A line positioning device for electrical engineering
By designing the clamping structure of the first and second positioning components, and combining it with the adjusting threaded column and the limiting component, the problem of unstable fixation in existing positioning devices is solved, achieving stable clamping and length adjustment of the line, and improving fixation stability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- LIAONING TECHNICAL UNIVERSITY
- Filing Date
- 2025-01-24
- Publication Date
- 2026-06-19
Smart Images

Figure CN224384939U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of electrical engineering technology, and in particular to a line positioning device for electrical engineering. Background Technology
[0002] Electrical wiring is mainly wires that provide power transmission to electrical equipment. It is a prerequisite for ensuring the stable operation of electrical equipment. During the laying of wiring, it is necessary to clamp the wiring to prevent it from becoming loose and affecting the operation of electrical equipment. Therefore, people have increasingly higher requirements for electrical wiring positioning brackets.
[0003] Patent document with announcement number (CN215267542U) discloses an electrical wiring installation and fixing device for electrical engineering construction, including an upper collar and a lower collar. A rotating groove is formed on the right side of the lower surface of the upper collar, and a rotating rod is fixedly connected to the right side of the upper surface of the lower collar. The top of the rotating rod is located inside the rotating groove, and the lower collar and the upper collar are rotatably connected through the rotating rod and the rotating groove. A connecting block is fixedly connected to the left side of the interior of the upper collar, and a U-shaped piece is fixedly connected to the left side of the interior of the lower collar. A sliding groove is formed on the lower surface of the connecting block. By rotatably connecting the upper collar and the lower collar to form a whole collar, the electrical wire is closed, realizing convenient fixing and disassembly of the electrical wire, reducing the repetitive work time caused by forgetting to drill holes, and the design of clamps, compression springs, locking blocks and locking grooves ensures the stability of the upper collar and the lower collar when fixed, and prevents them from falling off.
[0004] When using the above technology, the following technical problems were found in the existing technology: the existing positioning device is not stable enough in fixing the line when in use. Therefore, an electrical engineering line positioning device is designed to provide another technical solution to the above technical problems. Utility Model Content
[0005] Therefore, it is necessary to provide an electrical engineering line positioning device to address the aforementioned technical problems, thereby solving the technical issue that existing positioning devices do not provide sufficient and secure fixation for the lines during use.
[0006] To solve the above-mentioned technical problems, the present invention adopts the following technical solution:
[0007] An electrical engineering line positioning device includes a first positioning component and a second positioning component. The second positioning component is located on top of the first positioning component and is symmetrically arranged with the first positioning component. Both ends of the first positioning component are fixed with a fixed seat. A sliding block is slidably connected inside the top of the fixed seat. A fixed plate is fixed on the top of the sliding block. An adjusting threaded column is rotatably connected inside the fixed seat. The outer side of the adjusting threaded column is threadedly connected to both the fixed plate and the adjusting threaded column.
[0008] In a preferred embodiment of the electrical engineering line positioning device provided by this utility model, a first rotating groove is provided inside the top of the adjusting threaded column.
[0009] In a preferred embodiment of the electrical engineering line positioning device provided by this utility model, both the first positioning component and the second positioning component include a positioning block, a splicing block, a translation limit block, and a limit component. Positioning blocks are fixed at adjacent ends of the two fixed plates and adjacent ends of the two fixed seats. A splicing block is provided between the two positioning blocks. A translation limit block is slidably connected to the bottom of the adjacent ends of the positioning block and the splicing block. A limit component for positioning the translation limit block is installed between the positioning block and the splicing block.
[0010] In a preferred embodiment of the electrical engineering line positioning device provided by this utility model, the shape of the translation limit block is mountain-shaped.
[0011] In a preferred embodiment of the electrical engineering line positioning device provided by this utility model, a first sliding groove is provided at the bottom of one adjacent end of the positioning block and the splicing block, and the positioning block and the translation limit block are slidably connected through the first sliding groove.
[0012] In a preferred embodiment of the electrical engineering line positioning device provided by this utility model, the limiting component includes a first positioning plate, a limiting threaded post, a translation block, and a second positioning plate. The first positioning plate is slidably connected to the positioning block, the first positioning plate is slidably connected to the splicing block, and the first positioning plate is slidably connected to the translation limiting block. A translation block is slidably connected to the inside of one side of the first positioning plate, and a second positioning plate is fixed to one side of the translation block. The second positioning plate is slidably connected to the positioning block and the second positioning plate is slidably connected to the splicing block. A limiting threaded post is rotatably connected to the inside of the first positioning plate, and the outer side of one side of the limiting threaded post is threadedly connected to the translation block.
