The flexibility of the composite shielding insulation sleeve is first reflected in its adaptability to narrow spaces in complex line layout. When the line needs to pass through narrow areas such as gaps and corners inside the equipment, the flexibility allows the sleeve to bend flexibly along the direction of the line, and it can pass through these restricted spaces smoothly without forcibly breaking or cutting. This feature avoids the situation where the sleeve cannot enter a narrow area due to being too hard, allowing the line layout to remain smooth inside a compact device, and will not affect the reasonable layout of the line due to space limitations.
In the scenario of parallel layout of multiple lines, the convenience brought by flexibility is more obvious. Multiple lines often need to be bundled together or arranged in layers. The flexible sleeve can easily fit the shape of each line, allowing the lines to be arranged closely without squeezing each other. Even if the lines are crossed or entangled, the sleeve can be deformed accordingly, and tension will not be generated between the lines due to excessive rigidity, reducing the risk of line damage due to pulling, making the arrangement and fixation of multiple lines easier.
In the face of the multi-angle bending requirements of the line, the flexibility of the composite shielding insulation sleeve provides full support. The lines inside the equipment often need to be bent 90 degrees or even more according to the position of the components. The flexibility allows the casing to deform naturally according to the curvature of the line, and there will be no creases or cracks after bending. This characteristic of changing with the bending of the line ensures that the casing continues to protect the line, and will not reduce the insulation or shielding performance due to bending, so that the line is always safe in a complex direction.
In scenarios where the line needs to be adjusted frequently, flexibility allows the casing to repeatedly adapt to the changes in the line. During equipment maintenance or line modification, the position of the line may need to be changed many times. The flexible casing can be bent and straightened many times as the line moves, and will not age or break due to repeated deformation. Compared with the rigid casing, it saves the trouble of frequently replacing the casing due to line adjustment, reduces the cost and workload of line modification, and improves the efficiency of line adjustment.
For irregularly shaped line components, the flexibility of the composite shielding insulation sleeve enables it to be tightly wrapped to provide comprehensive protection. Some lines are connected to irregularly shaped connectors, terminals and other components. The flexibility allows the casing to fit the contours of these components. Even if the surface is uneven, the casing can completely cover it through its own deformation without leaving any gaps. This tight wrapping not only enhances the insulation and shielding effect, but also prevents dust and moisture from entering the connection, ensuring the stability of the line connection.
In the process of manual line layout, flexibility makes the operator's work easier. The operator can easily bend the casing and adjust the line direction without the help of special tools. Whether it is one-handed operation or working in an environment with poor visibility, the flexibility of the casing can quickly complete the layout and fixation of the line. This ease of operation reduces the difficulty of manual operation, reduces the possibility of damage to the casing or line due to improper operation, and improves the efficiency and quality of the overall line layout.
In addition, the combination of flexibility and the strength of the casing itself allows the line to be better protected when it is hit by slight external forces. There may be slight vibrations or component movement during the operation of the equipment. The flexibility allows the casing to absorb the impact of these external forces, buffer the pressure through its own deformation, and prevent the line from being directly subjected to external forces. This buffering effect reduces the loosening or wear of the line due to vibration, extends the service life of the line, and improves the overall stability of complex line layout.
