An electrical engineering measuring device
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU CHANGYUAN ELECTRIC POWER TECH CO LTD
- Filing Date
- 2025-08-26
- Publication Date
- 2026-06-23
Smart Images

Figure CN224398625U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of power engineering technology, and specifically relates to a power engineering measuring device. Background Technology
[0002] Cable laying refers to the process of laying and installing cables along a surveyed route to form a cable line. Depending on the application, it can be divided into several laying methods, such as overhead, underground (pipes and direct burial), underwater, wall, and tunnel. The appropriate selection of cable laying method is very important for ensuring the transmission quality, reliability, construction, and maintenance of the line.
[0003] Patent application number 202420982897.1 discloses a cable measuring device for power engineering construction, relating to the field of power engineering construction technology. This utility model includes a base, a housing fixedly connected to the top of the base, a cable disposed inside the housing, a baffle fixedly connected to the right side of the base, a conveying roller disposed above the base, a support block fixedly connected to the front of the housing, a second motor fixedly connected to the left side of the support block, and a gear fixedly connected to the output end of the second motor on its right side.
[0004] The above technical solution uses a rangefinder to measure the distance of the pulled cable and then uses a rotating printing wheel to press and print the mark. However, because the cable needs to be stopped intermittently during the printing process, it is difficult to continuously feed the cable. In addition, the cable has inertia during the feeding process, which causes the cable to slide forward after measuring the distance, resulting in poor accuracy of the printed mark on the cable. Utility Model Content
[0005] (1) Technical problems to be solved
[0006] To address the shortcomings of existing technologies, the purpose of this utility model is to provide a power engineering measuring device. This device aims to solve the technical problems of poor accuracy in cable printing marks caused by the need for intermittent cable feeding during the printing process, which makes continuous cable feeding difficult, and the inertia of the cable during feeding, which causes the cable to continue sliding forward after measuring the distance.
[0007] (2) Technical solution
[0008] To solve the above-mentioned technical problems, this utility model provides a power engineering measuring device, which includes a base and an adjustable embossing wheel mounted on the top of the base. Fixed seats are installed on both sides of the top surface of the base, and mounting rods are symmetrically fixed to the top of each of the two fixed seats. Support wheels are symmetrically rotatably arranged between the two fixed seats. A lifting plate is fixed between the two mounting rods via a positioning adjustment component. A rotating shaft is rotatably arranged in the lifting plate. Both ends of the embossing wheel are fixedly connected to the rotating shaft via an installation mechanism, and a cable body is tightly arranged between the embossing wheel and the two support wheels.
[0009] When using this technical solution, an embossing wheel is rotatably installed at the top of the base. The arc-shaped grooves on the outer walls of the embossing wheel and two support wheels are tightly connected to the outer wall of the cable body. During the conveying process, the cable body drives the embossing wheel and support wheels to rotate. The embossing wheel measures the outer wall of the cable body with embossing when it rotates once. By quantitatively setting the circumference of the embossing wheel, quantitative embossing measurement is achieved during the movement of the cable body, improving the smoothness and accuracy of the embossing. Fastening shafts are fixed at both ends of the embossing wheel and are slidably inserted into the rotating shaft. After unscrewing the nut, the fastening bolt slides out of the second through hole, allowing the embossing wheel to be disassembled and replaced. By replacing the embossing wheel with one of different circumferences, it is suitable for embossing positioning of different lengths of the cable body. Multiple first through holes are opened on the side wall of the mounting rod. The knob bolt passes through the first through holes at different positions and connects to the screw hole, allowing embossing wheels with different circumferences to be installed at different positions on the mounting rod. This ensures that the embossing wheels with different circumferences are tightly connected to the outer wall of the cable body, making it suitable for embossing distance measurement of different spacings of the cable body.
[0010] Preferably, the outer wall center of the embossing wheel and the two support wheels are provided with an arc-shaped groove that fits the outer wall of the cable body, and an embossing plate protruding from the arc-shaped groove is fixed in the embossing wheel.
[0011] Furthermore, each of the two mounting rods has a sliding groove at one end that is close to the other, and the side wall of the mounting rod has a first through hole that is equidistant from the sliding groove.
[0012] Furthermore, both ends of the lifting plate are fitted into the sliding groove, and the side walls of the lifting plate are symmetrically provided with screw holes.
[0013] Furthermore, the positioning adjustment component is a knob bolt that slides into the first through hole, and the knob bolt extends into the sliding groove and is threaded into the screw hole.
[0014] Furthermore, both ends of the embossing wheel are fixed with fastening shafts that fit into the rotating shaft, and the side wall of the rotating shaft is provided with a second through hole that passes through the fastening shaft.
