An isolated triangle has three lines round it. If you add another triangle beside it, you lose one line where they merge, and gain two others from the new triangle. So you can keep track of the set of lines that appear as boundaries to a group of triangles placed beside each other, and you can also keep track of which of these lines meet which other lines.
I am assuming here that only sharing a boundary joins two triangles in a group, and not sharing a point. Lines meet at a point, and if only sharing a boundary counts as joining two triangles, then each outer line is connected with just one other outer line at each of its ends.
If you follow (e.g. with depth first search) the graph formed where nodes are lines and links between lines show where a line is adjacent to another line, you will trace a cycle of lines - it can't be more complicated than that because any single line meets at most two other lines, one at each of its end points.
If your group of triangles has no holes inside it you will then retrieve a single cycle which is its outer boundary. If the group of triangles has holes in it you will retrieve the outer boundary and a cycle for each of the holes. The outer boundary must be the cycle that contains the largest area, because it contains all of the holes.