A cable with a connector
By designing the installation and connection mechanisms, utilizing spring clips for clamping and pressing plates for fixing, combined with extrusion components, the problem of requiring complex tools for cable connections is solved, enabling fast and reliable cable connections, reducing the risk of poor contact, and ensuring stable cable transmission.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- HEBEI YETAI CABLE CO LTD
- Filing Date
- 2025-12-05
- Publication Date
- 2026-06-19
Smart Images

Figure CN122246503A_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of cable technology, specifically a cable with a connector. Background Technology
[0002] A cable is a wire product made of one or more mutually insulated conductors (such as copper wire, aluminum wire, and other metal conductors) with an outer insulating protective layer. It is used to transmit electrical energy, signals, or realize electromagnetic energy conversion. A connector is a device used to connect two or more devices, components, or cables, enabling them to establish an electrical connection or signal transmission. By installing suitable connectors at both ends or one end of a cable, it can be directly connected to other devices or components without the need for additional processing of the cable. This combination combines the transmission function of a cable with the connection function of a connector, greatly improving the convenience and efficiency of equipment connection.
[0003] The authorized publication number "CN117832949B" describes "a communication cable with a connector and a connector assembly. This invention relates to the field of connector technology, comprising cable bodies arranged opposite each other. Each of the two cable bodies has a mating block on its opposite side for engaging the cables. A connecting sleeve is engaged between the outer surfaces of the two mating blocks. A limiting sleeve is fitted on the outer surface of the cable body, wherein the limiting sleeve is locked to the connecting sleeve by a rotational connection structure; the limiting sleeve comprises two hinged connecting plates. This communication cable with a connector assembly, through the arrangement of the mating blocks, facilitates the classification and placement of cables of different colors, allowing for direct one-to-one connection during subsequent connection. The cooperation between the connecting sleeve and the limiting sleeve facilitates sealing of the cable connection points, ensuring connection effectiveness, effectively preventing detachment, and improving the connection effect between cables."
[0004] The aforementioned patent facilitates the classification and placement of cables of different colors through the design of the mating blocks, enabling direct one-to-one connection during subsequent connections. However, this patent requires the cooperation of locking screws and locking sleeves to install the connector between the two cables. The locking screws and locking sleeves require corresponding tools for installation, making the connector installation cumbersome. Furthermore, it cannot secure the contact ends of the two cables, affecting the tightness between them and potentially leading to electrical faults due to poor connection, thus affecting the normal operation of power transmission. Summary of the Invention
[0005] The purpose of this invention is to achieve rapid connection of two cables through the cooperation of the installation mechanism and the connection mechanism, without the need for complex tools and professional skills. Operators can quickly complete the cable connection work, saving time and improving work efficiency. The fixing component uses the elasticity of the spring to clamp the cable and prevent it from shaking in the installation mechanism. The pressing component presses and fixes the cable through the pressing plate, further enhancing the stability of the fixation. This dual fixing method effectively reduces the movement of the cable during the connection process, ensures the accuracy of the connection position, and improves the reliability of the connection. The squeezing component in the connection mechanism can precisely squeeze the connection point of the two cable bodies, making each cable core in close contact. This close contact effectively reduces contact resistance, improves the quality of power transmission, reduces the risk of electrical faults caused by poor contact, and ensures stable transmission of power and signals.
[0006] The technical solution adopted in this invention is as follows: A cable with a connector, comprising:
[0007] Two cable bodies;
[0008] The installation mechanism is provided in two sets, and each set of the installation mechanism is provided on each cable body, which is used to fix the cable body;
[0009] A connecting mechanism is located between each set of installation mechanisms. It works in conjunction with the installation mechanisms to enable the two cable bodies to be quickly connected.
[0010] Multiple pressing plates are provided, each of which is mounted on the installation mechanism and is used to press and fix the cable body;
[0011] Multiple extrusion plates are provided, each of which is mounted on the connecting mechanism and is used to extrude the connection between two cable bodies.
[0012] The cable body includes multiple cable cores, multiple insulation layers, and a protective sleeve. Each insulation layer is wrapped around the outer wall of the cable core, and the protective sleeve is wrapped around the outer wall of each insulation layer.