[0013] In a preferred embodiment of the electrical engineering line positioning device provided by this utility model, the positioning block and the splicing block are provided with second sliding grooves on both sides of the first sliding groove. The second sliding grooves are connected to the first sliding grooves. The second positioning plate and the positioning block, the second positioning plate and the splicing block, the first positioning plate and the positioning block, and the first positioning plate and the splicing block are all slidably connected through the second sliding grooves.
[0014] In a preferred embodiment of the electrical engineering line positioning device provided by this utility model, a second rotating groove is provided inside the limiting threaded column on the side away from the second positioning plate.
[0015] It is clear without a doubt that the technical solution described above in this application can solve the technical problem that this application aims to address.
[0016] At the same time, through the above technical solutions, this utility model has at least the following beneficial effects:
[0017] This utility model provides a line positioning device for electrical engineering. Through the cooperation of a first positioning component, a second positioning component, a fixing plate, and a fixing seat, the line can be clamped and fixed by the approach of the fixing plate and the fixing seat when the line is located between the first positioning component and the second positioning component. At the same time, the lengths of the first positioning component and the second positioning component can be adjusted before assembly as needed.
[0018] By cooperating with positioning blocks, splicing blocks, translation limit blocks, and the first positioning plate, the number of splicing blocks in the first and second positioning components can be adjusted according to the length requirements. The multiple splicing blocks are translated and limited between each other and between the splicing blocks and the positioning blocks by translation limit blocks. At the same time, the cooperation of the first and second positioning plates prevents them from detaching. Attached Figure Description
[0019] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0020] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0021] Figure 2 This is a schematic diagram showing the working state of this utility model;
[0022] Figure 3 This is a schematic diagram of the internal structure of the fixing base of this utility model;
[0023] Figure 4 This is a schematic diagram of the positioning component of this utility model;
[0024] Figure 5 This is a schematic diagram of the internal structure of the positioning block of this utility model;
[0025] Figure 6 This is a schematic diagram of the translational limiting block of this utility model.
[0026] In the diagram: 1. First positioning component; 2. Second positioning component; 3. Fixed plate; 4. Fixed base; 5. Sliding block; 6. Adjusting threaded column; 7. First rotating groove; 8. Positioning block; 9. Splicing block; 10. First sliding groove; 11. Second sliding groove; 12. Translation limit block; 13. First positioning plate; 14. Limiting threaded column; 15. Second rotating groove; 16. Translation block; 17. Second positioning plate. Detailed Implementation
[0027] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present utility model and are not intended to limit the present utility model.
[0028] To enable those skilled in the art to better understand the present invention, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings.
[0029] It should be noted that, unless otherwise specified, the embodiments and features and technical solutions in the present invention can be combined with each other.
[0030] It should be noted that similar labels and letters in the following figures indicate similar items. Therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.
[0031] Reference Figures 1-6 An electrical engineering line positioning device includes a first positioning element 1 and a second positioning element 2. The second positioning element 2 is located on top of the first positioning element 1 and is symmetrically arranged with the first positioning element 1, thereby enabling the line to be clamped between the first positioning element 1 and the second positioning element 2 for positioning. Both ends of the first positioning element 1 are fixed with a fixing seat 4, so that the fixing seat 4 can be fixed to an external object by bolts. The top of the fixing seat 4 is slidably connected to a sliding block 5, and the top of the sliding block 5 is fixed with a fixing plate 3. The fixing seat 4 is rotatably connected to an adjusting threaded column 6. The outer side of the adjusting threaded column 6 is threadedly connected to the fixing plate 3 and the adjusting threaded column 6, so that the adjusting threaded column 6 can rotate through the threaded connection between the fixing plate 3 and the sliding block 5. The top of the adjusting threaded column 6 is provided with a first rotating groove 7. The first rotating groove 7 is a multi-faceted groove, so that tools such as a hex wrench can be inserted into the first rotating groove 7 from the top of the fixing plate 3, driving the adjusting threaded column 6 to rotate, thereby allowing the sliding block 5 and the fixing plate 3 to be adjusted in height on the fixing seat 4.
