Spiral heat exchanger for hydrodesulfurizer feedstock

The invention claimed is: 1. An apparatus comprising: an annular passage configured to have a flow of hot gas therethrough and having a cylindrical outer wall; at least one rod having a plurality of coils surrounding and in thermal contact with said cylindrical outer wall; a thin cylindrical shell surrounding and in contact with said at least one rod, thereby establishing a plurality of spiral passages in which to flow gas around said outer wall to absorb heat from said flow of hot gas; an annular hydrodesulfurizer having an inner cylindrical wall with a diameter at least a few millimeters greater than the diameter of said thin shell, said spiral passages opening into said hydrodesulfurizer; said annular passage surrounding a cylindrical shift converter configured to change CO to CO 2 ; and said cylindrical shift converter, said annular passage, and said spiral passages forming a unit which is configured for insertion during manufacture into a cavity defined by said inner cylindrical wall. 2. A method comprising: preparing an annular hydrodesulfurizer having an inner cylindrical wall of a first diameter that defines a cavity; preparing a cylindrical shift converter configured to change CO to CO 2 , said shift converter surrounded by an annular passage configured to have a flow of hot gas therethrough, said annular passage having a cylindrical outer wall with at least one rod coiled around said outer wall a plurality of times, and a thin cylindrical shell surrounding and in contact with said at least one rod, thereby establishing one or more spiral passages configured to flow gas around said outer wall to absorb heat from said flow of hot gas, said spiral passages opening into said hydrodesulfurizer; and inserting said shift converter into said cavity to form a unitized desulfurizer, heat exchanger, and shift converter assembly; wherein said thin cylindrical shell has a second diameter that is less than the first diameter and provides a clearance fit between the cylindrical shell and the inner cylindrical wall within said cavity. 3. The method of claim 2 , wherein said inserting is performed such that a gap between the inner cylindrical wall and the thin cylindrical shell is approximately 4-6 mm. 4. The method of claim 2 , wherein the clearance fit between the cylindrical shift converter and the inner cylindrical wall defines an annular chamber having a seal that prevents gas from the one or more spiral passages from flowing into the annular chamber. 5. The apparatus of claim 1 , wherein when the cylindrical shift converter is inserted into the cavity, a gap between the inner cylindrical wall and the thin cylindrical shell is approximately 4-6 mm. 6. The apparatus of claim 1 , wherein when the cylindrical shift converter is inserted into the cavity, an annular chamber is formed between the inner cylindrical wall and the thin cylindrical shell, the chamber having a seal that prevents gas from the spiral passages from flowing into the annular chamber.