This isn't formed quite well enough to suggest a particular algorithm. I suggest clustering and "clique" algorithms, but you'll still need to define your "best grouping" metric. "as much as possible", in the face of trade-offs and undefined desires, is meaningless. Your clustering algorithm will need this metric to form your groups.

Data representation is simple: you need a directed graph. An edge from A to B means that A likes B; lack of an edge means A doesn't like B. That will encode the "likes" information in a form tractable to your algorithm. You have 75 nodes and one edge for every "like".

Start by researching clique algorithms; a "clique" is a set in which every member likes every other member. These will likely form the basis of your clustering.

Note, however, that you have to define your trade-offs. For instance, consider the case of 13 nodes consisting of two distinct cliques of 4 and 8 people, plus one person who likes one member of the 8-clique. There are no other "likes" in the graph.

How do you place that 13th person? Do you split the 8-clique and add them to the group with the person they like? If so, you do split off 3 or 4 people form the 8? Is it fair to break 15 or 16 "likes" to put that person with the one person they like -- who doesn't like them? Is it better to add the 13th person to the mutually antagonistic clique of 4?

Your eval function must return a well-ordered metric for all of these situations. It will need to support adding to a group, splitting a large group, etc.