I never liked the term "flux walking" and I suggest people move away from using it. It simply means unbalanced DC. It doesn't matter that it goes up incrementally over many cycles, of course it does, it's a low frequency transient, what else would it be?
It's easily avoided in half-bridge configurations by simply cap-coupling the output. Most ATX PSUs for example have a 0.47-3.3uF cap in series with the winding, which may be in series with the inverter, or returned to DC link +, center tap (for the voltage-doubler input type) or -. A pair of caps in series can also be used (this is preferred when a center tap is absent, as in single-supply or active PFC converters; basically, making the center-tap with a cap divider).
It's least easily avoided in push-pull (CT primary) configurations, which cannot be cap-coupled. In that case, magnetizing current can affect the fall time or voltage level during the dead time between pulses. It may be helpful to reduce inductance (gap the core) to force this to occur faster, which is to say, the flux imbalance needs to drive an impedance (whatever is driving the transformer when the switches are off -- in a forward converter, this includes the secondary rectifier, and primary (switch) capacitance), and it should do so without saturating. Minimizing flux imbalance in the first place is best, which can be done with toggle-type controllers like TL494.
A transformer can be measured for DC resistance, magnetizing and leakage inductance, turns ratio, saturation current, and other parameters that may be of interest (stray capacitance, bandwidth, ringing, etc.) in the usual ways. Inductance with a suitable meter (beware that crude methods, or at too low frequency, likely give erroneous results), magnetizing inductance with all windings open, leakage with all others shorted. Saturation is easiest with a pulsed method, measuring the current ramp in a boost converter type configuration. Operate at a low duty cycle, and increase pulse width until the current ramp is seen to steepen. Mind that DC resistance (which slows dI/dt) may mask saturation, in which case you would need to test at higher voltage (--> shorter pulse widths) or with less resistance somehow (say if the switch and current shunt are dominating loop resistance, as is often the case for small value, high current inductors).
Saturation is the upper limit of peak current, or flux (flux = applied voltage (square pulse) * pulse width), that can be applied to a winding while having a linear enough response. Typically, operation is somewhat below saturation due to core losses. The easiest way to test core losses is simply to wire it up for an application and see how hot it gets. If it gets too hot, reduce the applied voltage, power level, or increase frequency (may not be feasible e.g. that would shift a flyback into CCM operation), and see if that helps.
Typical ferrite materials have reasonable core losses in the 50-200kHz range, for flux density around 0.1-0.3T (and saturation 0.3-0.45T). Larger cores should run lower density, in part because of surface area to volume ratio (effectively less cooling). Higher performance materials may be suitable at 50-100mT at 500kHz or more.
There are broadly two kinds of transformer: coupled inductor (purpose is to store and release energy within a cycle, or over several cycles) and transformer (purpose is to transform power instantaneously, less a minor delay due to leakage). Flyback transformers are the former case, as well as SEPIC/Cuk inductors. Forward converters are the latter case, though as mentioned above, they may intentionally store some energy, but for purposes other than supplying output power (i.e., some energy transfer (from/to the primary side alone) may be required to achieve flux balance without saturating). Note then, CMCs are also a type of transformer, merely used sideways (instead of transforming power, they are used to block noise power). Resonant transformers may be an inbetween case, or also may have lower coupling factor (relatively high leakage inductance), in which case "coupled inductors" is the more meaningful description but notice the three-element (Lpri, Lsec, Lleak) equivalent circuit, in other words the general non-ideal transformer case. (They're all NI transformers of course; the distinction is more about how it's used, which correlates strongly but not perfectly with the parameters.)
So, you will need to identify the type/application as well. A forward converter transformer might be usable as a flyback coupled inductor, but at much lower power levels (because saturation will be relatively low). Type is also easy to recognize from the circuit the component is found in.
Tim
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