14575053 (P.T.A.B. Sep. 21, 2018)

Ex Parte MILLER

Patent Trial and Appeal BoardSep 21, 2018

14575053 (P.T.A.B. Sep. 21, 2018)

UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE 14/575,053 12/18/2014 28395 7590 09/25/2018 BROOKS KUSHMAN P.C./FG1L 1000 TOWN CENTER 22NDFLOOR SOUTHFIELD, MI 48075-1238 FIRST NAMED INVENTOR Kenneth James MILLER 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. 83484175 3386 EXAMINER MOTT, GENNA M ART UNIT PAPER NUMBER 3662 NOTIFICATION DATE DELIVERY MODE 09/25/2018 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): docketing@brookskushman.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte KENNETH JAMES MILLER 1 Appeal2018-000449 Application 14/575,053 Technology Center 3600 Before JENNIFER D. BAHR, STEVEN D.A. McCARTHY, and WILLIAM A. CAPP, Administrative Patent Judges. BAHR, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE Appellant appeals under 35 U.S.C. Â§ 134(a) from the Examiner's decision rejecting claims 1-17. We have jurisdiction under 35 U.S.C. Â§ 6(b ). We REVERSE. 1 Ford Global Technologies, LLC (Appellant) is the Applicant, as provided in 37 C.F.R. Â§ 1.46, and is identified as the real party in interest Appeal Br. 2. Appeal2018-000449 Application 14/575,053 THE CLAIMED SUBJECT MATTER Appellant's invention is directed to a system and method for controlling the switchover from motor propulsion of a hybrid vehicle to engine propulsion, upon a driver depressing an accelerator pedal, for example. See Spec. ,r,r 1, 2, 17. Claims 1, 7, and 12 are independent. Claims App. 1-3. Claim 1, reproduced below from page 1 of the Claims Appendix, is illustrative of the claimed subject matter. 1. A vehicle control method comprising: in response to an engine starting and achieving a target speed while an electric machine is generating torque to drive the vehicle, retarding engine spark to reduce engine torque; and in response to the engine torque falling below a threshold value, locking a clutch configured to mechanically couple the engine and the electric machine. REJECTIONS I. Claims 1, 2, 7, 12, and 13 stand rejected under 35 U.S.C. Â§ 103 as unpatentable over Shimabukuro et al. (US 2002/0170758 Al, pub. Nov. 21, 2002, hereinafter "Shimabukuro") and Genise et al. (US 6,042,507, iss. Mar. 28, 2000, hereinafter "Genise"). II. Claims 3-5, 8-10, and 14--16 stand rejected under 35 U.S.C. Â§ 103 as unpatentable over Shimabukuro, Genise, and Kato et al. (US 2013/0325238 Al, pub. Dec. 5, 2013, hereinafter "Kato"). III. Claims 6, 11, and 17 stand rejected under 35 U.S.C. Â§ 103 as unpatentable over Shimabukuro, Genise, and Matsuda (US 2012/0022751 Al, pub. Jan. 26, 2012). 2 Appeal2018-000449 Application 14/575,053 DISCUSSION Rejection I Each of Appellant's independent claims 1, 7, and 12 requires, in response to the engine starting and achieving a target speed while an electric machine ( e.g., a traction motor) generates torque to drive the vehicle, retarding engine spark to reduce engine torque and, in response to the engine torque falling below a threshold value, locking a clutch to couple the engine to the electric machine ( or traction motor). The Examiner finds that Shimabukuro discloses, in response to the engine starting and achieving a target speed while an electric machine is generating torque to drive the vehicle (Shimabukuro ,r,r 70, 103-104, Figs. 3 and 13, steps SlO and S300), retarding ignition timing to temporarily reduce engine torque (id., Fig. 13, step S302; ,r 104), and, after the torque falls (id., Fig. 6), locking a clutch by sharply increasing the hydraulic pressure applied thereto to mechanically couple the engine and motor/machine (id., Fig. 6; ,r 111 ). Final Act. 3--4. The Examiner finds that "Shimabukuro does not teach locking the clutch 'in response to' the engine torque falling 'below a threshold value."' Id. at 4 (boldface omitted). The Examiner finds that it was well known to wait until engine torque is sufficiently low to engage a clutch to improve the quality of the clutch engagement, as evidenced by Genise, which "teaches reducing engine torque to a desired dwell torque before fully engaging a lockup clutch." Id. ( emphasis omitted) ( citing Genise 1 :40--46; Figs. 3--4). The Examiner determines it would have been obvious "to modify the invention of Shimabukuro by waiting for the engine torque to fall below a threshold 3 Appeal2018-000449 Application 14/575,053 value before responding by fully engaging the clutch in order to achieve a relatively smooth, high quality lockup event." Final Act. 4. Appellant argues that the Examiner's rationale assumes that Shimabukuro does not achieve a smooth, high quality lockup event, but nothing in Shimabukuro suggests this is the case. Appeal Br. 3. In fact, Appellant submits that Shimabukuro explains that in response to the difference between engine and motor speeds becoming smaller than a threshold, increasing the pressure to the clutch to fully engage the clutch, and that this aspect of the process effectively reduces shock at clutch engagement during switchover. Id. According to Appellant, since Shimabukuro already achieves a smooth, high quality lockup event, "there is no motivation to