초록 ▼

The fluid delivery system includes a pressurizing device for delivering a pressurized injection fluid, a low pressure fluid delivery system, and a pressure isolation mechanism adapted for fluid communication with the pressurizing device and low pressure fluid delivery system. The pressure isolation

The fluid delivery system includes a pressurizing device for delivering a pressurized injection fluid, a low pressure fluid delivery system, and a pressure isolation mechanism adapted for fluid communication with the pressurizing device and low pressure fluid delivery system. The pressure isolation mechanism includes a housing defining an inlet port, an isolation port, and an internal cavity. The housing defines a seal seat in the internal cavity between the inlet port and isolation port. A valve member is disposed in the internal cavity. The valve member is free floating in the internal cavity and is adapted to engage the seal seat. The valve member has an open position permitting fluid communication between the inlet port and isolation port, and is fluid flow responsive to fluid flow in the inlet port to engage the seal seat and attain a closed position preventing fluid flow between the inlet port and isolation port.

대표청구항 ▼

The invention claimed is: 1. A flow-based pressure isolation mechanism, comprising: a housing body defining an inlet port, an isolation port, an internal cavity disposed between the inlet port and the isolation port, a seal seat in the internal cavity between the inlet port and the isolation port,

The invention claimed is: 1. A flow-based pressure isolation mechanism, comprising: a housing body defining an inlet port, an isolation port, an internal cavity disposed between the inlet port and the isolation port, a seal seat in the internal cavity between the inlet port and the isolation port, and a flow initiating port defining a branch lumen in fluid communication with the isolation port; a valve member disposed within and free floating in the internal cavity and comprising a disk-shaped body having top and bottom projections extending from top and bottom sides, respectively, of the disk-shaped body and adapted to center the valve member within the internal cavity, the valve member adapted to move between an open position permitting fluid communication between the inlet port and the isolation port and a closed position preventing fluid flow between the inlet port and the isolation port, wherein the valve member is fluid flow responsive to fluid flow in the inlet port to engage the seal seat and thereby attain the closed position preventing fluid flow between the inlet port and the isolation port; and a flow initiating mechanism associated with the flow initiating port and adapted to provide sufficient upstream capacitance to initiate fluid flow around the valve member such that the valve member moves to the closed position substantially upon flow initiation, the flow initiating mechanism comprising a flow initiating member disposed and retained within the branch lumen by a retainer and an air inlet prevention filter disposed in a bore defined in the retainer and adapted to prevent air from entering the internal cavity when the filter is wetted with fluid. 2. A flow-based pressure isolation mechanism as claimed in claim 1, further comprising a pressure transducer associated with the isolation port. 3. A flow-based pressure isolation mechanism as claimed in claim 1 wherein the valve member is formed of compliant material. 4. A flow-based pressure isolation mechanism as claimed in claim 3 wherein the compliant material is selected to transmit hemodynamic pressure signals through the valve member to a pressure transducer associated with the isolation port. 5. A flow-based pressure isolation mechanism as claimed in claim 1 wherein the housing body further defines a second seal seat radially outward and concentric to the first seal seat. 6. A fluid delivery system with flow-based pressure isolation, comprising: a pressurizing device for delivering injection fluid under pressure; a low pressure fluid delivery system; and a pressure isolation mechanism adapted for fluid communication with the pressurizing device and the low pressure fluid delivery system, and comprising: a housing body defining an inlet port, an isolation port, an internal cavity disposed between the inlet port and the isolation port, a seal seat in the internal cavity between the inlet port and the isolation port, and a flow initiating port defining a branch lumen in fluid communication with the isolation port; a valve member disposed within and free floating in the internal cavity and comprising a disk-shaped body having top and bottom projections extending from top and bottom sides, respectively, of the disk-shaped body and adapted to center the valve member within the internal cavity, the valve member adapted to move between an open position permitting fluid communication between the inlet port and the isolation port and a closed position preventing