In this paper a novel outer-rotor consequent pole permanent magnet machine (OR-CPPMM) with H-type modular stator core is proposed for higher average torque ( ), flux linkage (Ф) and efficiency ( ) whereas low cogging torque ( ), torque ripple () and harmonics content in flux linkage (Ф ) and back-EMF (EMF ). The proposed OR-CPPMM is investigated with different stator flux gaps width for static and dynamics electromagnetic performances. Analysis reveals that flux gaps in H-type stator core not only improve electromagnetic performance i.e., Ф is enhanced by 10.23%, Ф is suppressed by 80.65%, diminished EMF by 59.37%, truncate by 44.37% and improve by 15.99% but also exhibits better flux focusing effect to enhance flux linkage and diminish harmonic contents. In addition, H-type modular stator structure provide physical isolation of adjacent phase that de-couple the adjacent phase coupling flux which enhance self-inductance and weaken mutual-inductance and hence improve fault tolerant capability. In addition, to elaborate effectiveness of the proposed and justification of OR-CPPMM novelty with H-type modular stator, electromagnetic performance is extensively compared with existing state of the art including E-core and C-core structure. Analysis and comparison with state-of-the-art reveals that proposed OR-CPPMM enhanced Ф by 65.35%, diminish Ф by 67.24%, truncate by 96.72%, suppresses by 44.40%, diminish by 77.23% whereas is enhanced by 91.69%. Furthermore, the proposed design novelty is justified with comparison of OR-CPPMM with inner rotor and dual rotor permanent magnet flux switching machines. Comparison and analysis unveil that OR-CPPMM exhibits higher up to 35.16%, truncate up to 32.88%, enhanced Ф up to 22.13% and boost to 3.41 times at the cost of 2.58% increase in .