Passive blade tip clearance control system for gas turbine engine

What is claimed is: 1. A gas turbine engine comprising a compressor configured to pressurize air moving along a primary gas path of the gas turbine engine, a combustor fluidly coupled to the compressor to receive pressurized air discharged from the compressor and configured to ignite fuel mixed with the pressurized air, and a turbine including (i) a high-pressure section fluidly coupled to the combustor to receive combustion gases generated by fuel burned in the combustor and (ii) a low-pressure section fluidly coupled to receive the combustion gasses exiting the high-pressure section, wherein the high-pressure section includes a turbine wheel mounted for rotation about a central reference axis, a variable-diameter turbine shroud ring that extends around the turbine wheel, and a passive blade-tip clearance control system including a shroud-ring support coupled to the variable-diameter turbine shroud ring that is configured to drive motion of the turbine shroud ring radially inward or outward based on temperature of the shroud-ring support and defining at least in part a cavity located radially outward of the variable-diameter turbine shroud ring, wherein the cavity is fluidly coupled to a bleed-air passageway that extends from the compressor to the cavity without interruption from a valve and a cooling-air passageway that extends from the cavity to the low pressure section such that pressurized bleed air from the compressor is conducted to the cavity of the passive blade tip clearance control system so that the temperature and motion of the shroud-ring support is controlled based on the operating conditions of the engine without active control of the pressurized bleed air provided to the cavity, wherein the passive blade tip clearance control system further includes an outer case and the shroud-ring support is mounted radially-inward of the outer case to define the cavity radially between an inner surface of the outer case and an outer surface of the shroud-ring support so that pressurized bleed air from the compressor passes over the outer surface of the shroud-ring support, wherein the shroud-ring support includes a panel that is coupled to the turbine shroud ring and a flange coupled to an axially-forward end of the panel, the flange coupled to the outer case and having a U-shape when viewed circumferentially so that the flange is configured to flex as the shroud-ring support moves radially inward and outward relative to the outer case as the pressurized bleed air drives movement of the shroud-ring support, wherein the outer case further includes an outer panel that is concentric with the panel of the shroud-ring support and defines the inner surface of the outer case, an annular duct that extends circumferentially around the reference axis and defines a manifold in fluid communication with the bleed-air passageway, and an inner panel that extends axially forward from the annular duct at an outlet of the manifold and is located radially inward of the outer panel and radially outward of the shroud-ring support to define a gap radially therebetween that is configured to accelerate a flow of the pressurized bleed air from the manifold axially forward over the outer surface of the shroud-ring support toward the flange. 2. The gas turbine engine of claim 1 , wherein the passive blade tip clearance control system further includes an inlet conduit coupled to the outer case and opening into the cavity and an outlet, the inlet configured to conduct the bleed air from the compressor into the cavity and the outlet configured to conduct the bleed air from the cavity to the low pressure section of the turbine. 3. The gas turbine engine of claim 2 , wherein the passive blade-tip clearance control system is configured to heat the shroud-ring support during start-up conditions of the gas turbine engine and is configured to cool the shroud-ring support during cruise conditions. 4. The gas turbine engine of claim 1 , wherein the cavity formed between the outer case and the shroud-ring support is sealed off from a gas path of the high pressure section of the turbine such that the temperature of gases within the cavity controls the gap while allowing for pressure within the cavity to be less than pressure within the primary gas path of the high pressure turbine section. 5. The gas turbine engine of claim 1 , wherein the passive blade tip clearance control system includes a plurality of inlet conduits fluidly coupled to the manifold and spaced apart circumferentially around the reference axis and a plurality of outlets spaced apart circumferentially around the reference axis that extend through the manifold and are offset from each inlet conduit. 6. The gas turbine engine of claim 1 , wherein the high pressure section of the turbine includes a first turbine blade stage, a second turbine blade stage axially aft of the first turbine blade stage, and a vane stage axially between the first and second turbine blade stages, and the passive blade tip clearance control system is configured to control a gap radially between second turbine blade stage and the turbine shroud ring. 7. The gas turbine engine of claim 6 , wherein the outer panel is spaced apart from the central reference axis a first distance, and the inner panel is spaced apart from the central reference axis a second distance that is less than the first distance. 8. The gas turbine engine of claim 7 , wherein the inner panel is positioned radially outward of the second turbine blade stage such that the cavity is narrowed outward of the second turbine blade stage. 9. The gas turbine engine of claim 7 , wherein the inner panel is adjustable axially to target additional turbine blade stages included in the high pressure section of the turbine. 10. The gas turbine engine of claim 6 , wherein the shroud-ring support includes a plurality of turbulators coupled to the outer surface of the shroud-ring support within the cavity radially outward of the second turbine blade stage to increase heat transfer between the bleed air and the shroud-ring support directly outward of the second turbine blade stage. 11. The gas turbine engine of claim 1 , wherein the flange includes a radially inner flex-section coupled to the panel that extends axially forward from the pane, a radially outer flex-section coupled to the radially inner flex-section that extends axially aft from the radially inner flex-section, and a mount section that extends radially outward from the radially outer flex-section and couples to the outer case to mount the shroud-ring support to and the turbine shroud ring to the outer case, wherein the radially inner flex-section and the radially outer flex-section are arranged at an angle relative to one another to provide the U-shape of the flange. 12. A high pressure turbine section for use in a gas turbine engine, the turbine section comprising a turbine wheel mounted for rotation about a central reference axis, a plurality of blades that extend radially outward from the turbine wheel to interact with gases moving through a primary gas path of the turbine section, a variable-diameter turbine shroud ring that extends around the turbine wheel to define a radially-outer boundary of the primary gas path, and a passive blade-tip clearance control system configured to drive motion of the turbine shroud ring radially inward and outward relative to the central reference axis to control size of a gap radially between the turbine wheel and the variable-diameter turbine shroud ring, the passive blade-tip clearance control system including an outer case, a shroud-ring support mounted radially-inward of the outer case to define a cavity radially therebetween, and