Realize that by using a built-in set, you're going to have some path-level compression based on the nature of your data. Of course, this depends on the container's implementation.
Look at some information on radix trees, digital search trees, red-black trees, etc. You'll see that you don't need to store each and every string, but rather the patterns. For instance, let's simplify your problem: we have only 3 characters that can appear an maximum of 2 times each, and each string is 6 characters long. Three possible strings are:
AABBCC, AABCBC, and AACBCB
With these examples, we could get away with using a maximum of 6 + 3 + 4 = 13 nodes instead of a full 18 nodes. not substantial, but I don't know what you're doing either. As with any type of compression, the more your prefix patterns are reused, the more compression you have.
The numbers 13 and 18 come from the path-level compression. For instance, in straight C (for argument/discussion), if I am implementing my string storage class as a wrapper around an array I would probably just have an array of character pointers with each pointer referencing a spot in memory that contains a pattern. In the example I gave above, this would take 18 characters ( 6 * 3 = 18). Adding on the size of the array (let's say that sizeof(char*) is 4, our array would take 3 * 4 bytes of storage = 12 + 18 or 30 bytes total to store our patterns.
If I am instead storing the patterns in a sort of digital search tree, I make a small tradeoff. The nodes in my tree are going to be larger than 1 byte apiece (1 byte for the character in the node, 4 bytes for the "next" pointer in each node, 5 bytes apiece). The first pattern we store is AABBCC. This is 6 nodes in the tree. Next is AABCBC. We reuse the path AAB from the first tree and need only an additional 3 nodes for CBC. The last pattern is AACBCB. We reuse AA, and need 4 new nodes for CBCB. This is a total of 13 nodes * 5 bytes = 65 bytes of storage. However, if you have a lot of long, repeating patterns in the prefix of your data, then you'll see some prefix path-level compression.
If this isn't the case for you, I would look into Huffman or LZW compression. This will require you to build a dictionary of patterns that have integer numbers tied to them. When you compress, you build the dictionary and create integer id's for each pattern in your text. You then replace the patterns in your text with the integer id's. When uncompressing, you do the opposite. I don't have the time to describe these algorithms in more detail, so you'll need to look them up.
It's a tradeoff in simplicity/time. If your data will allow it, take the shorter method and just use the built-in container. If not, you will need something more tailored to your data.