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Overview of the EPA Approved Gasoline Engine Long Distance Remote Control Tracked Remote-Driven Hammer Mulcher
The EPA approved gasoline engine long distance remote control tracked remote-driven hammer mulcher represents a significant advancement in mulching technology. Designed and manufactured by Vigorun Tech, this machine is equipped with a powerful V-type twin-cylinder gasoline engine, specifically the Loncin brand model LC2V80FD. With a rated power of 18 kW at 3600 rpm, the 764cc engine ensures strong performance for various applications.
This innovative mulcher features a clutch that engages only when the engine reaches a predetermined rotation speed, promoting efficient operation and prolonging engine life. The design not only enhances performance but also increases safety during operation, making it an ideal choice for professional landscaping and maintenance tasks.
Equipped with two 48V 1500W servo motors, the mulcher delivers robust power and excellent climbing ability. A built-in self-locking function ensures that the machine remains stationary when throttle input is absent, effectively preventing unintended movement. This feature significantly enhances operational safety, providing peace of mind to operators working on challenging terrains.
Advanced Features and Benefits
One of the standout features of the EPA approved gasoline engine long distance remote control tracked remote-driven hammer mulcher is its high reduction ratio worm gear reducer. This mechanism multiplies the already impressive torque generated by the servo motors, allowing the machine to tackle steep inclines with ease. Even in a power-off state, the friction between the worm and gear provides mechanical self-locking, ensuring that the machine does not slide downhill during power loss.
The intelligent servo controller integrated into the machine plays a crucial role in regulating motor speed and synchronizing the left and right tracks. This capability allows for straight-line travel without the need for constant adjustments from the remote control. As a result, operators experience reduced workload and minimized risks associated with over-correction, particularly on steep slopes.
