How to improve Silent Pipeline Mixed Flow Fan performance by reducing airflow turbulence?

Airflow turbulence refers to the irregular fluctuations or disturbances produced by the air during the flow process, which usually manifests as the unevenness and fluctuation of the airflow. During fan operation, airflow turbulence will not only reduce the efficiency of air flow, but may also cause increased noise during fan operation. Traditional fans usually produce large airflow turbulence due to improper design or unbalanced impellers, which directly affects the ventilation effect and noise level of the fan.

Efficiency loss caused by airflow turbulence: Turbulence will make the air flow unstable, increase the resistance when the air flows through the fan, and cause the fan's working efficiency to decrease. This will not only affect the air volume output of the fan, but may also affect the performance of the entire ventilation system.

Increased noise levels: Air flow turbulence is one of the important sources of fan noise. When the air flow is unstable, the friction and collision between the air flow and the fan blades will significantly increase the noise. Especially during high load or high-speed operation, the turbulence phenomenon becomes more significant, and the noise also increases, affecting the comfort of the environment.

Silent Pipeline Mixed Flow Fan adopts a double impeller structure to effectively reduce airflow turbulence, thereby improving the overall performance of the fan.

Double wind wheel parallel design optimizes air flow: The design of the double wind wheel structure allows the two wind wheels to work together to jointly promote air flow. The configuration of two wind wheels ensures that the airflow is smoother when passing through the fan and reduces the generation of turbulence. Compared with the single wind wheel design, the double wind wheel design allows the fan to operate at a higher efficiency, and the air flow path is more uniform, avoiding irregular fluctuations in the air flow.

Enhanced wind wheel efficiency and air flow stability: Each wind wheel in the double wind wheel structure operates independently, cooperating with each other while promoting air flow to increase the overall air volume output. Under this design, the path of air flow through each wind wheel is more stable, reducing pressure fluctuations and turbulence caused by uneven air flow. Since the airflow channel of each wind wheel has been carefully designed, the air flows more smoothly, and the airflow friction and turbulence inside the system are effectively controlled, ensuring that the fan can work efficiently and quietly.

Optimized airflow guide design: In addition to the design of the wind wheel, Silent Pipeline Mixed Flow Fan also takes optimization measures in other parts of the fan. For example, the fan's cold-rolled sheet metal casing not only enhances the structural stability of the device, but also further suppresses the generation of airflow turbulence by reducing vibration.
Increased air volume output: The direct result of reducing airflow turbulence is increased air volume output of the fan. The reduction in turbulence allows air to flow more smoothly through the fan, increasing airflow efficiency and thereby enhancing the effectiveness of the ventilation system. In applications requiring high air volumes, reduced turbulence allows the Silent Pipeline Mixed Flow Fan to provide more stable and efficient air flow.

Reduced Noise Level: The reduction in airflow turbulence significantly reduces the noise level when the fan is operating. In traditional fans, turbulence often results in an erratic flow of air, which increases noise. Through the optimization of the double wind wheel structure, the Silent Pipeline Mixed Flow Fan can effectively suppress air flow fluctuations, reduce the fan's noise output, and provide a quieter working environment.

Improved equipment life: Reducing airflow turbulence also reduces wear and vibration on internal components of the fan. By reducing impeller collisions and pressure fluctuations caused by turbulence, the fan's operation becomes smoother, reducing equipment losses and extending the fan's service life.