A vehicle routing and crew scheduling problem (VRCSP) consists of
simultaneously planning the routes of a fleet of vehicles and scheduling the
crews, where the vehicle-crew correspondence is not fixed through time. This
allows a greater planning flexibility and a more efficient use of the fleet,
but in counterpart, a high synchronisation is demanded. In this work, we
present a VRCSP where pickup-and-delivery requests with time windows have to be
fulfilled over a given planning horizon by using trucks and drivers. Crews can
be composed of 1 or 2 drivers and any of them can be relieved in a given set of
locations. Moreover, they are allowed to travel among locations with
non-company shuttles, at an additional cost that is minimised. As our problem
considers distinct routes for trucks and drivers, we have an additional
flexibility not contemplated in other previous VRCSP given in the literature
where a crew is handled as an indivisible unit. We tackle this problem with a
two-stage sequential approach: a set of truck routes is computed in the first
stage and a set of driver routes consistent with the truck routes is obtained
in the second one. We design and evaluate the performance of a metaheuristic
based algorithm for the latter stage. Our algorithm is mainly a GRASP with a
perturbation procedure that allows reusing solutions already found in case the
search for new solutions becomes difficult. This procedure together with other
to repair infeasible solutions allow us to find high-quality solutions on
instances of 100 requests spread across 15 cities with a fleet of 12-32 trucks
(depending on the planning horizon) in less than an hour. We also conclude that
the possibility of carrying an additional driver leads to a decrease of the
cost of external shuttles by about 60% on average with respect to individual
crews and, in some cases, to remove this cost completely