The photoluminescence efficiency of a fluorescent molecule is governed by the rates of its non-radiative excited-state relaxation processes, which are known to be accelerated by certain intramolecular motions. This phenomenon is known as the “free-rotor effect” or “loose-bolt effect”. Suppressing this effect by restriction of intramolecular motion by intermolecular aggregation or environmental viscosities often lead to the enhancement of fluorescence quantum yields as well as the increase of fluorescence lifetimes. A deeper understanding of this behavior would provide guidelines for the design of efficient photoluminescent molecules. In this work, we perform a more detailed analysis of a previously studied pentiptycene-derived molecular braking system o-Pp-Ss. The molecular motions are investigated by VT-NMR experiments and DFT-calculations, and the correlations between the modes of the molecular motion and the non-radiative deacivation are discussed based on the viscosity-dependent fluorescence lifetimes. In addition, a model compound p-Pp-Ss has also been studied. From this study, we have gained more detailed insight into the photophysical behaviors of o-Pp-Ss, and a fundamental model for the motion-induced excited-state relaxation process is proposed.