2019002438 (P.T.A.B. Oct. 28, 2020)

John A. Blaisdell et al.

Patent Trials and Appeals BoardOct 28, 2020

2019002438 (P.T.A.B. Oct. 28, 2020)

UNITED STATES PATENT AND TRADEMARK OFFICE UNITED STATES DEPARTMENT OF COMMERCE United States Patent and Trademark Office Address: COMMISSIONER FOR PATENTS P.O. Box 1450 Alexandria, Virginia 22313-1450 www.uspto.gov APPLICATION NO. FILING DATE FIRST NAMED INVENTOR ATTORNEY DOCKET NO. CONFIRMATION NO. 13/798,418 03/13/2013 JOHN A. BLAISDELL NSD 2011-024 6434 26353 7590 10/28/2020 WESTINGHOUSE ELECTRIC COMPANY LLC K&L GATES LLP 210 SIXTH STREET K&L Gates Center PITTSBURGH, PA 15222-2613 EXAMINER GARNER, LILY CRABTREE ART UNIT PAPER NUMBER 3646 NOTIFICATION DATE DELIVERY MODE 10/28/2020 ELECTRONIC Please find below and/or attached an Office communication concerning this application or proceeding. The time period for reply, if any, is set in the attached communication. Notice of the Office communication was sent electronically on above-indicated "Notification Date" to the following e-mail address(es): uspatentmail@klgates.com uspatentmail@klgates.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte JOHN A. BLAISDELL, EDWARD M. CHU, CAMILLA S. ROTANDER, and GURIKAR V. KUMAR Appeal 2019-002438 Application 13/798,418 Technology Center 3600 Before STEFAN STAICOVICI, WILLIAM A. CAPP, and NATHAN A. ENGELS, Administrative Patent Judges. ENGELS, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE Pursuant to 35 U.S.C. § 134(a), Appellant1 appeals from the Examiner’s decision to reject claims 1–6. See Final Act. 1. We have jurisdiction under 35 U.S.C. § 6(b). We AFFIRM. 1 We use the word Appellant to refer to “applicant” as defined in 37 C.F.R. § 1.42. Appellant identifies the real party in interest as Westinghouse Electric Company LLC. Appeal Br. 2. Appeal 2019-002438 Application 13/798,418 2 CLAIMED SUBJECT MATTER Appellant’s Specification states that “[t]he invention provides methods for protecting against fuel damage and fuel cladding failures in boiling water reactor . . . cores due to anticipated coupled thermal hydraulic/neutronic core instability.” Spec. ¶ 25. The Specification states that boiling water reactors have a characteristic relation between core flow and power generation and that “[f]or a fixed amount of control rod withdrawal from the core, constant rod lines (also called flow control lines and load lines . . .) can be established.” Spec. ¶ 2. Core flow and power generation can be depicted on a power/flow operating map, such as those depicted in Appellant’s Figures 1 and 2, copied below. Spec. ¶ 3. Appeal 2019-002438 Application 13/798,418 3 Appellant’s Figure 1 is a power/flow map that depicts core thermal power plotted against core flow and a corresponding Average Power Range Monitor (“APRM”) flow-biased trip without set down, in accordance with the prior art. Spec. ¶ 22. Appellant’s Figure 2 is a power/flow map that depicts core thermal power plotted against core flow and a corresponding APRM flow-biased trip with set down in accordance with certain embodiments of Appellant’s invention. Spec. ¶ 23. Figures 1 and 2 generally show that “[i]ncreasing the core flow slowly will increase the power along [the] constant rod lines” and “[l]oad line limits are established to satisfy various safety limits including fuel thermal limits.” Spec. ¶ 2; see Spec. ¶¶ 22–24, Figs. 1–3. “As power uprates (e.g., up to 120% of the original licensed power) are implemented, load line limits are raised to realize increased power Appeal 2019-002438 Application 13/798,418 4 generation at a design (maximum) core flow limit.” Spec. ¶ 3. “However, core thermal hydraulic stability is aggravated by power uprates and changes the power/flow operating map in a direction that causes a propensity to encounter instability” in high power/low core flow conditions. Spec. ¶ 3. According to the Specification, there are known approaches for the detection and suppression of instabilities that are suitable