[0032] The first positioning component 1 and the second positioning component 2 both include a positioning block 8, a splicing block 9, a translation limit block 12, and a limiting component. The two fixed plates 3 and the two fixed seats 4 are each fixed with a positioning block 8 at one adjacent end. A splicing block 9 is provided between the two positioning blocks 8, so that the length of the first positioning component 1 and the second positioning component 2 can be adjusted according to the number of splicing blocks 9. The bottom of the adjacent end of the positioning block 8 and the splicing block 9 is slidably connected with a translation limit block 12. The translation limit block 12 is mountain-shaped and can also be slidably connected between the bottom of two adjacent splicing blocks 9. Translation limit is achieved by the translation limit block 12.
[0033] A limiting component for positioning translation limiting block 12 is installed between positioning block 8 and splicing block 9. The bottom of adjacent ends of positioning block 8 and splicing block 9 are provided with first sliding grooves 10. Positioning block 8 and translation limiting block 12, and splicing block 9 and translation limiting block 12 are slidably connected through the first sliding grooves 10. This allows the translation limiting block 12, which is slidably connected between positioning block 8 and splicing block 9, and between two adjacent splicing blocks 9, to enter the first sliding groove 10, preventing positioning block 8 and splicing block 9, and between two adjacent splicing blocks 9, from being translated and separated. The limiting component includes a first positioning plate 13, a limiting threaded post 14, a translation block 16, and a second positioning plate 17. The cross-section of the first positioning plate 13 and the second positioning plate 17 is T-shaped, so that the first positioning plate 13 and the second positioning plate 17 enter from both sides of positioning block 8 or splicing block 9 and are connected. At this time, the first positioning plate 13 and the second positioning plate 17 cannot be separated from positioning block 8 or splicing block 9.
[0034] In this embodiment, both the top of the positioning block 8 and the splicing block 9 are provided with arc-shaped grooves to keep the line inside the arc-shaped grooves and to clamp and position it by the proximity of the first positioning member 1 and the second positioning member 2.
[0035] The first positioning plate 13 is slidably connected to the positioning block 8, the splicing block 9, and the translation limiting block 12, allowing the first positioning plate 13 to extend into the translation limiting block 12 from one side of the positioning block 8 and the splicing block 9. This makes the translation limiting block 12 inseparable from the positioning block 8 and the splicing block 9, and also inseparable between the positioning block 8 and the splicing block 9, or between two splicing blocks 9. A translation block 16 is slidably connected to the interior of one side of the first positioning plate 13, and a second positioning plate 17 is fixed to one side of the translation block 16. The second positioning plate 17 and... The positioning blocks 8 are slidably connected to each other, and the second positioning plate 17 is slidably connected to the splicing block 9. The positioning blocks 8 and splicing blocks 9 are provided with second sliding grooves 11 on both sides of the first sliding groove 10. The second sliding grooves 11 are connected to the first sliding groove 10. The second positioning plate 17 is slidably connected to the positioning blocks 8, the second positioning plate 17 is slidably connected to the splicing block 9, the first positioning plate 13 is slidably connected to the positioning blocks 8, and the first positioning plate 13 is slidably connected to the splicing block 9 through the second sliding grooves 11, so that the first positioning plate 13 and the translation block 16 can enter the interior of the first sliding groove 10 from the interior of the second sliding groove 11.
[0036] The first positioning plate 13 is rotatably connected to a limiting threaded post 14. The outer side of one side of the limiting threaded post 14 is threadedly connected to the translation block 16, so that the rotation of the limiting threaded post 14 allows the translation block 16 to slide inside the first positioning plate 13. The limiting threaded post 14 is provided with a second rotation groove 15 on the side away from the second positioning plate 17, so that tools such as hex wrenches can enter the interior of the second rotation groove 15 and drive the limiting threaded post 14 to rotate.
