vertical side enclosed compression chamber 138 shown positioned for compressing the springs 119, a loading position for a movable vertical side enclosed compression chamber 138 labelled 140 to differentiate the loading position 140 shown in dashed lines from the compressing position 138 shown in solid lines, a powered cylinder 148, a powered cylinder 144, a movable resistance block 142, and a solid floor 150 with opening 141 directly below powered ram 136.

In more detail, still referring to the invention of Fig. 5, in operation, the springs 131 are loaded into the movable vertical side enclosed compression chamber 130, then the hydraulic pump 146 powers the powered cylinder 148 to reposition both the connected via spacer 132 the movable vertical side enclosed compression chamber 138 to the loading position 140 and the movable vertical side enclosed compression chamber 130 to the compression directly below the powered ram 136. During movement, floor 150 acts as a bottom to keep springs 131 inside the movable vertical side enclosed compression chamber 130 until the movable vertical side enclosed compression chamber 130 is located directly under powered ram 136 and directly above the opening 141 in floor 150. At the same time, the movable vertical side enclosed compression chamber 138 is now in loading position 140 where springs 143 are loaded into the movable vertical side enclosed compression chamber 138. Then the hydraulic pump 146 powers the powered cylinder 134 moving the powered ram 118 downward into the movable vertical side enclosed compression chamber 130 compressing the springs 131 beyond their bending point against the movable resistance block 142. Then the hydraulic pump 146 powers the powered cylinder 134 moving the powered ram 118 upward into the movable vertical side enclosed compression chamber 130 relieving the pressue on the now compressed springs 131. Then the hydraulic pump 146 powers the powered cylinder 144 moving the movable resistance block 142 clear of the opening 141 at which time the now compressed springs 131 may fall out the bottom of opening 141 or powered ram 136 may be used to push the now compressed springs 131 out of opening 141. Then the hydraulic pump 146 powers the powered cylinder 134 moving the powered ram 118 upward out of the movable vertical side enclosed compression chamber 130 back to its original position as shown. Then the hydraulic pump 146 powers the powered cylinder 144 moving the movable resistance block 142 under the opening 141 as shown in Fig. 5. Then the hydraulic pump 146 powers the powered cylinder 148 to reposition both the connected via spacer 132 the movable vertical side enclosed compression chamber 138 and the movable vertical side enclosed compression chamber 130 to their original positions as shown in Fig. 5. During movement, floor 150 acts as a bottom to keep springs 141 inside the movable vertical side enclosed compression chamber 138 until the movable vertical side enclosed compression chamber 138 is located directly under powered ram 136 and directly above the opening 141 in floor 150. Then the hydraulic pump 146 powers the powered cylinder 134 moving the powered ram 118 downward into the movable vertical side enclosed compression chamber 138 compressing the springs 143 beyond their bending point against the movable resistance block 142. Then the hydraulic pump 146 powers the powered cylinder 134 moving the powered ram 118 upward into the movable vertical side enclosed compression chamber 138 relieving the pressue on the now compressed springs 143. Then the hydraulic pump 146 powers the powered cylinder 144 moving the movable resistance block 142 clear of the opening 141 at which time the now compressed springs 143 may fall out the bottom of opening 141 or powered ram 136 may be used to push the now compressed springs 143 out of opening 141. Then the hydraulic pump 146 powers the powered cylinder 134 moving the powered ram 118 upward out of the movable