Magnetics Business & Technology - Spring 2014 - (Page 16)
WHITE PAPER
Toroidal Line Power Transformers. Power Ratings Tripled.
By Bridgeport Magnetics Group, Inc.
Toroidal power transformers utilize ring shaped cores, which are made by winding a
continuous strip of grain oriented silicon steel, GOSS, around a cylindrical mandrel. Toroids are more efficient and require less core steel and conductor material than conventional transformers. Material savings often amount to 30 to 50 percent, added to indirect
savings on smaller enclosures and associated structure, plus of course years and years of
power savings.
In a toroid, the primary and secondary windings are placed directly on top of one another. In most cases, by completely enclosing the core and due to the close mutual coupling, the voltage drop under load (regulation) is lower than in a conventional transformer.
For the same reason, toroids emit minimal magnetic stray field virtually eliminating noise
caused by interaction with sheet steel enclosures and adjacent structure, and due to the
absence of joints the cores exhibit minimal inherent hum. As a result toroids are much quieter in operation than conventional transformers, a feature, which is gaining importance in
case of indoor installation e.g. in an office environment.
In general toroids are smaller and lighter than equivalent transformers with stacked, laminated cores, but in spite of their potentially better performance relatively few are offered
with power ratings above 10 KVA, and practically none above 25 KVA. The reason for this is
largely limitations in technology and lack of sophisticated, fully mechanized, heavy duty coil
winding equipment. Traditionally, large toroidal winding machines are scaled up versions of
the table top machines used to produce smaller transformers, and their architecture and
general layout impede the loading and handling of heavy cores as well of partly and fully
completed transformers weighing up to 300 pounds.
Manufacturing a large toroidal transformer is more labor intensive than its laminated
counterpart. The reason for this is difficulties inherent in the winding process, which become harder to overcome as the units grow larger. The main issue is that in a toroid the
core cannot be opened or taken apart, and this means that the coils cannot be wound in a
separate process and installed later, but must be wound turn for turn into the permanently
closed ring cores.
Adding to the complexity, the winding of each coil section requires that the entire length
of conductor is first loaded onto a ring shaped magazine surrounding the core section and
then transferred onto the core in a second winding process via a system of guides and rollers located on a large diameter ring gear, while maintaining sufficient tension to secure that
the windings are tight and placed precisely onto the core.
Manufacturing a toroidal transformer is usually done in stages, requiring the core to be
placed in the machine for winding the first set of coils and then removed for termination
and insulation, after which it is placed back in the machine for winding of a second set of
coils, and so on, until all connections and the final insulation are in place. The problem,
when manufacturing large heavy transformers is that each insertion into and removal from
the winding machine is time consuming and presents a risk of damaging the coils and
insulation. In later years attempts have been made to alleviate the problem by adding a
separate taping head to the coil winding machine, enabling insulation to be applied without removing the transformer, but the layout of machines still impedes manual work such
as forming, stripping and splicing of the terminations, and removal of the finished piece
remains a tricky process, often requiring the help of a second operator.
Another problem special for high power transformers is that the curvature of the core
prevents the use of wide foil conductors. As a consequence windings carrying high current
must be made from many heavy wires wound individually and connected in parallel. The
process is labor intensive and hard on the equipment, and new issues arise when the ratings move up into the 50 to 100 KVA level when just forming and bending the wire as it is
wound onto the core becomes a difficult task in itself.
The winding torque and the forces involved require large dimensioned, high strength
components, meaning that the combined weight of the ring magazine and its load can easily amount to 50 pounds or more and, due to variations in angular velocity inertial forces
come into play, causing variation in winding tension while winding onto rectangular core
sections. The tension may easily snap light wire gauges and often requires that the winding
process is slowed down as far as 60 turns per minute or less.
150 KVA System 3 toroids, 50 KVA 480v Delta
208/120 Wye.
Start, primary winding on tape insulated core
AWG 4 round
Finish, low voltage winding
30 KVA 7U rack assembly
16
Magnetics Business & Technology * Spring 2014
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