The quantum enhanced classical sensor network consists of K clusters of Ne entangled quantum states that have been trialled r times, each feeding into a classical estimation process. Previous literature has shown that each cluster can {ideally} achieve an estimation variance of 1/Ne2r for sufficient r. We begin by deriving the optimal values for the minimum mean squared error of this quantum enhanced classical system. We then show that if noise is \emph{absent} in the classical estimation process, the mean estimation error will decay like Ω(1/KNe2r). However, when noise is \emph{present} we find that the mean estimation error will decay like Ω(1/K), so that \emph{all} the sensing gains obtained from the individual quantum clusters will be lost.