The cyclone tower utilizes centripetal force to cause the dust-laden gas to move horizontally inward, resulting in a longer residence time and enhanced washing effect. This thoroughly improves the technical drawbacks of the spray tower, such as incomplete dust removal under certain operating conditions and a tendency to clog.

The product utilizes fluid dynamics technology to prevent clogging of pumps and nozzles, significantly enhancing production efficiency. The water in the pond can be recycled, avoiding the hassle of secondary pollution and conserving water resources. The cyclone tower is equipped with several "circular vortex buckets" and efficient demisting plates. Solid filling balls are placed inside the vortex buckets, and the upper demisting plates are used to purify water mist, achieving the goal of dehydration. Dusty gases spiral up inside the tower and come into contact with the liquid vortex entering from the top on each plate, completing the dust removal task. Through the force of centrifugal force, large particles in the waste gas settle into the pond, and then are manually removed and cleaned from the casing, thus the gas is purified, meets emission standards, and the water in the cyclone tower can continue to be recycled.

Aerodynamic swirl tower plate blades resemble fixed windmill blades, where the gas stream generates rotation and centrifugal motion as it passes through them. The absorbent fluid is evenly distributed to each blade through an intermediate blind plate, forming a thin liquid film. This film combines with the upward-moving swirling gas stream, creating a rotating and centrifugal effect. After being sprinkled, the fluid becomes fine droplets, which are then thrown towards the tower wall. The droplets are collected in a collecting trough by gravity and flow through a downcomer to the blind area of the next swirl tower plate for waste gas treatment. The gas stream to be treated, with a certain wind pressure and velocity, enters from the bottom and exits from the top of the tower. The absorbent fluid enters from the top and exits from the bottom of the aerodynamic swirl tower. The gas stream and absorbent fluid move relative to each other within the tower, forming a large surface area of water film at the structural parts of the swirl tower plates, thereby greatly enhancing the absorption effect. Each layer of absorbent fluid, after being subjected to swirl and centrifugal forces, falls into the collection trough at the edge and then enters the next layer of tower plate through a guide pipe for the next absorption process.