e(t) = l di + ri(t) 2.1

this is a differential equati** with c**stant coefficients, of which the soluti** is in two parts:

where:
ih(t) is the soluti** of the homogeneous equati** corresp**d ing to the transient period and ip(t) is the soluti** to the particular equati** corresp**ding to the steady-state period.
By the use of differential equati** theory, which will not be discussed in detail here, the complete soluti** can be determined and expressed iii the following form:

where:

b (α–Φ)=π/2
an approximate formula for calculating the effective value of the total asymmetric current,
including the ac and dc comp**ents, with acceptable accuracy can be obtained from the following expressi**:

the fault current which results when an alternator is short circuited can easily be analysed since this is similar to the case which has alreadybeen analysed, i.e. When voltage is, applied to an rl circuit. The reducti** in current from its value at the **set, owing to the gradual decrease in the magnetic flux caused by the reducti** of the e.m.f. Of the inducti** current, can be seen in figure 3. This effect is known as armature reacti**.
The physical situati** that is presented to a generator, and which makes the calculati**s quite difficult, can be interpreted as a reactancewhich varies with time. Notwithstanding this, in the majority of practical applicati**s it is possible to take account of the variati** of reactance in **ly three stages without producing significant errors. In figure 4 it will be noted that the variati** of current with time, 1(t), comes close to the three discrete levels of current, i", 1' and i, the subtransient, transient and steady-state currents, respectively. The corresp**ding values of direct axis reactance are denoted by and xd,

figure 4 variati** of current with time during a fault

figure 5 variati** of generator reactance with time during a fault

and the typical variati** with, time for each of these is illustrated in
figure 5.
To sum up, when calculating short-circuit currents it is necessary to take into account two factors which could result in the currents varying with time:
· the presence of the dc comp**ent;
· the behaviour of the generator under short circuit c**diti**s.

in studies of electrical protecti** some adjustment has to be made to the values of instantaneous short circuit current calculated using subtransient reactance's which result in higher values of current.
Time delay units can be set using the same values but, in some cases, short-circuit values based ** the transient reactance are used, depending ** the operating speed of the protecti** relays. Transient reactance values are generally used in stability studies.
Of necessity, switchgear specificati**s require reliable calculati**s of the short-circuit levels which can be present ** the electrical network. Taking into account the rapid drop of the short-circuit current due to the armature reacti** of the synchr**ous machines, and the fact that extincti** of an electrical arc is never achieved instantaneously, ansi standards c37.010 and c37.5 recommend using different values of subtransient reactance when calculating the so-called momentary and interrupting duties of switchgear.
Asymmetrical or symmetrical r.m.s. Values can be defined depending ** whether or not the dc comp**ent is included. The peak values are obtained by multiplying the r.m.s. Values by.

the asymmetrical values are calculated as the square root of the sum of the squares of the dc comp**ent and the r.m.s. Value of the ac current, i.e.: