Hi Jim and all:
Like I said in the 1st paragraph, most high power HF transformers ARE wound
on ferrite cores. they employ transmission line based windings in which the
energy is coupled to the secondary by a different mechanism than flux link
coupling, which relies on the core. This goes as far as employing semi rigid
coax for the windings. We did it at Elisra for multi kilowatt transformers,
using a pair of 3 inches toroids! Even the use of tubing as the one turn
winding creates a section of coaxial line! There is very little flux leakage
into the core, as a percentage.
The binocular type of core lend itself to favorising transmission line by
ensuring close proximity of the primary and secondary windings, more so than
the more spread out prevalent with toroid transformers. This is why you find
them almost exclusively in high power modern modules!
I mentioned the lower tangent loss of the ferrites. What causes losses in
cores is primarily Hysteresis; ferrites have the lower values of loss due to
their squarer hysteresis curves.
Cores with high u and low bulk resistance get lossy very fast with
increasing frequency while low u would negate their use at the low
frequency end.
BTW, the values of u I mentioned have been proved as optimal during 30 years
of amplifier design at Elisra and Tadiran in tens of thousands of modules at
the 500 watts level. You can't argue with facts!
-----Original Message-----
From: amps-bounces@contesting.com [mailto:amps-bounces@contesting.com] On
Behalf Of Jim Brown
Sent: Sunday, March 29, 2009 8:41 PM
To: Amps
Subject: Re: [Amps] 'red' cores versus 43 cores
On Sun, 29 Mar 2009 17:43:55 +0200, Alex wrote:
>2) Cores for transformers are for the most part ferrite material and they
>have a much higher initial u factor. The high frequency cores rely more on
>transmission line characteristics, with the core being there only to
>increase the fringing inductance at the low frequency end of the range.
WRONG! When a conductor is wound around (or passed through) a ferrite
material, nearly all of the magnetic flux resulting from current in the
conductor flows in the ferrite core. Any loss in the core will couple into
the electrical circuit as resistance. Nearly all ferrite materials have low
loss at lower frequencies and high loss at higher frequencies. That loss
will
also cause the ferrite material to get hot, and when it gets hot enough, it
temporarily loses its magnetic properties! That heat can also melt
insulation
on the conductor.
When a parallel wire "transmission line" is wound around a ferrite core in
the form of a bifilar winding, a significant part of the magnetic flux leaks
to the ferrite core (typically 30-40%). If the core is lossy at the
frequency
of that flux there will be heating and power loss.
Most ferrite materials, including #43 and #61, will be efficient (that is,
low loss, low heating) at lower frequencies, but will have high losses (more
heating, more power loss) at higher frequencies. As Carl says, ANY
discussion
of ferrite materials MUST consider the operating frequency.
>3) Usual u ranges are 120 for the HF range, about 15 to 25 for low VHF (6
>meters or so) and about 10 for UHF (100 to 500 MHz).
>What is more important is the core loss, lower in ferrites and the ability
>to withstand the volts/second stress at the frequencies of interest.
>73 and all the best:
WRONG! Mu is NOT the most important property. LOSS is a VERY important
property! Also, ferrite materials are semiconductors -- that is, they have
varying degrees of electrical conductivity depending on their chemical
composition (the mix). Some are such good insulators (#44) that bare wires
can be wound through them, while others are good enough conductors that bare
wires would short out the inductance! Ferrite materials also have
permitivity -- that is, they act as a dielectric and add shunt capacitance
to
the inductor.
The high equivalent circuit of a wire passing through a ferrite core, and of
a coil wound around a ferrite core, is a parallel resonant circuit. At low
frequencies, the equivalent circuit simplifies to shunt R and L. Typical Q
values are less than 1.
If a ferrite choke is handling power, voltage breakdown can also be a
factor!
Materials like Fair-Rite #31 and #43 are PRIMARILY designed for RFI
suppression at VHF. Ferrites are good suppressors around their resonant
frequency, where they are primarily resistive! They CAN be used as
transformers at lower frequencies where their losses are small enough that
they don't overheat. How low is low? Study the Fair-Rite data.
Materials like Fair-Rite #61 and #67 are PRIMARILY designed as HF
transformers, but #61 is also very useful for suppression in the 200-1,000
MHz range. In general, materials that have the least loss also have lower
mu.
#67 has less HF loss than #61, but also lower mu.
In general, LOW power transformers can work fine on lossy materials (if you
can tolerate the loss), but HIGH power transformers are likely to be
problematic. If you're putting more than a few tens of watts into a core you
need to consider loss.
Repeating my earlier advice -- the Fair-Rite catalog is an EXCELLENT
resource. You can learn a lot from studying it. It is online in pdf form.
There is a materials section at the front that has graphs of the electrical
properties of each of their materials. You will be better equipped to
understand what you see in that catalog if you first study the section of my
tutorial on ferrites.
http://audiosystemsgroup.com/RFI-Ham.pdf
73,
Jim Brown K9YC
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