I am currently working on research involving packing problems and am finding myself needing the tools from Combinatorial Geometry (in particular, I've been reading Pach and Agarwal's book on the subject) and I am in the dark on what I think should be a very simple point. I apologize if the question is too elementary for MO.

For reasons I won't get into, I am needing to give a bound for the number of spherical $2$-simplexes which can occur among $n$-points in $\mathbb{S}^2$, as this will tell me how many exposed faces of a simplicial $3$-complex there are among a certain subset of $n$-points in $\mathbb{E}^3$. I am at a point in a Lemma where I am needing to generalize the following claim about graphs in the plane, to simplicial $2$-complexes (graphs) in $\mathbb{S}^2$.

> I cite from Pach and Agarwal's Combinatorial Geometry: "The internal angle of a simple closed polygon $C$ which bounds a graph $G$ at a vertex of degree $d$ is at least $(d-1)\frac{\pi}{3}$."

Does anyone know a proof of this fact, or have a simple explanation of it so that I can have a hope of generalizing it to "the internal angle of a simple closed spherical polygon which bounds a simplicial $2$-complex at a vertex of degree $d$ is at least [something] in $\mathbb{S}^2$".

Thank you, I appreciate any responses.