Abstract:
A moisture separator reheater (10) tube support where the tubes are resiliently supported on curve-shaped metal spring members (46 or 58-64) in a manner permitting differential thermal radial and axial growth between the tube runs (26) and the support and spacer plate (30). The moisture separator reheater (10) units are used in nuclear pressurized water reactor systems.

Description:
BACKGROUND OF THE INVENTION 
     Moisture Separator-Reheater (MSR) units are used in nuclear pressurized water reactor systems to reheat the steam after it has passed through the high pressure turbine. MSR&#39;s have been plagued by warped tube bundles and support plates due mainly to thermal growth of the tube bundle and its interaction with the tube support plates. These problems have resulted in replacement of the tube bundle, repair of the tube supports, or even the complete replacement of the MSR unit, resulting in lost operating time and great expense. 
     SUMMARY OF THE INVENTION 
     In accordance with the invention, the tubes in the tube bundle of an MSR are supported in a support plate by resilient means which permit the tubes to grow axially, and the support plates to grow radially, due to thermal expansion. The resilient means is a curve-shaped metal member and can be either an O-ring or C-ring contained within a retainer member secured to the support plate; or it may be in the form of a curve-shaped edge portion of a metal sleeve welded to each tube. The sleeve has rolled sections attached thereto which act as a spring to absorb thermal growth. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     FIG. 1 is a sectional side view of a moisture-separator reheater (MSR) incorporating the invention; 
     FIG. 2 is an enlarged sectional side view of one of the tubes of the tube bundle contained in the MSR; 
     FIG. 3 is an end view of the restraining ring of FIG. 2; 
     FIG. 4 is an elevational view of an alternative support arrangement of the invention; and 
     FIG. 5 is a view taken on line 5--5 of FIG. 4. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Looking now to FIG. 1, there is shown a moisture separator-reheater (MSR) vessel 10, where moisture is removed from the cycle steam which exits from a high pressure turbine (not shown) of a nuclear power plant, and also where the steam is reheated before it is admitted to a low pressure turbine (not shown). The steam enters the unit through inlet 12, flowing upwardly through a wire mesh moisture separator 14. Separated moisture is discharged from the unit through lower outlet 16. The dried steam exiting the separator 14 flows through a heat exchanger or reheater 18, where it is heated to a higher temperature before exiting through outlets 20 to a low pressure turbine (not shown). Heating steam is supplied to the tubes of the tube bundle through inlet manifold 22, and after the steam has given up heat to the low pressure steam traversing the reheater outside of the tubes, it exits via outlet manifold 24. 
     The reheater 18 comprises a plurality of U-shaped tubes 26 which extend across the entire length of the MSR, with both ends being secured to the tube sheet 28. In order to properly space and support the tubes 26 along their entire length, a plurality of support plates 30 are spacedly provided. These plates are supported along their outer edges, and each plate has a plurality of holes or openings therein, with a tube leg or run extending through each. These support plates 30, although performing the needed task of spacing and supporting the tube legs, have been the source of problems in the past. The tubes and plates grow at different thermal expansion rates, and also the two legs of a single tube can grow at different rates. Thus, if adequate precautions are not taken, some of the tubes can become locked into one or more of the plates. This can cause bowing or warpage of the plates, and eventually lead to tube leaks or breaks. 
     Looking now to FIGS. 2 and 3, the manner in which the tubes is supported in the support plate are shown in more detail. Each tube leg 26 has a restraining ring 32 surrounding it at the location of each support plate 30. As can be seen in FIG. 3, the restraining rings have a plurality of equadistantly spaced enlarged portions 34 which are in close proximity or contact with the tube. In between, the ring has areas 36 which are somewhat spaced from the tube wall. Thus, the tube is adequately supported, while still not presenting so much frictional resistance to prevent the tubes from thermally expanding and moving axially relative to the restraining ring 32. Looking again to FIG. 2, an angled annular retainer ring 40 is welded at 42 to one end face 44 of the plate 30. Trapped or supported within the retainer ring is a metal annular C-ring 46. This C-ring acts as a spring to absorb radial growth, and also permits the tube 26 to grow axially without it becoming frozen or locked in the plate 30, while still adequately supporting and spacing this and the other tubes 26. The C-ring will spring back to its original shape when relaxation occurs during cool-down of the unit. Although a C-ring is shown, a flexible metal O-ring would work equally as well. 
     Looking now to FIGS. 4 and 5, an alternative tube support arrangement is shown which will allow relative axial and radial growth between the tube and its support. As can be seen, a sleeve 50 is attached to the tube 26(a) by silver solder 52 at its ends. The sleeve has a pair of openings 54, 56, cut therein in such a manner that sections 58, 60, and 62, 64 can be rolled back to form the openings. These rolled sections resiliently contact the support plate 30(a), and act as springs to permit the relative axial and radial growth between the tube legs and the support plate, and between the two legs of each U-tube.