[0013] Each of the installation mechanisms includes a first threaded cylinder, an inner threaded cylinder, multiple connecting cylinders, a fixing component, and a pressing component. The first threaded cylinder is movably sleeved on the outer wall of the cable body. The inner threaded cylinder is threadedly connected to the outer wall of the first threaded cylinder. The fixing component is located inside the first threaded cylinder. The pressing component is located inside the first threaded cylinder. Each connecting cylinder is equidistantly embedded in one side of the outer wall of the first threaded cylinder along the circumferential direction. Each insulation layer movably penetrates the inner wall of the connecting cylinder. Each cable body movably penetrates the inner wall of the first threaded cylinder.
[0014] Each set of fixing components includes a mounting ring, multiple spring pieces, an internal threaded groove, a third threaded cylinder, and a conical groove. The mounting ring is fixedly disposed on the inner wall of the first threaded cylinder. Each spring piece is equidistantly disposed on one side of the outer wall of the mounting ring along the circumferential direction. The internal threaded groove is opened on the inner wall of the first threaded cylinder. The third threaded cylinder is threadedly connected to the internal threaded groove. The conical groove is opened on the inner wall of the third threaded cylinder. Each spring piece is located on the inner wall of the conical groove.
[0015] Each set of pressing components includes a rotating shaft, a circular plate, multiple first cam holes, multiple moving rods, multiple moving holes, and a rotating assembly. The rotating shaft is rotatably embedded in one side of the outer wall of the first threaded cylinder. The circular plate is fixedly sleeved on the outer wall of the rotating shaft. Each first cam hole is equidistantly opened along the circumferential direction on one side of the outer wall of the circular plate. Each moving rod is slidably embedded in the inner wall of the first cam hole. Each moving hole is opened on one side of the outer wall of the first threaded cylinder. Each moving rod is slidably embedded in the inner wall of the moving hole. Each pressing plate is fixedly installed on the top of the outer wall of the moving rod. The rotating assembly is located on the first threaded cylinder.
[0016] Each of the rotating components includes a protective shell, a first gear, a first rack, and a first threaded rod. The protective shell is fixedly disposed on one side of the outer wall of the first threaded cylinder. The first gear is fixedly sleeved on the outer wall of the rotating shaft. The first rack is threadedly connected to the outer wall of the first threaded rod, and the first rack and the protective shell are in sliding fit, and the first rack and the first gear are meshed.
[0017] The connecting mechanism includes an installation cylinder, two second threaded cylinders, an installation plate, multiple installation frames, multiple fixed cylinders, and an extrusion component. Each second threaded cylinder is fixedly disposed on both sides of the outer wall of the installation cylinder, and each second threaded cylinder is threadedly connected to the inner wall of the inner threaded cylinder. The extrusion component is disposed inside the installation cylinder. The installation plate is fixedly disposed on the inner wall of the installation cylinder. Each installation frame is equidistantly embedded in one side of the outer wall of the installation plate along the circumferential direction. Each fixed cylinder is fixedly embedded in one side of the outer wall of the installation cylinder. Each connecting cylinder is snapped into the inner wall of the fixed cylinder.
[0018] The extrusion component includes an annular plate, multiple second cam holes, multiple push rods, multiple push grooves, a rotating assembly, and a driving assembly. The annular plate is movably fitted onto the outer wall of the mounting plate. Each second cam hole is equidistantly opened on one side of the outer wall of the annular plate along the circumferential direction. Each push rod is slidably embedded in the inner wall of the second cam hole. Each push groove is opened on one side of the outer wall of the mounting plate. Each push rod is slidably embedded in the inner wall of the push groove. Each extrusion plate is fixedly installed on the top of the outer wall of the push rod. The rotating assembly is located on the annular plate, and the driving assembly is located on the mounting cylinder.
[0019] The rotating assembly includes a large gear, a rotating shaft, and a small gear. The large gear is fixedly sleeved on one side of the outer wall of the annular plate, the rotating shaft is rotatably embedded on one side of the outer wall of the mounting cylinder, and the small gear is fixedly sleeved on the outer wall of the rotating shaft, with the small gear meshing with the large gear.
[0020] The drive assembly includes a placement frame, a second gear, a second rack, and a second threaded rod. The placement frame is fixedly disposed on one side of the outer wall of the mounting cylinder. The second gear is fixedly sleeved on the outer wall of the rotating shaft. The second rack is threadedly connected to the outer wall of the second threaded rod, and the second rack and the placement frame are in sliding engagement, and the second rack and the second gear are meshed. The second threaded rod is rotatably embedded in the inner wall of the placement frame.
