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Without air gap, energy is stored, but less than with air gap. A flyback transformer must store energy during the primary 'charging' part of the cycle, in order to release energy into the secondary during the flyback phase.
Imagine them with bobbin. A gap is necessary to increase the energy storing capability of the transformer - it tilts the B-H curve - but more importantly, it stabilizes the inductance by making it independent from the material permeability. Yes, you are right @VerbalKint . The main event in the transformer is the airgap.
A flyback transformer must store energy during the primary 'charging' part of the cycle, in order to release energy into the secondary during the flyback phase. If you are going to buy a lump of magnetic material for your transformer, you will want it to store as much energy as possible.
The flyback transformer is a misnomer and ought to be considered as a switched inductor with coupling, as it does store energy unlike an ideal transformer. However the addition of a small air gap allows more current with greater H fields now occupied in the air gap Not all the energy is in the gap but optimally it can be 2x as much as in the core.
And when the switch opens this energy is transferred (partially or fully) to the secondary. Without air gap no energy is stored. So an air gap is a must in a flyback transformer. Quite possibly
The switch in the circuit shown in the figure opens at t=0 after being closed for a long time. How many milliseconds after the switch opens is the energy stored in the capacitor 36 % 36% of its final value?
Here is the following assertion : Question: Why is it commonly stated that in a flyback transformer, the "air gap carries most of the stored magnetic energy"? Answer: We can intuitively
In this case, ( v_o (0+) ) represents the voltage across a certain component in the circuit immediately after the switch is closed. Since there is no energy stored in the circuit at that moment,
Do Transformers store undesired energy? In practice,all transformers do store some undesired energy: Leakage inductance represents energy stored in the non-magnetic regions between windings,caused
In practice,all transformers do store some undesired energy: Leakage inductance represents energy stored in the non-magnetic regions between windings,caused by imperfect flux coupling. In the
And when the switch opens this energy is transferred (partially or
The first step in solving 3 problem number 25 trying to solve the problem we have to refer to the textbook question: There is no energy stored in the circuit in Fig. P13.25 at the time the switch is closed. a)
Question: 2) There is no energy stored in the circuit shown below at the time the switch is opened. a. Derive the integrodifferential equations that govern the behavior of the node voltages v1 (t) and v2 (t).
There is no energy stored in the circuit shown in Fig. P12.27 at the time the switch is opened. a) Derive the integro differential equation that governs the behavior of the voltage   b)
Step 1/8The circuit in Figure P5 consists of a voltage source of 400 V, a capacitor with a capacitance of 1.25 F, and an inductor with an inductance of 0.25 H.Step 2/8When the switch is closed at t=0, the
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