The minimum cost maximum flow algorithm is just a solver for a specific kind of linear program.
What makes linear programs solvable efficiently is convexity: in this case, if you have two feasible flows F and G, then for all t in [0, 1], the flow tF + (1-t)G is feasible and has cost(tF + (1-t)G) ≤ t cost(F) + (1-t) cost(G). For your objective, this basically means FixedCost in [1, X] is 0, C1 ≤ C2, FixedCost in [X + 1, Y] is (C1 - C2)X ≤ 0. That looks something like this:
0 1 X
Probably it is important to you that FixedCost in [1, X] > 0, but this makes the problem NP-hard. A reduction from Steiner tree in graphs is to make the capacity of each edge infinite and cost the weight specified by the Steiner tree problem for the first unit and 0 thereafter. Make one of the k - 1 Steiner terminals a source with capacity k - 1 and the others sinks with capacity 1. Request the cheapest flow of k - 1 units.