Patent Number: 050358529
Section: claims

1. An elongated guide tube support pin for removably mounting a lower flange of a control rod guide tube to a core plate having a bore, wherein a variable shear load is applied to said guide tube relative to said core plate, comprising: a first pin portion mountable on the lower flange of the guide tube; and  a second pin portion receivable within the bore of the core plate and frictionally engageable therein, said second pin portion having a split leaf section including an upper portion and a lower portion whose outer diameter is substantially the same as the inner diameter of the bore, and a split intermediate section having a tapered outer diameter for causing stresses in said split leaf section to be substantially uniform wherever a shear load is applied to the support pin.  a first pin portion mountable on the guide tube lower flange; and  a second pin portion resiliently receivable within said upper core plate bore, said second pin portion including a solid body section adjacent said first pin portion and having an outer diameter which is accommodated by said bore by a close clearance fit, and a split leaf section including a split intermediate section extending from said solid body section and having an outer diameter less than the outer diameter of said solid body section and a split end section extending from said split intermediate section and having a portion that biasingly engages at least a portion of the wall of said bore, said split intermediate section being tapered from a maximum outer diameter adjacent said solid body section to a minimum outer diameter substantially adjacent said split end section such that said support pin is secured within said upper core plate by a fictional fit  wherein loads applied transversely to said longitudinal axis of said support pin are reacted to substantially in pure shear by said second pin portion substantially through said solid body section, and wherein the tapered varying outer diameter of said split intermediate section causes the stress through said split leaf section to be substantially constant.  at least one support pin comprising a first pin portion mountable on the first structural member, and a second pin portion receivable within the bore;  locking means mounted on said support pin for retaining the first structural member against the second structural member; and  stress reduction means including a washer disposed around said support pin between said locking means and the first structure member, wherein said washer and said locking means include mutually engaging, rounded surfaces for eliminating bending moments and stresses on said support pin during mounting of said locking means on said support pin.  a support pin having a longitudinal axis and comprising a first pin portion mountable on the guide tube lower flange, and a second pin portion receivable within said upper core plate bore, said second pin portion including a solid body section adjacent said first pin portion and having an outer diameter which is accommodated by said bore by a close clearance fit, and a split leaf section including a split intermediate section extending from said solid body section and having a tapered outer diameter less than the outer diameter of said solid body section for reducing stress in said split leaf section, and a split end section extending from said split intermediate section and biasingly engaging at least a portion of the wall of said bore;  locking means mounted on said first pin portion of said support pin for retaining the guide tube lower flange between said solid body section of said second pin portion and said locking means; and  a washer disposed around said first pin portion between said locking means and the control rod guide tube flange, said washer and said locking means including mutually engaging rounded surfaces for eliminating bending moments and stresses on said support pin during mounting of said locking means on said first pin portion of said support pin.  a first pin portion mountable on the first structural member; and  a second pin portion receivable within the bore and frictionally engageable therein, said second pin portion having a split leaf section inclining an upper portion and a lower portion whose outer diameter is substantially the same as the inner diameter of the bore, and a split intermediate section having a tapered outer diameter for causing stresses in said split leaf section to be substantially uniform wherever a shear load is applied to the support pin,  wherein said upper portion of said second pin portion includes a solid body section between said first pin portion and said split leaf section and having an outer diameter which is accommodated by the bore by a close clearance fit, said split intermediate section outer diameter is less than the outer diameter of said solid body section, and said lower portion of said split leaf section further includes a split end section extending from said split intermediate section and biasingly engaging at least a portion of the wall of the bore to secure said support pin therein by a frictional fit, and wherein shear loads applied transversely to said longitudinal axis of said support pin are secured to substantially in pure shear by said second pin portion substantially through said solid body section. 2. The support pin according to claim 1, wherein said split intermediate section has a maximum diameter at its end adjacent said upper portion and a minimum diameter at its opposite end adjacent to said lower portion. 3. The support pin according to claim 1, wherein said upper portion of said second pin portion includes a solid body section between said first pin portion and said split leaf section and having an outer diameter which is accommodated by the bore by a close clearance fit, said split intermediate section outer diameter is less than the outer diameter of said solid body section, and said lower portion of said split leaf section further includes a split end section extending from said split intermediate section and biasingly engaging at least a portion of the wall of the bore to secure said support pin therein by a frictional fit, and wherein shear loads applied transversely to said longitudinal axis of said support pin are reacted to substantially in pure shear by said second pin portion substantially through said solid body section. 