Home Appliances

Thanks to their resistance to high-temperature aging and moisture corrosion, as well as their reliable self-resetting capability, formed springs are widely used in applications such as refrigerator door seal clips, washing machine spin basket balance rings, microwave oven door interlock switches, and terminal blocks for indoor air conditioning units. They primarily serve functions such as securing sealing structures, triggering safety interlocks, ensuring stable high-current conduction, and providing vibration damping and protection. As such, they are critical elastic components that ensure the safe operation of home appliances and extend their service life.

Power Tools

Thanks to their high strength, impact resistance, high current-carrying capacity, and excellent fatigue resistance, formed springs are widely used in electric drill spindle chucks, angle grinder switch contacts, torque adjustment mechanisms in electric screwdrivers, and battery contacts in lithium-ion power tools. They primarily facilitate stable high-current transmission, rapid switching, precise torque adjustment, and structural anti-loosening, serving as core components that ensure the stable operation of power tools in high-vibration, high-load environments.

Robot

Thanks to their smooth cushioning, high-precision force feedback, and wear-free connection, formed springs are widely used in the joint flexion and extension mechanisms of humanoid robots, fingertip tactile sensors in service robots, grippers on the end-effectors of industrial robotic arms, AGV positioning latches, and other robotic systems. They primarily serve functions such as joint motion cushioning, low-force sensing feedback, precise positioning and gripping, and flexible structural connections. As core elastic components, they enable robots to perform high-precision operations, achieve biomimetic interaction, and ensure stable operation.

Industrial Automation

Thanks to their high stiffness-to-weight ratio, precise force-to-displacement conversion, and fatigue resistance, formed springs are widely used in mechanical systems such as positioning mechanisms for machine tool spindles, limit stops in stamping lines, moving contacts in industrial relays, and shock absorbers for precision instrument stages. They primarily perform functions such as precision positioning and guidance, energy absorption and cushioning, high-frequency on-off control, and precise force-to-displacement conversion, serving as the fundamental elastic components that enable stable control and precise measurement in automated equipment.

Medical equipment

Thanks to their non-magnetic compatibility, biocompatibility, and long-term implant stability, formed springs are widely used in medical devices such as MRI-compatible control panels, internal connectors for pacemakers, precision control buttons for infusion pumps, and contacts for wearable monitors. They primarily provide stable electrical conductivity in non-magnetic environments, precise force-controlled triggering, resistance to corrosion from bodily fluids, and long-term electrical stability. As such, they are indispensable biocompatible elastic components in high-reliability medical devices.

Automotive Parts

Thanks to their wide-temperature-range stability, millisecond-level response times, and automotive-grade EMC shielding performance, formed springs are widely used in automotive airbag triggers, door latch mechanisms, seat adjustment switches, high-speed ECU connectors, and in-vehicle radar mounts. They primarily perform functions such as millisecond-level signal triggering, anti-misoperation control, EMC shielding, and precision structural positioning, serving as the foundational components that ensure the functional safety and reliable operation of automotive electronic systems.