IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0768751
(2004-01-29)
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발명자
/ 주소 |
- Woodall,Robert
- Garcia,Felipe
- Doyle,Chris
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출원인 / 주소 |
- The United States of America as represented by the Secretary of the Navy
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인용정보 |
피인용 횟수 :
7 인용 특허 :
0 |
초록
▼
A tandem track system and method provides for safe withdrawal of a tracked vehicle if either of the main tracks becomes separated. The tracked vehicle has a main track longitudinally extending in a closed endless main loop on opposite sides and engaging a separate main drive sprocket assembly, exten
A tandem track system and method provides for safe withdrawal of a tracked vehicle if either of the main tracks becomes separated. The tracked vehicle has a main track longitudinally extending in a closed endless main loop on opposite sides and engaging a separate main drive sprocket assembly, extending under roadwheels to a main drive idler wheel, and back to the main drive-sprocket assembly in the main loop. The tandem drive system has a secondary track engaging each main drive-sprocket assembly and extending forward along the track vehicle from each main drive-sprocket assembly under only an aft-most fractional portion of the roadwheels. The secondary track is configured as a closed endless secondary loop inside of the main loop of each main track whereby each secondary track can transfer rotary power to move the tracked vehicle to safety.
대표청구항
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We claim: 1. A tandem drive system for a tracked vehicle having a main track longitudinally extending in a closed endless main loop on opposite sides and engaging a separate main drive sprocket assembly, extending under roadwheels to a main drive idler wheel, and back to said main drive-sprocket as
We claim: 1. A tandem drive system for a tracked vehicle having a main track longitudinally extending in a closed endless main loop on opposite sides and engaging a separate main drive sprocket assembly, extending under roadwheels to a main drive idler wheel, and back to said main drive-sprocket assembly in said main loop, each main track having an inboard face on an inward facing inner surface said tandem drive system comprising: a secondary track engaging each main drive-sprocket assembly and extending forward along the tracked vehicle from each main drive-sprocket assembly under only an aft-most fractional portion of the roadwheels, each secondary track being configured as a closed endless secondary loop inside of said main loop of each main track, and each secondary track being adjacent to and laterally extending across the inboard face of a separate main track where said main and secondary tracks are wrapped around each main drive-sprocket assembly. 2. The system of claim 1 wherein each secondary track is shorter than each main track. 3. A tandem drive system for a tracked vehicle having a main track longitudinally extending in a closed endless main loop on opposite sides and engaging a separate main drive sprocket assembly, extending under roadwheels to a main drive idler wheel, and back to said main drive-sprocket assembly in said main loop, said tandem drive system comprising: a secondary track engaging each main drive-sprocket assembly and extending forward along the tracked vehicle from each main drive-sprocket assembly under only an aft-most fractional portion of the roadwheels, said secondary track being configured as a closed endless secondary loop inside of and shorter than said main loop of each main track, wherein each main track is made of steel and has inwardly extending longitudinally spaced-apart guide horns, and each secondary track has a fiber reinforced flexible belt-like structure having longitudinally spaced-apart openings correspondingly spaced with respect to said guide horns. 4. The system of claim 3 comprising: a tensioning apparatus mounted on each opposite lateral side of the tracked vehicle in contact with a separate secondary track to selectably exert a pushing, tensioning force on each secondary track; and a hub provided with annular outside surfaces on each main drive-sprocket assembly, said tensioning force exerted by said tensioning apparatus tightening each secondary track around each drive sprocket assembly. 5. The system of claim 4 wherein tightening of each secondary track around each drive sprocket assembly frictionally engages said annular outside surfaces of each hub of each main drive-sprocket assembly to transfer rotary power to move said secondary track and said tracked vehicle. 6. The system of claim 3 comprising: secondary sprockets having annular gear teeth extending from a hub on each rear-mounted main drive-sprocket assembly; and longitudinally spaced-apart holes in each secondary track, said spaced apart holes in each secondary track being correspondingly spaced apart with respect to said gear teeth. 7. The system of claim 6 wherein said gear teeth engage said spaced apart holes in each secondary track to transfer rotary power to move said secondary track and said tracked vehicle. 8. A tracked vehicle comprising: a main return idler wheel on opposite sides and at the front of a tracked vehicle; a main drive sprocket assembly on each of said opposite sides mounted at the rear of said tracked vehicle; roadwheels on each of said opposite sides, said roadwheels being spaced apart from one another and located along the bottom of said tracked vehicle; a main track longitudinally extending in a closed endless main loop on each of said opposite sides, each main track engaging a separate main drive sprocket assembly, extending to a separate main drive idler wheel, under said roadwheels, and back to said separate rear-mounted main drive-sprocket assembly in said main loop each main track having an inboard face on an inward facing inner surface; and a tandem drive system having a secondary track inside said main loop of each main track, each secondary track of said tandem drive system engaging a separate rear-mounted main drive-sprocket assembly, extending forward along the tracked vehicle from each main drive-sprocket assembly under said roadwheels, and defining a closed endless secondary loop inside of and shorter than said main loop, and each secondary track being adjacent to and laterally extending across the inboard face of a separate main track where the main and secondary tracks are wrapped around each main drive-sprocket assembly. 