and the subcomponent fixed resistence block 280 and compacting within the subcomponent four sided compression chamber 270 the set of springs 275 between the moveable resistence block 268 and the subcomponent fixed resistence block 282. Then the hydraulic pump 278 activates the movable cylinder 276 moving the movable base 272 backwards just enough to relieve the pressure on both the now compacted set of springs 271 and the now compacted set of springs 275. Then the hydraulic pump 278 activates the movable cylinder 260 moving the movable resistance block 262 upwards clearing the top of the subcomponent four sided compression chamber 264 and the hydraulic pump 278 activates the movable cylinder 266 moving the movable resistance block 268 upwards clearing the top of the subcomponent four sided compression chamber 270. Then the hydraulic pump 278 activates the movable cylinder 276 moving the movable base 272 forward far enough to first unload the now compacted set of springs 271 and the now compacted set of springs 275 and then backwards far enough to allow placing the set of springs 279 the set of springs loading area 263. Then the hydraulic pump 278 activates the movable cylinder 276 moving the movable base 272 backwards until the subcomponent fixed resistence block 267 has gone far enough for the movable power cylinder 265 to move the moveable resistence block 269 downward to where it almost touches the movable base 272 which is then accomplished via the hydraulic pump 278 activating the movable cylinder 265 moving the movable resistence block 269 to said position. Then the hydraulic pump 278 activates the movable cylinder 276 moving the movable base 272 backwards compacting within the subcomponent four sided compression chamber 270 the set of springs 279 between the moveable resistence block 269 and the subcomponent fixed resistence block 280. Then the hydraulic pump 278 activates the movable cylinder 276 moving the movable base 272 forwards just enough to relieve the pressure on the now compacted set of springs 279. Then the hydraulic pump 278 activates the movable cylinder 265 moving the movable resistance block 269 upwards clearing the top of the subcomponent four sided compression chamber 270. Then the hydraulic pump 278 activates the movable cylinder 260 moving the movable resistance block 262 downwards to its original starting position as shown in Fig. 10. The now compacted set of springs 279 – as stated in the NOTE above – may be removed in the next cycle of this invention.

In further detail, still referring to the invention of Fig. 10, the construction details of the invention as shown in Fig. 10 are "as shown" and "may be" made of steel, more preferably steel harder than the set of springs 279.

The advantages of the present invention shown in Fig. 10 include, without limitation, efficiency gained via its ability to compact more than one set of springs on the forward stroke and its ability to compact a set of springs on the reverse stroke.

In broad embodiment, the present invention Fig.10, may comprise any number of compaction chambers and may be of any shape or size. It may be operated horizontally as shown or vertically or any angle in between.

Referring now to the invention in more detail, in Fig. 11 there is shown one horizonatal single chamber embodiment of the current invention comprising: a hydraulic pump 306, a continuous stationary floor 302 with a subcomponent four sided compression chamber 296, a movable base