I'll write an answer based on the comment by Dylan, and we shall have one suffering unanswered question more out of its misery:
Let $\,P\in Syl_7(G)\,\Longrightarrow P=\langle\,x\,\rangle\,\,,\,|P|=7\,$ . Suppose $\,G\,$ is simple and thus $\,P\,$ is not normal in $\,G\,\Longrightarrow n_7=8\,\,,\,\text{with}\,\,n_p=\,$ number of Sylow $p$-subgroups in $\,G\,$ , since $\,8\,$ is the only number both congruent to $\,1\pmod 7\,$ and also dividing $\,|G|=560\,$.
We thus have $n_7=8=[G:N_G(P)]=\frac{|G|}{|N_G(P)|}\Longrightarrow |N_G(P)|=70=2\cdot 5\cdot 7$Since $\,|Aut(P)|=6\,$ and $\,N_G(P)/C_G(P)\,$ isomorphic to a subgroup of $\,Aut(P)\,$ , we get $\left|N_G(P)/C_G(P)\right|=\frac{|N_G(P)|}{|C_G(P)|}=\frac{70}{|C_G(P)|}\mid 6\Longrightarrow |C_G(P)|\in\{35,70\}\Longrightarrow 5\mid |C_G(P)|$so $\,\exists\,y\in C_G(P)\,\,s.t.\,\,\operatorname{ord}(y)=5\,$ , by Cauchy's Theorem, and since $\,xy=yx\,\,\,and\,\,\,\operatorname{ord}(x)=7\,$ , we get that $\,\operatorname{ord}(xy)=35$ . $\;\;\;\;(**)$
As $\,G\,$ has a subgroup of index $\,8\,$ , as noted above, the action of $\,G\,$ on the left cosets of this subgroup (left multiplication) determines a monomorphism of $\,G\,$ into $\,S_8\,$ (as $\,G\,$ is simple), and thus it must be that in fact $\,G\leq A_8\,$ (otherwise, within $\,S_8\,\,,\,\,G\cap A_8\,$ has index $\,2\,$ in $\,G\,$).
But a simple check with the possible lengths of disjoint cycles reveals at once that there is no element of order $\,35\,$ in $\,S_8\,$ , let alone in $\,A_8\,$, contradicting $\;(**)$ .