Wire stripping tool
By introducing an articulated structure and magnetic components into the wire stripping tool, the problem of traditional wire strippers relying on hand strength is solved, achieving efficient and comfortable wire stripping, adapting to various scenario needs, and improving operational accuracy and safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENHUA SHENDONG POWER
- Filing Date
- 2025-07-07
- Publication Date
- 2026-06-09
AI Technical Summary
Traditional wire stripper operation relies on hand strength, which leads to hand fatigue and makes it difficult to meet precision requirements, posing safety hazards, especially in precision electronic equipment assembly and aerospace cable handling.
Design a wire stripping tool that uses a hinged structure of a first clamp body and a second clamp body, combined with a magnetic component to help fix the wire, reducing the force of hand gripping. The magnetic component automatically attracts the metal conductor of the wire to achieve stable positioning and reduce hand strain.
Significantly reduces hand fatigue, improves operating comfort, enhances wire stripping accuracy, reduces the risk of conductor damage, adapts to different wire diameters and materials, extends tool life, saves storage space, and reduces the risk of parts loss.
Smart Images

Figure CN224342826U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of electrical tools, and in particular to a wire stripping tool. Background Technology
[0002] Wire strippers are a common tool in electrical work, mainly used to remove the insulation layer from the surface of electrical wires. Their structure mainly consists of two handles connected by a pivot and a head. In actual operation, the user needs to precisely place the wire in a specific position on the head, then grip the handles tightly, causing the two heads to move closer together under the action of the pivot. Using the blades or cutting edges of the heads, the wire is clamped. After the blades cut into the insulation layer, as the pressure continues to increase, the insulation layer is successfully cut off, thus completing the wire stripping action.
[0003] While this method of operation is simple, direct, and easy to learn, it requires a high level of hand strength from the user. If the strength is insufficient, it may be impossible to complete the wire stripping operation smoothly. Prolonged use of traditional wire strippers can easily lead to hand fatigue, which not only affects work efficiency but may also cause safety issues due to operational errors. Utility Model Content
[0004] In view of the above problems, this utility model is proposed. This utility model provides a wire stripping tool that can help fix the wire during the wire stripping operation, reduce the force of the operator's hand on the wire, and reduce hand fatigue.
[0005] According to one aspect of the present invention, a wire stripping tool is provided, comprising a first clamp body, a second clamp body, and at least one magnetic component. The first clamp body and the second clamp body are hinged together. The first clamp body includes a first stripping portion and a first gripping portion. The second clamp body includes a second stripping portion and a second gripping portion. The first stripping portion and the second stripping portion are disposed opposite to each other. At least one of the magnetic components is detachably fixed to the surface of the first stripping portion and / or at least one of the magnetic components is detachably fixed to the surface of the second stripping portion.
[0006] Compared with the prior art, the wire stripping tool provided by this utility model includes: a first clamp body and a second clamp body, which are hinged together. The first clamp body includes a first stripping part and a first gripping part, and the second clamp body includes a second stripping part and a second gripping part. The first stripping part and the second stripping part are arranged opposite to each other. Therefore, when wire stripping is required, the wire is simply placed between the first stripping part and the second stripping part, and a gripping force is applied by the first gripping part and the second gripping part to close the first stripping part and the wire stripping operation is completed. At this time, since the wire stripping tool also includes at least one magnetic component, at least one magnetic component is detachably fixed to the surface of the first stripping part and / or at least one magnetic component is detachably fixed to the surface of the second stripping part. Therefore, during the wire stripping operation, when the wire is placed between the first stripping part and the second stripping part, the magnetic component can be used to help fix the wire. The magnetic component will automatically attract the metal conductor of the wire, positioning and stabilizing the wire, so that a small gripping force is applied to the first gripping part and the second gripping part to close the first stripping part and the second stripping part. During this process, operators do not need to use a lot of hand strength to press the wires, which greatly reduces the gripping force and reduces hand muscle strain. Even when stripping wires for a long time, it is not easy to cause hand fatigue, which significantly improves the comfort of operation.
[0007] Based on this, the magnetic component is detachably fixed to the surface of the first and / or second wire stripping sections, allowing for easy disassembly and replacement of the magnetic component after its magnetic force weakens or is damaged. This extends the overall service life of the wire stripping tool and reduces operating costs. Furthermore, it allows for flexible selection of whether to install the magnetic component based on actual needs, adapting to different working scenarios.
[0008] Furthermore, when storing the aforementioned wire stripping tools, they can be magnetically attached to surfaces such as metal tool racks and electrical boxes, saving space compared to traditional drawer storage. The visible hanging design improves retrieval speed and is suitable for emergency repair scenarios. In addition, the magnetic components can attract small parts such as screws and blades, reducing the risk of loss, making them particularly suitable for scenarios requiring frequent use of loose parts, such as electronics repair and industrial wiring. Attached Figure Description
[0009] The above and other objects, features, and advantages of this utility model will become more apparent from the more detailed description of the embodiments thereof in conjunction with the accompanying drawings. The drawings are provided to further illustrate the embodiments of this utility model and form part of the specification. They are used together with the embodiments of this utility model to explain the utility model and do not constitute a limitation thereof. In the drawings, the same reference numerals generally represent the same components or steps.
[0010] Figure 1 This is a schematic diagram of the wire stripping tool provided in an embodiment of the present utility model;
[0011] Figure 2 This is a schematic diagram of the structure of the first clamp body provided in an embodiment of the present utility model;
[0012] Figure 3 This is a schematic diagram of the structure of the second clamp body provided in an embodiment of the present utility model.
[0013] Figure label:
[0014] 100-First clamp body, 110-First stripping part, 111-First stripping blade, 112-First cutting blade, 120-First grip part, 121-First protrusion, 200-Second clamp body, 210-Second stripping part, 211-Second stripping blade, 212-Second cutting blade, 220-Second grip part, 221-Second protrusion, 300-Magnetic component, 310-Fixing structure, 320-Magnetic element, 400-Hinged structure, 500-Reset spring, 600-Anti-slip structure. Detailed Implementation
[0015] To make the objectives, technical solutions, and advantages of this utility model more apparent, exemplary embodiments according to this utility model will be described in detail below with reference to the accompanying drawings. Obviously, the described embodiments are merely some embodiments of this utility model, and not all embodiments of this utility model. It should be understood that this utility model is not limited to the exemplary embodiments described herein.
[0016] In the electrical engineering fields, including power system installation, maintenance, and electrical equipment manufacturing, efficient and precise stripping of wire insulation is a crucial process for ensuring the quality of electrical connections. Among existing wire stripping techniques, traditional wire strippers are the most widely used manual tools. Their structure mainly consists of two handle assemblies hinged by a pivot and a pliers head. The pliers head integrates a specific-shaped blade or cutting edge structure. The working principle of this type of tool is based on a lever transmission mechanism. The user applies force with their hand to drive the handles to rotate around the pivot, causing the pliers head cutting edge to generate shearing force on the wire insulation, thus separating the insulation.
[0017] However, this technical solution has significant limitations: First, the operation relies on the operator's continuous and stable gripping force. When handling wires of different diameters and materials, the applied force needs to be adjusted frequently, requiring high precision in the operator's force control. Second, prolonged and frequent use can easily cause muscle strain and fatigue in the operator's hands, leading to decreased operational stability and reduced work efficiency. Third, insufficient gripping force or improper operation can result in incomplete insulation stripping and damage to the wire conductor, which not only affects electrical connection performance but may also cause safety hazards such as short circuits and leakage. In particular, in scenarios such as the assembly of precision electronic equipment and the handling of aerospace cables where stringent wire stripping precision is required, traditional wire strippers are no longer sufficient to meet the needs of modern electrical engineering development.
[0018] To address the aforementioned problems, this utility model provides a wire stripping tool that helps secure the wire during the stripping process, reducing the operator's grip on the wire and minimizing hand muscle strain. Even during prolonged wire stripping operations, hand fatigue is less likely to occur, significantly improving operational comfort. It should be understood that this wire stripping tool can be wire strippers.
[0019] Figure 1 A schematic diagram of the wire stripping tool provided in an embodiment of the present invention is shown. Figure 2 A schematic diagram of the structure of the first clamp provided in an embodiment of this utility model is shown. Figures 1 to 3 As shown, the wire stripping tool of this utility model embodiment includes a first clamp body 100, a second clamp body 200 and at least one magnetic component 300, wherein the first clamp body 100 and the second clamp body 200 are hinged together. Figure 2 A schematic diagram of the structure of the first clamp provided in an embodiment of this utility model is shown. Figure 2 As shown, the first clamp body 100 includes a first stripping part 110 and a first gripping part 120. Figure 3 A schematic diagram of the structure of the second clamp provided in an embodiment of this utility model is shown. Figure 3 As shown, the second clamp body 200 includes a second stripping portion 210 and a second gripping portion 220, with the first stripping portion 110 and the second stripping portion 210 disposed opposite to each other. The magnetic component 300 is detachably fixed to the surface of the first stripping portion 110 and / or the second stripping portion 210.