for various reactor types and sizes, depending on the specific plant stability properties. Spec. ¶ 4. Known methods include Oscillation Power Range Monitor (“OPRM”) hardware and software systems that use oscillation detection algorithms. Spec. ¶ 4. The Specification states that in some known systems, “an OPRM system is ‘armed’ (trip-enabled)” such that “[i]f the set point of the OPRM system is exceeding, indicating the presence of unstable (growing) power oscillations, an automatic scram or selected rod insertion is initiated to suppress unstable operation before the oscillations have the potential to cause fuel damage.” Spec. ¶ 6. “It is an object of the invention to employ existing licensed stability methodologies in an [extended operating domain]” by “introducing a set down of the APRM flow-biased scram line below a certain (e.g., preselected or predetermined) core flow set point or level.” Spec. ¶ 27. Claim 1, reproduced below, is illustrative of the claimed subject matter: 1. A method of protecting a core in a nuclear reactor from fuel damage due to thermal hydraulic instability in an extended operating domain for an uprated power level, comprising: operating the nuclear reactor in a permissible operating domain that is above a first flow control line that corresponds to an existing power level and below a second flow control line that corresponds to the uprated power level; bounding a region of the operating domain with a stability limit line determined by an algorithm; Appeal 2019-002438 Application 13/798,418 5 employing OPRM instruments for detecting power oscillations and thermal hydraulic instability in a first region above the first flow control line and below the stability limit line; wherein, when an OPRM setpoint is exceeded, an action selected from an alarm and a scram signal is generated; identifying a second region above the stability limit line and below the second flow control line; identifying a predetermined core flow setpoint; and modifying an existing APRM flow-biased scram line when actual core flow decreases below the predetermined core flow setpoint, causing an action preventing operation in the second region, the action selected from the group consisting of an APRM scram and a selected rod insert. REFERENCES The prior art relied upon by the Examiner is: Name Reference Date Eckert US 5,528,639 June 18, 1996 Stirn US 5,141,710 Aug. 25, 1992 Casillas US 2004/0013220 A1 Jan. 22, 2004 REJECTIONS Claims 1, 5, and 6 stand rejected under 35 U.S.C. § 103(a) as being unpatentable in view of Eckert and Stirn. Claims 2–4 stand rejected under 35 U.S.C. § 103(a) as being unpatentable in view of Eckert, Stirn, and Casillas. OPINION Claim 1 The Examiner’s rejection of claim 1 includes a limitation-by- limitation comparison of claim 1 to Eckert, with additional citation to Stirn as evidence of known APRM and OPRM diagnostics. Final Act. 2–3; Appeal 2019-002438 Application 13/798,418 6 accord Ans. 5–6. Among other things, the Examiner states that Eckert teaches operating a nuclear reactor in a permissible operating domain depicted by the power/flow map of Eckert’s Figure 1. Final Act. 2–3; accord Ans. 6 (additionally citing Eckert’s claim 1). As cited by the Examiner, Eckert’s power/flow map depicts an operating domain that includes a region between 100% rated power and a “Maximum Normal Flow” limit representing uprated flow, with scram and alarm setpoints lines representing additional boundaries of the operating domain. Final Act. 3. The Examiner also cites Eckert’s disclosures of monitoring operations and adjusting setpoints during operation. Final Act. 3 (citing Eckert 3:24–35, 3:63–4:10, 5:24–50); Ans. 6. Appellant acknowledges that Eckert’s power/flow maps depict an operating domain and that Eckert teaches adjusting alarm and scram setpoints, but Appellant argues Eckert describes operating and adjusting setpoints at less than 100% power, below the maximum operating line. Appeal Br. 4–5. According to