High speed stamping does not only refer to the single punching operation mode, it actually covers multiple stamping methods. Single punching is just one of them, which means completing punching in one go, including straight line distribution, circular arc distribution, circumferential distribution, and grid hole punching. However, high-speed stamping also includes various other modes, such as directional continuous punching, multi-directional continuous punching, nibbling, single forming, continuous forming, and array forming.
In the high-speed stamping process, the punching machine converts circular motion into linear motion, and through the operation of the main motor, flywheel, clutch, gear, crankshaft (or eccentric gear), connecting rod and other mechanisms, the linear motion of the slider is achieved, thereby completing various stamping operations. This high-speed, continuous, and precise stamping method makes high-speed stamping widely used in the manufacturing industry.
Therefore, although single punching is an operating mode of high-speed stamping, high-speed stamping is not limited to single punching. It can choose suitable stamping methods according to different production needs and material characteristics to achieve efficient, accurate, and high-quality production.
High speed stamping is of great significance in the manufacturing of instruments and meters. For the casing and panels of instruments and meters, high-speed stamping can quickly shape and size accurately. For example, the casing of instruments such as oscilloscopes and multimeters can be designed to be lightweight, sturdy, and aesthetically pleasing through high-speed stamping, while providing good protection for internal components.
In the production of internal components in instruments and meters, high-speed stamping can efficiently manufacture various connectors, contacts, and spring plates. These parts typically require high precision and good elasticity, and high-speed stamping can meet these requirements.
High speed stamping brings the following advantages to instrument manufacturing:
Improve production efficiency: able to produce complex shaped components in large quantities in a short period of time, meeting the large-scale demand of the instrumentation industry.
Ensure accuracy and stability: Ensure the dimensional accuracy and performance consistency of parts, thereby improving the measurement accuracy and reliability of instruments and meters.
Cost reduction: Through efficient production and rational utilization of materials, the manufacturing cost of instruments and meters has been reduced.