Vacuum system for fuel degassing

What is claimed is: 1. A vacuum assembly comprising: a housing; a movable assembly positioned within the housing, a body of the movable assembly including an integrally formed first portion and a second portion, a first chamber being defined by an end of the first portion and a first end of the housing and a second chamber being defined by an end of the second portion and a second, opposite end of the housing, wherein movement of the movable assembly relative to the housing creates a low pressure area in the first chamber; a first port formed in the housing for delivering a first fluid to the first chamber; a second port formed in the housing for delivering a second fluid, distinct from the first fluid, to the first chamber; a fluid flow conduit extending through the body of the movable assembly and fluidly coupling the first chamber and the second chamber, an inlet of the fluid flow conduit being located at the first portion of the movable assembly of the arranged in fluid communication with the first chamber, and an outlet of the fluid flow conduit being located at the second portion of the movable assembly in fluid communication with the second chamber; a valve disposed along the fluid flow conduit; and a leakage valve disposed within the fluid flow conduit, the leakage valve being movable between a first valve position and a second valve position to restrict a flow through the fluid flow conduit upon detection of an undesired fluid within the low pressure area. 2. The vacuum assembly of claim 1 , wherein the leakage valve further comprises: a body arranged in fluid communication with fluid flow conduit; and a biasing mechanism coupled to the body arranged in the fluid flow conduit, wherein a biasing force of the biasing mechanism retains the body arranged in the fluid flow conduit in a first body position. 3. The vacuum assembly of claim 2 , wherein in the first valve position, both a first end and a second end of the body arranged in the fluid flow conduit are in fluid communication with the fluid flow conduit. 4. The vacuum assembly of claim 3 , wherein in the second valve position, the second end of the body arranged in the fluid flow conduit is not in fluid communication with the fluid flow conduit. 5. The vacuum assembly of claim 2 , wherein the leakage valve transforms from the first valve position to the second valve position in response to the body arranged in the fluid flow conduit being filled with a viscous fluid. 6. The vacuum assembly of claim 5 , wherein a pressure drop generated by the viscous fluid overcomes the biasing force of the biasing mechanism. 7. The vacuum assembly of claim 5 , wherein the viscous fluid is fuel. 8. The vacuum assembly of claim 2 , further comprising a check valve disposed within fluid flow conduit upstream from the leakage valve. 9. The vacuum assembly of claim 1 , further comprising a biasing mechanism coupling the movable assembly to the housing. 10. The vacuum assembly of claim 1 , wherein the movable assembly is movable in response to one or more pressures applied to the movable assembly by one or more sources external to the housing. 11. The vacuum assembly of claim 1 , wherein a third chamber is formed between the housing and a part of the movable assembly between the first portion and the second portion. 12. The vacuum assembly of claim 11 , wherein the second chamber is fluidly connected to ambient air. 13. The vacuum assembly of claim 11 , wherein the third chamber is fluidly connected to a fuel pump. 14. The vacuum assembly of claim 11 , wherein the first chamber is fluidly connected to a deoxygenation system and the low pressure area is formed within the first chamber. 15. The vacuum assembly of claim 1 , wherein the movable assembly includes a piston. 16. The vacuum assembly of claim 7 , wherein the movable assembly includes a rolling diaphragm.