Appellant, Eckert’s Figures 2 and 3 show examples “wherein alarm and scram setpoints are adjusted, i.e., setdown, in relation to a corresponding set down in power from the maximum operating line to the partial power operating point 1.” Appeal Br. 5. Although Eckert does describe adjusting alarm and scram setpoints at partial power conditions below 100% rated power, we disagree with Appellant’s suggestion that such disclosures distinguish claim 1. Contrary to Appellant’s suggestion, nothing limits Eckert to partial power conditions, and Eckert is clear that its “operating point 1” and the setpoint adjustments described for operating point 1 are merely an example. Eckert 5:6–65. Eckert expressly states that the principles of its invention “can be applied as Appeal 2019-002438 Application 13/798,418 7 needed throughout the entire normal power/flow operating range” (Eckert 5:11–13). Further, as cited by the Examiner (Ans. 7 (citing Eckert 2:46–55, Fig. 1)), Eckert describes operating a reactor throughout the range of its operating domain, noting that the “maximum operating level is normally about 120% of rated power” (Eckert 2:54–55). Finally, to the extent that Appellant argues to distinguish Eckert on the basis of claim 1’s recitation of APRM-based trip system (see Appeal Br. 5–6), we find Appellant’s arguments unpersuasive. As noted by the Examiner (Ans. 8), in addition to Stirn’s disclosure of OPRM and APRM systems, Appellant’s Specification evidences that OPRM and APRM hardware and systems were well known in the prior art (Spec. 4 (describing OPRM hardware and software as part of a “widely available approach”), 11 (describing an APRM flow-biased trip as part of “[a]nother known stability solution”)). Eckert describes in general terms use of various known monitoring parameters to control the operation of a reactor, including monitoring neutron flux. E.g., Eckert 1:31–45, 1:62–63, 2:46–50 (stating that conventional power-related nuclear reactor protection systems use monitored nuclear flux to sense when an increase in power occurs), Fig. 1 (depicting a “Fixed High APRM Flux Scram” line). Among other things, the Examiner’s determination that Eckert’s teachings would have been compatible with known OPRM and APRM systems is consistent with the description of known APRM systems for monitoring neutron flux. See Spec. ¶ 29 (describing an “APRM neutron flux flow-biased scram”). Accordingly, we agree with the Examiner that a person of ordinary skill would have recognized OPRM and APRM-based systems as known options for implementing Eckert’s teachings. Appeal 2019-002438 Application 13/798,418 8 Having considered the Examiner’s rejection in view of Appellant’s arguments and the evidence of record, we sustain the Examiner’s rejection of claim 1 as being unpatentable in view of the combined teachings of Eckert and Stirn. Claims 2–6 For dependent claims 2–6, Appellant relies on the same arguments addressed above regarding claim 1. Appeal Br. 6–7. Having considered the Examiner’s rejections in view of Appellant’s arguments and the evidence of record, for the same reasons discussed supra, we sustain the Examiner’s rejections of claims 2 and 3 as being unpatentable in view of the combined teachings of Eckert, Stirn, and Casillas and of claims 4–6 as being unpatentable in view of the combined teachings of Eckert and Stirn. CONCLUSION The Examiner’s rejections are affirmed. More specifically, we affirm the Examiner’s rejections of claims 1 and 4–6 as being unpatentable in view of the combined teachings of Eckert and Stirn and claims 2 and 3 as being unpatentable in view of the combined teachings of Eckert, Stirn, and Casillas. Appeal 2019-002438 Application 13/798,418 9 DECISION SUMMARY Claims Rejected 35 U.S.C. § Reference(s)/Basis Affirmed Reversed 1, 4–6 103 Eckert, Stirn 1, 4–6 2, 3 103 Eckert, Stirn, Casillas 2, 3 TIME PERIOD FOR RESPONSE No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a). See 37 C.F.R. § 1.136(a)(1)(iv). AFFIRMED