[0021] In summary, due to the adoption of the above technical solution, the beneficial effects of the present invention are:
[0022] (1) In this invention, the installation mechanism and the connection mechanism work together to achieve a quick connection of two cables without the need for complicated tools and professional skills. Operators can quickly complete the cable connection work, saving time and improving work efficiency. The fixing component uses the elasticity of the spring to clamp the cable and prevent it from shaking in the installation mechanism. The pressing component presses and fixes the cable through the pressing plate, which further enhances the stability of the fixation. This double fixing method effectively reduces the movement of the cable during the connection process, ensures the accuracy of the connection position, and improves the reliability of the connection.
[0023] (2) In this invention, the extrusion component in the connection mechanism can precisely extrude the connection between the two cable bodies, so that each cable core is in close contact. This close contact effectively reduces the contact resistance, improves the power transmission quality, reduces the risk of electrical faults caused by poor contact, and ensures the stable transmission of power and signals. Attached Figure Description
[0024] Figure 1 This is a perspective view of the present invention;
[0025] Figure 2 This is a schematic diagram of the installation mechanism of the present invention;
[0026] Figure 3 This is a partially exploded view of the mounting mechanism of the present invention;
[0027] Figure 4 This is a cross-sectional view of the present invention;
[0028] Figure 5 This is a cross-sectional view of the placement frame of the present invention;
[0029] Figure 6 This is a cross-sectional view of the mounting cylinder of the present invention;
[0030] Figure 7 This is an exploded view of the connecting mechanism of the present invention;
[0031] Figure 8 This is a schematic diagram of the structure of the first threaded cylinder of the present invention;
[0032] Figure 9 This is a cross-sectional view of the first threaded cylinder of the present invention;
[0033] Figure 10 For the present invention Figure 4 An enlarged diagram of A in the diagram.
[0034] Markings in the diagram: 1. Cable body; 101. Cable core; 102. Insulation layer; 103. Protective sleeve; 2. Installation mechanism; 201. First threaded cylinder; 202. Internal threaded cylinder; 203. Connecting cylinder; 204. Mounting ring; 205. Spring; 206. Internal threaded groove; 207. Third threaded cylinder; 208. Tapered groove; 209. Rotating shaft; 210. Circular plate; 211. First cam hole; 212. Moving rod; 213. Moving hole; 214. Protective shell; 215. First gear; 21 6. First rack; 217. First threaded rod; 3. Connecting mechanism; 301. Mounting cylinder; 302. Second threaded cylinder; 303. Mounting plate; 304. Mounting frame; 305. Fixing cylinder; 306. Annular plate; 307. Second cam hole; 308. Push rod; 309. Push groove; 310. Second threaded rod; 311. Large gear; 312. Rotating shaft; 313. Small gear; 314. Placement frame; 315. Second gear; 316. Second rack; 4. Pressing plate; 5. Extrusion plate. Detailed Implementation
[0035] To make the objectives, technical solutions, and advantages of this invention clearer, the invention 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 and not intended to limit the invention.
[0036] Example 1, refer to Figure 1-10 A cable with a connector, comprising:
[0037] Two cable bodies 1;
[0038] The installation mechanism 2 is provided in two sets, with each set of installation mechanism 2 being installed on each cable body 1, which is used to fix the cable body 1.
[0039] The connecting mechanism 3 is located between each set of installation mechanisms 2. It cooperates with the installation mechanism 2 to enable the two cable bodies 1 to be quickly connected.
[0040] Multiple pressing plates 4 are provided, each pressing plate 4 is provided on the mounting mechanism 2, and is used to press and fix the cable body 1;
[0041] There are multiple extrusion plates 5, each of which is located on the connecting mechanism 3 and is used to extrude the connection between the two cable bodies 1.
