Roles of stress corrosion cracking (SCC) and hydrogen embrittlement (HE) in fracture mechanism have been investigated in this paper. The experimental methods included fracture morphology observation, corrosion products analysis, and internal friction measurement. The results showed that the fracture mode of 316 stainless steel tube was transgranular type with feather-like and cleavage-like facets. The chloride was the main corrosion products on the failure surface. On the other hand, internal friction verified the high hydrogen peak and S-K peak in the rupture pipe. The closer the sample from rupture end, the stronger the intensity of hydrogen peak was. According to the results, the fracture mechanism could be divided into two parts. The initiation of crack was controlled by SCC, chloride corroding the passive film or low pH value inducing anodic dissolution. The propagation of crack was joined with HE, hydrogen decohering the bonding force of atoms. The relationship between SCC and HE was synergistic. Therefore, the failure tube demonstrated both TGSCC on the fracture surface and higher hydrogen content in the structure.