vertical side enclosed compression chamber 138 back to its original position as shown and ready to start another cycle as described herein.

In further detail, still referring to the invention of Fig. 1A and Fig. 5, the interior dimensions of the movable vertical side enclosed compression chamber 130 may be slightly larger than the exterior dimensions of the metal springs 131 in order to enable loading the metal springs 131 into the movable vertical side enclosed compression chamber 130. The interior dimensions of the movable vertical side enclosed compression chamber 138 may be slightly larger than the exterior dimensions of the metal springs 143 in order to enable loading the metal springs 143 into the movable vertical side enclosed compression chamber 138. The interior width of the movable vertical side enclosed compression chamber 130 may be slightly longer than the height 133 of the metal springs 131, more preferably the interior width of the side enclosed compression chamber 130 will be the width that maintains the angles 10 and 12 of the metal springs 131 as they are are being compressed. The interior width of the movable vertical side enclosed compression chamber 138 may be slightly longer than the height 145 of the metal springs 143, more preferably the interior width of the side enclosed compression chamber 138 will be the width that maintains the angles 10 and 12 of the metal springs 143 as they are are being compressed. Further the length of the face of movable powered ram 136 must be slightly less than the length of both the movable vertical side enclosed compression chamber 130 and the movable vertical side enclosed compression chamber 138, and the width of the movable powered ram 118 face must be slightly less than the both the width of the movable vertical side enclosed compression chamber 130 and the width of the movable vertical side enclosed compression chamber 138 to enable the movable powered ram 136 to move through both the movable vertical side enclosed compression chamber 120 and the movable vertical side enclosed compression chamber 138 without damaging either the movable vertical side enclosed compression chamber 130 or the movable vertical side enclosed compression chamber 138. Further the length of the movable resistance block 142 may be slightly more than the length of the movable vertical side enclosed compression chamber 130 and the length of the movable vertical side enclosed compression chamber 138 and the length of opening 141, and the width of the movable resistance block 142 may be slightly wider than the width of the movable vertical side enclosed compression chamber 130 and the width of the movable vertical side enclosed compression chamber 138 and the width of opening 141 to enable the movable resistance block 142 to close the bottom of the opening 141. Opening 141 may be slightly larger than the lengths and widths of either or both the movable vertical side enclosed compression chambers 130 and/or138.

 

The construction details of the invention as shown in Fig. 5, the movable powered ram 136 and the movable resistance block 142 and the movable vertical side enclosed compression chambers 130 and 138 may be be constructed of material of adequate strength to withstand both the initial pressures of compressing the metal springs 131 or 143 and the increased pressures exerted by the metal springs 131 or 143 during the compaction operation as the movable powered ram 136 compacts the compressed metal springs 131 or 143 against the movable resistance block 142, preferably the material may be metal, more preferably the material may be metal harder than the metal of the metal springs 131 or 143, and more preferably the material may be machine finished