If the lines are actually a path, then perhaps you wouldn't be averse to the requirement that each rectangle cover a contiguous portion of the path. In this case, there's a dynamic program that runs in time O(n^{2} r), where n is the number of segments and r is the number of rectangles.

Compute a table with entries C(i, j) denoting the cost of covering segments 1, …, i with j rectangles. The recurrence is, for i, j > 0,

C(0, 0) = 0

C(i, 0) = ∞

C(i, j) = min over i' < i of (C(i', j - 1) + [cost of the rectangle covering segments i' + 1, …, i])

There are O(n r) entries, each of which is computed in time O(n). Recover the optimal collection of rectangles at the end by, e.g., storing the best i' for each entry.

I don't know of a simple, optimal algorithm for the general case. Since there are “only” O(n^{4}) rectangles whose edges each contain a segment endpoint, I would be tempted to formulate this problem as an instance of generalized set cover.