SYNCHRONOUS GENERATORS AND MOTORS        67


































                         Figure 3.3 D-axis sub-transient reactance versus field leakage reactance.
           3.4.1 Sensitivity of X md , X a , X f and X kd to Changes in Physical Dimensions


                 Assume a particular machine has a given rotor length and diameter, and radial depth of stator
           core. Allow other dimensions to vary.
                 The mutual coupling X md between the rotor and the stator is much influenced by the radial
           length of the air gap.

                 A large air gap gives rise to a high reluctance path and a small mutual reactance X md .Large
           air gaps facilitate the efficient removal of heat from the rotor and stator surfaces. Unfortunately a
           large air gap also results in more ampere-turns being needed in the rotor to fully excite the machine.
           This requires more volume in the rotor and for a given air gaps a larger mean diameter of the stator,
           hence a heavier and more expensive machine. As the kW rating of a machine increases so do its
           synchronous reactances, see sub-section 3.8.

                                          diameter of rotor × length of rotor
                                   X md ∝
                                               air-gap radial distance
                 A low armature leakage reactance X a requires the number of stator slots per phase to be kept
           small, and a high utilisation of conductors per slot. Double layer slots are most often used for high
           voltage machines.
                 The armature leakage reactance is very much dependent upon the stator slot dimensions. It
           can be shown that:
                                        axial length of slots × depth of slots
                                   X a ∝
                                                  width of slots