotating column rotation is connected in the top inner wall of forming machine distribution station main part through bearing. In the utility model, through setting up copper bar main part, adjusting mechanism, can according to different use scene and demand, the position and state of copper bar main part are adjusted flexibly, realize and the stable connection of ground, ensure that static electricity can be conducted to the grounding device efficiently, stably, avoid the influence that static electricity accumulation causes to equipment and production.

Description

Technical Field

[0001] This utility model relates to the technical field of copper busbar components, and in particular to an anti-static grounding and current-conducting copper busbar component for a forming machine feeding station. Background Technology

[0002] The anti-static discharge of the molding machine's material distribution station must follow a closed-loop logic of "charge generation → rapid capture → low-resistance conduction → safe discharge". Through grounding system design, material selection and structural optimization, the electrostatic potential is controlled within a safe threshold (usually <100V) to avoid material adsorption and equipment failure.

[0003] The anti-static grounding copper busbar assembly effectively avoids problems such as material agglomeration and equipment malfunction caused by static electricity through its low-impedance current-conducting design. In practical applications, the grounding density needs to be adjusted according to the material characteristics (such as insulation and particle size). For example, when handling highly insulating powder, the spacing between the copper busbars should be ≤500mm to enhance the discharge effect. Through the low-impedance conductive path, the static charge generated by material friction and mechanical rotation during the operation of the material distribution station is quickly conducted to the ground, avoiding material adsorption, equipment failure, or safety hazards (such as dust explosion risk) caused by static accumulation.

[0004] The grounding conductor copper busbar assembly has the following defects: the copper busbar assembly is placed directly on the ground for grounding, but when the ground is inclined or vertically grounded, the copper busbar assembly is not easy to fit well, which affects the grounding anti-static performance. Therefore, the anti-static grounding conductor copper busbar assembly for the forming machine material distribution station is proposed to solve the above problems. Utility Model Content

[0005] To overcome the above shortcomings, this utility model provides an anti-static grounding copper busbar assembly for the material distribution station of a molding machine, which aims to improve the problem that the copper busbar assembly is not easy to fit well when the ground is inclined or vertical.

[0006] To achieve the above objectives, the present invention adopts the following technical solution: an anti-static grounding copper busbar assembly for a molding machine material distribution station, comprising a molding machine material distribution station body and a material distribution connecting pipe. The material distribution connecting pipe is fixedly connected to the top outer wall of the molding machine material distribution station body. A first grounding wire is fixedly connected to the bottom outer wall of the molding machine material distribution station body. A copper busbar body is fixedly connected to the right end of the first grounding wire. An adjustment mechanism is provided on the copper busbar body. An auxiliary mechanism is provided on the adjustment mechanism. The adjustment mechanism includes a rotating column. The rotating column is rotatably connected to the top inner wall of the molding machine material distribution station body via a bearing. A threaded cone is fixedly connected to the bottom outer wall of the rotating column. A slide rail is opened on the front inner wall of the rotating column. Hexagonal plates are slidably connected to the left and right inner walls of the slide rail. A compression spring is fixedly connected to the top outer wall of the hexagonal plate.

[0007] As a further description of the above technical solution: the auxiliary mechanism includes a pointing mark, which is opened on the top outer wall of the hexagonal plate. A matching interface is opened on the right inner wall of the copper busbar body. An extension head is threadedly connected to the side inner wall of the matching interface. A second grounding wire is fixedly connected to the rear outer wall of the extension head. A groove is fixedly connected to the side outer wall of the extension head.

[0008] As a further description of the above technical solution: a wear-resistant pad is fixedly connected to the outer side wall of the hexagonal plate and the slot, and the hexagonal plate is snapped into the bottom inner wall of the slot.

[0009] As a further description of the above technical solution: the end of the compression spring away from the hexagonal plate is fixedly connected to the top inner wall of the rotating column, and the rotating column is rotatably connected to the bottom outer wall of the copper busbar body through a bearing.

[0010] As a further description of the above technical solution: a reflective sticker is fixedly connected to the top outer wall of the hexagonal plate.

[0011] As a further description of the above technical solution: the top outer wall of the directional marker is fixedly connected with a bright coating.

[0012] As a further description of the above technical solution: a frosted pad is fixedly connected to the outer side wall of the groove, there are several copper busbar bodies, and the right end of the second grounding wire is fixedly connected to a copper busbar body.

[0013] This utility model has the following beneficial effects:

[0014] 1. In this utility model, by setting up a copper busbar body and an adjustment mechanism, the position and state of the copper busbar body can be flexibly adjusted according to different usage scenarios and needs to achieve a stable connection with the ground, ensuring that static electricity can be efficiently and stably conducted to the grounding device, avoiding the impact of static electricity accumulation on equipment and production, and improving the stability and reliability of static electricity discharge.

[0015] 2. In this utility model, auxiliary structures such as directional markers, reflective stickers, and wear-resistant pads provide clear operating instructions for workers, facilitating installation and adjustment in various environments. At the same time, through the structure of interfaces, expansion heads, and second grounding wires, the number of copper busbars can be flexibly increased according to the actual static electricity generation, enhancing the static grounding capability and improving the practicality and functionality of the components. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall main view of the anti-static grounding copper busbar assembly for the molding machine feeding station proposed in this utility model;

[0017] Figure 2This is a schematic diagram showing the disassembled anti-static grounding current-conducting copper busbar assembly of the molding machine feeding station proposed in this utility model;

[0018] Figure 3 This is a schematic diagram of the adjustment mechanism of the anti-static grounding copper busbar assembly for the molding machine feeding station proposed in this utility model;

[0019] Figure 4 This is a schematic diagram of the auxiliary mechanism of the anti-static grounding copper busbar assembly for the molding machine feeding station proposed in this utility model.

[0020] Legend:

[0021] 1. Main body of the forming machine's material distribution station; 2. Material distribution connecting pipe; 3. First grounding wire; 4. Main body of the copper busbar; 5. Adjustment mechanism; 51. Rotating column; 52. Slide rail; 53. Hexagonal plate; 54. Threaded taper; 55. Slot; 56. Compression spring; 6. Auxiliary mechanism; 61. Pointing mark; 62. Connecting interface; 63. Extension head; 64. Corrugated groove; 65. Second grounding wire. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Reference Figures 1-3This utility model provides an embodiment of an anti-static grounding copper busbar assembly for a molding machine material distribution station. The assembly includes a molding machine material distribution station body 1 and a material distribution connecting pipe 2. The material distribution connecting pipe 2 is fixedly connected to the top outer wall of the molding machine material distribution station body 1. This fixed connection enables material transfer between the molding machine material distribution station body 1 and external equipment, ensuring smooth material distribution. A first grounding wire 3 is fixedly connected to the bottom outer wall of the molding machine material distribution station body 1. A copper busbar body 4 is fixedly connected to the right end of the first grounding wire 3. The copper busbar body 4 is connected to the first grounding wire 3 and serves as the main carrier for static electricity conduction, efficiently transmitting static electricity and guiding it to the ground. The grounding device enables safe release of static electricity. The main body 4 of the copper busbar is equipped with an adjustment mechanism 5, and the adjustment mechanism 5 is equipped with an auxiliary mechanism 6. The adjustment mechanism 5 includes a rotating column 51, which is rotatably connected to the top inner wall of the forming machine's material distribution station main body 1 via a bearing. A threaded cone 54 is fixedly connected to the bottom outer wall of the rotating column 51. When the rotating column 51 is rotated, the threaded cone 54 can be screwed into the ground to achieve a stable connection between the main body 4 of the copper busbar and the ground, thereby enhancing the stability of grounding. A slide rail 52 is opened on the front inner wall of the rotating column 51. Hexagonal plates 53 are slidably connected to the inner walls of the left and right sides of the slide rail 52. A compression spring 56 is fixedly connected to the top outer wall of the hexagonal plate 53.

[0024] Reference Figures 2-4 Wear-resistant pads are fixedly connected to the outer side wall of the hexagonal plate 53 and the slot 55. The wear-resistant pads can reduce the friction loss between the hexagonal plate 53 and the slot 55, extend the service life of the components, and ensure the long-term stable operation of the adjustment mechanism 5. The hexagonal plate 53 is snapped into the bottom inner wall of the slot 55. The end of the compression spring 56 away from the hexagonal plate 53 is fixedly connected to the top inner wall of the rotating column 51. The rotating column 51 is rotatably connected to the bottom outer wall of the copper busbar body 4 through the bearing. Reflective stickers are fixedly connected to the top outer wall of the hexagonal plate 53. The reflective stickers make it easy for the staff to clearly observe the position and status of the hexagonal plate 53 in low light conditions, which is convenient for operation and inspection.