fluid flow between the inlet port and the isolation port, wherein the valve member is fluid flow responsive to fluid flow in the inlet port to engage the seal seat and thereby attain the closed position preventing fluid flow between the inlet port and the isolation port; and a flow initiating mechanism associated with the flow initiating port and adapted to provide sufficient upstream capacitance to initiate fluid flow around the valve member such that the valve member moves to the closed position substantially upon flow initiation, the flow initiating mechanism comprising a flow initiating member disposed and retained within the branch lumen by a retainer and an air inlet prevention filter disposed in a bore defined in the retainer and adapted to prevent air from entering the internal cavity when the filter is wetted with fluid. 7. A fluid delivery system as claimed in claim 6 wherein the inlet port is in fluid communication with the pressurizing device and the low pressure fluid delivery system via a fitting. 8. A fluid delivery system as claimed in claim 6, further comprising a pressure transducer associated with the isolation port. 9. A fluid delivery system as claimed in claim 6 wherein the valve member is formed of compliant material. 10. A fluid delivery system as claimed in claim 9 wherein the compliant material is selected to transmit hemodynamic pressure signals through the valve member to a pressure transducer associated with the isolation port. 11. A fluid delivery system as claimed in claim 6 wherein the housing body further defines a second seal seat radially outward and concentric to the first seal seat. 12. A flow-based pressure isolation mechanism as claimed in claim 1 wherein an aperture connects the internal cavity with the isolation port and the top projection of the valve member extends through the aperture. 13. A flow-based pressure isolation mechanism as claimed in claim 1 wherein the disk-shaped body further comprises a series of tab members provided on the bottom side thereof. 14. A flow-based pressure isolation mechanism as claimed in claim 1 wherein the branch lumen comprises a first portion and a larger, stepped portion, the flow initiating member being positioned within the first portion and the retainer being positioned within the stepped portion. 15. A flow-based pressure isolation mechanism as claimed in claim 14 wherein an amount of radial clearance is provided radially about the flow initiating member and an inner wall of the first portion of the branch lumen and an amount of distal clearance is provided at a distal end of the air inlet prevention filter. 16. A flow-based pressure isolation mechanism as claimed in claim 1 wherein the upstream capacitance is provided by the flow initiating member being adapted to compress in an axial direction within the branch lumen to thereby allow fluid to pass around the flow initiating member and into contact with the air inlet prevention filter. 17. A fluid delivery system as claimed in claim 6 wherein an aperture connects the internal cavity with the isolation port and the top projection of the valve member extends through the aperture. 18. A fluid delivery system as claimed in claim 6 wherein the disk-shaped body further comprises a series of tab members provided on the bottom side thereof. 19. A fluid delivery system as claimed in claim 6 wherein the branch lumen comprises a first portion and a larger, stepped portion, the flow initiating member being positioned within the first portion and the retainer being positioned within the stepped portion. 20. A fluid delivery system as claimed in claim 19 wherein an amount of radial clearance is provided radially about the flow initiating member and an inner wall of the first portion of the branch lumen and an amount of distal clearance is provided at a distal end of the air inlet prevention filter. 21. A fluid delivery system as claimed in claim 6 wherein the upstream capacitance is provided by the flow initiating member being adapted to compress in an axial direction within the branch lumen to thereby allow fluid to pass around the flow initiating member and into contact with the air inlet prevention filter. 22. A fluid delivery system as claimed in claim 7 wherein the fitting defines a first input port in fluid communication with the pressurizing device, a second input port in fluid communication with the low pressure fluid delivery system, an outlet port and a pressure transducer port in fluid communication with the inlet port of the pressure isolation mechanism. 23. A fluid delivery system as claimed in claim 22 wherein the inlet port of the pressure isolation mechanism is adapted to mate with the pressure transducer port of the fitting via a threaded or a welded connection. 24. A fluid delivery system as claimed in claim 22 wherein the bottom projection of the valve member projects into the pressure transducer port of the fitting. 25. A fluid delivery system as claimed in claim 7 wherein the fining is a Y-T fitting.