[0020] It is understood that the first clamp body 100 and the second clamp body 200 can be clamp bodies with a shape similar to those of conventional wire strippers. The connection between the first stripping part 110 and the first gripping part 120 and the connection between the second stripping part 210 and the second gripping part 220 are hinged.
[0021] For example, a pivot (such as a rivet or bolt) passing through the first clamp body 100 and the second clamp body 200 can be used to form a rotatable connection point. At the connection between the first clamp body 100 and the second clamp body 200, the pivot passes through the hinge hole of both, allowing the first clamp body 100 and the second clamp body 200 to rotate around the pivot. Simultaneously, a small gap can be reserved at the hinge to ensure that the first stripping part 110 and the second stripping part 210 can open and close flexibly under the drive of the first grip part 120 and the second grip part 220, while avoiding jamming due to excessive tightness. When the user squeezes the first grip part 120 and the second grip part 220, the first grip part 120 and the second grip part 220 rotate around the pivot, causing the first stripping part 110 and the second stripping part 210 to close and complete the stripping.
[0022] In practical applications, when wire stripping is required, simply place the wire between the first stripping section 110 and the second stripping section 210, apply gripping force through the first gripping section 120 and the second gripping section 220 to close the first stripping section 110 and the second stripping section 210, thus completing the stripping operation. At this time, since the wire stripping tool also includes at least one magnetic component 300, which is detachably fixed to the surface of the first stripping section 110 and / or at least one magnetic component 300 is detachably fixed to the surface of the second stripping section 210, during the stripping operation, when the wire is placed between the first stripping section 110 and the second stripping section 210, the magnetic component 300 can be used to assist in fixing the wire. The magnetic component 300 automatically attracts the metal conductor of the wire, positioning and stabilizing the wire, thus requiring only a small gripping force to close the first stripping section 110 and the second stripping section 210. During this process, operators do not need to use a lot of hand strength to press the wires, which greatly reduces the gripping force and reduces hand muscle strain. Even when stripping wires for a long time, it is not easy to cause hand fatigue, which significantly improves the comfort of operation.
[0023] Based on this, the magnetic component 300 is detachably fixed to the surface of the first wire stripping part 110 and the second wire stripping part 210, allowing the magnetic component 300 to be easily disassembled and replaced after the magnetic force weakens or is damaged, thus extending the overall service life of the wire stripping tool and reducing operating costs. At the same time, it also allows for flexible selection of whether to install the magnetic component 300 according to actual needs, adapting to different working scenarios.
[0024] Furthermore, when storing the aforementioned wire stripping tools, they can be magnetically attached to surfaces such as metal tool racks and electrical boxes, saving space compared to traditional drawer storage. The visible hanging design improves retrieval speed and is suitable for emergency repair scenarios. In addition, the magnetic component 300 can attract small parts such as screws and blades, reducing the risk of loss, making it particularly suitable for scenarios requiring frequent use of loose parts, such as electronic repair and industrial wiring.
[0025] It is understood that the number of the above-mentioned magnetic components 300 can be one or more, and the installation position of the magnetic components 300 is flexible and selective. The magnetic components 300 can be fixed on the surface of the first stripping part 110 and the second stripping part 210 according to the stripping requirements and wire characteristics, or they can be installed on the surface of the first stripping part 110 and the second stripping part 210 at the same time.
[0026] For example, when there is only one magnetic component 300, it can be fixed to the surface of the first stripping portion 110 or the surface of the second stripping portion 210. When there are multiple magnetic components 300, some of them can be fixed to the surface of the first stripping portion 110, and others to the surface of the second stripping portion 210. Therefore, the number and installation position of the magnetic components 300 can be adjusted as needed according to the wire specifications, material, and stripping scenario, and are not limited here. Furthermore, the magnetic components 300 are detachably designed on the surfaces of the first stripping portion 110 and / or the second stripping portion 210, which facilitates maintenance and replacement of the magnetic components 300.