[0037] The usage process of the electrical engineering line positioning device provided by this utility model is as follows: During use, the number of splicing blocks 9 in the first positioning component 1 and the second positioning component 2 is adjusted according to the number of lines to be positioned. Then, the positioning block 8 and the splicing block 9, as well as the two adjacent splicing blocks 9, are all translatably limited by the bottom sliding translation limit block 12. Then, the first positioning plate 13 enters the translation limit block 12 from the inside of the second sliding groove 11. At the same time, the second positioning plate 17 drives the translation block 16 from the corresponding second sliding groove 11 into the inside of the first positioning plate 13, and the second positioning plate 17 enters the inside of the second sliding groove 11. Then, a tool such as a hex wrench is used to enter the inside of the second rotating groove 15, driving the limiting threaded column 14 to rotate. The rotation of the limiting threaded column 14 drives the threaded translation block 16 to completely enter the inside of the first positioning plate 13, thereby making the positioning block 8 and the splicing block 9 inseparable, forming the first positioning component 1 and the second positioning component 2.
[0038] Then, position the limiter that needs to be positioned between the first positioning member 1 and the second positioning member 2. Then, insert tools such as a hex wrench into the first rotating groove 7 to drive the adjusting threaded column 6 to rotate. The rotation of the adjusting threaded column 6 causes the threaded sliding block 5 to descend inside the fixed seat 4. The descent of the sliding block 5 causes the fixed plate 3 to descend, which in turn causes the second positioning member 2 to move closer to the first positioning member 1. Thus, the circuit is clamped and positioned by the proximity of the second positioning member 2 and the first positioning member 1.
[0039] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the present utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of the present utility model, thereby enabling those skilled in the art to better understand and utilize it. The present utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A line positioning device for electrical engineering, characterized in that, It includes a first positioning component (1) and a second positioning component (2). The second positioning component (2) is located on top of the first positioning component (1). The second positioning component (2) and the first positioning component (1) are symmetrically arranged. Both ends of the first positioning component (1) are fixed with a fixed seat (4). The top of the fixed seat (4) is slidably connected with a sliding block (5). The top of the sliding block (5) is fixed with a fixed plate (3). The fixed seat (4) is rotatably connected with an adjusting threaded column (6). The outer side of the adjusting threaded column (6) is threadedly connected to the fixed plate (3) and the adjusting threaded column (6).
2. The electrical engineering line positioning device according to claim 1, characterized in that, The top of the adjusting threaded column (6) has a first rotating groove (7).
3. The electrical engineering line positioning device according to claim 1, characterized in that, The first positioning component (1) and the second positioning component (2) both include a positioning block (8), a splicing block (9), a translation limit block (12), and a limiting component. The two fixed plates (3) and the two fixed seats (4) are each fixed with a positioning block (8) at one adjacent end. A splicing block (9) is provided between the two positioning blocks (8). The bottom of the adjacent ends of the positioning block (8) and the splicing block (9) is slidably connected with a translation limit block (12). A limiting component for positioning the translation limit block (12) is installed between the positioning block (8) and the splicing block (9).
4. The electrical engineering line positioning device according to claim 3, characterized in that, The shape of the translation limit block (12) is mountain-shaped.
5. The electrical engineering line positioning device according to claim 3, characterized in that, The bottom of the adjacent end of the positioning block (8) and the splicing block (9) are provided with a first sliding groove (10). The positioning block (8) and the translation limit block (12) and the splicing block (9) and the translation limit block (12) are slidably connected through the first sliding groove (10).
6. The electrical engineering line positioning device according to claim 3, characterized in that, The limiting assembly includes a first positioning plate (13), a limiting threaded post (14), a translation block (16), and a second positioning plate (17). The first positioning plate (13) is slidably connected to the positioning block (8), to the splicing block (9), and to the translation limiting block (12). The translation block (16) is slidably connected to the inside of one side of the first positioning plate (13). The second positioning plate (17) is fixed to one side of the translation block (16). The second positioning plate (17) is slidably connected to the positioning block (8) and to the splicing block (9). The limiting threaded post (14) is rotatably connected inside the first positioning plate (13). The outer side of one side of the limiting threaded post (14) is threadedly connected to the translation block (16).
7. The electrical engineering line positioning device according to claim 6, characterized in that, The positioning block (8) and the splicing block (9) are provided with second sliding grooves (11) on both sides of the first sliding groove (10). The second sliding grooves (11) are connected to the first sliding groove (10). The second positioning plate (17) and the positioning block (8), the second positioning plate (17) and the splicing block (9), the first positioning plate (13) and the positioning block (8), and the first positioning plate (13) and the splicing block (9) are all slidably connected through the second sliding grooves (11).
8. A line positioning device for electrical engineering according to claim 6, characterized in that, The limiting threaded post (14) has a second rotating groove (15) on the side away from the second positioning plate (17).