leakage inductance

However, the physical dimensions of the coil are increased, which results in higher leakage inductance.

Transformers are therefore normally designed to have very low leakage inductance.

The leakage inductance may be variable so the operator can set the output current.

In these cases, the leakage inductance limits the current flow to the desired magnitude.

The transformer therefore has a larger leakage inductance value.

Leakage inductance depends on the geometry of the core and the windings.

Knowledge of leakage inductance is for example useful when transformers are operated in parallel.

This arrangement minimizes the leakage inductance of the primary.

Leakage inductance can be an undesirable property, as it causes the voltage to change with loading.

A step-up transformer with a greater leakage inductance value is suitable for use in this case.

Transformers with variable leakage inductance are used to control the current in arc welding sets.

The autotransformer is designed with enough leakage inductance so that the current is appropriately limited.

The leakage inductance was such that it reduced the output voltage on the secondary side of the transformer.

NSTs are designed to have high leakage inductance to limit their short circuit current to a safe level.

The design of the transformer is also very important, as the leakage inductance should be minimized, or cross conduction may occur.

Without the leakage inductance, the negative resistance characteristic of these gas discharge lamps would cause them to conduct excessive current and be destroyed.

The leakage inductance is inevitably high, resulting in very poor regulation, and so such designs are unsuitable for use in power distribution.

Mosfet Q6 avalanches repetitively and absorbs the energy stored in the leakage inductance of the coil.

The leakage inductance value of the step-up transformer is further increased from that of the three-times resonance design.

Good high-frequency response requires carefully designed and implemented windings without excessive leakage inductance or stray capacitance.

It uses the leakage inductance of its secondary windings in combination with external capacitors, to create one or more resonant circuits.

A normal (low leakage inductance) high-voltage transformer must use an external limiter (sometimes called a ballast) to limit current.

The windings of signal coils minimize leakage inductance and stray capacitance to improve high-frequency response.

Leakage inductance is by itself largely lossless, since energy supplied to its magnetic fields is returned to the supply with the next half-cycle.

They're also used for resonant transformers such as Tesla coils where they can achieve reasonably low loss in spite of the high leakage inductance.