Binary and ternary blends of the high viscosity recycled high-density polyethylene (reHDPE) from milk bottles, containing either homopolymer polypropylene (PP) or copolymer polypropylene (coPP), were developed in an effort to reduce viscosity and encourage ease of processing by injection molding, without a significant loss in mechanical properties. A grade of PP and a grade of coPP that had crystallization temperatures close to and slightly lower than that of reHDPE were chosen for blending in order to obtain simultaneous crystallization of the reHDPE and (co)PP phases. The resulting reHDPE/(co)PP blends (reHDPE wt% = 77) generally showed very good mechanical properties and, in particular, sufficiently high impact strength while engendering considerably lower viscosity than reHDPE. The PP was more useful at very high and low shear rates whereas the coPP was the most efficient in the mid-range of shear rates (10(2) - 10(3) sec(-1)). Good impact resistance shown by the reHDPE/(co)PP blends was attributed in part to the fine dispersion of (co)PP phase, possible involvement of a portion of the polymers in a co-continuous structure and simultaneous crystallization of the components. Ternary blends of reHDPE (reHDPE wt% = 77), PP and low-density polyethylene (LDPE) showed good mechanical performance, although they were more viscous than (co)PP blends. In the ternary blends, co-crystallization of reHDPE and LDPE phases was preserved (1).