Novel collinear magnet, the altermagnet (AM) with spin-splitting energy band and zero net magnetization have attracted great interest due to its potential spintronic applications. Here, we demonstrate AM-like phases in a microscopic Kondo lattice model, widely used for heavy fermion compounds. With the framework of fermionic parton mean-field theory, we find the \(d\)-wave AM state can coexist with the intrinsic Kondo screening effect in such itinerant-local electron system if an alternating next-nearest-neighbor-hopping (NNNH) is included. Such alternating NNNH take nonmagnetic atoms, neglected in usual antiferromagnetism study, into account when encountering real-life candidate AM materials. The AM-like states are characterized by their spin-splitting quasiparticle bands, Fermi surface, spin-resolved distribution function and conductivity. It is suggested that the magnetic quantum oscillation and charge transport measurement can detect those AM-like phases. We hope the present work may be useful for exploring AM-like phases in \(f\)-electron compounds.