Compression molded double wall blocks for a pallet and associated methods

The invention claimed is: 1 . A compression molding system comprising: a first extruder configured to output melted plastic; a second extruder downstream from said first extruder and configured to mix the melted plastic with wood chips to output a composite material; a transfer valve downstream from said second extruder, wherein the transfer valve alternately switches between an inner block output and an outer block output, so as to direct the composite material to a single one of these outputs at any time; at least one inner block assembly comprising: at least one inner block mold to receive the composite material from the inner block output associated with said transfer valve, and at least one inner block press aligned with said at least one inner block mold, and configured to press the composite material in the at least one inner block mold into a desired shape of at least one inner block having an opening on one side; at least one outer block assembly comprising: at least one outer block mold to receive the composite material from the outer block output associated with said transfer valve, and at least one outer block press aligned with said at least one outer block mold, and configured to press the composite material in the at least one outer block mold into a desired shape of at least one outer block having an opening on one side; and a press assembly downstream from said at least one inner and outer block assemblies, and configured to press one of the at least one inner blocks into the opening in one of the at least one outer blocks to form a double wall block; a robot arm positioned between said inner and outer block mold assemblies, and configured to alternately grab the at least one inner block and the at least one outer block as they exit the at least one inner and outer block molds; an inner block conveyor positioned between said robot arm and said press assembly, and configured to receive the at least one inner block from said robot arm; and an outer block conveyor adjacent said inner block conveyor and positioned between said robot arm and said press assembly, and configured to receive the at least one outer block from said robot arm, wherein: the inner block output directs the composite material to the at least one inner block mold and the outer block output directs the composite material to the at least one outer block mold; and said press assembly is configured to receive the at least one inner block and the at least one outer block from said inner and outer block conveyors. 2 . The compression molding system according to claim 1 further comprising: an inner block carousel, wherein said at least one inner block assembly comprises a plurality of inner block assemblies spaced apart on said inner block carousel; and an outer block carousel, wherein said at least one outer block assembly comprises a plurality of outer block assemblies spaced apart on said outer block carousel; said inner and outer block carousels are configured to rotate, with the composite material alternately being deposited into the at least one inner and outer block molds as they become available on their respective inner and outer block carousels. 3 . The compression molding system according to claim 1 further comprising: an inner block coolant system configured to circulate a coolant through each inner block mold when the composite material therein is under pressure by the at least one inner block press associated therewith; and an outer block coolant system configured to circulate a coolant through each outer block mold when the composite material therein is under pressure by the at least one outer block press associated therewith. 4 . The compression molding system according to claim 3 wherein cooling the inner and outer block molds while under pressure allows the composite material to stabilize in order for the inner and outer blocks to be removed from their respective inner and outer block molds without being soft and sagging. 5 . The compression molding system according to claim 1 further comprising a first chilled sprayer adjacent said inner and outer block conveyors, and configured to cool the at least one inner and outer blocks as they travel on the respective inner and outer block conveyors to said press assembly. 6 . The compression molding system according to claim 5 , further comprising: a second chilled sprayer adjacent said inner and outer block conveyors, and configured to cool the double wall block as it travels on said conveyors. 7 . The compression molding system according to claim 6 wherein a temperature of the outer block in the double wall block is warmer than a temperature of the inner block in the double wall block, and as the outer block cools, the outer block shrinks onto the inner block to create a tight seal at an interface between the inner and outer blocks. 8 . The compression molding system according to claim 1 wherein the composite material is about 50% plastic and about 50% wood. 9 . The compression molding system according to claim 1 wherein the double wall block is formed with a hollow center. 10 . The compression molding system according to claim 9 wherein the inner block is configured as a 5-sided block with the opening on a remaining side, and the outer block is configured as a 5-sided block with the opening on a remaining side, with the inner and outer blocks being oriented so that the opening of the inner block is facing the opening of the outer block. 11 . A compression molding system comprising: a first extruder configured to output melted plastic; a second extruder downstream from said first extruder and configured to mix the melted plastic with wood chips to output a composite material; a transfer valve downstream from said second extruder and configured to alternately direct the composite material between an inner block output and an outer block output associated with said transfer valve; at least one inner block assembly comprising: at least one inner block mold to receive the composite material from the inner block output associated with said transfer valve, and at least one inner block press aligned with said at least one inner block mold, and configured to press the composite material in the at least one inner block mold into a desired shape of at least one inner block having an opening on one side; at least one outer block assembly comprising: at least one outer block mold to receive the composite material from the outer block output associated with said transfer valve, and at least one outer block press aligned with said at least one inner block mold, and configured to press the composite material in the at least one outer block mold into a desired shape of at least one outer block having an opening on one side; and a press assembly downstream from said at least one inner and outer block assemblies, and configured to press one of the at least one inner blocks into the opening in one of the at least one outer blocks to form a double wall block; a robot arm positioned between said inner and outer block mold assemblies, and configured to alternately grab the at least one inner block and the at least one outer block as they exit the at least one inner and outer block molds; an inner block conveyor positioned between said robot arm and said press assembly, and configured to receive the at least one inner block from said robot arm; an outer block conveyor adjacent said inner block conveyor and positioned between said robot arm and said press assembly, and configured to receive the at least one outer block from said robot arm; and said press assembly is configured to receive the at least one in