14641948 - (D) (P.T.A.B. Nov. 9, 2020)

Zhiyue Xu et al.

Patent Trials and Appeals BoardNov 9, 2020

14641948 - (D) (P.T.A.B. Nov. 9, 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. 14/641,948 03/09/2015 Zhiyue Xu TYI458294USNP (BAO1307US) 1752 44639 7590 11/09/2020 CANTOR COLBURN LLP-BAKER HUGHES, A GE COMPANY, LLC 20 Church Street 22nd Floor Hartford, CT 06103 EXAMINER WANG, NICHOLAS A ART UNIT PAPER NUMBER 1734 NOTIFICATION DATE DELIVERY MODE 11/09/2020 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): usptopatentmail@cantorcolburn.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE ____________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ____________ Ex parte ZHIYUE XU, BOBBY J. SALINAS, and ZHIHUI ZHANG ____________ Appeal 2020-000783 Application 14/641,948 Technology Center 1700 ____________ Before KAREN M. HASTINGS, MONTÉ T. SQUIRE, JANE E. INGLESE, Administrative Patent Judges. INGLESE, Administrative Patent Judge. DECISION ON APPEAL Appellant1 requests review under 35 U.S.C. § 134(a) of the Examiner’s final rejection of claims 1, 5–17, 22–25, and 27–31.2 We have jurisdiction under 35 U.S.C. § 6(b). We REVERSE. 1 We use the word “Appellant” to refer to the “applicant” as defined in 37 C.F.R. § 1.42. Appellant identifies Baker Hughes Incorporated as the real party in interest. Appeal Brief filed June 17, 2019 (“Appeal Br.”) at 2. 2 Final Office Action entered January 17, 2019 (“Final Act.”) at 1. Appeal 2020-000783 Application 14/641,948 2 CLAIMED SUBJECT MATTER Appellant claims a low density, selectively degradable composite material (independent claim 1) and a selectively degradable article comprising a low density, selectively degradable composite material (independent claim 27). Appeal Br. 2–3. Claim 1 illustrates the subject matter on appeal, and reads as follows: 1. A low density, selectively degradable composite material comprising a compacted powder mixture of a first powder, the first powder comprising first metal particles comprising Mg, Al, Mn, or Zn, or an alloy of any of the above, or a combination of any of the above, having a first particle oxidation potential, a second powder, the second powder comprising low- density, hollow or porous ceramic, cermet, intermetallic, metal, or polymer second particles, and a third metal powder, the third metal powder comprising third metal particles having an oxidation potential that is different than the first particle oxidation potential, the compacted powder mixture having a microstructure comprising: a matrix comprising the first metal particles; and the second particles and third particles dispersed within the matrix, the third particles comprising a network of third particles extending throughout the matrix, the low density, selectively degradable composite material having a density of about 3.5 g/cm3 or less; wherein the composite material comprises about 15 wt.% to about 50 wt.% of the first metal particles, about 50 wt.% to 85 wt.% of the second particles, and about 0.5 wt.% to about 10 wt.% of the third metal particles, each based on a weight of the composite material. Appeal Br. 14 (Claims Appendix) (emphasis and spacing added). Appeal 2020-000783 Application 14/641,948 3 REJECTIONS The Examiner maintains the following rejections in the Examiner’s Answer entered September 6, 2019 (“Ans.”): I. Claims 1, 9–11, 14–16, and 27–31 under 35 U.S.C. § 103 as unpatentable over O’Malley3 in view of Yih4 and Cochran,5 as evidenced by Scientificpolymer;6 II. Claims 5 and 6 under 35 U.S.C. § 103 as unpatentable over O’Malley in view of Yih, Cochran, and Jamison,7 as evidenced by Scientificpolymer; III. Claims 5, 6, 10, and 11 under 35 U.S.C. § 103 as unpatentable over O’Malley in view of Yih, Cochran, and Agrawal,8 as evidenced by Scientificpolymer; IV. Claims 7 and 8 under 35 U.S.C. § 103 as unpatentable over O’Malley in view of Yih and Cochran, as evidenced by Scientificpolymer and Venysek;9 V. Claims 12 and 13 under 35 U.S.C. § 103 as unpatentable over O’Malley in view of Yih, Cochran, and Slipenyuk,10 as evidenced by 3 US 2014/0014339 A1, published January 16, 2014. 4 Yih, et al., A Comparative Study of the Coated filler method and the Admixture Method of Powder Metallurgy for Making Metal-Matrix Composite, 32 Journal of Materials Science, 2873–2882 (1997). 5 Cochran, Ceramic Hollow Spheres and Their Applications (1998). 6 Scientificpolymer (2014). 7 US 2014/0231082 A1, published August 21, 2014. 8 US 2013/0000985 A1, published January 3, 2013. 9 Vanysek, CRC Handbook, Electrochemichal Series. 