Which parts of the suspension movement are the most critical

In the suspension movement, there are several components that play a crucial role in its performance, accuracy and overall operation. Here is an overview of these key components:

Levitating parts (such as tourbillons) : The levitating parts are the core of the levitating movement, and they are specially designed to achieve a near-contactless levitating state, which greatly reduces friction and improves timing accuracy and movement stability. The levitating parts may use magnetic levitation technology or other innovative designs to ensure that they are not affected by traditional contact friction during movement.

Magnetic levitation system (if applicable) : In movements using magnetic levitation technology, the magnetic levitation system is the key to maintaining the stable suspension of the suspended components. The magnetic suspension system uses the principle of magnetic attraction and repulsion, and realizes the stable suspension and accurate control of the suspended parts by precisely controlling the magnetic field strength and direction.

The transmission system is responsible for transferring power from the spring to the suspension components and other key components, and its efficiency and stability directly affect the overall performance of the movement. Transmission systems are often optimally designed to reduce energy loss and increase transmission efficiency. In a suspension movement, the drivetrain may need to take special consideration of how to work with the suspension components to achieve optimal performance.

Energy storage and release mechanisms (such as spring and spring) : These components are responsible for storing and releasing energy to provide continuous power support for the movement. In the suspension movement, due to the special design of the suspension components, the requirements for energy storage and release mechanisms may be higher. Components such as spring and spring are usually made of high-precision materials and manufacturing processes to ensure the stability of energy storage and uniform release. In the suspension movement, technologies such as double hair bar linkage may also be used to improve the efficiency of energy release.

Support and positioning structure: Although the suspended components themselves achieve a suspended state, they still require stable support and precise positioning to ensure normal operation. The support and positioning structure is usually made of high-precision machining and special materials to ensure that the suspended parts can maintain a stable running trajectory and accurate positioning in the suspended state.

Control system (such as intelligent movement) In some high-end suspension movements, intelligent control systems may also be equipped to monitor and adjust the status of the movement in real time. These systems utilize advanced technologies such as sensors and microprocessors to collect data on the movement's operating status, and perform real-time analysis and adjustment through algorithms to improve the adaptability and stability of the movement.

Key components in the suspension movement include suspension components (such as tourbillons), magnetic levitation systems (where applicable), transmission systems, energy storage and release mechanisms (such as spring and spring), support and positioning structures, and control systems (such as intelligent movements). These components work together to ensure that the floating movement achieves high precision, high stability and a unique aesthetic experience.