Induction heater
An induction heater is a key piece of equipment used in all forms of induction heating. Typically an induction heater operates at either medium frequency (MF) or radio frequency (RF) ranges.[1]
Four main component systems form the basis of a modern induction heater
- the control system, control panel, or ON / OFF switch; in some cases this system can be absent
- the power unit (power inverter)
- the work head (transformer)
- and the heating coil (inductor)
How it works
Induction heating is a non contact method of heating a conductive body by utilising a strong magnetic field. Supply (mains) frequency 50 Hz or 60 Hz induction heaters incorporate a coil directly fed from the electricity supply, typically for lower power industrial applications where lower surface temperatures are required. Some specialist induction heaters operate at 400 Hz, the Aerospace power frequency.
Induction heating should not be confused with induction cooking, as the two heating systems are mostly very physically different from each other. Notably, induction heating systems work by applying an alternating magnetic field to a ferrous material to induce an alternating current in the material, so exciting the atoms in the material heating it up.
Main equipment components
An induction heater typically consists of three elements.
Power unit
Often referred to as the inverter or generator. This part of the system is used to take the mains frequency and increase it to anywhere between 10 Hz and 400
Work head
This contains a combination of
Work coil
Also known as the inductor, the coil is used to transfer the energy from the power unit and work head to the work piece. Inductors range in complexity from a simple wound solenoid consisting of a number of turns of copper tube wound around a mandrel, to a precision item machined from solid copper, brazed and soldered together. As the inductor is the area where the heating takes place, coil design is one of the most important elements of the system and is a science in itself.[4]
Definitions
Radio frequency (RF) induction generators work in the frequency range from 100 kHz up to 10
MF induction generators work from 1 kHz to 10 kHz. The output range typically incorporates 50 kW to 500 kW. Induction heaters within these ranges are used on medium to larger components and applications such as the induction forging of a shaft.[1]
Mains (or supply) frequency induction coils are driven directly from the standard AC supply. Most mains-frequency induction coils are designed for single phase operation, and are low-current devices intended for localised heating, or low-temperature surface area heating, such as in a drum heater.
History
The basic principle involved in induction heating was discovered by
Initially the principles were put to use in the design of
Early in the 20th century engineers started to look for ways to harness the heat-generating properties of
At around the same time engineers at
Over time, the technology advanced and units in the 3 to 10 kHz frequency range with powers outputs to 600 kW became common place in
Early in the evolutionary process it became obvious to engineers that the ability to produce a higher radio frequency range of equipment would result in greater flexibility and open up a whole range of alternative applications. Methods were sought to produce these higher RF power supplies to operate in the 200 to 400 kHz range.
Development in this particular frequency range has always mirrored that of the
The use of this technology survived until the early 1990s at which point the technology was all but replaced by power
Mains frequency induction heaters are still widely used throughout manufacturing industry due to their relatively low cost and
Valve oscillator based power supply
Due to its flexibility and potential frequency range, the valve oscillator based induction heater was until recent years widely used throughout industry.[9] Readily available in powers from 1 kW to 1 MW and in a frequency range from 100 kHz to many MHz, this type of unit found widespread use in thousands of applications including soldering and brazing, induction hardening, tube welding and induction shrink fitting. The unit consists of three basic elements:
High voltage DC power supply
The DC (
Self exciting class 'C' oscillator
The oscillator circuit is responsible for creating the elevated frequency electric current, which when applied to the work coil creates the magnetic field which heats the part. The basic elements of the circuit are an inductance (tank coil) and a capacitance (tank capacitor) and an oscillator valve. Basic electrical principles dictate that if a voltage is applied to a circuit containing a capacitor and inductor the circuit will oscillate in much the same way as a swing which has been pushed. Using our swing as an analogy if we do not push again at the right time the swing will gradually stop this is the same with the oscillator. The purpose of the valve is to act as a switch which will allow energy to pass into the oscillator at the correct time to maintain the oscillations. In order to time the switching, a small amount of energy is fed back to the grid of the triode effectively blocking or firing the device or allow it to conduct at the correct time. This so-called grid bias can be derived, either capacitively, conductively or inductively depending on whether the oscillator is a Colpitts, Hartley oscillator, Armstrong tickler or a Meissner.[11]
Means of power control
Power control for the system can be achieved by a variety of methods. Many latter day units feature
Solid state power supplies
In the early days of induction heating, the
To overcome these limitations the induction heating industry turned to the inductor-generator. This type of machine features a toothed rotor constructed from a stack of punched iron laminations. The excitation and AC windings are both mounted on the stator, the rotor is therefore a compact solid construction which can be rotated at higher peripheral speeds than the standard AC generator above thus allowing it to be greater in diameter for a given RPM. This larger diameter allows a greater number of poles to be accommodated and when combined with complex slotting arrangements such as the Lorenz gauge condition or Guy slotting which allows the generation of frequencies from 1 to 10 kHz.
As with all rotating electrical machines, high rotation speeds and small clearances are utilised to maximise flux variations. This necessitates that close attention is paid to the quality of bearings utilised and the stiffness and accuracy of rotor. Drive for the alternator is normally provided by a standard induction motor for convention and simplicity. Both vertical and horizontal configurations are utilised and in most cases the motor rotor and generator rotor are mounted on a common shaft with no coupling. The whole assembly is then mounted in a frame containing the motor stator and generator stator. The whole construction is mounted in a cubicle which features a heat exchanger and water cooling systems as required.
The motor-generator became the mainstay of medium frequency power generation until the advent of
In the early 1970s the advent of solid state switching technology saw a shift from the traditional methods of induction heating power generation. Initially this was limited to the use of thyristors for generating the 'MF range of frequencies using discrete electronic control systems.
State of the art units now employ SCR (
A whole range of techniques are employed in the generation of MF and RF power using semiconductors, the actual technique employed depends often on a complex range of factors. The typical generator will employ either a current or a voltage fed topology. The actual approach employed will be a function of the required power, frequency, individual application, the initial cost and subsequent running costs. Irrespective of the approach employed however, all units tend to feature four distinct elements:[15]
AC to DC rectifier
This takes the mains supply voltage and converts it from the supply frequency of 50 or 60 Hz and also converts it to 'DC'. This can supply a variable DC voltage, a fixed DC voltage or a variable DC current. In the case of a variable systems, they are used to provide overall power control for the system. Fixed voltage rectifiers need to be used in conjunction with an alternative means of power control. This can be done by utilising a switch mode regulator or a by using a variety of control methods within the inverter section.
DC to AC inverter
The
Output circuit
The output circuit has the job of matching the output of the inverter to that required by the coil. This can in it simplest form be a capacitor or in some cases will feature a combination of capacitors and transformers.
Control system
The control section monitors all the parameters in the load circuit, the inverter and supplies switching pulses at the appropriate time to supply energy to the output circuit. Early systems featured discrete electronics with variable
The voltage-fed inverter
The voltage-fed inverter features a filter capacitor on the input to the inverter and a series resonant output circuits. The voltage-fed system is extremely popular and can be used with either SCRs up to frequencies of 10 kHz, IGBTs to 100 kHz and MOSFETs up to 3 MHz. A voltage-fed inverter with a series connection to a parallel load is also known as a third order system. Basically this is similar to solid state, but in this system the series connected internal capacitor and inductor are connected to a parallel output tank circuit. The principal advantage of this type of system is the robustness of the inverter due to the internal circuit effectively isolating the output circuit making the switching components less susceptible to damage due to coil flash-overs or mismatching.[16]
The current-fed inverter
The current-fed inverter is different from the voltage-fed system in that it utilizes a variable DC input followed by a large inductor at the input to the inverter bridge. The power circuit features a parallel resonant circuit and can have operating frequencies typically from 1 kHz to 1 MHz. As with the voltage-fed system, SCRs are typically used up to 10 kHz with IGBTs and MOSFETs being used at the higher frequencies.[17]
Suitable materials
See also
References
Notes
- ^ a b Rudnev, p. 229.
- ^ Rudnev, p. 627.
- ^ Rudnev, p. 628.
- ^ Rudnev, p. 629.
- ^ Rudnev, p. 227.
- ^ Rudnev, p. 1.
- ^ Rudnev, p. 2.
- ^ a b Rudnev, p. 632.
- ^ Rudnev, p. 635.
- ^ Rudnev, p. 636.
- ^ Rudnev, p. 690.
- ^ Rudnev, p. 478.
- ^ Rudnev, p. 652.
- ^ Rudnev, p. 630.
- ^ Rudnev, p. 637.
- ^ Rudnev, p. 640.
- ^ Rudnev, p. 645.
Bibliography
- Rudnev, Valery; Loveless, Don; Cook, Raymond; Black, Micah (2002), Handbook of Induction Heating, CRC Press, ISBN 0-8247-0848-2.
External links
- Sheffield University undertakes fundamental and applied research on enabling induction heater technologies - University of Sheffield
- Induction soldering using induction heater technology example from TWI
- Animation showing heating rates derived from FEA of mains frequency Induction Drum Heater - LMK Thermosafe Ltd
- Comprehensive tutorial on the theory and operation of an induction heater, including schematics for a low and high power device capable of levitating metals.