Abstract
Axial-flow fan with advantages such as large air volume, high head pressure, and low noise is commonly used in the work of air-conditioner outdoor unit. In order to investigate the internal flow mechanism of the axial-flow fan with different trailing edge structures of impellers, four kinds of impellers were designed, and numerical simulation and experiment were deployed in this article. The pressure distribution on the blades surface and distribution of vorticity in impellers were obtained using numerical simulation. Distribution of blade loading and velocity at the circumference are discussed. The relationship between the wideband noise and the trailing edge was established based on the experiment results. The results show that after the optimization of the trailing edge structure, the distribution of vorticity near the trailing edge of the blade is more uniform, especially at the trailing edge of 80% of the chord length of the suction surface. From the blade height position of 70% to the impeller tip, the pressure on the surface rapidly increases due to the tip vortex and the vortex shedding on the blade edge occurred in the top region of impeller. The pressure fluctuation amplitude at the trailing edge structure of the tail-edge optimization structure is smaller. In the distribution of blade loading, the three tail-edge optimization structures have smaller pressure fluctuations and pressure differences at the trailing edge structure. It is extremely important to control the fluctuation amplitude at the trailing edge. The amplitude of low-frequency sound pressure level of optimizing the trailing edge structure decreases obviously in the range of 50–125 Hz, and the optimization structure of trailing edge has an obvious effect on low-frequency wideband noise.
Highlights
In the air conditioning system, the axial-flow fan is generally used in the air-conditioner outdoor unit because of it has many advantages, such as compact structure, large air volume, high head pressure, and low noise
The impeller rotational speed is 850 r/min, which is driven by the motor, adjusting the speed to get the flow rate of bonus points, and the total pressure predicted by numerical simulation results are in agreement with the experimental results, as shown in Figures 7 and 8, Figure 7
It shows that numerical simulation is more accurate for axial-flow fan performance prediction
Summary
In the air conditioning system, the axial-flow fan is generally used in the air-conditioner outdoor unit because of it has many advantages, such as compact structure, large air volume, high head pressure, and low noise. Due to the shroud only exists near the trailing edge of the tip, it is similar to the semi-open axial-flow fan. With the continuous development of industrial technology, higher requirements are put forward for noise of axial-flow fans. The broadband component of the noise spectrum is primarily induced by the pulsating force with random characteristics, such as vortex shedding at the tail of the blade, tip vortex, and turbulent flow. How to deal with the trailing edge of the axial-flow fan blade reasonably and effectively improve the pressure
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
