Heat exchanger closure assemblies and methods of using and installing the same

What is claimed is: 1. A process for assembling a tube heat exchanger assembly comprising: providing an elongated heat exchanger enclosure having an interior chamber and an open cylindrical end, including the heat exchanger enclosure defining a longitudinal axis; providing a closure assembly having a locking assembly configured to secure to the open cylindrical channel end of the elongated heat exchanger enclosure, the locking assembly including: a cylindrical shaped lock ring member defining a cylindrical outer surface portion and a cylindrical shaped interior portion wherein the cylindrical outer surface portion is provided with a plurality of spaced-apart lock ring hub sections separated in a circumferential direction around the cylindrical shaped lock ring member by non-hub sections, the plurality of spaced-apart lock ring hub sections configured to interdigitate with corresponding channel hub sections formed on a cylindrical inner surface portion of the elongated heat exchanger enclosure; and a cylindrical shaped cover member secured concentric with the cylindrical shaped interior portion of the cylindrical shaped lock ring member; inserting the locking assembly of the closure assembly into the open cylindrical channel end axially along the longitudinal axis of the interior chamber of the heat exchanger such that the plurality of spaced-apart lock ring hub sections of the cylindrical shaped lock ring member and corresponding channel hub sections on the cylindrical inner surface portion of the elongated heat exchanger enclosure do not contact one another; and turning the locking assembly about the longitudinal axis of the elongated heat exchanger enclosure less than 360 degrees relative to the elongated heat exchanger enclosure to cause the locking assembly to removably secure to the elongated heat exchanger enclosure with the plurality of spaced-apart hub sections on the cylindrical shaped locking member interdigitating with the corresponding channel hub sections on the elongated heat exchanger enclosure such that a load is transferred between the closure assembly and the elongated heat exchanger enclosure. 2. The process for assembling a tube heat exchanger as recited in claim 1 , wherein the locking assembly of the closure assembly and the elongated heat exchanger enclosure cooperatively form a bayonet locking assembly. 3. The process for assembling a tube heat exchanger as recited in claim 2 , further including, and prior to inserting the locking assembly: inserting a tube sheet gasket into the open cylindrical channel end axially along the longitudinal axis of the elongated heat exchanger enclosure to be positioned adjacent a channel shoulder configuration formed in the elongated heat exchanger enclosure; inserting a tube sheet into the open cylindrical channel end axially along the longitudinal axis of the elongated heat exchanger enclosure to be positioned adjacent the tube sheet gasket so as to define a shell side and a channel side within the interior chamber of the elongated heat exchanger enclosure, wherein the interior chamber is configured to removably receive a tube bundle positioned within the shell side of the interior chamber; inserting an annular sleeve member into the open cylindrical channel end axially along the longitudinal axis of elongated heat exchanger enclosure to be positioned adjacent the tube sheet; inserting an elastic torsion member into the open cylindrical channel end along the longitudinal axis of the elongated heat exchanger enclosure so as to be positioned adjacent the sleeve member; inserting a bearing ring into the open end of the cylindrical channel along the longitudinal axis of the elongated heat exchanger enclosure so as to be positioned adjacent the elastic torsion member; and inserting a diaphragm into the open end of the cylindrical channel along the longitudinal axis of the elongated heat exchanger enclosure so as to be positioned adjacent the bearing ring. 4. The process for assembling a tube heat exchanger as recited in claim 3 , further including: adjusting a plurality of first outer elongate compression members provided along an outer radius portion of the closure assembly which extend in the closure assembly coaxially along the longitudinal axis of the closure assembly so as to transmit a first force to a first compression ring, which transmits the first force to a rim portion of the diaphragm and the diaphragm gasket so as to compress the diaphragm gasket against the diaphragm; and adjusting a plurality of second inner elongate compression members provided along an inner radius portion of the closure assembly which extend in the closure assembly coaxially along longitudinal axis of the closure assembly so as to transmit a second force to a second compression ring, which transmits the second force against a portion of the diaphragm causing a portion of the diaphragm to deflect distal from the closure assembly and towards the elastic torsion member of heat exchanger assembly when the closure assembly is secured to the elongated heat exchanger enclosure. 5. The process for assembling a tube heat exchanger as recited in claim 4 , wherein the tube sheet, sleeve member, first and second compression rings, closure assembly, the plurality of first outer elongate compression members, and the plurality of second inner elongate compression members are configured to remain elastic up to or above a total axial load from preload, thermal and pressure loads when the closure assembly is secured to the heat exchanger enclosure. 6. The process for assembling a tube heat exchanger as recited in claim 5 , wherein when the plurality of first outer elongate compression members and the plurality of second inner elongate compression members are preloaded, the plurality of first outer elongate compression members and the plurality of second inner elongate compression members impart the preload through a first axial load path to a first contact area of the elastic torsion member, which transmits the preload through a torsional load path through the elastic torsion member to a second contact area of the elastic torsion member, which transmits the preload through a second axial load path to a tube sheet gasket. 7. The process for assembling a tube heat exchanger as recited in claim 6 , wherein the torsional load is resisted by an increase in stress and a torsional rotation enabling the first contact area of the elastic torsion member to move towards the tube sheet. 8. A closure assembly configured to removably secure to an open channel end of an interior chamber of a heat exchanger assembly, comprising: a cylindrical shaped lock ring member defining a cylindrical outer surface portion and a cylindrical shaped interior portion wherein the cylindrical outer surface portion is provided with a plurality of spaced-apart lock ring hub sections separated in a circumferential direction around the cylindrical shaped lock ring member by non-hub sections, the plurality of spaced-apart lock ring hub sections configured to interdigitate with corresponding channel hub sections formed on a cylindrical inner surface portion of the heat exchanger assembly; and a cylindrical shaped cover member secured concentric with the cylindrical shaped interior portion of the cylindrical shaped lock ring member, wherein the plurality of spaced-apart lock ring hub sections are configured to interdigitate with the corresponding channel hub sections by rotating the cylindrical shaped lock ring member less than 360 degrees relative to the open channel end of the heat exchanger assembly to secure the cylindrical shaped lock ring member to the heat exchanger assembly. 9. The closure assembly as recited in claim 8 , wherein the cylindrical