4. A mounting system for removably mounting a lower flange of a control rod guide tube over an opening in an upper core plate of a nuclear reactor comprising at least one elongated support pin mountable on the guide tube lower flange and resiliently receivable in a bore formed in the upper core plate, wherein said support pin has a longitudinal axis and comprises: 5. The mounting system according to claim 4, wherein said mounting system further comprises a plurality of support pins for mounting the lower flange of a control rod guide tube over an opening in the upper core plate of a nuclear reactor. 6. The mounting system according to claim 4, wherein said lower flange of said control rod guide tube is formed with a through-bore and said first pin portion of said support pin is receivable within said through-bore. 7. The mounting system according to claim 4, further comprising locking means for retaining the guide tube lower flange between said solid body section of said second pin portion and said locking means. 8. The mounting system according to claim 7, wherein said first pin portion of said support pin includes and externally threaded section and wherein said locking means includes an internally threaded section which threadedly engages said externally threaded section of said first pin portion. 9. The mounting system according to claim 8, wherein said locking means further includes a locking nut having side walls and said locking nut comprises a crimpable cylindrical section integrally connected to said internally threaded section and extending from the outermost portion of said internally threaded portion. 10. The mounting system according to claim 9, wherein said first pin portion further includes an end section remotely positioned from said second pin portion adjacent said externally threaded section and having a plurality of recesses formed on the external surface, and wherein said crimpable cylindrical section of said locking nut is crimpingly engageable with at least one of said plurality of recesses of said support pin to prevent relative rotation between said locking nut and said support pin. 11. The mounting system according to claim 8, wherein said locking means includes a locking nut having side walls, said first pin portion further includes an end section remotely positioned from said second pin portion adjacent said externally threaded section and having a plurality of recesses formed on the external surface, and said mounting system further comprises crimping means for engaging at least one of said plurality of recesses of said support pin to prevent relative rotation between said locking nut and said support pin. 12. The mounting system according to claim 11, wherein said crimping means includes a crimp cap mounted on said end section of said support pin. 13. The mounting system according to claim 4, wherein said split intermediate section is uniformly tapered such that said split intermediate section is conical. 14. The mounting system according to claim 13, wherein said split intermediate section has a shape that maintains stresses in said support pin below the yield point of said support pin. 15. The mounting system according to claim 13, wherein said split intermediate section includes a plurality of leaves separated by a longitudinal gap, wherein said longitudinal gap extends into said solid body section to increase the flexibility of said support pin. 16. The mounting system according to claim 8, further comprising a washer disposed around said first pin portion between said locking means and the control rod guide tube flange. 17. The mounting system according to claim 16, wherein said washer includes stress reduction means for eliminating bending moments and stresses on said support pin during mounting of said locking means on said first pin portion of said support pin. 18. The mounting system according to claim 17, wherein said stress reduction means includes a concave spherical surface formed on the upper surface of said washer, said spherical surface being shiftable during mounting of said locking means to compensate for nonperpendicular alignment between said support pin and the control rod guide tube flange. 19. A support pin system for removably mounting a first structural member to a second structural member having a bore, said support pin system comprising: 20. The support pin system according to claim 19 wherein said support pin has a longitudinal axis and includes a first pin portion mounted to the first structural member and a second pin portion secured within the bore, said second pin portion having a solid body section adjacent said first pin portion and having an outer diameter which is accommodated by the bore by a close clearance fit and a split leaf section including a split intermediate section extending from said solid body section and having a tapered outer diameter less than the outer diameter of said solid body section and a split end section extending from said split intermediate section and biasingly engaging at least a portion of the wall of the bore, wherein said tapered shape of said split intermediate section lowers stresses in said split leaf section. 21. A mounting system for removably mounting the lower flange of a control rod guide tube over an opening in the upper core plate of a nuclear reactor comprising at least one elongated support pin mounted on the guide tube lower flange and resiliently receivable in a bore formed in the upper core plate, wherein said mounting system comprises: 22. An elongated support pin for removably mounting a first structural member to a second structural member having a bore, wherein a variable shear load is applied to said first structural member relative to said second structural member, comprising: