If I didn't get my wires crossed, the cartesian product of two transmission-regular graphs is also transmission-regular.  This can be used to make examples of arbitrarily high diameter. I'll add a proof tomorrow if nobody finds a counterexample to my claim while I sleep.

ADDED:
Let $G, H$ be connected graphs of order $m,n$, respectively.  Then in the Cartesian product $G\times H$, we have $d_{G\times H}((u,x),(v,y)) = d_G(u,v)+d_H(x,y)$. From this it is easy to see that the transmission of $(u,x)$ is $n\sigma_u(G) + m\sigma_x(G)$.  So $G\times H$ is transmission-regular iff both $G,H$ are.