The average value of flux density must be taken into account to calculate the MMF required for the airgap.

The reluctance of the airgap with slotted armature will be more as compared to the smooth armature (core) machine.

The airgap reluctance for a machine having ventilation ducts will be more than a machine having no ventilation ducts.

All of these

The average value of flux density must be taken into account to calculate the MMF required for the airgap.

The reluctance of the airgap with slotted armature will be more as compared to the smooth armature (core) machine.

The airgap reluctance for a machine having ventilation ducts will be more than a machine having no ventilation ducts.

All of these

The average value of flux density must be taken into account to calculate the MMF required for the airgap.

The reluctance of the airgap with slotted armature will be more as compared to the smooth armature (core) machine.

The airgap reluctance for a machine having ventilation ducts will be more than a machine having no ventilation ducts.

All of these

$= \frac{average flux density over the pole pitch}{maximunm flux density in the airgap}$

$= \frac{Reluc\tan ce of airgap with slotted armature }{Reluc\tan ce of airgap with smooth armature}$

$= \frac{Reluc\tan ce of airgap with ducts }{Reluc\tan ce of airgap without ductsr}$

$= \frac{concentraded winding }{distributed winding }$

$= \frac{average flux density over the pole pitch}{maximunm flux density in the airgap}$

$= \frac{Reluc\tan ce of airgap with slotted armature }{Reluc\tan ce of airgap with smooth armature}$

$= \frac{Reluc\tan ce of airgap with ducts }{Reluc\tan ce of airgap without ductsr}$

$= \frac{concentraded winding }{distributed winding }$

$= \frac{average flux density over the pole pitch}{maximunm flux density in the airgap}$

$= \frac{Reluc\tan ce of airgap with slotted armature }{Reluc\tan ce of airgap with smooth armature}$

$= \frac{Reluc\tan ce of airgap with ducts }{Reluc\tan ce of airgap without ductsr}$

$= \frac{concentraded winding }{distributed winding }$

$= \frac{pole arc}{pole pitch \left({\tau }_p\right)}$

$=\frac{{\tau }_s}{{\tau }_s - K_{cs} b_s}$

$= \frac{L}{L - K_{cd} n_d b_d}$

$A{T}_g = 800000 K_{g }{B}_g l_g$

$= \frac{pole arc}{pole pitch \left({\tau }_p\right)}$

$=\frac{{\tau }_s}{{\tau }_s - K_{cs} b_s}$

$= \frac{L}{L - K_{cd} n_d b_d}$

$A{T}_g = 800000 K_{g }{B}_g l_g$

$= \frac{pole arc}{pole pitch \left({\tau }_p\right)}$

$=\frac{{\tau }_s}{{\tau }_s - K_{cs} b_s}$

$= \frac{L}{L - K_{cd} n_d b_d}$

$A{T}_g = 800000 K_{g }{B}_g l_g$

0.722

0.881

0.692

2.76