replace Shimabukuro's speed-based clutch-lock initiation with Genise's purported torque-based clutch-lock initiation." Appeal Br. 3--4. In the Answer, the Examiner clarifies that the rejection does not propose to replace Shimabukuro's speed-based technique with a torque- based approach. Ans. 2. The Examiner emphasizes that Shimabukuro already teaches reducing engine torque by retarding ignition timing prior to clutch engagement in order to avoid abrupt changes in engine output during the engagement. Id. at 2-3 (citing Shimabukuro ,r 104). The Examiner finds Shimabukuro deficient only "in that it does not evaluate engine torque with respect to a threshold to determine how much it is reduced." Id. at 3. Thus, the clutch locking is not in response to the torque falling below the threshold. Id. The Examiner explains that the rejection merely proposes "a threshold to evaluate whether the engine torque has been sufficiently lowered, as a torque criterion subsequent to the speed criteria taught by 4 Appeal2018-000449 Application 14/575,053 Shimabukuro, before engaging the clutch." Id. According to the Examiner, "[ s ]uch a modification would ensure the intended effect of Shimabukuro - that of avoiding abrupt changes in engine output during the engagement thereby providing a smooth and high quality lock-up event-which is a motivation also supported by Genise." Id. In the Answer, the Examiner also sets forth an alternative rationale for the combination. Id. In particular, the Examiner reasons that it would have been obvious to use "the added torque-based criterion ... as an alternative to the speed-based criterion," such that the clutch is "engaged when either the torque-based criterion or the speed-based criterion is met." Id. According to the Examiner, "[t]his would provide a more robust system capable of the same function and effect even if one parameter became unavailable ( e.g. a faulted sensor)." Id. In reply, Appellant essentially repeats the aforementioned arguments set forth in the Appeal Brief, and adds that the new alternative rationale set forth in the Answer "is problematic" because such a modification "would prompt an attempt to fully engage the clutch responsive to the torque-based criterion being met even if there are significant speed differences between the engine and motor," which, according to Appellant, "would ... not result in a smooth and high quality lock-up event." Reply Br. 2. Shimabukuro discloses simultaneous motor control, engine control, and clutch pressure control during the switchover from electric motor- powered driving to internal combustion engine-powered driving. See Shimabukuro, Fig. 3. All of these controls are based on the speed difference ( dN) between the engine and the motor. See id., Figs. 11-13. 5 Appeal2018-000449 Application 14/575,053 Shimabukuro' s Figure 11 is a flowchart showing the motor control. Id., Fig. 11; ,r,r 77-86. The controller checks to see if the speed difference ( dN) is less than a first threshold ( dN2), and increases motor torque command until the speed difference is less than the first threshold; then, the controller checks to see if the speed difference is less than a second threshold ( dN5), and further increases motor torque command until the speed difference is less than the second threshold. Id., Fig. 11 (steps S102- S106); ,r,r 79-82. Next, Shimabukuro's controller checks to see whether the motor torque command (MTO) exceeds a third threshold and decreases the motor torque command sharply until it no longer exceeds the third threshold. Id., Fig. 11 (steps Sl 10-Sl 12); ,r 83-84. Finally, the controller decreases the motor torque command down to zero. Id., Fig. 11 (steps Sl 14--Sl 16); i185. Figure 13 is a flowchart showing the engine control. Id. ,r 101. As soon as the speed difference is less than a sixth threshold ( dN3), Shimabukuro begins retarding ignition timing by a small amount ( dQ); then, when the speed difference is less than a fifth threshold (dN4) ignition timing is retarded by a large amount (QTRTD). Id., Fig. 13 (steps S300-S308); ,r,r 103-105. Next, the controller waits for a timer to exceed a predetermined time value (trtd), during which engine output torque is decreased markedly. Id., Fig. 13 (step S310); ,r,r 105-106. Notably, Shimabukuro does not disclose measuring or determining engine output torque during this time delay. After passage of the predetermined time (trtd), the ignition timing is increased, or advanced, by an amount equal to the large retard amount (QTRTD), and then by the small retard amount (dQ), back to the original ignition timing. Id., Fig. 13 (steps S312-S314); ,r 107. 