[0027] In one alternative approach, such as Figure 1 and Figure 2 As shown, in this embodiment of the present disclosure, the first stripping part 110 and the second stripping part 210 are both provided with stripping blades on their relatively inner sides, and the ends of the first stripping part 110 and the second stripping part 210 are both provided with shearing blades.
[0028] For example, the wire stripper blade described above can be configured with a semi-circular arc-shaped cutting edge, which can conform to the surface of the wire and reduce scratches on the wire conductor. Figure 2 As shown, the stripping blade on the first stripping section 110 can be defined as the first stripping blade 111, and the stripping blade on the second stripping section 210 can be defined as the second stripping blade 211. The shearing blade on the first stripping section 110 can be defined as the first shearing blade 112, and the shearing blade on the second stripping section 210 can be defined as the second shearing blade 212.
[0029] In practical use, when it is necessary to strip the wire, the wire can be placed between the corresponding stripping blades on the inner sides of the first stripping part 110 and the second stripping part 210, ensuring that the wire is perpendicularly aligned with the stripping blades. At this time, the first gripping part 120 and the second gripping part 220 are pinched together. The first gripping part 120 and the second gripping part 220 drive the first stripping part 110 and the second stripping part 210 to close, so that the stripping blades cut into the insulation layer. Continue to maintain the grip and slowly pull the wire to peel off the insulation layer. When it is necessary to cut the wire, the part of the wire to be cut can be aligned with the end cutting blades of the first stripping part 110 and the second stripping part 210, ensuring that the wire is perpendicular to the cutting blades. Then, the first gripping part 120 and the second gripping part 220 are pinched together, thereby using the closing cutting blades to cut the wire.
[0030] Based on this, the present invention, by placing the wire stripping blade at the center of the first wire stripping part 110 and the second wire stripping part 210, and placing the cutting blade at the ends of the first wire stripping part 110 and the second wire stripping part 210, can achieve a spatially staggered layout of the wire stripping blade and the cutting blade, thereby achieving functional integration. This not only meets the high-frequency operation requirements of wire stripping and cutting in the daily work of electricians, but also improves the portability and durability of the tool through structural optimization.
[0031] In one feasible approach, such as Figures 1 to 3 As shown, in this embodiment of the present disclosure, the magnetic component 300 is detachably fixed to the portion of the first stripping portion 110 and / or the second stripping portion 210 near the stripping blade, that is, the magnetic component 300 is detachably fixed to the portion of the first stripping portion 110 and / or the second stripping portion 210 near the stripping blade. For example, the magnetic component 300 can be positioned within 5mm of the stripping blade to ensure that the wire conductor can directly adhere to the blade edge after being attracted by the magnetic component 300. It is understood that the installation position of the magnetic component 300 can maintain a safe distance of 1mm to 2mm from the blade edge, which ensures the conduction of the attraction force and avoids collision and wear between the magnet and the blade edge, thus extending the service life of both.
[0032] During use, the operator can first place the wire near the stripping blade. At this time, the magnetic component 300 attracts and positions the wire. The operator then moves the wire to the first stripping section 110 and the second stripping section 210 for cutting. This avoids offset errors when manually adjusting the wire position, as well as incomplete insulation cutting or conductor damage caused by inaccurate positioning. Therefore, by precisely placing the magnetic component 300 near the key part of the stripping blade, this embodiment of the present disclosure achieves close-range magnetic attraction and positioning of the wire conductor, while also avoiding interference from the magnet in the stripping action through a reasonable structural design. This improves stripping accuracy while also considering the durability and maintainability of the magnet, allowing the tool to perform optimally in both delicate electronic operations and heavy-duty industrial scenarios.
[0033] In one example, such as Figure 1 As shown, the magnetic assembly 300 of this embodiment includes a fixing structure 310 and a magnetic component 320. The fixing structure 310 is used to fix the magnetic component 320 to the surface of the first stripping portion 110 and / or the second stripping portion 210. The magnetic component 320 is selected from neodymium iron boron magnets or ferrite magnets, preferably neodymium iron boron magnets. The combination of the fixing structure 310 and the magnetic component 320 enables detachable installation and functional adaptation of the magnetic assembly 300, facilitating maintenance and replacement, and allowing for flexible adjustment of the type and quantity of the magnetic component 320 according to stripping requirements.
[0034] It is understood that the aforementioned fixing structure 310 may adopt a threaded fixing structure, a magnetic fixing structure, or a slot fixing structure.
