Air cycle machine strut plate assembly

The invention claimed is: 1. An air cycle machine, comprising: a fan rotor; a diffuser cone axially aligned with the fan rotor; and a strut plate assembly comprising a first strut plate and a second strut plate with an ejector formed as a gap axially between a nozzle portion of the first strut plate and a diffuser portion of the second strut plate, the diffuser portion having a greater radius than the nozzle portion and radially non-overlapping the nozzle portion, the first strut plate axially positioned between the fan rotor and the ejector and the second strut plate axially positioned between the ejector and the diffuser cone, wherein the first strut plate comprises a plurality of outer struts and is absent inner struts between the fan rotor and the ejector, and the second strut plate comprises a plurality of inner struts and outer struts, the inner struts axially positioned between the ejector and the diffuser cone, and the ejector defines a recirculation flow path to recirculate a flow generated by the fan rotor back to the fan rotor. 2. The air cycle machine according to claim 1 , wherein the first strut plate further comprises a first intermediate cylindrical portion and a first outer cylindrical portion, where the outer struts of the first strut plate are formed between the first intermediate cylindrical portion and the first outer cylindrical portion. 3. The air cycle machine according to claim 2 , wherein the second strut plate further comprises a hub that extends to coaxially align with the first intermediate cylindrical portion of the first strut plate. 4. The air cycle machine according to claim 3 , wherein the second strut plate further comprises a second intermediate cylindrical portion and a second outer cylindrical portion, where the outer struts of the second strut plate are formed between the second intermediate cylindrical portion and the second outer cylindrical portion, and the inner struts are formed between the second intermediate cylindrical portion and the hub. 5. The air cycle machine according to claim 4 , wherein the first intermediate cylindrical portion forms the nozzle portion and the second intermediate cylindrical portion forms the diffuser portion. 6. The air cycle machine according to claim 4 , wherein an inlet flow path from a heat exchanger is defined between the second intermediate cylindrical portion and the second outer cylindrical portion, an outlet flow path to the diffuser cone is defined between the second intermediate cylindrical portion and the hub, and the ejector recirculates the flow to the recirculation flow path responsive to a flow reduction from the inlet flow path. 7. The air cycle machine according to claim 1 , wherein the inner struts of the second strut plate are airfoils angled to align with a flow produced at a design point condition of the fan rotor. 8. The air cycle machine according to claim 7 , wherein the design point condition is a maximum rotation velocity of the fan rotor. 9. A method of installing a strut plate assembly in an air cycle machine, the method comprising: positioning a first strut plate of the strut plate assembly proximate a fan rotor on a central axis of the air cycle machine, the first strut plate comprising a plurality of outer struts; positioning a second strut plate of the strut plate assembly proximate a diffuser cone on the central axis of the air cycle machine, the second strut plate comprising a plurality of inner struts and outer struts; and establishing a gap axially between a nozzle portion of the first strut plate and a diffuser portion of the second strut plate to form an ejector, the diffuser portion having a greater radius than the nozzle portion and radially non-overlapping the nozzle portion, wherein the inner struts of the second strut plate are axially positioned between the ejector and the diffuser cone, the first strut plate is absent inner struts between the fan rotor and the ejector, and the ejector defines a recirculation flow path to recirculate a flow generated by the fan rotor back to the fan rotor. 10. The method according to claim 9 , wherein the first strut plate further comprises a first intermediate cylindrical portion and a first outer cylindrical portion, where the outer struts of the first strut plate are formed between the first intermediate cylindrical portion and the first outer cylindrical portion. 11. The method according to claim 10 , wherein the second strut plate further comprises a hub that extends to coaxially align with the first intermediate cylindrical portion of the first strut plate. 12. The method according to claim 11 , wherein the second strut plate further comprises a second intermediate cylindrical portion and a second outer cylindrical portion, where the outer struts of the second strut plate are formed between the second intermediate cylindrical portion and the second outer cylindrical portion, and the inner struts are formed between the second intermediate cylindrical portion and the hub. 13. The method according to claim 12 , wherein the first intermediate cylindrical portion forms the nozzle portion and the second intermediate cylindrical portion forms the diffuser portion. 14. The method according to claim 12 , wherein an inlet flow path from a heat exchanger is defined between the second intermediate cylindrical portion and the second outer cylindrical portion, an outlet flow path to the diffuser cone is defined between the second intermediate cylindrical portion and the hub, and the ejector recirculates the flow to the recirculation flow path responsive to a flow reduction from the inlet flow path. 15. The method according to claim 9 , wherein the inner struts of the second strut plate are airfoils angled to align with a flow produced at a maximum rotation velocity of the fan rotor.