9. The vehicle of claim 8 wherein said secondary track extends forward under only an aft-most fractional portion of said roadwheels. 10. A tracked vehicle comprising: a main return idler wheel on opposite sides and at the front of a tracked vehicle; a main drive sprocket assembly on each of said opposite sides mounted at the rear of said tracked vehicle; roadwheels on each of said opposite sides, said roadwheels being spaced apart from one another and located along the bottom of said tracked vehicle; a main track longitudinally extending in a closed endless main loop on each of said opposite sides, each main track engaging a separate main drive sprocket assembly, extending to a separate main drive idler wheel, under said roadwheels, and back to said separate rear-mounted main drive-sprocket assembly in said main loop, each main track having an inboard face on an inward facing inner surface; a tandem drive system having a secondary track inside said main loop of each main track, each secondary track of said tandem drive system engaging a separate rear-mounted main drive-sprocket assembly, extending forward along the tracked vehicle from each main drive-sprocket assembly under said roadwheels, and defining a closed endless secondary loop inside of and shorter than said main loop, said secondary track extending forward under only an aft-most fractional portion of said roadwheels, and each secondary track being adjacent to and laterally extending across the inboard face of a separate main track where the main and secondary tracks are wrapped around each main drive-sprocket assembly wherein each main track is made of steel and has inwardly extending longitudinally spaced-apart guide horns, and each secondary track has a fiber reinforced flexible belt-like structure having longitudinally spaced-apart openings correspondingly spaced with respect to said guide horns. 11. The vehicle of claim 10 comprising: a tensioning apparatus mounted on each opposite lateral side of said tracked vehicle and in contact with a separate secondary track to selectably exert a pushing, tensioning force on each secondary track; a hub provided with annular outside surfaces on each main drive-sprocket assembly, said tensioning force exerted by said tensioning apparatus tightening each secondary track around each drive sprocket assembly. 12. The vehicle of claim 11 wherein tightening of each secondary track around each drive sprocket assembly frictionally engages said annular outside surfaces of each hub of each main drive-sprocket assembly to transfer rotary power to move said secondary track and said tracked vehicle. 13. The vehicle of claim 10 comprising: secondary sprockets having annular gear teeth extending from a hub on each rear-mounted main drive-sprocket assembly and; longitudinally spaced-apart holes in each secondary track, said spaced apart holes in each secondary track being correspondingly spaced apart with respect to said gear teeth. 14. The vehicle of claim 13 wherein said gear teeth engage said spaced apart holes in each secondary track to transfer rotary power to move said secondary track and said tracked vehicle. 15. A method of creating a tandem drive system for a tracked vehicle having a main track longitudinally extending in a closed endless main loop on opposite sides and engaging a separate main drive sprocket assembly, extending under roadwheels to a main drive idler wheel, and returning back to said main drive-sprocket assembly in said main loop, each main track having an inboard face on an inward facing inner surface said method comprising the steps of: engaging a secondary track by each main drive-sprocket assembly; extending said secondary track forward along the track vehicle from each main drive-sprocket assembly under only an aft-most fractional portion of the roadwheels; and configuring said secondary track as a closed endless secondary loop inside of and shorter than said main closed endless loop of each main track, each secondary track being adjacent to and laterally extending across the inboard face of a separate main track where said main and secondary tracks are wrapped around each main drive-sprocket assembly. 16. A method of creating a tandem drive system for a tracked vehicle having a main track longitudinally extending in a closed endless main loop on opposite sides and engaging a separate main drive sprocket assembly, extending under roadwheels to a main drive idler wheel, and returning back to said main drive-sprocket assembly in said main loop, said method comprising the steps of: engaging a secondary track by each main drive-sprocket assembly; extending said secondary track forward along the track vehicle from each main drive-sprocket assembly under only an aft-most fractional portion of the roadwheels; configuring said secondary track as a closed endless secondary loop inside of and shorter than said main closed endless loop of each main track; providing inwardly extending longitudinally spaced-apart guide horns on each main track; and forming each secondary track from fiber reinforced flexible belt-like structure having longitudinally spaced-apart openings correspondingly spaced with respect to said guide horns. 17. The method of claim 16 further comprising the steps of; mounting a tensioning apparatus on each opposite lateral side of the tracked vehicle in contact with a separate secondary track to selectably exert a pushing, tensioning force on each secondary track: and tightening each secondary track on a hub provided with annular outside surfaces on each main drive-sprocket assembly by said tensioning force exerted by said tensioning apparatus. 18. The method of claim 17 further comprising the step of: frictionally engaging said annular outside surfaces of each hub of each main drive-sprocket assembly by the step of tightening each secondary track around each drive sprocket assembly to transfer rotary power to move said secondary track and said tracked vehicle. 19. The method of claim 16 further comprising the steps of: providing secondary sprockets having annular gear teeth extending from a hub on each rear-mounted main drive-sprocket assembly and; providing longitudinally spaced-apart holes in each secondary track, said spaced apart holes in each secondary track being correspondingly spaced apart with respect to said gear teeth. 20. The method of claim 19 further comprising the steps of: engaging said spaced apart holes in each secondary track by said gear teeth engage; and transferring rotary power via the engaged spaced apart holes and gear teeth to move said secondary track and said tracked vehicle.
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