[0035] For example, when the aforementioned fixing structure 310 is a threaded fixing structure, the threaded fixing structure includes a fixing seat (not shown in the figure) and a fastener. The fixing seat is fixedly connected to the first stripping part 110 and / or the second stripping part 210, and the fastener detachably fixes the magnetic element 320 to the fixing seat. It should be understood that the fixing seat can be fixedly connected to the first stripping part 110 and / or the second stripping part 210 by welding, threaded connection, or other feasible fixing connection methods in the prior art, and is not limited here.
[0036] Specifically, the aforementioned fixing base is provided with a threaded hole (not shown in the figure), the fastener is a fixing bolt, the magnetic component 320 has a through hole (not shown in the figure), the head of the fixing bolt passes through the through hole and is threadedly connected to the threaded hole, so that the magnetic component 320 is clamped and fixed between the fixing base and the head of the fixing bolt.
[0037] In practical applications, the mounting base can be fixedly connected to the side of the first stripping part 110 and / or the second stripping part 210 near the stripping blade. Then, the through hole of the magnetic component 320 is aligned with the threaded hole of the mounting base and placed on top of the mounting base. A fixing bolt is then passed through the through hole of the magnetic component 320 and screwed into the threaded hole of the mounting base. The bolt head presses down on the magnetic component 320, making it tightly adhere to the surface of the mounting base. Therefore, the axial tensile force generated by the threaded engagement of the bolt and the threaded hole can be used to clamp the magnetic component 320 between the bolt head and the mounting base, forming a rigid fixation. On the one hand, this prevents the magnetic component 320 from loosening after a period of use; on the other hand, it ensures that the relative position of the magnetic component 320 and the stripping blade is precisely fixed, so that the wire conductor, after being attracted, always aligns with the cutting position of the stripping blade, improving stripping accuracy.
[0038] For example, when the aforementioned fixing structure 310 is a magnetic fixing structure 310, it can be fixedly connected to the first stripping part 110 and / or the second stripping part 210, and then the magnetic component 320 can be attracted to the magnetic fixing structure 310 to achieve quick disassembly. It should be understood that the method of fixing the magnetic fixing structure 310 to the first stripping part 110 and / or the second stripping part 210 can be welding, threaded connection, or other feasible fixing connection methods in the prior art, and is not limited here.
[0039] For example, when the above-mentioned fixing structure 310 is a slot-type fixing structure, a T-shaped groove or dovetail groove can be opened on the surface of the first stripping part 110 and / or the second stripping part 210. Then, a protrusion corresponding to the T-shaped groove or dovetail groove can be set on the bottom of the magnetic component 320. After inserting the bottom of the magnetic component 320 into the T-shaped groove or dovetail groove, it can be locked, which can make the magnetic component 320 more firmly fixed and less likely to fall off.
[0040] For example, such as Figure 1 As shown, the wire stripping tool in this embodiment of the present disclosure also includes a hinge structure 400, through which the first clamp body 100 and the second clamp body 200 are connected. The hinge structure 400 can be a rotating pair formed by a pin (such as a rivet or bolt) passing through the hinge hole of the first clamp body 100 and the second clamp body 200, allowing both to rotate around it.
[0041] In practical applications, when the operator needs to perform wire stripping or cutting operations, the first gripping part 120 and the second gripping part 220 can be pinched together, causing the first gripping part 120 and the second gripping part 220 to rotate around the pin shaft, transmitting force to the first stripping part 110 and the second stripping part 210, so that the first stripping part 110 and the second stripping part 210 close to complete the wire stripping.
[0042] In one feasible embodiment, such as Figures 1 to 3 As shown, the first gripping part 120 of this embodiment has a first protrusion 121, and the second gripping part 220 has a second protrusion 221. The first protrusion 121 and the second protrusion 221 are disposed opposite to each other. A return spring 500 is provided between the first protrusion 121 and the second protrusion 221. One end of the return spring 500 is connected to the first protrusion 121, and the other end of the return spring 500 is connected to the second protrusion 221.
[0043] It is understandable that the first gripping part 120 and the second gripping part 220 can be selected as symmetrical clamp handle structures, made of high-strength plastic or metal (such as aluminum alloy). The first protrusion 121 is located inside the first gripping part 120, and the second protrusion 221 is located inside the second gripping part 220. The structural dimensions of the first protrusion 121 can match the structural dimensions of the second protrusion 221 to ensure that the coaxiality error of the return spring 500 after installation is ≤0.2mm. The return spring 500 can be a cylindrical helical compression spring. The connection method between the return spring 500 and the first protrusion 121 and the second protrusion 221 is as follows: the two ends of the return spring 500 are ground flat and closed to form support rings that are respectively fitted onto the first protrusion 121 and the second protrusion 221.
