Lubrication system for aerial vehicles

What is claimed is: 1. A lubrication system for an aerial vehicle, the lubrication system comprising: a lubrication oil (LO) tank configured to operate at a first internal pressure; and an intake chamber (IC) configured to operate at a second internal pressure greater than the first internal pressure, the IC comprising: an ingress port configured to receive LO from a sump of an equipment of the aerial vehicle, wherein the sump comprises a first egress port and a second egress port, wherein the first and second egress ports are disposed on generally opposite sides of the sump, and wherein the ingress port of the IC is in fluid communication with both the first and second egress ports of the sump; an overflow port in fluid communication with the LO tank; and a supply port in fluid communication with the sump and configured to supply LO to the sump; a makeup fluid circuit having a first makeup fluid passageway and a second makeup fluid passageway in fluid communication with the LO tank at generally opposite sides of the LO tank; and an air-oil separator in fluid communication with the first and second fluid passageways and the first and second makeup fluid passageways, and wherein the oil-air separator is configured to provide the LO to the IC and vent air to an external environment. 2. The lubrication system of claim 1 , wherein the IC is configured to maintain a generally constant pressure of LO to the sump independent of an attitude of the aerial vehicle with respect to gravitational force. 3. The lubrication system of claim 1 , wherein the ingress port of the IC is configured to receive LO at a first pressure, P 1 , wherein the overflow port is configured to dispense LO at a second pressure P 2 , wherein the supply port is configured to dispense LO at a third pressure, P 3 , and wherein P 1 is generally equal to a sum of P 2 and P 3 . 4. The lubrication system of claim 1 , wherein the first egress port is coupled to the IC through a first fluid passageway, wherein the second egress port is coupled to the IC through a second fluid passageway, wherein the first fluid passageway comprises a first scavenge pump and the second fluid passageway comprises a second scavenge pump, wherein the first and second fluid passageways are in fluid communication with an oil-air separator configured to remove air from the LO, and wherein the oil-air separator is configured to provide the LO to the IC and vent air to an external environment. 5. The lubrication system of claim 1 , wherein the IC has a first internal volume, wherein the LO tank has a second internal volume, and wherein the first internal volume is less than the second internal volume. 6. The lubrication system of claim 1 , wherein the IC is disposed at least partially within the LO tank. 7. The lubrication system of claim 1 , further comprising a rotating inlet pick up disposed within the IC and fluidly coupled to the supply port, the rotating inlet pick up configured to rotate about a pivot point through gravitational forces. 8. An aerial vehicle comprising: a lubrication system, the lubrication system comprising: a lubrication oil (LO) tank configured to operate at a first internal pressure; and an intake chamber (IC) configured to operate at a second internal pressure greater than the first internal pressure, the IC comprising: an ingress port configured to receive LO from a sump of an equipment of the aerial vehicle, wherein the sump comprises a first egress port and a second egress port, wherein the first and second egress ports are disposed on generally opposite sides of the sump, and wherein the ingress port of the IC is in fluid communication with both the first and second egress ports of the sump; an overflow port in fluid communication with the LO tank; and a supply port in fluid communication with the sump and configured to supply LO to the sump; a makeup fluid circuit having a first makeup fluid passageway and a second makeup fluid passageway in fluid communication with the LO tank at generally opposite sides of the LO tank; and an air-oil separator in fluid communication with the first and second fluid passageways and the first and second makeup fluid passageways, and wherein the oil-air separator is configured to provide the LO to the IC and vent air to an external environment. 9. The aerial vehicle of claim 8 , wherein the IC is configured to receive LO from the one or more of the first egress ports and the second egress port of the sump at a first pressure, P 1 , wherein the IC comprises: an overflow port in fluid communication with the LO tank, wherein the LO tank is configured to receive overflow LO from the IC, the overflow port being configured to dispense the overflow LO to the LO tank at a second pressure, P 2 ; and a supply port configured to supply LO to the sump at a third pressure, P 3 , wherein P 1 is generally equal to a sum of P 2 and P 3 . 10. The aerial vehicle of claim 9 , wherein the overflow port is configured to pass a flow of LO into the LO tank at substantially all times during operation of the aerial vehicle. 11. The aerial vehicle of claim 9 , wherein P 2 is variable, and wherein P 3 is generally constant. 12. The aerial vehicle of claim 8 , wherein the generally constant pressure of LO supplied to the sump by the lubrication system is configured to deviate from a desired pressure by less than 1 pound per square inch (PSI) during operation of the aerial vehicle. 13. The aerial vehicle of claim 8 , wherein the lubrication system is retrofit in the aerial vehicle.