[0015] Furthermore, the mounting mechanism includes a fastening bolt and a nut threaded onto the fastening bolt, the fastening bolt being slidably inserted into the second through hole.
[0016] (3) Beneficial effects
[0017] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0018] This utility model features an embossing wheel that rotates at the top of the base. The arc-shaped grooves on the outer walls of the embossing wheel and two support wheels are tightly connected to the outer wall of the cable body. During the transport process, the cable body drives the embossing wheel and support wheels to rotate. The embossing wheel measures the outer wall of the cable body with embossing when it rotates one revolution. By quantitatively setting the circumference of the embossing wheel, quantitative embossing measurement is achieved during the movement of the cable body, thereby improving the smoothness and accuracy of the embossing process.
[0019] By fixing fastening shafts at both ends of the embossing wheel, which are slidably inserted into the rotating shaft, and by unscrewing the nut to allow the fastening bolt to slide out of the second through hole, the embossing wheel can be disassembled and replaced. By replacing the embossing wheel with one of different circumferences, it is suitable for embossing and positioning of different lengths of cable body. By opening multiple first through holes on the side wall of the mounting rod, and connecting the knob bolts through the first through holes at different positions to the screw holes, embossing wheels with different circumferences can be installed at different positions on the mounting rod, so that the embossing wheels with different circumferences are tightly connected to the outer wall of the cable body, which is suitable for embossing and measuring different spacings of the cable body. Attached Figure Description
[0020] 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 some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0021] Figure 1 This is a schematic diagram of the structure of this utility model;
[0022] Figure 2 This is a cross-sectional structural diagram of the present invention;
[0023] Figure 3 This utility model Figure 2 Enlarged schematic diagram of the structure at point A;
[0024] Figure 4 This utility model Figure 2 Enlarged schematic diagram of the structure at point B.
[0025] The markings in the attached diagram are as follows: 1. Base; 2. Cable body; 3. Fixing seat; 4. Mounting rod; 5. Embossing wheel; 6. Embossing plate; 7. Arc groove; 8. Slide groove; 9. Lifting plate; 10. Support wheel; 11. Rotating shaft; 12. First through hole; 13. Screw hole; 14. Knob bolt; 15. Fastening shaft; 16. Fastening bolt; 17. Nut; 18. Second through hole. Detailed Implementation
[0026] 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.
[0027] This specific embodiment is a power engineering measuring device, and its structural schematic diagram is shown below. Figure 1 and Figure 2 As shown, the power engineering measuring device includes a base 1 and an adjustable embossing wheel 5 mounted on the top of the base 1. Fixed seats 3 are installed on both sides of the top surface of the base 1. Mounting rods 4 are symmetrically fixed on the top of the two fixed seats 3. Support wheels 10 are symmetrically rotatably arranged between the two fixed seats 3. A lifting plate 9 is fixed between the two mounting rods 4 through a positioning adjustment component. A rotating shaft 11 is rotatably arranged in the lifting plate 9. Both ends of the embossing wheel 5 are fixedly connected to the rotating shaft 11 through an installation mechanism. A cable body 2 is tightly arranged between the embossing wheel 5 and the two support wheels 10.
[0028] The outer walls of the embossing wheel 5 and the two support wheels 10 are all provided with arc-shaped grooves 7 that fit against the outer wall of the cable body 2. An embossing plate 6 protruding from the arc-shaped groove 7 is fixed in the embossing wheel 5. The two mounting rods 4 are each provided with a sliding groove 8 at their closest ends. The side walls of the mounting rods 4 are provided with first through holes 12 that communicate with the sliding grooves 8 at equal intervals. Both ends of the lifting plate 9 are fitted into the sliding grooves 8, and the side walls of the lifting plate 9 are symmetrically provided with screw holes 13. The arc-shaped grooves 7 on the outer walls of the embossing wheel 5 and the two support wheels 10 are tightly connected to the outer wall of the cable body 2. During the conveying process of the cable body 2... The embossing wheel 5 and the support wheel 10 are driven to rotate. When the embossing wheel 5 rotates once, it embosses and measures the outer wall of the cable body 2. By quantitatively setting the circumference of the embossing wheel 5, the embossing measurement of the cable body 2 is quantitatively achieved during movement. A laying device for moving the power cable is set on one side of the base 1. The laying device is existing technology and will not be described in detail here. There are multiple sets of embossing wheels 5. The inner circumference of the arc groove 7 of the multiple embossing wheels 5 is 1 meter, 2 meters and 5 meters respectively. The lifting plates 9 on both sides of the embossing wheels 5 with different circumferences are fixed to the through holes at different positions, thereby realizing the embossing positioning of the cable with different lengths.