[0044] In practical applications, when the operator pinches the first grip 120 and the second grip 220, the distance between the first protrusion 121 and the second protrusion 221 decreases, the return spring 500 is compressed, and the spring potential energy increases. During this process, the hinge structure 400 can transmit the hand force to the first stripping part 110 and the second stripping part 210, causing the first stripping part 110 and the second stripping part 210 to close and complete the stripping. The spring's reaction force is amplified through the lever, reducing the actual force required by the hand. When the operator releases the first grip 120 and the second grip 220, the spring releases its elastic potential energy, pushing the first protrusion 121 and the second protrusion 221 to separate, causing the first stripping part 110 and the second stripping part 210 to automatically open and return to their original positions. Therefore, through the combination of protrusions and springs, the automatic return of the first grip 120 and the second grip 220 and the effortless operation are achieved, making it particularly suitable for professional scenarios requiring continuous and precise stripping. At the same time, the detachable spring structure ensures the maintainability and service life of the tool.
[0045] In one example, such as Figures 1 to 3 As shown, the surfaces of the first grip portion 120 and the second grip portion 220 in this embodiment of the present disclosure have an anti-slip structure 600. For example, the surfaces of the first grip portion 120 and the second grip portion 220 can be configured as the anti-slip structure 600, or the surfaces of the first grip portion 120 and the second grip portion 220 can be covered with an anti-slip material. When the surfaces of the first grip portion 120 and the second grip portion 220 are configured as the anti-slip structure 600, a specific method can be to roll a cross-shaped mesh pattern onto the surfaces of the first grip portion 120 and the second grip portion 220 to increase the coefficient of friction of the contact surface, thereby improving the friction in a dry environment. Alternatively, during the manufacturing process of the first grip portion 120 and the second grip portion 220, the surfaces can be directly formed into hemispherical protrusions to increase friction and improve anti-slip properties. When the surfaces of the first grip portion 120 and the second grip portion 220 are covered with an anti-slip material, a rubber material can be used. The rubber material can be silicone rubber. The anti-slip structure 600 on the surfaces of the first grip 120 and the second grip 220 effectively improves the operational stability of the tool in different scenarios through physical texture, material coating or ergonomic design.
[0046] In one alternative embodiment, the materials of the first stripping portion 110 and the second stripping portion 210 of this disclosure can be selected from alloys or ceramics. Alloys include, for example, tungsten steel alloy, chromium vanadium alloy steel, titanium alloy or aluminum alloy, and ceramics include, for example, zirconium oxide. No limitation is made here.
[0047] This utility model's wire stripping tool achieves dual optimization in user experience and tool management. During stripping, the magnetic component 320 automatically attracts the wire conductor, replacing finger pressure and reducing hand grip strength requirements, significantly alleviating fatigue during prolonged work. Simultaneously, the positioning accuracy between the wire and the stripping blade is good, greatly reducing conductor damage. For storage, the tool can be directly attached to metal tool racks, distribution boxes, etc., saving space compared to traditional drawer storage. The visible hanging design improves retrieval speed, making it suitable for emergency repair scenarios. Furthermore, the magnetic component 300 can also attract small parts such as screws and blades, reducing the risk of lost parts, making it particularly suitable for scenarios requiring frequent use of loose parts, such as electronics repair and industrial wiring.
[0048] The basic principles of this utility model have been described above with reference to specific embodiments. However, it should be noted that the advantages, benefits, and effects mentioned in this utility model are merely examples and not limitations, and should not be considered as essential features of each embodiment of this utility model. Furthermore, the specific details disclosed above are for illustrative and facilitative purposes only, and are not limitations. These details do not limit the utility model from being implemented using the aforementioned specific details.
[0049] The block diagrams of the devices, apparatuses, equipment, and systems involved in this utility model are merely illustrative examples and are not intended to require or imply that they must be connected, arranged, or configured in the manner shown in the block diagrams. As those skilled in the art will recognize, these devices, apparatuses, equipment, and systems can be connected, arranged, and configured in any manner. Words such as “comprising,” “including,” and “having” are open-ended terms meaning “including but not limited to” and are used interchangeably with them. The terms “or” and “and” as used herein refer to the terms “and / or” and are used interchangeably with them unless the context clearly indicates otherwise. The term “such as” as used herein refers to the phrase “such as but not limited to” and is used interchangeably with it.