[0042] In this implementation scheme: the installation mechanism 2 and the connection mechanism 3 work together to achieve a quick connection of the two cable bodies 1 without the need for complicated tools or professional skills. Operators can quickly complete the connection of the cable bodies 1, saving time and improving work efficiency. Each pressing plate 4 and extrusion plate 5 has a rubber pad on the side of its outer wall that contacts the cable body 1, which provides good cushioning and protection, avoiding damage to the cable during pressing and extrusion, and extending the cable's service life. The connection mechanism 3 ensures tight contact between each cable core 101. The pressing action of the pressing plate 4 effectively fixes the cable, reduces cable movement during the connection process, and improves the reliability and quality of the connection. The extrusion plate 5 extrudes the connection point of the two cable bodies 1 to ensure tight contact, effectively reducing contact resistance, improving power transmission quality, and reducing the risk of electrical faults caused by poor contact.
[0043] Specifically, the cable body 1 includes multiple cable cores 101, multiple insulation layers 102, and a protective sleeve 103. Each insulation layer 102 is wrapped around the outer wall of the cable core 101, and the protective sleeve 103 is wrapped around the outer wall of each insulation layer 102.
[0044] In this embodiment: the cable core 101 is the core part of the cable for transmitting electrical energy and is responsible for the conduction of electrical energy. The insulation layer 102 plays an insulating role, preventing leakage between cable cores 101 and between cable cores 101 and the outside world, thus ensuring electrical safety. The protective sleeve 103 protects the internal cable cores 101 and insulation layer 102, resisting external mechanical damage, chemical corrosion, etc., and extending the service life of the cable.
[0045] Specifically, each installation mechanism 2 includes a first threaded cylinder 201, an inner threaded cylinder 202, multiple connecting cylinders 203, a fixing component, and a pressing component. The first threaded cylinder 201 is movably sleeved on the outer wall of the cable body 1. The inner threaded cylinder 202 is threadedly connected to the outer wall of the first threaded cylinder 201. The fixing component is located inside the first threaded cylinder 201. The pressing component is located inside the first threaded cylinder 201. Each connecting cylinder 203 is equidistantly embedded in one side of the outer wall of the first threaded cylinder 201 along the circumferential direction. Each insulation layer 102 movably penetrates the inner wall of the connecting cylinder 203. Each cable body 1 movably penetrates the inner wall of the first threaded cylinder 201.
[0046] In this embodiment: the first threaded cylinder 201 provides an installation position for other components. The internal threaded cylinder 202 enables a fixed connection between the first threaded cylinder 201 and the second threaded cylinder 302. The connecting cylinder 203 is used to guide and fix the insulation layer 102, ensuring the accurate position of the cable core 101 within the installation mechanism 2. The fixing component is used to firmly fix the cable body 1 within the installation mechanism 2. The pressing component is used to press and fix the cable core 101, further fixing the cable body 1, enhancing the stability of the fixation, and achieving reliable installation and fixation of the cable body 1. This provides a stable foundation for subsequent connection operations, effectively preventing the cable body 1 from loosening or shifting during the connection process, and improving the reliability of the connection.
[0047] Specifically, each set of fixing components includes a mounting ring 204, multiple spring pieces 205, an internal threaded groove 206, a third threaded cylinder 207, and a tapered groove 208. The mounting ring 204 is fixedly disposed on the inner wall of the first threaded cylinder 201. Each spring piece 205 is fixedly disposed equidistantly on one side of the outer wall of the mounting ring 204 along the circumferential direction. The internal threaded groove 206 is opened on the inner wall of the first threaded cylinder 201. The third threaded cylinder 207 is threadedly connected to the internal threaded groove 206. The tapered groove 208 is opened on the inner wall of the third threaded cylinder 207. Each spring piece 205 is located on the inner wall of the tapered groove 208.
[0048] In this embodiment: the mounting ring 204 provides a mounting base for the spring piece 205. The spring piece 205 has a certain elasticity and can deform when compressed, thereby generating a clamping force on the cable body 1. The internal thread groove 206 and the third threaded cylinder 207 are connected by threads to adjust the degree of compression of the spring piece 205. The tapered groove 208 cooperates with the spring piece 205 so that the spring piece 205 can contract inward evenly when compressed, thereby better fixing the cable body 1 and effectively preventing the cable body 1 from shaking in the mounting mechanism 2, thereby reducing connection failures caused by cable loosening.