[0025] Reference Figures 3-4The auxiliary mechanism 6 includes a directional marker 61, which is located on the top outer wall of the hexagonal plate 53. The directional marker 61 provides directional guidance for operators to rotate the hexagonal plate 53, preventing adjustment errors due to incorrect rotation direction. An interface 62 is provided on the right inner wall of the copper busbar body 4, providing an interface for connecting the expansion head 63, facilitating the expansion connection of the copper busbar body 4 and enhancing the electrostatic grounding effect. An expansion head 63 is threadedly connected to the inner side wall of the interface 62, and a second expansion head 63 is fixedly connected to the rear outer wall of the expansion head 63. The grounding wire 65 and the extension head 63 have a groove 64 fixedly connected to their side outer wall. The top outer wall of the directional mark 61 has a bright coating, which makes the directional mark 61 more conspicuous and allows workers to quickly identify it even in complex environments, further improving the accuracy and convenience of operation. The groove 64 has a frosted pad fixedly connected to its side outer wall, which further increases the friction of the groove 64, preventing the extension head 63 from slipping during operation and ensuring the reliability of the connection. There are several copper busbar bodies 4, and the right end of the second grounding wire 65 is fixedly connected to a copper busbar body 4.

[0026] Working principle: The copper busbar body 4 is attached to the inclined road surface that needs to be fixed. Then, the hexagonal plate 53 is pulled to separate from the slot 55. The direction of rotation is then observed by the indicator mark 61. The hexagonal plate 53 is then rotated to make the slide rail 52 rotate. The rotation of the slide rail 52 drives the rotating column 51 to rotate. The rotation of the rotating column 51 drives the threaded cone 54 to rotate. The threaded cone 54 rotates and penetrates into the ground soil, so that the copper busbar body 4 is firmly attached to the ground, so that the static electricity transfer reaches the best and most stable state. When the static electricity grounding effect of a single copper busbar body 4 is not good, the extension head 63 is threaded to the interface 62, and then the second copper busbar body 4 is fixedly connected to the second grounding wire 65. Then, the second copper busbar body 4 is attached to the ground, so that the static electricity discharge stability of the copper busbar body 4 is improved.

[0027] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A molding machine material distribution station anti-static grounding copper busbar assembly, comprising the molding machine material distribution station body (1) and material distribution connecting pipe (2), characterized in that: The material distribution pipe (2) is fixedly connected to the top outer wall of the molding machine material distribution station body (1). The bottom outer wall of the molding machine material distribution station body (1) is fixedly connected to a first grounding wire (3). The right end of the first grounding wire (3) is fixedly connected to a copper busbar body (4). An adjustment mechanism (5) is provided on the copper busbar body (4). An auxiliary mechanism (6) is provided on the adjustment mechanism (5). The adjustment mechanism (5) includes a rotating column (51), which is rotatably connected to the top inner wall of the forming machine distribution station body (1) via a bearing. A threaded cone (54) is fixedly connected to the bottom outer wall of the rotating column (51). A slide (52) is provided on the front inner wall of the rotating column (51). Hexagonal plates (53) are slidably connected to the left and right inner walls of the slide (52). A compression spring (56) is fixedly connected to the top outer wall of the hexagonal plate (53).

2. The anti-static grounding copper busbar assembly for the molding machine feeding station according to claim 1, characterized in that: The auxiliary mechanism (6) includes a pointing mark (61), which is opened on the top outer wall of the hexagonal plate (53). The inner right side wall of the copper busbar body (4) is provided with a mating interface (62). The inner side wall of the mating interface (62) is threaded with an extension head (63). The outer rear wall of the extension head (63) is fixedly connected with a second grounding wire (65). The outer side wall of the extension head (63) is fixedly connected with a groove (64).

3. The anti-static grounding copper busbar assembly for the molding machine feeding station according to claim 1, characterized in that: The hexagonal plate (53) is fixedly connected to the outer side wall of the slot (55) with a wear-resistant pad, and the hexagonal plate (53) is snapped into the bottom inner wall of the slot (55).

4. The anti-static grounding copper busbar assembly for the molding machine feeding station according to claim 1, characterized in that: The end of the compression spring (56) away from the hexagonal plate (53) is fixedly connected to the top inner wall of the rotating column (51), and the rotating column (51) is rotatably connected to the bottom outer wall of the copper busbar body (4) through a bearing.

5. The anti-static grounding copper busbar assembly for the molding machine feeding station according to claim 1, characterized in that: The top outer wall of the hexagonal plate (53) is fixedly connected with reflective stickers.

6. The anti-static grounding copper busbar assembly for the molding machine feeding station according to claim 2, characterized in that: The top outer wall of the directional marker (61) is fixedly connected with a bright coating.

7. The anti-static grounding copper busbar assembly for the molding machine feeding station according to claim 2, characterized in that: A frosted pad is fixedly connected to the outer side wall of the groove (64), and there are several copper busbar bodies (4). The right end of the second grounding wire (65) is fixedly connected to the copper busbar body (4).

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