Ex Parte Taras et alDownload PDFPatent Trial and Appeal BoardJul 9, 201813988568 (P.T.A.B. Jul. 9, 2018) Copy Citation UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE FIRST NAMED INVENTOR 13/988,568 05/21/2013 Michael F. Taras 87059 7590 07/11/2018 Cantor Colburn LLP - Carrier 20 Church Street, 22nd Floor Hartford, CT 06103 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 ATTORNEY DOCKET NO. CONFIRMATION NO. 56344US02 (U350260US2) 1886 EXAMINER JONES, GORDON A ART UNIT PAPER NUMBER 3744 NOTIFICATION DATE DELIVERY MODE 07/11/2018 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 Exparte MICHAEL F. TARAS, ARINDOM JOARDAR, JACK L. ESFORMES, and KEVIN B. DUNSHEE Appeal2017-008931 Application 13/988,568 Technology Center 3700 Before: CHARLES N. GREENHUT, JEFFREY A. STEPHENS, and BRENT M. DOUGAL, Administrative Patent Judges. GREENHUT, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE Appellants appeal under 35 U.S.C. § 134 from a rejection of claims 19 and 33. We have jurisdiction under 35 U.S.C. § 6 (b). We affirm. Appeal2017-008931 Application 13/988,568 CLAIMED SUBJECT MATTER The claims are directed to a multiple tube bank flattened tube finned heat exchanger. Claim 19, reproduced below, with emphasis added, is illustrative of the claimed subject matter: 19. A heat exchanger comprising: a first tube bank including at least a first and a second flattened tube segments extending longitudinally in spaced parallel relationship; a second tube bank including at least a first and a second flattened tube segments extending longitudinally in spaced parallel relationship, said second tube bank disposed downstream with respect to airflow over said first tube bank with a leading edge of the second tube bank spaced from a trailing edge of the first tube bank; and a continuous folded plate fin extending between the first and second flattened tube segments of both of said first tube bank and said second tube bank; wherein the air flow passes first transversely across the flattened tube segments of said first tube bank and then passes transversely across the flattened tube segments of said second tube bank, and the refrigerant flows first through a first pass of the first tube bank, then through a first pass of the second tube bank, then through a second pass of the second tube bank, and then through a second pass of the first tube bank; wherein the first plurality of heat exchange tube segments of the first pass of the first tube bank collectively define a first refrigerant flow area, the first plurality of heat exchange tube segments of the first pass of the second tube bank collectively define a second refrigerant flow area; the second plurality of heat exchange tube segments of the second pass of the second tube bank collectively define a third refrigerant flow area, and the second plurality of heat exchange tube segments of the second pass of the first tube bank collectively define a fourth refrigerant flow area, the respective refrigerant flow areas becoming progressively larger from the first refrigerant flow area to the second refrigerant flow area to the third refrigerant flow area to the fourth refrigerant flow area. 2 Appeal2017-008931 Application 13/988,568 REJECTION Claims 19 and 33 are rejected under 35 U.S.C. § I03(a) as being unpatentable over Shinmura (U.S. 5,086,835), Lee (U.S. Pub. 2003/0066633) and Berthome 1 (FR 2914407 Al). OPINION The Examiner relies on Shinmura as disclosing the basic structure claimed, but without the refrigerant flow sequence described in the first limitation emphasized above, or the progressive area increase described in the second limitation emphasized above. Final Act. 2--4. The Examiner relies on Lee and Berthome to cure those deficiencies, respectively. Id. at 4--7. Appellants first argue that Berthome discloses a different refrigerant flow sequence. App. Br. 4 (reproducing Berthome Figs. 4, 5). Appellants correctly anticipate the Examiner's response to this argument: that Lee, not Berthome was cited for this particular teaching. Id. at 4--5; Ans. 2. However, the only further arguments on this point appear to be premised on Appellants proposing to incorporate the teachings of Berthome into Shinmura and Lee in a manner that conflicts with the express teachings of Berthome: It is important to note th[ at] Berthome provides the larger refrigerant flow area by increasing the width of a tube bank in the air flow directions. Figure 4 of Berthome shows one tube bank having a width Rl less than the width of the other tube bank, R2. [Lee2 Fig. 3 omitted] 1 References herein are to the machine translation of record. 