[0049] Specifically, each pressing component includes a rotating shaft 209, a circular plate 210, multiple first cam holes 211, multiple moving rods 212, multiple moving holes 213, and a rotating assembly. The rotating shaft 209 is rotatably embedded in one side of the outer wall of the first threaded cylinder 201. The circular plate 210 is fixedly sleeved on the outer wall of the rotating shaft 209. Each first cam hole 211 is equidistantly opened in the circumferential direction on one side of the outer wall of the circular plate 210. Each moving rod 212 is slidably embedded in the inner wall of the first cam hole 211. Each moving hole 213 is opened in one side of the outer wall of the first threaded cylinder 201. Each moving rod 212 is slidably embedded in the inner wall of the moving hole 213. Each pressing plate 4 is fixedly set on the top of the outer wall of the moving rod 212. The rotating assembly is set on the first threaded cylinder 201.
[0050] In this embodiment: the rotating shaft 209 serves as the rotation center of the circular plate 210, enabling the circular plate 210 to rotate. As the circular plate 210 rotates, the first cam hole 211 on the circular plate 210 pushes the moving rod 212 to slide within the moving hole 213, causing the moving rod 212 to drive the pressing plate 4 to move up and down, thereby pressing and fixing the cable. The rotating assembly is used to drive the rotating shaft 209 to rotate. Each moving rod 212 is movably inserted through the inner wall of the connecting cylinder 203, so that the pressing plate 4 can fix the insulation layer 102 in each connecting cylinder 203, further enhancing the stability of the cable within the installation mechanism 2 and ensuring that the cable will not move during the connection process.
[0051] Specifically, each rotating assembly includes a protective shell 214, a first gear 215, a first rack 216, and a first threaded rod 217. The protective shell 214 is fixedly disposed on one side of the outer wall of the first threaded cylinder 201. The first gear 215 is fixedly sleeved on the outer wall of the rotating shaft 209. The first rack 216 is threadedly connected to the outer wall of the first threaded rod 217, and the first rack 216 and the protective shell 214 are in sliding engagement, and the first rack 216 and the first gear 215 are meshed.
[0052] In this embodiment: the protective shell 214 is wrapped around the outer wall of the circular plate 210. A sliding hole is provided on one side of the outer wall of the protective shell 214. The first rack 216 is slidably embedded in the inner wall of the sliding hole. The sliding hole guides the movement of the first rack 216. The protective shell 214 protects the first gear 215 and the first rack 216 inside, preventing external impurities from entering and affecting the normal operation of the components. The first gear 215 and the first rack 216 are meshed and transmitted, converting the linear motion of the first rack 216 into the rotational motion of the first gear 215, thereby driving the rotating shaft 209 to rotate. The first threaded rod 217 is used to drive the first rack 216 to make linear motion. This transmission method has the characteristics of high transmission accuracy and good stability, which can ensure that the pressing plate 4 performs the pressing operation according to the predetermined requirements, accurately adjust the pressing degree of the pressing plate 4, and improve the accuracy and reliability of pressing.
[0053] Specifically, the connecting mechanism 3 includes an mounting cylinder 301, two second threaded cylinders 302, a mounting plate 303, multiple mounting frames 304, multiple fixed cylinders 305, and a pressing component. Each second threaded cylinder 302 is fixedly disposed on both sides of the outer wall of the mounting cylinder 301, and each second threaded cylinder 302 is threadedly connected to the inner wall of the inner threaded cylinder 202. The pressing component is disposed inside the mounting cylinder 301. The mounting plate 303 is fixedly disposed on the inner wall of the mounting cylinder 301. Each mounting frame 304 is fixedly embedded at equal intervals along the circumferential direction on one side of the outer wall of the mounting plate 303. Each fixed cylinder 305 is fixedly embedded on one side of the outer wall of the mounting cylinder 301. Each connecting cylinder 203 is snapped into the inner wall of the fixed cylinder 305.
[0054] In this embodiment: each connecting cylinder 203 has a protrusion on its outer wall and each fixing cylinder 305 has a groove on its inner wall. The protrusion can be embedded in the groove, so that the connecting cylinder 203 is snapped into the fixing cylinder 305. The mounting plate 303 in the mounting cylinder 301 can provide a mounting base for the mounting frame 304. The mounting frame 304 plays an auxiliary role in fixing and positioning. The fixing cylinder 305 snaps into the connecting cylinder 203 so that the cable core 101 in each cable body 1 can enter the mounting frame 304. With the help of the pressing component, the cable cores 101 of the two cable bodies 1 are pressed to make each cable core 101 in close contact, ensuring reliable conduction of electrical energy and avoiding poor connection stability and poor contact.
