Radially coacting ring seal

What is claimed is: 1. A ring seal apparatus for high temperature sealing for use with a case housing having an axial retention abutment and an inner diameter, the ring seal apparatus comprising: a first ring including a pair of radial faces, a ring portion and an outer diameter, wherein the ring portion and the axial retention abutment are in contact and the outer diameter of the first ring and the inner diameter of the case housing are in circumferential sealing contact; a second ring including a second pair of radial faces substantially parallel to the first pair of radial faces, the second ring adapted to coact with the first ring; the first and second rings together defining a pair of coacting mating faces, wherein the mating faces are obliquely angled relative to the radial faces, such that each of the coacting mating faces is adapted to seal an interface of the two rings at an angle relative to the radial faces; wherein the first ring and the second ring are adapted to seal a circumferential gap between a pair of components. 2. The ring seal apparatus of claim 1 , wherein the first and second rings are axially positioned side-by-side, such that the coacting mating faces are adapted to slide with respect to each other at an angle relative to the radial faces of the rings when the ring seal apparatus is subject to thermal expansion and vibration. 3. The ring seal apparatus of claim 1 , wherein the obliquely angled mating faces comprise a separate sealing interface between the first and second rings in addition to the seal of the circumferential gap provided by the ring seal apparatus. 4. The ring seal apparatus of claim 1 , wherein the sealing interface between the first and second rings is adapted to function as a wedge for enhancement of radial sealing of the ring seal apparatus. 5. The ring seal apparatus of claim 1 , wherein radial sealing is enhanced as a direct function of axial pressure between the coacting mating faces of the first and second rings. 6. The ring seal apparatus of claim 1 , wherein each of the first and second rings defines a component sealing surface. 7. The ring seal apparatus of claim 6 , wherein each component sealing surface is defined by a rounded corner. 8. The ring seal apparatus of claim 1 , wherein when the seals are applied to asymmetrically oriented component surfaces, at least three sealing contacts are established between the ring seal and the component surfaces. 9. A ring seal apparatus and axial support structure for high temperature sealing of a circumferential gap between a pair of components for use with a case housing having an axial retention abutment and an inner diameter, the ring seal apparatus comprising: a first ring including a pair of radial faces, a ring portion and an outer diameter, wherein the ring portion and the axial retention abutment are in contact and the outer diameter of the first ring and the inner diameter of the case housing are in circumferential sealing contact; a second ring including a second pair of radial faces substantially parallel to the first pair of radial faces, the second ring adapted to coact with the first ring; the support structure comprising a pair of axially spaced abutments adapted to axially retain the first and second rings; the first and second rings together defining a pair of coacting mating faces, wherein the mating faces are obliquely angled relative to the radial faces, such that each of the mating faces is adapted to slide at an angle relative to the radial faces; wherein the first ring and the second ring seal the circumferential gap between the components, and wherein the abutments are fixed to one of the aligned components. 10. The ring seal apparatus and axial support structure of claim 9 , wherein the first and second rings are axially positioned side-by-side, such that the coacting mating faces are adapted to slide with respect to each other at an angle relative to the radial faces of the rings when the ring seal apparatus is subject to thermal expansion and vibration. 11. The ring seal apparatus and axial support structure of claim 9 , wherein the obliquely angled mating faces comprise a separate sealing interface between the first and second rings in addition to the seal of the circumferential gap provided by the ring seal apparatus. 12. The ring seal apparatus and axial support structure of claim 9 , wherein the sealing interface between the first and second rings is adapted to function as a wedge for enhancement of radial sealing of the ring seal apparatus. 13. The ring seal apparatus and axial support structure of claim 9 , wherein radial sealing is enhanced as a direct function of axial pressure between the coacting mating faces of the first and second rings. 14. The ring seal apparatus and axial support structure of claim 9 , wherein each of the first and second rings defines a component sealing surface. 15. The ring seal apparatus and axial support structure of claim 14 , wherein each component sealing surface is defined by a rounded corner. 16. The ring seal apparatus and axial support structure of claim 9 , wherein when the seals are applied to asymmetrically oriented component surfaces, at least three sealing contacts are established between the ring seal and the component surfaces. 17. A method of sealing a circumferential gap between components with a case housing having an axial retention abutment and an inner diameter, the method comprising: forming a ring seal apparatus including a first ring having a pair of radial faces, a ring portion and an outer diameter, wherein the ring portion and the axial retention abutment are in contact and the outer diameter of the first ring and the inner diameter of the case housing are in circumferential sealing contact; forming a second ring having a second pair of radial faces substantially parallel to the first pair of radial faces, and providing that the second ring is adapted to coact with the first ring; forming an obliquely angled face in each of the first and second rings to define a pair of coacting mating faces relative to the radial faces of each ring, such that each of the mating faces is adapted to slide at an angle relative to the radial faces; juxtaposing the first and second rings axially side-by-side so that their coacting mating faces are adapted to seal a circumferential gap between asymmetrically aligned components. 18. The method of claim 17 , further comprising providing a pair of abutments on one of the components to axially retain the first and second rings. 19. The method of claim 18 , wherein the pair of abutments defines a peripheral slot adapted to axially retain the rings. 20. The method of claim 19 , further comprising forming rounded corners on each ring to define enhanced component sealing surfaces.