Does the temperature affect the use of the reducer?

For a normally used speed reducer, its temperature rise under rated load is theoretically independent of the ambient temperature, but is actually affected by such factors as ambient temperature. Now let's talk about the effect of temperature on gear reducer use.

Reducer

Gear reducer is a type of transmission that is driven by gears to achieve the purpose of deceleration. It is a type of gear reducer that is often seen and used in many reducers.

For normal running reducers, the temperature rise under rated load is theoretically independent of the ambient temperature, but it is actually affected by such factors as ambient temperature. This chapter is about the influence of temperature on the operation of the gear reducer.

I. Limit operating temperature of insulating material refers to the hottest temperature in winding insulation during the design life expectancy of the reducer. If the operating temperature exceeds the limit operating temperature of the material for a long time, the aging of the insulation will be aggravated and the service life will be greatly shortened. Therefore, the temperature is one of the main factors for the service life of the reducer in operation.

2. Temperature rise is the temperature difference between the reducer and the environment, which is caused by the heating of the reducer. Temperature rise is an important index in the design and operation of the reducer, which indicates the degree of heat generation of the reducer. In operation, if the temperature rise of the reducer increases abruptly, the reducer is faulty, or the air duct is blocked or the load is too heavy.

3. When we use the reducer, the iron core of the reducer will lose its iron in the alternating magnetic field. After the winding is energized, copper loss and other stray losses will occur. These things like these all cause the temperature of the reducer to rise. There is also heat dissipation in the gear reducer. Equilibrium is achieved when heat and heat are equally dissipated, if the temperature does not rise any more and stabilizes on a level surface. When heat is increased or heat dissipation is reduced, this destroys the equilibrium, causing the temperature to continue to rise and the temperature difference to be enlarged, which increases heat dissipation and enables a new equilibrium to be achieved at a higher temperature.