What faults may occur in the JZQ750-31.5-1 reducer if the heat sink is installed properly
Publish Time: 2025-05-23 Origin: Site
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Poor heat dissipation: The installation position of the heat sink is incorrect. If it is not installed near the heating area of the reducer, or if it is too tight or loose, it will affect heat conduction, which will prevent the heat generated inside the reducer from being dispersed into the surrounding environment in time, causing the oil temperature to rise, and thus causing the overall temperature of the reducer to rise. Long-term overheating will accelerate the aging and deterioration of the lubricant, reduce its lubricating performance, and affect the normal operation of the reducer.
Local overheating: The heat sink is not installed uniformly, which will lead to uneven heat dissipation on the surface of the reducer and local overheating. This may cause some parts of the reducer to be deformed and damaged due to excessive temperatures, such as deformation of the seal, resulting in oil leakage, and wear of components such as gears and bearings.
Increased noise and vibration
Insecure installation can generate additional noise, which may also cause friction between the heat sink and the reducer housing, further increasing noise. In addition, this vibration may also be transmitted to the reducer, causing vibrations of internal components to intensify, resulting in unstable gear meshing and bearing wear, which will in turn generate greater noise and vibration.
Resonance problem: If the heat sink is installed incorrectly and its natural frequency is similar to the vibration frequency of the reducer, it may cause resonance. Resonance will greatly increase the vibration amplitude of the reducer, which will not only produce strong noise, but will also cause serious damage to the reducer structure, such as loosening of the base bolts and deformation of the gear shaft.
Reduced efficiency: Overheating of the reducer will reduce the viscosity of the lubricant, resulting in poor lubrication effect, increasing friction between internal parts, and thus reducing the transmission efficiency of the reducer. In addition, long-term overheating may intensify wear of gears and bearings, increase gaps, and affect the transmission accuracy and efficiency of the reducer.
Sealing damage: Overheating will cause the reducer's seal to age and deform, reduce its sealing performance, and lead to lubricant leakage. Once oil leakage occurs, it will not only pollute the working environment, but also cause insufficient lubricating oil inside the reducer, further aggravating wear and overheating, forming a vicious cycle.
Shorten service life: The long-term accumulation of the above faults will cause all components of the reducer to bear additional stress and wear, thereby shortening the overall service life of the reducer, increasing maintenance costs and downtime, and affecting production efficiency.