We theoretically study the quantum transport behavior of a normal-superconductor-normal junction based on a type-II Weyl semimetal which is rotated by a certain angle. The calculation results show that the orientation angle decides the scattering mechanism of the system. The double Andreev reflections (ARs) and double Election transmissions (ETs) happen simultaneously when the orientation angle is small, including retro AR, specular AR, retro ET and specular ET. And the retro AR are gradually suppressed with the further increase of the orientation. When the orientation angle exceeds the critical angle, the scattering mechanism of the system is same as the NSN junction based on the normal mental, i.e., normal electron reflection, normal electron transmission, retro Andreev reflection and crossed Andreev reflection. In addition, the conductance of the system is unaffected by the chemical potential, and also unaffected by the incident angle when the orientation angle is smaller than the critical angle, but decreases with the increase of the incident angle when the orientation angle is greater than the critical angle. The conductance of crossed Andreev reflection (CAR) increase with the incident angle under some conditions.