[0055] Specifically, the extrusion component includes an annular plate 306, multiple second cam holes 307, multiple push rods 308, multiple push grooves 309, a rotating assembly, and a driving assembly. The annular plate 306 is movably sleeved on the outer wall of the mounting plate 303. Each second cam hole 307 is equidistantly opened on one side of the outer wall of the annular plate 306 along the circumferential direction. Each push rod 308 is slidably embedded in the inner wall of the second cam hole 307. Each push groove 309 is opened on one side of the outer wall of the mounting plate 303. Each push rod 308 is slidably embedded in the inner wall of the push groove 309. Each extrusion plate 5 is fixedly set on the top of the outer wall of the push rod 308. The rotating assembly is set on the annular plate 306, and the driving assembly is set on the mounting cylinder 301.
[0056] In this embodiment: the annular plate 306 serves as the basic structure of the extrusion component, providing an installation position for other components. As the annular plate 306 rotates, the second cam hole 307 drives the push rod 308 to slide within the push groove 309. The push rod 308 drives the extrusion plate 5 to move towards the cable core 101 on the cable body 1, thereby extruding the cable core 101 and ensuring that the cable core 101 on each cable body 1 can make close contact. This effectively avoids poor contact and improves the reliability of the connection and the quality of power transmission. The rotating component is used to drive the annular plate 306 to rotate, and the driving component provides power to the rotating component.
[0057] Specifically, the rotating assembly includes a large gear 311, a rotating shaft 312, and a small gear 313. The large gear 311 is fixedly sleeved on one side of the outer wall of the annular plate 306, the rotating shaft 312 is rotatably embedded on one side of the outer wall of the mounting cylinder 301, and the small gear 313 is fixedly sleeved on the outer wall of the rotating shaft 312, and the small gear 313 meshes with the large gear 311.
[0058] In this embodiment, the large gear 311 and the small gear 313 mesh to achieve the effect of speed reduction and torque increase, and transmit the power from the drive component to the annular plate 306 with appropriate torque and speed, thereby driving the annular plate 306 to rotate.
[0059] Specifically, the drive assembly includes a placement frame 314, a second gear 315, a second rack 316, and a second threaded rod 310. The placement frame 314 is fixedly disposed on one side of the outer wall of the mounting cylinder 301. The second gear 315 is fixedly sleeved on the outer wall of the rotating shaft 312. The second rack 316 is threadedly connected to the outer wall of the second threaded rod 310, and the second rack 316 and the placement frame 314 are in sliding engagement, and the second rack 316 and the second gear 315 are meshed. The second threaded rod 310 is rotatably embedded in the inner wall of the placement frame 314.
[0060] In this embodiment: a guide hole is provided on one side of the outer wall of the placement frame 314. The guide hole slides with the second rack 316, which guides and limits the second rack 316. The placement frame 314 provides installation space and protection for the second gear 315 and the second rack 316. The second gear 315 and the second rack 316 are meshed and transmitted, which converts the linear motion of the second rack 316 into the rotational motion of the second gear 315, thereby driving the rotating shaft 312 to rotate. The second threaded rod 310 is used to drive the second rack 316 to make linear motion. By rotating the second threaded rod 310, the moving distance of the second rack 316 is accurately controlled, thereby accurately controlling the extrusion degree of the extrusion plate 5, improving the accuracy and controllability of the extrusion operation.
