You're actually asking a few related questions at the same time, not just one single question.
Is there a Program A that, when given another arbitrary Program B as an input, provide an estimate of how long it will take Program B to run? No. Absolutely not. You can't even devise a Program A that will tell you if an arbitrary Program B will ever stop.
That second version-- will Program B ever halt-- is called the Halting Problem, cleverly enough, and it's been proven that it's just not decidable. Wikipedia has a nice web page, and the book Goedel, Escher, Bach is a very long, but very conversational and readable exposition of the ideas involved Goedel's Incompleteness Theorem, which is very closely related.
So if that's true, then how are the scientists coming up with those estimates? Well, they don't have arbitrary programs, they have particular programs that they have written. Some programs are undecidable, but not *all programs are undecidable. So, unless someone makes a serious error, the scientists aren't going to try to run a program that they haven't proven will stop.
Once they have proven that some program will stop, one of the major mathematical tools is called Big O notation. At a very intuitive level, Big O notation helps to develop scaling laws for how the run-time of a program varies with the size of the input. At a very trivial example, suppose your program is a loop, and the loop takes one arbitrary unit of time to run. If you run the loop N times, it takes N units of time. But, if that loop is itself in another loop that runs N times, the whole thing takes N*N units of time. Those two programs scale very differently. (That's a trivial example, but real examples can get quite complicated.)
That's a rather abstract, mathematical tool. Big O analyses are often so abstract that they simply assume that all sufficiently low level operations take "about" the same amount of time, and Big O doesn't really give answers in terms of seconds, hours, or days, anyway. In practice, real computers are also affected by hardware details, such as how long it takes to perform some very low level operation, or worse, how long it takes to move information from one part of the machine to another part which is extremely important on multi-processor computers. So in practice, the insights from the Big O analyses are combined with a detailed knowledge of the machine that it will run on in order to come up with an estimate.