downward to rest upon the top of the three sided compression chamber 234. The hydraulic pump 220 activates the movable cylinder 228 which moves the movable sub-top 226 downward engaging the set of springs 233 such that the set of springs is compressed via the downward force 16 applied by the movable sub-top 226 and the upward force 24 applied by the bottom of the three sided compression chamber 234. This action creates a four sided compression chamber comprising the movable sub-top 226 and the three sided compression chamber 234 hereafter referred to as the four sided compression chamber. Then hydraulic pump 220 activates movable cylinder 222 moving powered ram 224 forward into the four sided compression chamber compressing the set of springs 233 beyond their bending point against the fixed end of the movable top with fixed end resistance block 232. Then hydraulic pump 220 activates movable cylinder 222 moving powered ram 224 backward in the four sided compression chamber to relieve the pressure on now compressed set of springs 233 and the fixed end of the movable top with fixed end resistance block 232. Then the hydraulic pump 220 activates the movable cylinder 228 which moves the movable sub-top 226 upward to its original shown position. Then the hydraulic pump 220 activates the movable cylinder 230 moving the movable top with fixed end resistance block 232 upward clear of the top of the three sided compression chamber 234 and back to its original position as shown. Then hydraulic pump 220 activates movable cylinder 222 moving powered ram 224 forward in the three sided compression chamber 234 pushing the now compacted set of springs 233 out the far end of three sided compression chamber 234. Then hydraulic pump 220 activates movable cylinder 222 moving powered ram 224 backward in the three sided compression chamber 234 to its original position as shown.

In further detail, still referring to the invention of Fig. 1A and Fig. 1B and Fig. 7 and Fig. 28, the interior dimensions of the three sided compression chamber 234 may be slightly larger than the exterior dimensions of the set of springs 233 in order to enable loading the set of springs 233 into the three sided compression chamber 234. The interior height of the four sided compression chamber may be optimized for maximum compression results but will be limited by the height of the movable powered ram 224 as the movable powered ram 224 must be able to move through the four sided compression chamber without damaging the four sided compression chamber. The interior height of the four sided compression chamber may be increased for a set of springs 233 with a height of 235 up to the maximum height of the adjustable height powered ram 814 via moving the movable sub-top 226 up as well as the adjustable height powered ram 814 must be able to move through the four sided compression chamber without damaging the four sided compression chamber. Further the height of the subcomponent fixed end 231 should be slightly more than the height of the four sided compression chamber and the width of the subcomponent fixed end 231 should be slightly wider than the width of the four sided compression chamber to enable the movable top with fixed end resistance block 232 with its subcomponent fixed end 231 to close the end of the four sided compression chamber.

In further detail, referring to Fig. 8, the movable powered ram 224 and movable top with fixed end resistance block 232 with its subcomponent fixed end 231 and the three sided compression chamber 212 may be constructed of material of adequate strength to withstand both the initial pressures of compressing the set of springs 233 and the increased pressures exerted by the set of springs 233 during the compaction operation as the movable powered ram 224 compacts the