Your definition is only correct for NP-complete.
Starting from the bottom: P is the class of problems that can be solved by some deterministic Turing machine in polynomial time. NP is the class of problems that can be solved by some non-deterministic Turing machine in polynomial time (or whose solutions can be verified by deterministic Turing machines in polynomial time).
As for NP-hard, it means decision problems X that have the following property: given a Turing machine that solves the problem, one could restructure (Turing reduction) any instance of a problem in NP to an instance of X in polynomial time. Informally, this means that NP-hard problems are those that are "at least as hard as NP", or that the solution for X could be applied to every problem in NP. Note that the problem doesn't have to be verifiable in polynomial time, or actually verifiable at all. NP-hard includes undecidable and unrecognizable problems as well.
We don't know if NP-hard includes problems that can be solved in polynomial time or not (the P ?= NP problem). Currently, not a single polynomial-time solution for a NP-hard problem has been found, but neither has it been proven that such solution can't exist. If such a solution was found for some NP-hard problem X, that would mean P = NP as any instance of any problem in NP could be converted to an instance of X in polynomial time (because of the Turing reduction property of NP-hard problems) and then be solved in polynomial time by X's polynomial time solution.