The problem is bin packing with a side of ordering. Bin packing alone is NP-hard, so the running time of the exact algorithm that I'm going to suggest is not polynomial. Hopefully it will be useful anyway.
The first step is to generate all possible groups. Here's some Python to demonstrate what I mean.
def allgroups(terminals, fibrecount=12, groupsofar=):
if terminals: # is nonempty
terminal = terminals.pop() # last element
if terminal.portsize <= fibrecount:
yield from allgroups(terminals, fibrecount - terminal.portsize, groupsofar)
groupsofar.pop() # terminal
yield from allgroups(terminals, fibrecount, groupsofar)
The second step is to generate all possible groupings with Algorithm X, and the third step is to evaluate each of the groupings via dynamic programming. You didn't say what "in the order of the terminals as much as possible" means, so I'll try to minimize inversions. Actually the exact objective doesn't matter as long as it has optimal substructure, namely, given two orderings of the same groups, one is always better than the other regardless of how the other groups are arranged.
Before running the dynamic program, count, for every pair of groups, the number of inversions if the first appears before the second. This means an outer loop iterating over the first group and an inner loop iterating over the second, counting the number of times a terminal in the first group should have appeared after a terminal in the second. Now, for each subset of groups in nondecreasing order, determine the optimal order of that subset. Because of optimal substructure, the optimal order begins with some group in the subset and ends with the optimal solution we've already computed for the remainder. Minimize over all choices of which group comes first.