I know how to prove the following result. However, my proof is a little bit long and complicated and only uses fairly low tech results in group cohomology. It would be nice if I could find a citation in the literature that directly implies this claim but I am not experienced in group theory or homological algebra and to be honest I'm not sure where to start looking for such a result.

>$\textbf{Lemma}:$ Suppose $\mathbb{T}^n = \mathbb{R}^n/ \mathbb{Z}^n $ is the standard $n$-dimensional torus and $\Gamma$ is a finite group of order $k$. Consider a short exact sequence:
>$$ 0 \to \mathbb{T}^n \to E \to \Gamma \to 1 $$
>Suppose $ R := \{ t \in \mathbb{T}^n \ | \ kt = 0  \} $. Then the following short exact sequence splits:
>$$ 0 \to \mathbb{T}^n/R \to E/R \to \Gamma \to 1 $$

The proof basically boils down to the fact that $ H^2( \Gamma, \mathbb{T}^n) $ is annihilated by $k$ and using that to show that the induced map $ H^2(\Gamma, \mathbb{T}^n) \to H^2(\Gamma, \mathbb{T}^n/R) $ is the zero map and therefore the curvature class of the top short exact sequence projects to zero. 

I guess the things I would like to know are:

 - Is this 'obvious' to those experienced with finite group extensions or Lie theory?
 - Is there a textbook/paper where I can find a result or exercise that directly implies this lemma?