Orbital oscillator, a precision vibration equipment widely favored in the field of laboratory scientific research, has become an indispensable assistant for many researchers due to its unique working principle and wide range of application scenarios. It not only transcends the limitations of traditional mixing methods, but also leads an innovation in laboratory operation methods by cleverly applying the principles of centrifugal mechanics.

1. Working principle The orbital oscillator uses the driving force generated by the motor to convert the rotational motion into an elliptical trajectory swing of the sample in the horizontal direction through a specific mechanical structure. This swing method ensures that the sample is vibrated evenly and stably while avoiding excessive shear force or impact force, thereby protecting the integrity of the sample and the accuracy of the experimental results.

2. Features and advantages 1. High stability: The output frequency stability of the orbital oscillator is very high, and its stability can reach 1e-11 or even higher. This high stability is mainly due to the reference frequency source with higher stability inside the oscillator, such as crystal oscillator, ferrite oscillator, etc. 2. Broadband oscillation technology: Using wide-band oscillation technology, the number of components of the orbital oscillator is smaller. The size and power consumption of the entire device are smaller than other types of oscillators, making it more suitable for embedding into microcircuit chips. 3. Strong anti-interference: The internal phase-locked loop structure with self-correction mechanism can effectively resist external noise and interference and maintain the stability of the output frequency. This makes orbital oscillators more widely used in noisy environments such as radar, communications, and medical care. 4. Wide range of applications: Orbital oscillators are not only suitable for vibrating and mixing liquid and solid samples, but are especially suitable for experiments such as cell culture and microbial culture. They also have important applications in fields with high precision requirements such as frequency measurement and synchronous communication. .

3. Main components of the orbital oscillator 1. Motor system (1) Core components: DC brushless motor or stepper motor, which provides stable driving force to ensure that the oscillator can work according to the set frequency and amplitude. (2) Features: The motor has the advantages of low noise, long life, maintenance-free, etc., and can operate stably for a long time. 2. Transmission device (1) function: convert the rotational motion of the motor into an elliptical trajectory swing of the sample in the horizontal direction. (2) Structure: It may include eccentric devices, connecting rods, bearings and other components. Through precise mechanical structure design, smooth transmission of vibration is achieved. 3. Control system (1) Core component: microprocessor or PID controller, used to accurately control various parameters of the oscillator. (2) Function: Users can set parameters such as oscillation frequency, amplitude, and time through the operation interface, and the control system will adjust the working status of the motor in real time to ensure that the oscillator works according to the set parameters. (3) Display and feedback: Equipped with LED digital tube or LCD display to display the current working status, such as oscillation frequency, amplitude, time, etc. At the same time, it may also have audible alarm and automatic protection functions to ensure that the equipment can automatically shut down and send out an alarm signal under abnormal circumstances. 4. Sample holder (1) Function: Used to fix and support samples to be shaken, such as microplates, flasks, etc. (2) Features: The bracket usually adopts an easy-to-operate spring fixation method or an adjustable design to facilitate users to quickly install and remove samples. At the same time, the material and structural design of the bracket will also take into account the stability and safety of the sample. 5. Shell and structure (1) Function: Protect internal mechanical and electronic components from the external environment while providing stable support. (2) Features: The casing is usually made of strong and durable materials and has dust-proof, waterproof, vibration-proof and other properties. The internal structure is compact and reasonable to ensure the stability and durability of the equipment. 6. Optional accessories (1) According to different experimental needs, the orbital oscillator may also be equipped with some optional accessories, such as sample holders, trays, clamps, etc. of different specifications, so that users can respond to various experimental scenarios more flexibly.

In many fields such as biomedicine, chemical analysis, and materials science, orbital oscillators have played an irreplaceable role. Whether it is cell suspension and uniform distribution in cell culture, reagent mixing and acceleration of reaction processes in chemical reactions, or particle dispersion and structural characterization in materials science, orbital oscillators can be used for their excellent performance and stability. The performance helps scientific researchers overcome scientific problems one after another and promotes the continuous development of scientific research.