6 Appeal2018-000449 Application 14/575,053 Meanwhile, the clutch pressure is controlled as shown in Figure 12. Id. ,r,r 87-88. The clutch pressure command is increased by an addition term (CLCUl) until the speed difference ( dN) is less than a fourth threshold (dNl). Id., Fig. 12 (steps S202-S204); ,r 93. Then, once the speed difference ( dN) is less than the fourth threshold ( dNl ), the control loops around until the speed difference (dN) is less than a fifth threshold (dN4). Id., Fig. 13 (step S206); ,r 94. Once the speed difference (dN) is less than the fifth threshold, the clutch pressure command is increased to cause a rapid increase in the pressure supplied to the clutch, until it reaches the line pressure equivalent value shown in Figure 6. Id., Fig. 13 (steps S208- S21 O); ,r,r 94--96. Genise does not specifically mention hybrid vehicles, but, rather, deals broadly with engagement of an engine and a mechanical transmission with a torque converter lockup assembly. Genise 1 :5--40. In particular, Genise teaches ramping engine torque "smoothly down to a relatively low 'dwell torque' ... while the torque converter is locked up and [then ramping engine torque] smoothly back to the driver-demanded torque." Id. 1:43--47. According to Genise, [ s ]moothly ramping engine torque down to a predetermined dwell torque value and arriving at or dwelling at that value until the lockup clutch engagement is expected to be engaged, and thereafter smoothly ramping fuel back to operator's demand, has been shown to provide a smooth and high quality torque converter lockup event. Id. 4:44--49. Genise discloses using speed sensors "to provide input signals ... indicative of engine speed, transmission input shaft speed, ... transmission output shaft speed," and the operator setting of the throttle pedal to the controller to generate command output signals. Id. 2:32--42. 7 Appeal2018-000449 Application 14/575,053 Genise also discloses that "the function of the control [is] to monitor the torque level and determine how to best achieve the torque converter lockup event at the desired torque level for overall best driver impression (i.e., for best torque converter lockup event quality)," but does not elaborate on how torque level is determined from the sensors. Id. 3: 54--5 8. Shimabukuro discusses a prior art control technique in which motor output torque is detected while the motor is absorbing the output torque of the engine, engine output torque is estimated, and the desired torque of the motor is adjusted based on the difference between the detected torque and the estimated torque. Shimabukuro ,r 7. However, Shimabukuro considers this prior art technique to be unsatisfactory because engine output torque is difficult to estimate accurately. Id. ,r 8. Further, Shimabukuro teaches that, as a result of the control method shown in Fig. 6 ( and the flowcharts in Figs. 11-13), which is governed by the speed difference between the engine and the motor, shock at the time of engagement of the clutch can be reduced and the load on the clutch lowered, "with no need to estimate the output torque . . . of the engine." Shimabukuro ,r 112. In view of Shimabukuro' s teaching that estimating engine output torque is both difficult and not needed to achieve a smooth and high quality (low shock, low clutch load) clutch engagement using Shimabukuro' s control method, we agree with Appellant that a person having ordinary skill in the art would not have been prompted to modify Shimabukuro' s method by monitoring engine output torque and locking the clutch in response to the engine torque falling below a threshold value. Moreover, with respect to the Examiner's alternative rationale, the Examiner has not pointed to any evidence, or proffered any technical reasoning, to establish that fully 8 Appeal2018-000449 Application 14/575,053 engaging the clutch in response to an indication that engine output torque is below a predetermined threshold, in the absence of an indication in Shimabukuro' s control system that the speed difference is below the predetermined thresholds, would achieve a smooth and high quality clutch engagement. Accordingly, we do not sustain the rejection of independent claims 1, 7, and 12, or of claims 2 and 13, which depend from claims 1 and 12, respectively, as unpatentable over Shimabukuro and Genise. Re} ection II The teachings of Kato relied on by the Examiner in rejecting claims 3-5, 8-10, and 14--16, each of which depends from claim 1, claim 7, or claim 12, are directed to determining a target engine torque and electric motor torque required to achieve the desired change in operating speed of the engine during the process of shifting the transmission in response to an operation by the vehicle operator. See Final Act. 7-11. The Examiner does not articulate any additional findings or reasoning that would remedy the aforementioned deficiency in the combination of Shimabukuro and Genise. Accordingly, we do not sustain the rejection of claims 3-5, 8-10, and 14--16 as unpatentable over Shimabukuro, Genise, and Kato. Rejection III In rejecting claims 6, 11, and 17, which depend, directly or indirectly, from claims 1, 7, and 12, respectively, the Examiner relies on Matsuda for its teaching of "reducing engine torque by reducing air intake amount in addition to ignition retard control," and not for any teaching that would 9 Appeal2018-000449 Application 14/575,053 remedy the aforementioned deficiency in the combination of Shimabukuro and Genise. See Final Act. 11-12. Accordingly, we do not sustain the rejection of claims 6, 11, and 17 as unpatentable over Shimabukuro, Genise, and Matsuda. DECISION The Examiner's decision rejecting claims 1-17 is reversed. REVERSED 10