Heating a stainless steel sleeve for industrial washers
Shrinkfitting a steel mud pump liner
Shrink fit a steel gear onto a steel gear motor shaft
Shrink fitting a carbide ring into a valve seat
Shrink fitting auto turbo charger impeller blades onto an aluminum shaft
Shrink fitting aluminum pulley to insert inner bearing
Shrink fitting an assembled wrist pin into a connecting rod
Shrink fitting a cast iron rocker arm assemblies
Shrink fit a motor shaft and roller
Shrink fitting a Camshaft Gear
Shrink fitting a Fuel Pump Housing and Inserts
Shrink fit a carbon graphite ring insert into an outer steel band
- Overview
- Using Induction
- Setup
- Materials
- Problems
- Tricks
Most applications involve a shaft with a given outside diameter and another part such as a gear, steering knuckle or washer which has a bore hole. There are several forms of this type of joint, characterized by the amount of tolerance (space) between the two parts. The shrink fitting process is used for the interference fit type joint.
By heating the mass around the bore hole uniformly, it is possible to significantly expand the size of the hole. The shaft is then easily inserted into the expanded hole. Upon cooling, the mass around the hole shrinks back to its original size and frictional forces create a highly effective joint.
Modern induction heating systems provide the speed, accuracy and repeatability necessary to produce quality shrink-fitted joints. With a properly designed work coil, induction heating can uniformly heat the bore hole, producing repeatable expansion. With the remote heat station capability of solid state induction heating power supplies, shrink fitting can be done on the production line.
Induction systems typically used for metal to shrink fitting range from 1 to 20kW, depending on the parts and application requirements.
For induction shrink-fitting applications a pancake or helical-shaped coil is placed inside the metal part that is to be expanded. RF power is applied until the part reaches the appropriate temperature. The induction coil is then quickly removed from the hole and the shaft that is to be inserted is then slid into position. The assembly is then allowed to cool. Pressure develops as the heated component contracts. Depending on the mass of the material to be expanded, a pancake-shaped coil is sometimes employed.
Metal parts: metal housing material with a tight tolerance opening; insert for housing (tight tolerances on the outer diameter are also important)
Alignment fixture (optional)
Power Supply & Induction Coil: Fast, precise heating works best.
If the inner diameter and outer diameter are not held at tight tolerances, the shrink fit will not be possible.
There can be no burs on the joining surfaces.
If the two metal parts are not properly aligned, the shaft will not slide into the correct position.
Allow a long soak time for the metal housing to ensure that the whole mass has reached uniform temperature and expanded.
Employ an alignment fixture to smoothly guide the shaft into the housing.