[0029] like Figure 3 and Figure 4 As shown, the positioning adjustment component is a knob bolt 14 that slides into the first through hole 12. The knob bolt 14 extends into the slide groove 8 and is threaded into the screw hole 13. Both ends of the embossing wheel 5 are fixed with fastening shafts 15 that fit into the rotating shaft 11. The side wall of the rotating shaft 11 has a second through hole 18 that passes through the fastening shaft 15. The mounting mechanism includes a fastening bolt 16 and a nut 17 that is threaded onto the fastening bolt 16. The fastening bolt 16 slides into the second through hole 18. After unscrewing the nut 17, the fastening bolt 16 slides out of the second through hole 18, thereby disassembling and replacing the embossing wheel 5. By replacing the embossing wheel 5 with different circumferences, it is suitable for embossing positioning of different lengths of the cable body 2. By opening multiple first through holes 12 on the side wall of the mounting rod 4, the knob bolt 14 passes through the first through holes 12 at different positions and connects to the screw hole 13, thereby allowing the embossing wheels 5 with different circumferences to be installed at different positions on the mounting rod 4.
[0030] Working principle: When using the device of this technical solution, the cable body 2 passes through the arc-shaped groove 7 between the embossing wheel 5 and the support wheel 10. The arc-shaped groove 7 on the outer wall of the embossing wheel 5 and the two support wheels 10 are tightly connected to the outer wall of the cable body 2. During the conveying process, the cable body 2 drives the embossing wheel 5 and the support wheel 10 to rotate. When the embossing wheel 5 rotates once, it embosses and measures the outer wall of the cable body 2, so that the cable body 2 is quantitatively embossed during movement. After unscrewing the nut 17, the fastening bolt 16 is slid out of the second through hole 18, thereby disassembling and replacing the embossing wheel 5, which has different... The embossing wheel 5 with different circumferences is suitable for embossing and positioning of different lengths of the cable body 2. After replacement, the fastening shafts 15 at both ends of the embossing wheel 5 are slidably inserted into the rotating shaft 11 and fixed by the fastening bolts 16. At the same time, the lifting plate 9 moves in the slide groove 8 to correspond to the first through hole 12 at different positions. The knob bolt 14 passes through the first through hole 12 at different positions and connects with the screw hole 13, so that the embossing wheels 5 with different circumferences are installed at different positions of the mounting rod 4, so that the embossing wheels 5 with different circumferences are tightly connected to the outer wall of the cable body 2, which is suitable for embossing distance measurement of different spacings of the cable body 2.
[0031] All technical features in this embodiment can be freely combined according to actual needs.
[0032] 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 power engineering measuring device, comprising a base (1) and an adjustable embossing wheel (5) mounted on the top of the base (1), characterized in that, The base (1) has two fixed seats (3) installed on both sides of its top surface. The top of each of the two fixed seats (3) is symmetrically fixed with mounting rods (4). Support wheels (10) are symmetrically rotatably arranged between the two fixed seats (3). A lifting plate (9) is fixed between the two mounting rods (4) through a positioning adjustment component. A rotating shaft (11) is rotatably arranged in the lifting plate (9). Both ends of the embossing wheel (5) are fixedly connected to the rotating shaft (11) through an installation mechanism. A cable body (2) is tightly arranged between the embossing wheel (5) and the two support wheels (10).
2. The power engineering measuring device according to claim 1, characterized in that, The embossing wheel (5) and the two support wheels (10) are provided with arc-shaped grooves (7) that fit the outer wall of the cable body (2) in an arc shape at the center position of the outer wall. An embossing plate (6) protruding from the arc-shaped groove (7) is fixed in the embossing wheel (5).
3. The power engineering measuring device according to claim 1, characterized in that, Both mounting rods (4) have a sliding groove (8) at their closest ends, and the sidewalls of the mounting rods (4) have first through holes (12) that communicate with the sliding grooves (8) at equal intervals.
4. The power engineering measuring device according to claim 3, characterized in that, Both ends of the lifting plate (9) are fitted into the sliding groove (8), and the side wall of the lifting plate (9) is symmetrically provided with screw holes (13).
5. A power engineering measuring device according to claim 4, characterized in that, The positioning adjustment component is a knob bolt (14) that is slidably inserted into the first through hole (12), and the knob bolt (14) extends into the slide groove (8) and is threaded into the screw hole (13).
6. The power engineering measuring device according to claim 1, characterized in that, Both ends of the embossing wheel (5) are fixed with fastening shafts (15) that fit into the rotating shaft (11), and the side wall of the rotating shaft (11) is provided with a second through hole (18) that passes through the fastening shaft (15).
7. A power engineering measuring device according to claim 6, characterized in that, The mounting mechanism includes a fastening bolt (16) and a nut (17) threaded onto the fastening bolt (16), the fastening bolt (16) being slidably inserted into the second through hole (18).