Size-reduction machine and size-reduction unit therefor

The invention claimed is: 1. A size-reduction unit comprising: a circular cutter adapted and arranged to cut a product into strips; a rotating cross-cutter adapted and arranged to receive the strips from the circular cutter, the cross-cutter comprising knives each having a concave surface that terminates at an adjoining cutting edge, the cutting edges being adapted and arranged to cut the strips into a size-reduced product, each of the cutting edges being at a constant radius from an axis of rotation of the cross-cutter, a stripper plate defining a shear edge in proximity to the cutting edge of each of the knives of the cross-cutter as the cutting edges encounter the shear edge during rotation of the cross-cutter; wherein the cross-cutter has a helical fluted shape and comprising flutes between adjacent pairs of the knives, the concave surface defines a surface of the flute and the flutes are adapted and arranged to stabilize and cradle the product at a radial location close to the axis of rotation of the cross cutter, and each of the concave surfaces defines a flute angle of greater than 30 degrees to less than 60 degrees at the cutting edge thereof, and each of the flutes has a radial depth that is at least 50% of the constant radius of the cutting edges. 2. The size-reduction unit according to claim 1 , wherein each of the cutting edges has a helical geometric shape. 3. The size-reduction unit according to claim 1 , wherein the flutes have helical shapes and are not parallel to an axis of rotation of the cross-cutter. 4. The size-reduction unit according to claim 1 , wherein each of the cutting edges has a nonparallel relationship with the shear edge of the stripper plate to define a non-zero shear angle. 5. The size-reduction unit according to claim 1 , wherein the entirety of each of the cutting edges is at the constant radius from the axis of rotation of the cross-cutter so that a spacial relationship between the cutting edge and the shear edge of the stripper plate is the same along the entire length of the cutting edge as the cutting edge progressively interacts with the shear edge during rotation of the cross-cutter. 6. The size-reduction unit according to claim 1 , wherein the radial depths of the flutes are at least 65% of the constant radius of the cutting edges. 7. The size-reduction unit according to claim 1 , wherein the flute angles defined by the arcuate concave surfaces are each 50 degrees to less than 60 degrees. 8. The size-reduction unit according to claim 1 , wherein the cross-cutter has a herringbone shape in which each cutting edge defines opposite but equal helix angles within opposite longitudinal halves of the cross-cutter. 9. The size-reduction unit according to claim 1 , wherein the knives of the cross-cutter are integrally formed features of the cross-cutter. 10. The size-reduction unit according to claim 1 , wherein the knives of the cross-cutter are separate components attached to a rotor of the cross-cutter. 11. A size-reduction machine comprising the size-reduction unit of claim 1 . 12. The size-reduction machine according to claim 11 , further comprising a conveyor unit comprising a feed belt for conveying the product to the circular cutter. 13. The size-reduction machine according to claim 12 , wherein the conveyor unit comprises a belt having an infeed belt section that delivers the product to the circular cutter and an outfeed belt section that receives the size-reduced product from the cross-cutter, the outfeed belt section having a direction of travel away from the cross-cutter. 14. The size-reduction machine according to claim 13 , wherein the belt is driven by a single drive roller. 15. The size-reduction machine according to claim 13 , wherein the cross-cutter is adapted and configured to throw the size-reduced product in the same direction as the direction of travel of the outfeed belt section. 16. The size-reduction machine according to claim 11 , wherein the machine is a dicing machine. 17. A method of using the machine of claim 11 , the method comprising: feeding the product to the circular cutter to produce the strips; rotating the cross-cutter to dice the strips with the knives of the cross-cutter and produce diced product; capturing the diced product in the flutes of the cross-cutter as the cross-cutter rotates; and then expelling the diced product from the flutes of the cross-cutter as the cross-cutter continues to rotate. 18. The method according to claim 17 , wherein the entire cutting edge of each knife does not simultaneously engage the product but instead produces the cross-cut in the strips via a scissor action. 19. The method according to claim 17 , further comprising a conveyor unit having an infeed belt section that delivers the product to the circular cutter and an outfeed belt section that receives the diced product from the cross-cutter, the outfeed belt section having a direction of travel away from the cross-cutter. 20. The method according to claim 19 , wherein the cross-cutter throws the diced product in the same direction as the direction of travel of the outfeed belt section.