Small exit duct for a reverse flow combustor with integrated cooling elements

The invention claimed is: 1. A method of assembling a reverse flow combustor of a gas turbine engine, the method comprising: providing an annular ring and a plurality of cooling elements integrally formed on the annular ring, the plurality of cooling elements being spaced apart from each other and extending axially away from a concave inner surface of the annular ring, the plurality of cooling elements including a plurality of projecting pins and/or ribs; positioning the annular ring spaced apart from an inner liner of the reverse flow combustor, the inner liner having impingement apertures therein which are operable, in use, to direct impingement cooling air jets through the impingement apertures in the inner liner and onto the plurality of cooling elements and the concave inner surface of the annular ring, and positioning at least one heat shield panel in the reverse flow combustor and spaced apart from the inner liner to define an annular gap between the inner liner and the at least one heat shield, the annular gap configured for providing, in use, a film of cooling air along at least a portion of an outer surface of the annular ring, and providing a sealing ring between the inner liner and the annular ring, the sealing ring defining an outlet of the annular gap. 2. The method of claim 1 , comprising integrally forming the annular ring and the plurality of cooling elements by casting, metal injection molding, or 3D printing. 3. The method of claim 1 , comprising abutting an end of the annular ring to the sealing ring to form a single sealing interface between the annular ring and the sealing ring. 4. The method of claim 1 , comprising defining a passage between the annular ring and the inner liner. 5. A reverse flow combustor of a gas turbine engine, comprising: a combustion chamber defined between an inner combustor liner and an outer combustor liner; and a reverse flow duct defining a reverse flow exit passage of the combustion chamber, the reverse flow duct including: an outer duct wall disposed at a downstream end of the outer combustor liner relative to a flow through the reverse flow combustor, the outer duct wall forming a continuation of the outer combustor liner; an inner duct wall disposed at a downstream end of the inner combustor liner relative to the flow through the reverse flow combustor, the inner duct wall forming a continuation of the inner combustor liner; and an annular ring removably fastened to the inner duct wall and forming a boundary of the reverse flow exit passage, the annular ring spaced apart from the inner duct wall to define a cooling passage therebetween for receiving impingement cooling airflow, the annular ring having an outer convex surface facing the reverse flow exit passage and an opposite inner concave surface facing the cooling passage, and a plurality of cooling elements integrally formed with the annular ring, the plurality of cooling elements being spaced apart from each other and extending axially away from the inner concave surface to project into the cooling passage, the plurality of cooling elements including a plurality of projecting pins and/or ribs, the inner duct wall having impingement cooling apertures therein to direct the cooling impingement airflow against the plurality of cooling elements and the inner concave surface during operation of the gas turbine engine; and at least one heat shield panel disposed in the combustion chamber and spaced apart from the inner combustor liner thereby defining an annular gap therebetween, the annular gap configured for providing a film of cooling air along at least a portion of the outer convex surface of the annular ring, and a sealing ring disposed between the inner combustor liner and the annular ring, the sealing ring defining an outlet of the annular gap. 6. The reverse flow combustor of claim 5 , wherein the plurality of cooling elements are disposed entirely within the cooling passage. 7. The reverse flow combustor of claim 5 , wherein the annular ring and the plurality of cooling elements are simultaneously and integrally formed by casting, metal injection molding or 3D printing. 8. The reverse flow combustor of claim 5 , wherein the plurality of cooling elements are equally spaced apart from each other. 9. The reverse flow combustor of claim 5 , wherein an end of the annular ring abuts the sealing ring and forms a single sealing interface with the sealing ring, the outer convex surface of the annular ring being aligned with an outer surface of the sealing ring. 10. The reverse flow combustor of claim 5 , wherein the inner duct wall is integrally formed with the inner combustor liner. 11. The reverse flow combustor of claim 5 , wherein the annular ring has a ceramic or aluminide coating on at least a portion thereof for insulation and oxidation resistance.