[0050] Additionally, as used herein, the “or” used in a list of items beginning with “at least one” indicates a separate list, such that a list of, for example, “at least one of A, B, or C” means A or B or C, or AB or AC or BC, or ABC (i.e., A and B and C). Furthermore, the word “exemplary” does not imply that the described example is preferred or better than other examples.
[0051] It should also be noted that in the system and method of this utility model, the components or steps can be disassembled and / or recombined. These disassemblies and / or recombinations should be considered as equivalent solutions of this utility model.
[0052] Various changes, substitutions, and modifications can be made to the technology described herein without departing from the teachings defined by the appended claims. Furthermore, the scope of the claims of this utility model is not limited to the specific aspects of the processes, machines, manufacturing processes, events, means, methods, and actions described above. Currently existing or later-developed processes, machines, manufacturing processes, events, means, methods, or actions that perform substantially the same function or achieve substantially the same result as the corresponding aspects described herein can be utilized. Therefore, the appended claims include such processes, machines, manufacturing processes, events, means, methods, or actions within their scope.
[0053] The above description of the disclosed aspects is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these aspects will be readily apparent to those skilled in the art, and the general principles defined herein can be applied to other aspects without departing from the scope of the present invention. Therefore, the present invention is not intended to be limited to the aspects shown herein, but rather to be carried out within the widest scope consistent with the principles and novel features disclosed herein.
[0054] The above description has been given for purposes of illustration and description. Furthermore, this description is not intended to limit the embodiments of the present invention to the forms disclosed herein. Although numerous exemplary aspects and embodiments have been discussed above, those skilled in the art will recognize certain variations, modifications, alterations, additions, and sub-combinations therein.
Claims
1. A wire stripping tool, characterized in that, include: A first clamp body, a second clamp body, and at least one magnetic component, wherein the first clamp body and the second clamp body are hinged together, the first clamp body includes a first stripping part and a first gripping part, the second clamp body includes a second stripping part and a second gripping part, the first stripping part and the second stripping part are disposed opposite to each other, and at least one of the magnetic components is detachably fixed to the surface of the first stripping part and / or at least one of the magnetic components is detachably fixed to the surface of the second stripping part.
2. The wire stripping tool according to claim 1, characterized in that, Both the first stripping section and the second stripping section have stripping blades on their inner sides, and both the first stripping section and the second stripping section have shearing blades at their ends.
3. The wire stripping tool according to claim 2, characterized in that, The magnetic component is detachably fixed to the first stripping section and / or the second stripping section near the stripping blade.
4. The wire stripping tool according to claim 1, characterized in that, The magnetic assembly includes a fixing structure and a magnetic element, wherein the fixing structure is used to fix the magnetic element to the surface of the first stripping portion and / or the second stripping portion.
5. The wire stripping tool according to claim 4, characterized in that, The magnetic component is selected from neodymium iron boron magnets or ferrite magnets.
6. The wire stripping tool according to claim 4, characterized in that, The fixing structure includes a fixing base and a fastener. The fixing base is fixedly connected to the first stripping part and / or the second stripping part, and the fastener detachably fixes the magnetic component to the fixing base.
7. The wire stripping tool according to claim 6, characterized in that, The fixing base has a threaded hole, the fastener is a fixing bolt, the magnetic component has a through hole, the head of the fixing bolt passes through the through hole and is threadedly connected to the threaded hole, so that the magnetic component is clamped and fixed between the fixing base and the head of the fixing bolt.
8. The wire stripping tool according to any one of claims 1 to 7, characterized in that, The wire stripping tool also includes a hinge structure, through which the first clamp body and the second clamp body are hinged.
9. The wire stripping tool according to any one of claims 1 to 7, characterized in that, The first grip portion has a first protrusion, and the second grip portion has a second protrusion. The first protrusion and the second protrusion are disposed opposite to each other. A return spring is provided between the first protrusion and the second protrusion. One end of the return spring is connected to the first protrusion, and the other end of the return spring is connected to the second protrusion.
10. The wire stripping tool according to any one of claims 1 to 7, characterized in that, Both the first grip portion and the second grip component have anti-slip structures on their surfaces.