1. IntroductionCorn stover, among t

1. Introduction
Corn stover, among the crop-based residues, is considered as the most abundant biomass resource, while the straws of graminaceous crops such as wheat, barley, rice, oats, etc. follow the list of collectible biomass. Of the various corn stover components that are collectible from the field in a typical corn harvest, stalks dominate the available biomass (∼73% fresh mass at a moisture content of ∼62% wet basis (w.b.)) followed by leaf (∼20% fresh mass at ∼9% w.b.) and husk (∼7% fresh mass at ∼11% w.b.) (Igathinathane, Womac, Sokhansanj, & Pordesimo, 2006). On dry mass basis, about 56% of the total stover dry mass resided in the stalk, while its moisture ranged from 69% to 56% during the corn harvest; and the dry masses of other components were leaf at 21%, cob at 15%, and husk at 8% with total stover moisture content that ranged from 66% to 47% w.b. (Shinners & Binversie, 2007). These fibrous lignocellulosic materials, after meeting the field soil enrichment requirements, represent a substantial source of biomass that holds the promise for nonfood-based biofuel for present and future energy needs. Biomass, especially in the raw form, has to go through a pretreatment stage of size reduction, before any downstream energy or conversion procedure. Of the gross energy supplied to most hay-cutting devices, only a small portion was actually required for the size reduction as the rest was wasted due to inefficiencies (Chancellor, 1958). Size reduction/grinding is considered to be one of the most energy-intensive or energy-inefficient operations (Mohsenin, 1986). Given the expected scale of future biomass energy utilisation, any improvement in efficiency or energy reduction in the size reduction process means substantial energy saving.

Size reduction is a pretreatment that uses mechanical energy to produce a product which has better flowability, increased bulk density in general, and increased reactive surfaces. Studies have shown that the cutting energy is related to plant stems' physical and mechanical properties, and type of cutting element and blade edge sharpness (Prince et al., 1958 and Womac et al., 2005). Researchers have studied (Akritidis, 1974, Annoussamy et al., 2000, Burmistrova et al., 1963, Chattopadhyay and Pandey, 1999, Dowgiallo, 2005, McRandal and McNulty, 1980, O’Dogherty et al., 1995 and Prince, 1961) and reviewed (Miu et al., 2006, O’Dogherty, 1982 and Yu et al., 2003) the size reduction process of plant materials.

Shearing was shown to be the energy efficient method of size reduction, and was achieved by devices that used knives, shear bars, and linear knife grids with ram (Igathinathane et al., 2008 and Igathinathane et al., 2009). The reported mean ultimate shear stresses were approximately one-fourth of the ultimate tensile stresses for winter wheat (O’Dogherty et al., 1995) (8%–22% w.b.), one-fifth for switchgrass (Yu, Womac, Igathinathane, Ayers, & Buschermohle, 2006) (10%–60% w.b.), and one-third for alfalfa stems (Galedar et al., 2008) (10%–20% w.b.). Thus size reduction equipment that predominantly uses shear mode for failure may hold promise for improved energy efficiencies. An experimental shear-dominant linear knife grid consumed around one-fourth for corn stalks or more for switchgrass of the reported energy of an impact-dominant hammermill (Igathinathane et al., 2008 and Igathinathane et al., 2009). Distinguishing the difference in shear modes, Shinners, Koegel, Barrington, and Straub (1987) concluded that the longitudinal shear energy of alfalfa stems was less than one-tenth of the reported transverse shear values on a shear energy per unit area basis.