FIELD OF INVENTION
This invention relates to suspension systems for small aircraft.
DESCRIPTION OF PRIOR ART
Historically landing gear struts (FIG. 1, 100) used on light aircraft incorporating a cabane “v” have used bungee cords or rings (FIG. 1, 101) as the sole shock absorbing device. These struts are connected to the axle (FIG. 1, 102) of the landing gear and a cabane “v” (FIG. 1, 103) which is connected to the aircraft on either side of the fuselage (FIG. 1, 104) where the main leg of the landing gear (FIG. 1, 105) attaches. Bungees absorb and store kinetic energy upon landing or impact imparted by the expansion of the landing gear strut. The stored energy is released when the bungee contracts/recovers sometimes causing a spring or bounce effect. Other systems utilize compacted rubber discs (FIG. 2, 106) which work in much the same way as a bungee cord in that they absorb and store the kinetic energy imparted by the expansion of the landing gear strut and release that stored energy when they recover. However under the compression of a landing or impact these discs may not return/recover predictably or to a full static position.
DESCRIPTION OF THE INVENTION
The invention incorporates an oleo-pneumatic shock absorber and a bungee return assist. The invention uses a dynamic axle strut to compress a shock absorber while stretching the bungee return. This process works by using a shock absorber attached to the dynamic axle strut in parallel. The shock is connected to the dynamic axle strut through a slot in the static strut which is attached to the cabane “v”, and at the bottom of the static strut. When a landing load is applied the shock strut is allowed to expand; the dynamic strut compresses the oleo-pneumatic shock absorber. The shock absorber dampens/absorbs the kinetic energy imparted from landing then predictably recovers/returns at an adjustable and controllable rate assisted by the bungee return. This adjustable return rate can be set directly using a hand air pump or cartridge or remotely during flight from the cockpit using a compressor.
DESCRIPTION OF DRAWINGS
FIG. 1: This depicts a bungee shock strut suspension system on a small aircraft. The main landing gear, axle, cabane “v”, aircraft mounting points, and shock strut are included.
FIG. 2: This depicts a rubber disc compression suspension system on a small aircraft. The main landing gear, axle, cabane “v”, aircraft mounting points, and shock strut are included.
FIG. 3: Dynamic strut leg components
FIG. 4: Dynamic strut leg assembled
FIG. 5: Static strut leg
FIG. 6: Static strut leg assembled
FIG. 7: The dynamic shock mount and spring assist mechanism components
FIG. 8: The dynamic shock mount and spring assist mechanism assembled
FIG. 9: Dynamic strut leg and static strut leg assembled
FIG. 10: Dynamic strut leg, static strut leg, and dynamic shock mount and spring assist mechanism assembled
FIG. 11: Shock Absorber and Return Assist Spring
FIG. 12: Assembled shock strut with shock absorber and spring assist shown uncompressed
FIG. 13: Assembled shock strut with shock absorber and spring assist shown compressed
FIG. 14: Suspension strut side view “shock side”
FIG. 15: Suspension strut side view “bungee return assist side”
DETAILED DESCRIPTION OF THE INVENTION
Referring to FIGS. 3 and 4 the dynamic strut leg is depicted fully assembled in FIG. 4 while a components view is depicted in FIG. 3. The axle connection bushing (1) is welded to the end of the dynamic strut leg tube (2) at one end. A reinforcing patch (3) is then welded over the bushing and to the dynamic strut leg tube. The other end of the dynamic strut leg tube is drilled at (4) and the dynamic shock mount bushings (5) are inserted and welded in place.
FIGS. 5 and 6 refer to the static strut leg. In FIG. 5 the static strut leg components are shown while the assembled strut is shown in FIG. 6. The cabane “v” attachment tube (6) is drilled at one end (7) to allow the static strut to bolt to the cabane “v” (FIG. 1, 103). A cap (8) is then welded on the other end to prevent moisture and debris from entering the strut assembly. At this point the cabane “v” attachment tube is inserted into one end of the static strut leg tube (9) and welded in place. The static strut leg tube is slotted (10) perpendicular to the orientation of the cabane “v” attachment hole. A reinforcement sleeve (11) is then welded on the end of the static strut leg tube opposite the cabane “v” attachment tube. The static shock mount brackets (12) are then aligned with the cabane “v” attachment holes and welded to the reinforcement sleeve. A rubber bumper (13) is inserted in the static strut leg tube and set flush to the cap on the cabane “v” attachment tube. A bungee hook consisting of a bungee retainer (14) and bungee hook tube (15) is welded to the static strut between the dynamic shock mount and spring assist and the cabane “v” attachment (24) to complete the strut base assembly.
FIGS. 7 and 8 are of the dynamic shock mount and spring assist mechanism. Components of said system are shown in FIG. 7. The bungee hook retainer (14) is welded to the bungee hook tube (15). The bungee hook tube is then welded to the spring assist guide sleeve (16). The pushrod gusset (17) is welded to the dynamic bungee bracket (18). These two components are then connected by the pushrod (19); the pushrod is welded at one end to the spring assists guide sleeve and bungee hook while the other is welded to the pushrod gusset and dynamic bungee bracket.
The following is referenced in FIGS. 7, 8, 9, and 10. At this point the 3 main components of the suspension strut are ready to be assembled. The dynamic strut leg tube is inserted into the static strut leg. The dynamic shock bushings are aligned with the dynamic shock mount slot (FIG. 9). The spring assist guide sleeve bushing (20) is slid over the static strut leg then the spring assist guide sleeve is fitted over the bushing. The dynamic shock mount spacers (21) are then placed at the dynamic strut legs bushings (28). The dynamic shock mounts (22) are set into place and the dynamic bungee bracket is set over both of those. Bolts (23), washers (25), and nuts (26) are then installed through the dynamic bungee mechanism bracket holes (27) and the dynamic strut leg (FIG. 10).
FIG. 9 shows the dynamic strut and static strut assembled. FIG. 10 shows the dynamic shock mount and bungee assist mounted to the strut assembly.
The following references FIGS. 11, 12, 13, 14, and 15. FIG. 11 shows the returns assist spring (29) and shock absorber (30). The upper end of the shock absorber with the larger outside bell is bolted to the dynamic shock mount brackets while the lower end is bolted to the static brackets. The bungee spring assist is then installed over the static and dynamic bungee hooks. The return assist spring also serves to compensate for eccentric loading of the shock strut static and dynamic tubes. FIG. 12 is of the entire shock strut system sitting idle or uncompressed. This is the attitude during flight and while static or parked. FIG. 13 shows the system under compression. The dynamic strut slides outwards with the movements of the landing gear and axle when landing or upon impact. This compresses the shock absorber while stretching the bungee return spring assist. The shock absorber dissipates the kinetic energy then returns at a predictable and adjustable rate. The shock absorber can be adjusted to compensate for the static weight of the aircraft either on the ground or remotely from the cockpit during flight. FIGS. 14 and 15 show the side views of the shock absorber and return assist spring.
In reference to FIGS. 1, 2, and 12, the strut assembly replaces the bungee strut and the compacted discs respectively. The static tube of the strut is connected to the cabane “v” (FIG. 1, 103) via the cabane “v” attachment (FIG. 12, 7). The dynamic tube of the strut is connected to the axle (FIG. 1, 102) via the axle connection bushing (FIG. 12, 1).