The electron spectrum of 106mRh was analysed with an orange type magnetic spectrometer. Four components of the continuum spectrum were observed with end-point energies (in KeV) and relative intensities: 1700±50 (0.7±0.2); 1310±20 (3.1±0.6); 920±10 (66±13) and 700±50 (30±13). The conversion electrons of 15 transitions have been observed. Their energies, with a relative error of about 1 %, and relative intensities are: 221 (525±75); 387 (125±50); 406 (275±125); 426 (300±140); 450 (160±60); 512 (1000); 616 (140±24); 717 (107±38); 1050 (50±10); 1124 (17±5); 1200 (19±6); 1255 (12±3); 1376 (5±2); 1530 (14±4) and 1566 (6±2). The energy of the 616 keV transition was more precisely determined with a double-focussing iron-yoke magnetic spectrometer as 6 16.0±0.4 keV. Levels in 106Pd are established at energies in keV of: 0, 511.8, 1127.9, 1228.9, 1557.4, 1931.8, 2039.6, 2076.4, 2084.1, 2305.3, 2350.3, 2365.5, 2756.4 and 2951.3 with spins and parities 0 +, 2 +, 2 +, 4 +, (3, 4) +, (4) +, 4 +, (3–6) +, 3 +, (3, 4, 5) +, (4) +, (3, 4, 5) +, 5 +, (5, 6) +, respectively. The total decay energy of 106mRh was determined to be 3675±10 keV. Spin and parity 6 + is inferred for 106mRh. Several features of the decay are explained by the asymmetric rotor theory of Mallmann.