[0061] In use, each cable body 1 is first passed through the first threaded cylinder 201, and the insulation layer 102 on the cable body 1 is allowed to pass through the inner wall of the connecting cylinder 203. At the same time, the cable core 101 on the cable body 1 is exposed outside the connecting cylinder 203. The third threaded cylinder 207 is rotated. Since the third threaded cylinder 207 is threadedly connected to the inner threaded groove 206, as the third threaded cylinder 207 rotates, the conical groove 208 on its inner wall will gradually squeeze the spring piece 205 on the mounting ring 204. When squeezed, the spring piece 205 deforms and contracts evenly inward, thereby tightly clamping the cable body 1, achieving initial fixation of the cable body 1. The first threaded rod 21 is then manually rotated. 7. The first threaded rod 217 drives the first rack 216 to move linearly within the sliding hole of the protective shell 214. Since the first rack 216 meshes with the first gear 215, the first gear 215 rotates with the movement of the first rack 216. The first gear 215 is fixedly sleeved on the rotating shaft 209, so the rotating shaft 209 also rotates accordingly. The rotating shaft 209 drives the circular plate 210 to rotate. The first cam hole 211 on the circular plate 210, as it rotates, pushes the moving rod 212 to slide within the moving hole 213. The moving rod 212 drives the pressing plate 4 to move up and down, pressing the pressing plate 4 onto the insulating layer 102, further fixing the cable and enhancing its electrical stability. To ensure cable stability, each connecting cylinder 203 is placed inside the fixing cylinder 305, allowing each cable core 101 to be installed within the mounting frame 304. Then, the internal threaded cylinder 202 is rotated to thread it onto the second threaded cylinder 302, fixing the two first threaded cylinders 201 together with the mounting cylinder 301, thus achieving the initial connection of the two cable bodies 1. Finally, the second threaded rod 310 is manually rotated, driving the second rack 316 to move linearly within the guide hole of the placement frame 314. Since the second rack 316 meshes with the second gear 315, the second gear 315 rotates along with the movement of the second rack 316. The second gear 315 is fixedly sleeved on the rotating shaft 312, so the rotating shaft 312 will also rotate. The rotating shaft 312 drives the small gear 313 to rotate. The small gear 313 meshes with the large gear 311, driving the annular plate 306 to rotate. As the annular plate 306 rotates, the second cam hole 307 on the annular plate 306 drives the push rod 308 to slide in the push groove 309. The push rod 308 drives the extrusion plate 5 to move towards the cable core 101 on the cable body 1, thereby extruding the cable core 101 and ensuring that the cable core 101 on each cable body 1 can make close contact, effectively avoiding the occurrence of poor contact, and improving the reliability of the connection and the quality of power transmission.
[0062] The above description is merely a preferred embodiment of the present invention and is not intended to limit the present invention. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A cable with a connector, characterized in that, include: Two cable bodies (1); The installation mechanism (2) is provided in two sets. Each set of the installation mechanism (2) is provided on each cable body (1) and is used to fix the cable body (1). A connecting mechanism (3) is provided between each set of installation mechanisms (2), and it cooperates with the installation mechanism (2) to enable the two cable bodies (1) to be quickly connected; Multiple pressing plates (4) are provided, each pressing plate (4) is provided on the mounting mechanism (2), and is used to press and fix the cable body (1). There are multiple extrusion plates (5), each of which is located on the connecting mechanism (3) and is used to extrude the connection between the two cable bodies (1).
2. The cable with connector as described in claim 1, characterized in that: The cable body (1) includes multiple cable cores (101), multiple insulation layers (102) and a protective sleeve (103). Each insulation layer (102) is wrapped around the outer wall of the cable core (101), and the protective sleeve (103) is wrapped around the outer wall of each insulation layer (102).
3. A cable with a connector as described in claim 2, characterized in that: Each set of installation mechanisms (2) includes a first threaded cylinder (201), an inner threaded cylinder (202), multiple connecting cylinders (203), a fixing component, and a pressing component. The first threaded cylinder (201) is movably sleeved on the outer wall of the cable body (1). The inner threaded cylinder (202) is threadedly connected to the outer wall of the first threaded cylinder (201). The fixing component is located inside the first threaded cylinder (201). The pressing component is located inside the first threaded cylinder (201). Each connecting cylinder (203) is equidistantly embedded in one side of the outer wall of the first threaded cylinder (201) along the circumferential direction. Each insulation layer (102) movably penetrates the inner wall of the connecting cylinder (203). Each cable body (1) movably penetrates the inner wall of the first threaded cylinder (201).
4. A cable with a connector as described in claim 3, characterized in that: Each set of fixing components includes a mounting ring (204), multiple spring pieces (205), an internal threaded groove (206), a third threaded cylinder (207), and a conical groove (208). The mounting ring (204) is fixedly disposed on the inner wall of the first threaded cylinder (201). Each spring piece (205) is fixedly disposed equidistantly on one side of the outer wall of the mounting ring (204) along the circumferential direction. The internal threaded groove (206) is opened on the inner wall of the first threaded cylinder (201). The third threaded cylinder (207) is threadedly connected to the internal threaded groove (206). The conical groove (208) is opened on the inner wall of the third threaded cylinder (207). Each spring piece (205) is located on the inner wall of the conical groove (208).
5. A cable with a connector as described in claim 4, characterized in that: Each set of pressing components includes a rotating shaft (209), a circular plate (210), multiple first cam holes (211), multiple moving rods (212), multiple moving holes (213), and a rotating assembly. The rotating shaft (209) is rotatably embedded in one side of the outer wall of the first threaded cylinder (201). The circular plate (210) is fixedly sleeved on the outer wall of the rotating shaft (209). Each first cam hole (211) is equidistantly opened in the circumferential direction on one side of the outer wall of the circular plate (210). Each moving rod (212) is slidably embedded in the inner wall of the first cam hole (211). Each moving hole (213) is opened in one side of the outer wall of the first threaded cylinder (201). Each moving rod (212) is slidably embedded in the inner wall of the moving hole (213). Each pressing plate (4) is fixedly set on the top of the outer wall of the moving rod (212). The rotating assembly is set on the first threaded cylinder (201).
6. A cable with a connector as described in claim 5, characterized in that: Each of the rotating components includes a protective shell (214), a first gear (215), a first rack (216), and a first threaded rod (217). The protective shell (214) is fixedly disposed on one side of the outer wall of the first threaded cylinder (201). The first gear (215) is fixedly sleeved on the outer wall of the rotating shaft (209). The first rack (216) is threadedly connected to the outer wall of the first threaded rod (217). The first rack (216) and the protective shell (214) are in sliding engagement, and the first rack (216) and the first gear (215) are meshed.
7. A cable with a connector as described in claim 6, characterized in that: The connecting mechanism (3) includes an mounting cylinder (301), two second threaded cylinders (302), a mounting plate (303), multiple mounting frames (304), multiple fixed cylinders (305), and an extrusion component. Each second threaded cylinder (302) is fixedly disposed on both sides of the outer wall of the mounting cylinder (301), and each second threaded cylinder (302) is threadedly connected to the inner wall of the inner threaded cylinder (202). The extrusion component is disposed inside the mounting cylinder (301). The mounting plate (303) is fixedly disposed on the inner wall of the mounting cylinder (301). Each mounting frame (304) is fixedly embedded at equal intervals along the circumferential direction on one side of the outer wall of the mounting plate (303). Each fixed cylinder (305) is fixedly embedded on one side of the outer wall of the mounting cylinder (301). Each connecting cylinder (203) is snapped into the inner wall of the fixed cylinder (305).
8. A cable with a connector as described in claim 7, characterized in that: The extrusion component includes an annular plate (306), multiple second cam holes (307), multiple push rods (308), multiple push grooves (309), a rotating assembly, and a driving assembly. The annular plate (306) is movably sleeved on the outer wall of the mounting plate (303). Each second cam hole (307) is equidistantly opened on one side of the outer wall of the annular plate (306) along the circumferential direction. Each push rod (308) is slidably embedded in the inner wall of the second cam hole (307). Each push groove (309) is opened on one side of the outer wall of the mounting plate (303). Each push rod (308) is slidably embedded in the inner wall of the push groove (309). Each extrusion plate (5) is fixedly set on the top of the outer wall of the push rod (308). The rotating assembly is set on the annular plate (306), and the driving assembly is set on the mounting cylinder (301).
9. A cable with a connector as described in claim 8, characterized in that: The rotating assembly includes a large gear (311), a rotating shaft (312), and a small gear (313). The large gear (311) is fixedly sleeved on one side of the outer wall of the annular plate (306). The rotating shaft (312) is rotatably embedded on one side of the outer wall of the mounting cylinder (301). The small gear (313) is fixedly sleeved on the outer wall of the rotating shaft (312), and the small gear (313) meshes with the large gear (311).
10. A cable with a connector as described in claim 9, characterized in that: The drive assembly includes a placement frame (314), a second gear (315), a second rack (316), and a second threaded rod (310). The placement frame (314) is fixedly disposed on one side of the outer wall of the mounting cylinder (301). The second gear (315) is fixedly sleeved on the outer wall of the rotating shaft (312). The second rack (316) is threadedly connected to the outer wall of the second threaded rod (310). The second rack (316) and the placement frame (314) are in sliding engagement, and the second rack (316) and the second gear (315) are meshed. The second threaded rod (310) is rotatably embedded in the inner wall of the placement frame (314).