Rotary engine shim design for floating side plates

What is claimed is: 1. A rotary internal combustion engine comprising: a rotor housing having a peripheral wall circumscribing a rotor cavity; a rotor disposed within the rotor cavity; a side housing secured to the rotor housing, the side housing includes a sealing face that seats against a housing face of the rotor housing, an inner wall transverse to the sealing face and a shoulder extending inward from the inner wall; a plate defining a seal running surface for the rotor, the plate disposed between a portion of the side housing and the rotor housing; and at least one shim disposed between the plate and the side housing, the shim spacing the plate apart from contact with the side housing, wherein the plate is disposed within a clearance space between the at least one shim and the rotor housing, the at least one shim is seated on the shoulder, the shoulder includes a width and the at least one shim includes a width that is greater than the width of the shoulder. 2. The rotary internal combustion engine as recited in claim 1 , wherein the at least one shim is uninterrupted about the inner wall. 3. The rotary internal combustion engine as recited in claim 1 , wherein the side housing includes at least one coolant channel interrupting the inner wall and the shoulder, wherein the at least one shim extends over the at least one coolant channel. 4. The rotary internal combustion engine as recited in claim 3 , wherein the side housing includes a center seating surface spaced inward of the inner wall and the at least one shim comprises an outer shim seated on the shoulder and an inner shim seated on the center seating surface. 5. The rotary internal combustion engine as recited in claim 1 , wherein the at least one shim includes a surface roughness that is less than 32 Ra. 6. The rotary internal combustion engine as recited in claim 1 , wherein the at least one shim is formed from a cobalt-chromium alloy. 7. A rotary internal combustion engine comprising: a rotor housing having a peripheral wall circumscribing a rotor cavity; a rotor disposed within the rotor cavity; a side housing secured to the rotor housing, wherein the side housing includes a sealing face that seats against a housing face of the rotor housing, an inner wall transverse to the sealing face, a shoulder extending inward from the inner wall, at least one coolant channel interrupting the inner wall and the shoulder, and a center seating surface spaced inward of the inner wall; a plate defining a seal running surface for the rotor, the plate disposed between a portion of the side housing and the rotor housing; and at least one shim disposed between the plate and the side housing, the shim spacing the plate apart from contact with the side housing, wherein the plate is disposed within a clearance space between the at least one shim and the rotor housing, the at least one shim is seated on the shoulder and comprises an outer shim seated on the shoulder and an inner shim seated on the center seating surface and extends over the at least one coolant channel, wherein the center seating surface includes a gap and the inner shim includes a first end spaced apart across the gap from a second end. 8. The rotary internal combustion engine as recited in claim 7 , wherein the side housing includes at least one structure between the shoulder and the center seating surface, the at least one structure spaced apart from the side plate. 9. A rotary internal combustion engine comprising: a rotor housing having a peripheral wall circumscribing a rotor cavity and a housing face; a rotor disposed within the rotor cavity; a side housing secured to the rotor housing, the side housing including a sealing face that seals against the housing face, wherein the rotor housing includes a shoulder extending inward from an inner wall; a side plate disposed on an inner side of the side housing over the rotor cavity, the side plate defining a seal running surface for the rotor; and an outer shim disposed between the side plate and the side housing for spacing the side plate apart from contact with the side housing, wherein the side plate is disposed within a clearance space between the outer shim and the rotor housing, and the outer shim is seated on the shoulder and includes a width that is greater than a width of the shoulder of the side housing. 10. The rotary internal combustion engine as recited in claim 9 , wherein the side housing includes a center seating surface with an inner shim disposed between the center seating surface and the side plate. 11. The rotary internal combustion engine as recited in claim 10 , wherein the side housing includes a plurality of cooling channels that extend inwardly through the shoulder and the inner wall and the outer shim extends over each of the plurality of cooling channels. 12. The rotary internal combustion engine as recited in claim 11 , wherein the side housing includes at least one structure disposed between the inner wall and the center seating surface, wherein the at least one structure includes a top surface that is spaced apart from the side plate when the side plate is seated on the inner shim and the outer shim. 13. The rotary internal combustion engine as recited in claim 11 , wherein the plurality of cooling channels are disposed at varying intervals about the inner wall of the side housing. 14. A method of assembling a rotary internal combustion engine comprising: placing an outer shim on a shoulder of a side housing; placing a side plate onto the outer shim such that the side plate is spaced apart from the shoulder of the side housing; and attaching the side housing to a rotor housing such that the side plate is disposed within a clearance space between a surface of the rotor housing and the outer shim, wherein the side housing includes a center seating surface and assembly further includes placing an inner shim on the center seating surface and placing the side plate includes placing the side plate on the inner shim and the outer shim. 15. The method as recited in claim 14 , wherein placing the outer shim further comprises placing the outer shim across at least one coolant channel.