Trying to use the above comments by Dylan Wilson, seems like $V_p$ is the convex envelope of edge midpoints of $\Delta^{p+1}$.

Its facets are $p+2$ copies of $V_{p-1}$ (convex hulls of edge midpoints of each of the $p+2$ facets of $\Delta^{p+1}$) and $p+2$ copies of $\Delta^p$ (obtained at each of the $p+2$ vertices of $\Delta^{p+1}$ as a result of truncation (of length up to midpoint, which is the longest possible truncation until truncating hyperplanes begin to intersect inside the polyhedron)).

In addition to the facets described in two bullets a the end of the question, there is one more copy of $V_{p-1}$, corresponding to $\operatorname{cone}(f_1)\to\operatorname{cone}(f_2f_1)\to\operatorname{cone}(f_p\cdots f_1)$ and $p+1$ more copies of $\Delta^p$, corresponding to
\begin{align*}
&\operatorname{cone}(f_1)\to\operatorname{cone}(f_2f_1)\to\cdots\to\operatorname{cone}(f_{p-1}\cdots f_1)\to\operatorname{cone}(f_p\cdots f_1)\to\Sigma X_0,\\
&\operatorname{cone}(f_2)\to\operatorname{cone}(f_3f_2)\to\ \ \cdots\ \  \to\operatorname{cone}(f_p\cdots f_2)\to\Sigma X_1\to\Sigma\operatorname{cone}(f_1),\\
&\operatorname{cone}(f_3)\to\operatorname{cone}(f_4f_3)\to\ \ \ \cdots\ \ \  \to\Sigma X_2\to\Sigma\operatorname{cone}(f_2f_1)\to\Sigma\operatorname{cone}(f_2),\\
&\vdots\\
&\operatorname{cone}(f_p)\to\Sigma X_{p-1}\to\qquad\cdots\qquad\ \ \ \to\Sigma\operatorname{cone}(f_{p-1}f_{p-2})\to\Sigma\operatorname{cone}(f_{p-1}),\\
&\Sigma X_p\to\Sigma\operatorname{cone}(f_p\cdots f_1)\to\qquad\cdots\qquad\to\Sigma\operatorname{cone}(f_pf_{p-1})\to\Sigma\operatorname{cone}(f_p). 
\end{align*}
Hope the maps and the patterns are clear from the above. If not, tell me, I'll try to formulate more details.