10 Slipenyuk, et al., Properties of P/M Processed Particle Reinforced Metal Matric Composites Specified by Reinforcement Concentration and Matrix- to-Reinforcement Particle Size Ratio, 54 Acta Materialia, 157–166 (2006). Appeal 2020-000783 Application 14/641,948 4 Scientificpolymer; and VI. Claims 17 and 22–25 under 35 U.S.C. § 103 as unpatentable over O’Malley in view of Yih, Cochran, and Borisov,11 as evidenced by Scientificpolymer. FACTUAL FINDINGS AND ANALYSIS Upon consideration of the evidence relied upon in this appeal and each of Appellant’s contentions, we reverse the Examiner’s rejections of claims 1, 5–17, 22–25, and 27–31 under 35 U.S.C. § 103 for the reasons set forth in the Appeal and Reply Briefs, and below. Claim 1 recites, in part, a composite material comprising a compacted powder mixture of a first powder comprising first metal particles, a second powder, and a third metal powder. Independent claim 27 recites a selectively degradable article comprising a composite material as recited in claim 1. O’Malley discloses metal composite 200 that is designed to be disintegrable and is formed from compaction and sintering of powder particles 12 having particle cores 14 of core material 18 coated with metallic coating layers 16. O’Malley ¶¶ 21, 32, 33, 42, 44; Fig. 8. O’Malley discloses that during the compaction and sintering process, metallic coating layers 16 sinter together to form cellular nanomatrix 216, and particle cores 14 of core material 18 form metal matrix 214 comprising particle core material 218 dispersed in cellular nanomatrix 216. O’Malley ¶¶ 32, 33, 41, 42, 44; Figs. 6, 7, and 8. O’Malley discloses that “metal matrix 214 and particle core material 218 also can include an additive particle 222,” which 11 US 5,305,817, issued April 26, 1994. Appeal 2020-000783 Application 14/641,948 5 “provides a dispersion strengthening mechanism to the metal matrix 214 and provides an obstacle to, or serves to restrict, the movement of dislocations within individual particles of the metal matrix 214.” O’Malley ¶ 39. O’Malley discloses that “[a]dditionally, the additive particle 222 can be disposed in the cellular nanomatrix 216 to strengthen the metal composite 200.” O’Malley ¶ 39. The Examiner finds that O’Malley’s particle core material 218 corresponds to the second powder recited in claim 1, and O’Malley’s additive particle 22212 corresponds to the third metal powder recited in claim 1. The Examiner finds that O’Malley discloses that cellular nanomatrix 216 is initially in the form of a coating on particle core material 218. Final Act. 4. The Examiner finds that O’Malley does “not expressly teach that the material is in the form of an admixed powder” such that cellular nanomatrix 216 “is in the form of [first] particles as instantly claimed,” and the Examiner relies on Yih to address this feature missing from O’Malley’s disclosures. Final Act. 4. Yih discloses that “[p]owder metallurgical fabrication of a metal- matrix composite conventionally involves mixing the discontinuous 12 The Examiner refers to additive particles 222 as “disintegration agents (222)” in the Final Action. Final Act. 4. We find no disclosure in O’Malley, however, indicating that additive particles 222 and the disintegration agent described in O’Malley are one and the same. Rather, O’Malley describes additive particles 222 and the disintegration agent as two distinct components that can be included in metal composite 200. Compare O’Malley ¶¶ 31, 36, with O’Malley ¶ 39. Appellant argues that “O’Malley does not disclose that particles 222 are disintegration agents” as the Examiner asserts. Appeal Br. 5. We need not determine whether Appellant’s argument identifies reversible error in the Examiner’s assertions, however, for disposition of this appeal. Appeal 2020-000783 Application 14/641,948 6 reinforcement and matrix metal powder and subsequent sintering, which “is called the admixture method”. Yih p. 2873. Yih discloses that a “less conventional method of powder metallurgy is the coated filler method, which involves coating the discontinuous reinforcement with the matrix metal and subsequent sintering.” Id. Yih describes experiments conducted to compare the properties of copper-matrix composites containing molybdenum (Mo) reinforcement (filler) particles formed using the admixture method to properties of such composites formed using the coated filler method. Yih p. 2874. The Examiner finds that Yih discloses that “the admixture method is favorable for obtaining high porosity, while the filler-coated method achieves lower porosity.” Final Act. 4–5 (citing Yih p. 2875). In view of this disclosure in Yih, the Examiner concludes that it would have been obvious to modify O’Malley’s “material . . . by utilizing the admixture composition of Yih et al. in order to achieve higher porosity, and lower density accordingly, as taught by Yih.” Final Act. 5. Appellant argues that when considered as a whole, the disclosures of O’Malley and Yih would not have led one of ordinary skill in the art to replace O’Malley’s metallic coating layers 16 with metallic particles, in order to form O’Malley’s metal composite 200 using an admixture method as disclosed in Yih, rather than forming metal composite 200 using the coated filler method as taught in O’Malley. Appeal Br. 6–8. The Examiner responds to Appellant’s arguments by asserting in the Answer that Yih “discloses the powder admixture method and coated powder method to both be useful method[s] in forming metal matrix composites,” and, therefore, “one of ordinary skill in the art would have Appeal 2020-000783 Application 14/641,948 7 reasonably recognized that both of the aforementioned methods can achieve the metal matrix composite structure of O’Malley et al. absent persuasive evidence to the contrary.” Ans. 16. As Appellant points out (Appeal Br. 7), however, O’Malley discloses that the advantageous and “unexpectedly high disintegration rate of the metal composite [disclosed] herein is due to the microstructure provided by the metal matrix and cellular nanomatrix.” O’Malley ¶¶ 21, 56. O’Malley explains that “such microstructure is provided by using powder metallurgical processing (e.g., compaction and sintering) of coated powders, wherein the coating produces the nanocellular matrix and the powder particles produce the particle core material of the metal matrix.” O’Malley ¶ 56. O’Malley further explains that “[i]t is believed that the intimate proximity of the cellular nanomatrix to the particle core material of the metal matrix in the metal composite produces galvanic sites for rapid and tailorable disintegration of the metal matrix.” Id. O’Malley, therefore, indicates that the microstructure of O’Malley’s metal composite causes its desired high disintegration rate, and indicates that the microstructure results from forming the composite by compaction and sintering of coated powders—referred to as the “coated filler” method in Yih. As discussed above, Yih compares properties—including the microstructure—of copper-matrix composites containing molybdenum (Mo) reinforcement (filler) particles formed using the admixture method to properties of such composites formed using the coated filler method. Yih p. 2874. Yih discloses that when the Mo particle (filler) content was 70 vol %, “the composites made by the two methods are different in microstructure.” Yih p. 2874 (emphasis added). Appeal 2020-000783 Application 14/641,948 8 O’Malley discloses that including metal matrix 214 in an amount similar to the 70 vol % Mo particle (filler) content Yih discloses results in a different microstructure when forming a metal composite using the admixture and coated filler methods. O’Malley ¶ 37. One of ordinary skill in the art, therefore, reasonably would have understood from Yih’s disclosures that replacing O’Malley’s metallic coating layers 16 with metallic particles, and forming O’Malley’s metal composite 200 using the admixture method as proposed by the Examiner, would change the microstructure of the resulting composite, and could possibly produce a microstructure that differs from the microstructure desired by O’Malley that yields a highly disintegrable metal composite. KSR Int’l Co. v. Teleflex Inc., 550 U.S. 398, 418 (2007) ([A]n obviousness analysis “need not seek out precise teachings directed to the specific subject matter of the challenged claim, for [an examiner] can take account of the inferences and creative steps that a person of ordinary skill in the art would employ.”); see also In re Preda, 401 F. 2d 825, 826 (CCPA 1968) (“[I]t is proper to take into account not only specific teachings of the reference but also the inferences which one skilled in the art would reasonably be expected to draw therefrom.”). Consequently, on the record before us, the Examiner does not articulate reasoning having rational underpinning sufficient to explain why one of ordinary skill in the art would have replaced O’Malley’s metallic coating layers 16 with metallic particles, and formed O’Malley’s metal composite 200 using an admixture method as disclosed in Yih, rather than forming metal composite 200 from core material 18 coated with metallic coating layers 16 as taught in O’Malley. The Examiner, therefore, does not establish that the combined disclosures of O’Malley and Yih would have Appeal 2020-000783 Application 14/641,948 9 suggested a composite material comprising a compacted powder mixture of a first powder comprising first metal particles, a second powder, and a third metal powder, as required by claims 1 and 27. We, accordingly, do not sustain the Examiner’s rejection of claims 1 and 27, and rejections of claims 5–17, 22–25, and 28–31, which each depend from either claim 1 or claim 27, under 35 U.S.C. § 103. CONCLUSION Claims 35 U.S.C. § Reference(s)/ Basis Affirmed Reversed 1, 9–11, 14–16, 27– 31 103 O’Malley, Yih, Cochran, Scientificpolymer 1, 9–11, 14– 16, 27–31 5, 6 103 O’Malley, Yih, Cochran, Jamison, Scientificpolymer 5, 6 5, 6, 10, 11 103 O’Malley, Yih, Cochran, Agrawal, Scientificpolymer 5, 6, 10, 11 7, 8 103 O’Malley, Yih, Cochran, Scientificpolymer , Venysek 7, 8 12, 13 103 O’Malley, Yih, Cochran, Slipenyuk, Scientificpolymer 12, 13 17, 22–25 103 O’Malley, Yih, Cochran, Borisov, Scientificpolymer 17, 22–25 Overall Outcome 1, 5–17, 22– 25, 27–31 Appeal 2020-000783 Application 14/641,948 10 REVERSED