Your problem needs a little more clarification - it seems that you are given a family of subsets $$S_1,\ldots,S_n$$ of a set A, such that the union of the subsets equals A, and you want a minimum number of subsets whose union is still A.
The basic approach is branch and bound with some heuristics. E.g., if a particular element of A is in only one subset $$S_i$$, then you must select $$S_i$$. Similarly, if $$S_k$$ is a subset of $$S_j$$, then there's no reason to consider $$S_k$$; if element $$a_i$$ is in every subset that $$a_j$$ is in, then you can not bother considering $$a_i$$.
For branch and bound you need good bounding heuristics. Lower bounds can come from independent sets (if there are k elements $$i_1,\ldots,i_L$$ in A such that each if $$i_p$$ is contained in $$A_p$$ and $$i_q$$ is contained in $$A_q$$ then $$A_p$$ and $$A_q$$ are disjoint). Better lower bounds come from the LP relaxation described above.
The Espresso logic minimization system from Berkeley has a very high quality set covering engine.