Apparatus and methods for airflow testing, especially for air testing of gas turbine components on an airflow test bench. Various embodiments of the present invention include the use of a flow-stabilizing member downstream of the component being tested. Since the flow through or over the component i
Apparatus and methods for airflow testing, especially for air testing of gas turbine components on an airflow test bench. Various embodiments of the present invention include the use of a flow-stabilizing member downstream of the component being tested. Since the flow through or over the component is subsonic, a flow-stabilizing member placed down stream of the component can have an effect on the flow conditions in or around the component being tested. In one embodiment, the flow-stabilizing member provides more consistent results during the testing of the component.
대표청구항▼
What is claimed is: 1. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing defining a plenum chamber and an aperture for flowing of the gas into the internal gaspath of the component, said hous
What is claimed is: 1. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing defining a plenum chamber and an aperture for flowing of the gas into the internal gaspath of the component, said housing being adapted and configured to mount the component proximate to the aperture; a flow directing member located downstream of and proximate to the aperture, said flow directing member receiving gas from the internal gaspath of the component and exhausting the gas to about ambient conditions, said flow directing member including a plurality of open cells, each said cell having a plurality of walls for passage therebetween of a portion of the gas from the component; an instrument which measures a property of the gas; and wherein said housing is adapted and configured such that the internal gaspath of the component receives essentially all the gas flowing through the aperture, and said flow directing member and component define a gap therebetween such that gas exiting from the component entrains ambient air through the gap prior to entering the flow directing member. 2. The apparatus of claim 1 wherein said flow directing member is adapted and configured such that said flow directing member receives essentially all the gas flowing through the internal gaspath of the component. 3. The apparatus of claim 1 wherein said flow directing member is designed and adapted to be attached to at least one of the component or said housing. 4. The apparatus of claim 1 wherein each said cell has a cell flow area, the component is associated with a flow area of the internal gaspath, and each cell flow area is less than the gaspath flow area. 5. The apparatus of claim 1 wherein said flow directing member is located downstream from and spaced apart from the component such that gas exiting from the internal gaspath of the component entrains ambient air into said flow directing member. 6. The apparatus of claim 1 wherein the flow directing member includes a diverging nozzle. 7. The apparatus of claim 1 wherein the flow directing member includes a first ring of a first diameter and a second ring of a second diameter, the first diameter being greater than the second diameter, said first ring being concentric with said second ring, said first ring defining a boundary of a first annulus, said second ring defining a boundary of a second annulus, wherein a first portion of the air exiting from the component flows through the first annulus and a second portion of the air exiting from the component flows through the second annulus. 8. The apparatus of claim 1 wherein gas from said source flows generally in a direction toward the aperture, and the walls of each said cell are generally parallel to the direction. 9. The apparatus of claim 1 wherein the component has a centerline, and the walls of each said cell are generally parallel to the centerline. 10. The apparatus of claim 1 wherein said instrument is a flowmeter. 11. The apparatus of claim 1 wherein said instrument is a pressure gage. 12. The apparatus of claim 1 wherein said instrument is a flowmeter and the property is gas pressure. 13. The apparatus of claim 1 wherein the gas flowing through said flow directing member flows directly into about ambient conditions. 14. The apparatus of claim 1 wherein said flow directing member is a first flow directing member, and which further comprises a second flow directing member located upstream of the aperture for directing the gas from said source toward the component. 15. The apparatus of claim 14 wherein said second flow directing member includes a vane for changing the direction of gas flowing toward the component. 16. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing adapted and configured for mounting of the component; means for directing source gas toward the internal gaspath of the component, said source directing means including at least one internal vane for providing a predetermined velocity profile in the gas flowing into the internal gaspath of the component; means for directing gas exiting internal gaspath of the component, said exit gas directing means including at least one internal passageway for modifying the gas flowing from the internal gaspath of the component, said exit gas directing means being adapted and configured such that gas exiting from the internal gaspath of the component entrains ambient air into gas directing means; and an instrument for measuring a property of the flowing gas; wherein said housing is adapted and configured such that the internal gaspath of the component receives essentially all the gas flowing from said source gas directing means. 17. The apparatus of claim 16 which further comprises an electronic controller for controlling the source of gas. 18. The apparatus of claim 16 wherein said source gas directing means includes a plurality of passageways for making more uniform the properties of the gas from the source. 19. The apparatus of claim 16 wherein the passageways of said source gas directing means reduce the variation in the gas velocity profile proximate the entrance to the component. 20. The apparatus of claim 16 wherein said source of flowing gas is a motorized air blower located upstream of said source gas directing means, wherein the gas flowing through said exit gas directing means flows into about ambient conditions. 21. The apparatus of claim 16 which further comprises a gas flowmeter for measuring the quantity of gas flowing through said component. 22. The apparatus of claim 16 which further comprises a display for receiving a signal from said instrument and providing a visual response corresponding to the property measured by the instrument. 23. The apparatus of claim 16 wherein said exit gas directing means is adapted and configured such that said exit gas directing means receives essentially all the gas flowing through the internal gaspath of the component. 24. The apparatus of claim 16 wherein each said internal passageway has a passageway flow area, the component is associated with a flow area of the internal gaspath, and each passageway flow area is less than the gaspath flow area. 25. A method for evaluating a gasflow characteristic of an internal gaspath of a gaspath component for a gas turbine engine, comprising: providing a source of gas, a plenum chamber including a support member for supporting the component, and a gasflow directing member including a radially convoluted exit for exhausting of gas from said directing member; mounting the component with the support member; directing a steady flow of the gas from the source into the plenum chamber; flowing the gas from the chamber through the internal gaspath of the component; flowing the gas exiting the internal gaspath of the component into the gasflow directing member; and modifying the flow of gas through the internal gaspath of the component by the flow of gas through the gasflow directing member. 