A QUICK GUIDE TO INDUCTION HEATING
This guide details briefly the electrical
side of induction heating technology. Induction heating
is a technology that is found primarily in mass-manufacturing
which provides a superior alternative to other means
of heating metals, such as flame, furnace or resistive
heating, and is used for a wide variety of tasks including
melting, brazing, hardening, annealing and others. The
technology works on the same principle as a transformer,
using the "losses" caused by eddy currents
for producing useful heat.
In order to function efficiently, induction heating
systems need to create the strongest possible magnetic
field with maximum coupling to the part being heated.
Consequently, a system operating at extremely high currents
is desired. When induction heating is used at high frequencies
for surface treatment, these currents exceed what can
practically be generated or conducted over any distance.
The solution to this is to use an oscillator "tank"
circuit.
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A typical
parallel-resonant induction heating tank circuit is
shown here. It consists of a high frequency generator
which supplies the power and initialises the oscillation
and the resonator circuit. Due to the high currents
flowing (often thousands of amps) the resistive losses
in the components generate substantial amounts of heat,
and consequently the coil and the capacitor both require
cooling.
Coil design requires producing a coil which is physically
suited to the heating system requirements, which has
a high Q (minimal losses) and an appropriate inductance.
Coils are normally manufactured from copper pipe, with
cooling water flowing inside the pipe. The pipe should
be wide enough to allow sufficient water flow and to
minimise electrical resistance, and be rigid enough
to not vibrate under the enormous magnetic fields.
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The choice of capacitor
is dependent on the required operating characteristics.
The capacitor must operate safely at the desired operating
voltage, and be capable of handling the desired currents
at the operating frequency (determined by the depth
of heating required), as well as the total reactive
power. Capacitors may be conduction cooled or water-cooled,
and used singly or in banks. Conduction-cooled capacitor
banks allow variation of capacitance and therefore frequency,
making the system more flexible, and are cheaper and
easier to install than multiple water-cooled capacitors.
Capacitor
requirements can be calculated as follows:
Frequency: to be determined according to application
Voltage: maximum voltage of HF generator
Current: I = V x 2pfC
Reactive Power: Q = VI
Capacitance: C = (2pf)-2L-1
In order to choose an appropriate product,
a number of decisions have to be made. It is often preferable
to buy a solution where coil connections and water cooling
are already integrated, which is the case with any respectable
water-cooled capacitor. If more than one frequency of
operation is required, then an assembly system of conduction-cooled
capacitors will allow hot-swapping of the capacitors
in the bank in order to achieve this goal. Single capacitors
are limited in current and power, and in some cases
an assembly system is the only option, the more extreme
cases requiring the assembly to be custom designed.
Taking a high frequency example, Celem Power Capacitors
manufacture the CSP1005 water-cooled capacitor which
can handle up to 1000kVAr, but for power beyond this
one must turn to an assembly system, such as the Celem
AS150/5 which allows up to 2400kVAr.
If the designer is not confident in their
own design knowledge, the capacitor manufacturers are
normally happy to help find a product solution. They
should be provided with an overview of the application
and the frequency, voltage and reactive power requirements.
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