2 Appellants incorrectly label figure 3 of Lee as a figure of Shinmura. 3 Appeal2017-008931 Application 13/988,568 If one of tube banks 51 and 52 [ of Lee] was made wider than the other, then the refrigerant would not travel through progressively larger refrigerant flow areas. App. Br. 5 ( emphasis added). The Examiner correctly responds to this issue by pointing out that it is not the "airflow direction" in which Berthome teaches it is important to progressively increase the flow area, but the "refrigerant flow direction". See Ans. 3 ( citing and quoting from Berthome 1: 16-39); see also Berthome 2:26-36. It is undisputed that incorporating Berthome's teaching of increasing volume in the "refrigerant flow direction" depicted in the Figure 3A embodiment of Lee, would yield the claimed subject matter. Thus, we agree with the Examiner that combining Shinmura, Lee, and Berthome according to their express teachings would yield the subject matter of claim 19. 3 Appellants' next argument mischaracterizes Berthome' s technique as teaching "expanding the width" in order to conclude that Berthome' s 3 Additionally, we note, albeit without placing significant reliance on these facts, that, although an imperfect English translation, Berthome appears to contemplate a modification whereby area varies among rows, as opposed to banks, as illustrated in Figure 4. See Berthome 3 :20-21. This, of course, would make Berthome' s technique even further lend itself to incorporation into Shinmura and the Figure 3A embodiment of Lee, for example, by modifying the flow areas of adjacent rows forming the flow paths (Lee 5 la and 54a; Lee 52a and 53a). We also note, again without significant reliance, that the tube-group division provided by baffles 16, 26 in the Figure 3A embodiment of Lee appears, at least from the figure, to depict a progressively increasing flow area by increasing the number of tubes in paths 53a and 54a as compared to paths 51a and 52a. Although not expressly discussed in connection with the Figure 3A embodiment, such an arrangement, similar in many respects to what the Examiner cited Berthome for, and Appellants' own preferred embodiment (Fig. 13; Spec para. 45), would be consistent with Lee's discussion of the progressive decrease in refrigerant volume, and therefore required flow pipe volume, during cooling. See, e.g., Lee paras. 107-116; Figs. 16-18A. 4 Appeal2017-008931 Application 13/988,568 technique is inconsistent with vehicular heat exchangers of Shinnmra because they must operate in limited space. App. Br. 6. However, Berthome teaches it is the relative width, or more precisely, flow volume, that is important. Berthome 2:26-27. This does not require increasing the tube size as Appellants suggest but can also be achieved by reducing the size of tubes as well, which would make the overall design more compact. See e.g., Lee Fig. 16; paras. 109-112 (discussing how an embodiment using tube width variation allows for more compactness, not less). We note that Berthome recognizes that this could alternatively be achieved by altering the number of tubes in a pass. See, e.g., Berthome 3 :23-24. Regardless, Berthome clearly contemplates vehicular usage (Berthome 1 :3) so there appears to be no factual basis for concluding that Berthome' s teachings would be inapplicable to vehicular heat exchangers. Appellants' arguments concerning the rejection of claim 33 demonstrate that Appellants fail to appreciate that the Examiner's rejection is predicated on combining the teachings of both the embodiments depicted in respective Figures 2 and 3A of Lee in order to arrive at the claimed subject matter. App. Br. 7 ("The flow of refrigerant in Figure 2 of Lee is not equivalent to that recited in claim 33."); see Final Act. 7-12. As the Examiner correctly points out, Lee expressly suggests such combination. Ans. 4--8 ( citing Lee para. 79 ("The preferred embodiments of the present invention as shown in FIGS. 3A and 3B ... can be adopted in the preferred embodiment of FIG. 2.")). As Appellants' remarks do not address the Examiner's position, the ground of rejection for claim 33 stands essentially uncontroverted. See 37 C.F.R. § 41.37 ("The arguments shall explain why the examiner erred as to each ground of rejection contested by appellant. .. 5 Appeal2017-008931 Application 13/988,568 any arguments or authorities not included in the appeal brief will be refused consideration by the Board for purposes of the present appeal."). DECISION The Examiner's rejection is affirmed. 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)(l )(iv). AFFIRMED 6 Copy with citationCopy as parenthetical citation
