If you are calculating these things once a day... use the easiest data structure to code! Does it really take so much time to compute? If yes, go on reading.
The sum and average might be easier. If what you add are integers, you can use a FIFO and keep the sum in a variable. Whenever you insert or remove an element, update the sum accordingly (add or subtract).
If you add floating point values, then the method described above might lead to cumulative errors. This might happen if the values are of very different magnitudes and/or the series is very long. In this case, you would need something more complicated (see below).
For the max and min, the most efficient data structures are max/min-heaps. Note that you can embed them in arrays. You would need to have them cross-referenced with the elements of the FIFO queue in order to find immediately the element that has to be removed every time.
The most general solution would be an augmented self-balanced tree. Augmented data structures are explained in chapter 14 of "Introduction to Algorithms" by Cormen, Leiserson, Rivest and Stein. Basically, the tree would contain one element of your data sequence in every node. Every node would contain also the sum, min and max of its subtree. Every time you update a node, you have to update the sum, max and min in all the path from that node to the root. in the root you have the global sum, max and min.
You can find a C++ implementation of augmented self-balanced trees here.
Though, since you only want the sum, min and max of a fixed number of elements, and you always insert at one end and remove at the other, you can make it much simpler. You only need a circular buffer and an array-embedded tree (see how to embed such tree in an array). The tree would contain partial sum, min and max values, as in the augmented trees described before. The advantage is that you don't need to rebalance the tree because you never insert/remove in the middle of the sequence, and the tree always has the same size.
In order to have the statistics for the last 28 days, the last 14 days, the last week, and the last 3 days (for example), you would use a circular buffer and an array-embedded tree for every period: one for the last 3 days, another for the previous 4 (7 minus 3) days, another for the previous 7 days, and so on. Every day, you would take the last datum of every buffer and insert it in the next one.