26. The method of claim 25 which further comprises calculating a flow characteristic of the component based on a measurement of the flow of the gas prior to said flowing the gas from the chamber through the internal gaspath of the component. 27. The method of claim 25 wherein said source of gas is a motorized air blower located upstream of the component, and wherein the gas exiting the gasflow directing member flows to approximately ambient pressure. 28. The method of claim 25 wherein the chamber includes an interior and an exterior, and said mounting is to the exterior. 29. A method for evaluating a gasflow characteristic of an internal gaspath of a gaspath component for a gas turbine engine, comprising: providing a source of gas, a plenum chamber including a support member for supporting the component, and a gasflow directing member; mounting the component with the support member; placing the gas flow member aft of the support member such that there is a gap therebetween; directing a steady flow of the gas from the source into the plenum chamber; flowing gas from the chamber through the internal gaspath of the component; flowing the gas exiting the internal gaspath of the component into the gasflow directing member; entraining ambient air from the gap into the gasflow directing member by said flowing the exiting gas; and modifying the flow of gas through the internal gaspath of the component by said entraining. 30. The method of claim 29 wherein said flowing gas from the chamber is flowing essentially all of the gas from the chamber through the internal gaspath of the component. 31. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing defining a plenum chamber and an aperture for flowing of the gas into the internal gaspath of the component, said housing being adapted and configured to mount the component proximate to the aperture; a flow directing member located downstream of and proximate to the aperture, said flow directing member receiving gas from the internal gaspath of the component and exhausting the gas to about ambient conditions, said flow directing member including a plurality of open cells, each said cell having a plurality of walls for passage therebetween of a portion of the gas from the component; an instrument which measures a property of the gas; and wherein said housing is adapted and configured such that the internal gaspath of the component receives essentially all the gas flowing through the aperture; wherein the flow directing member includes a converging nozzle located on the aft end of said flow directing member. 32. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing defining a plenum chamber and an aperture for flowing of the gas into the internal gaspath of the component, said housing being adapted and configured to mount the component proximate to the aperture; a flow directing member located downstream of and proximate to the aperture, said flow directing member receiving gas from the internal gaspath of the component and exhausting the gas to about ambient conditions, said flow directing member including a plurality of open cells, each said cell having a plurality of walls for passage therebetween of a portion of the gas from the component; an instrument which measures a property of the gas; and wherein said housing is adapted and configured such that the internal gaspath of the component receives essentially all the gas flowing through the aperture; and wherein the flow directing member includes a radially convoluted exit for exhausting of gas from said flow-directing member. 33. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing defining a plenum chamber and an aperture for flowing of the gas into the internal gaspath of the component, said housing being adapted and configured to mount the component proximate to the aperture; a flow directing member located downstream of and proximate to the aperture, said flow directing member receiving gas from the internal gaspath of the component and exhausting the gas to about ambient conditions, said flow directing member including a plurality of open cells, each said cell having a plurality of walls for passage therebetween of a portion of the gas from the component; and an instrument which measures a property of the gas; wherein said flow directing member and component define a gap therebetween such that gas exiting from the component entrains ambient air through the gap prior to entering the flow directing member. 34. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing defining a plenum chamber and an aperture for flowing of the gas into the internal gaspath of the component, said housing being adapted and configured to mount the component proximate to the aperture; a flow directing member located downstream of and proximate to the aperture, said flow directing member receiving gas from the internal gaspath of the component and exhausting the gas to about ambient conditions, said flow directing member including a plurality of open cells, each said cell having a plurality of walls for passage therebetween of a portion of the gas from the component; and an instrument which measures a property of the gas; wherein the flow directing member includes a converging nozzle located on the aft end of said flow directing member. 35. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing defining a plenum chamber and an aperture for flowing of the gas into the internal gaspath of the component, said housing being adapted and configured to mount the component proximate to the aperture; a flow directing member located downstream of and proximate to the aperture, said flow directing member receiving gas from the internal gaspath of the component and exhausting the gas to about ambient conditions, said flow directing member including a plurality of open cells, each said cell having a plurality of walls for passage therebetween of a portion of the gas from the component; and an instrument which measures a property of the gas; wherein the flow directing member includes a radially convoluted exit for exhausting of gas from said flow-directing member. 36. An apparatus for flow testing of gas through a component having an internal gaspath, comprising: a test bench including a source of flowing gas and a housing adapted and configured for mounting of the component; means for directing source gas toward the internal gaspath of the component, said source directing means including at least one internal vane for providing a predetermined velocity profile in the gas flowing into the internal gaspath of the component; means for directing gas exiting internal gaspath of the component, said exit gas directing means including at least one internal passageway for modifying the gas flowing from the internal gaspath of the component; and an instrument for measuring a property of the flowing gas; wherein the flow directing member includes a radially convoluted exit for exhausting of gas from said flow-directing member.
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