11041910 (P.T.A.B. Oct. 31, 2012)

Ex Parte Cariveau et al

Patent Trial and Appeal BoardOct 31, 2012

11041910 (P.T.A.B. Oct. 31, 2012)

UNITED STATES PATENT AND TRADEMARK OFFICE ____________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ____________ Ex parte PETER THOMAS CARIVEAU, BALA DURAIRAJAN, and SUJIAN J. HUANG ____________ Appeal 2010-006162 Application 11/041,910 Technology Center 2100 ____________ Before SCOTT R. BOALICK, BRUCE R. WINSOR, and JAMES B. ARPIN, Administrative Patent Judges. ARPIN, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE Appellants appeal under 35 U.S.C. § 134(a) from the Examiner’s rejection of claims 1, 4-8, and 10. We have jurisdiction under 35 U.S.C. § 6(b). We affirm-in-part. Invention Appellants’ invention relates to a method for designing a fixed cutter drill bit, including simulating the fixed cutter drill bit drilling in an earth Appeal 2010-006162 Application 11/041,910 2 formation, determining a dynamic centerline trajectory of the drill bit, graphically displaying the dynamic centerline trajectory pattern, and adjusting at least one design parameter based upon the graphical display of at least the dynamic centerline trajectory pattern. The method includes repeating simulating the fixed cutter drill bit and determining a dynamic centerline trajectory of the drill bit, during the adjusting of at least one design parameter. Further, the method includes outputting a fixed cutter drill bit design. See generally Spec., Abstract. Claim 1 is reproduced below with the disputed term emphasized: 1. A method for designing a fixed cutter drill bit, comprising: calculating a dynamic response of a drilling tool assembly comprising a fixed cutter drill bit disposed at a distal end thereof; determining a dynamic centerline trajectory of the fixed cutter drill bit based on the dynamic response; displaying a dynamic centerline trajectory pattern; adjusting a value of at least one design parameter for the fixed cutter drill bit based upon at least the dynamic centerline trajectory pattern and repeating the calculating and determining to modify a dynamic centerline trajectory for the fixed cutter drill bit; and outputting a fixed cutter drill bit design through use of a computer. Claim 1 is illustrative of claims 4-8 and 10. The Examiner relies on the following as evidence of unpatentability: Brett EP 0 467 580 B1 Jan. 22, 1992 J.M. Hanson & W.R. Hansen, Dynamics Modeling of PDC Bits, SPE/IADC DRILLING CONF. 589-604 (1995). Appeal 2010-006162 Application 11/041,910 3 The Rejections The Examiner rejected claims 1, 4-8, and 10 under 35 U.S.C. § 103(a) as unpatentable over Hanson and Brett. Ans. 3-7.1 THE OBVIOUSNESS REJECTION OVER HANSON AND BRETT Regarding claim 1, the Examiner finds that Hanson generally discloses a method of modeling a fixed cutter drill bit to predict the performance of a PDC drill bit. Ans. 3. In particular, the Examiner finds that Hanson discloses calculating, e.g., simulating, a dynamic response of a drilling tool assembly comprising a fixed cutter drill bit disposed at a distal end thereof. Ans. 3-4 (citing Hanson at 590, 595; Figs. 11, 12). Further, the Examiner finds that Hanson discloses determining a dynamic centerline trajectory of the fixed cutter drill bit based on the calculated dynamic response. Ans. 4 (citing Hanson at 590, 595; Figs. 11, 12). Hanson also discloses displaying a dynamic centerline trajectory pattern for the fixed cutter drill bit. Ans. 4 (citing Hanson at 596; Figs. 9, 10). Although Hanson discloses the availability of a “numerical dynamics simulator,” the Examiner acknowledges that Hanson does not expressly teach the numerical bit dynamics simulator used for designing a fixed cutter drill bit wherein the value of at least one design parameter for the fixed cutter drill bit is adjusted based on the dynamic centerline trajectory pattern and repeating the calculating and determining to modify a dynamic centerline trajectory for the fixed cutter drill bit and outputting a fixed cutter drill bit design through the use of a computer. 1 Throughout this decision, we refer to (1) the Appeal Brief filed August 24, 2009 (“Br.”); and (2) the Examiner’s Answer mailed January 7, 2010 (“Ans.”). Appeal 2010-006162 Application 11/041,910 4 Ans. 4. The Examiner, however, finds that Brett teaches a method of manufacturing a drill bit, wherein the drill bit is designed on a computer. In particular, the Examiner finds that Brett discloses adjusting the value of at least one design parameter for a fixed cutter drill bit based on the dynamic centerline trajectory pattern. Ans. 4-5 (citing Brett, p. 12 (Table 1); p. 13 (Table 2); p. 20, ll. 4-18, 42-48; Fig. 17A). Further, referring to iterative loops 320 and 321 in Figure 17A, Brett discloses that the adjustment of the at least one design parameter for the fixed cutter drill bit may be repeated to improve the bit design. Ans. 5 (citing Brett, p. 20, ll. 12-37). Moreover, Brett discloses outputting the adjusted drill bit design through the use of a computer. Ans. 5 (citing Brett, p. 5, ll. 12-16; Fig. 17A). Consequently, the Examiner concludes that a person of ordinary skill would employ the “numerical dynamic simulator” taught by Hanson in the iterative method taught by Brett to adjust at least one design parameter for a fixed cutter drill and, thereby to output a drill bit design. Ans. 5-6. Appellants argue the pending claims separately in five groups: Group I (Claims 1 and 10),2 Group II (Claim 4), Group III (Claims 5 and 6), Group IV (Claim 7), and Group V (Claim 8). Br. 6. With respect to independent claim 1, Appellants argue that the proposed combination of Hanson and Brett fails to teach or suggest all of the limitations of the pending claims. Id. In particular, Appellants raise three arguments regarding the alleged deficiencies in the combination of Hanson and Brett. First, Appellants argue that Hanson fails to calculate a dynamic response of a drilling tool assembly, as that term is defined by Appellants. Br. 7. Second, Appellants argue that, because Hanson does not calculate the same dynamic response described in 2 Appellants do not argue claim 10 separately from claim 1. Appeal 2010-006162 Application 11/041,910 5 Appellants’ claim 1, Hanson does not teach or suggest (1) determining a dynamic centerline trajectory based on the dynamic response or (2) displaying a dynamic centerline trajectory pattern based on the determined dynamic centerline trajectory.3 Br. 10. Third, Appellants argue that, because Brett does not teach or suggest calculating a dynamic response of a drilling tool assembly, Brett fails to teach or suggest the limitations of claim 1 that allegedly are missing from Hanson. Br. 11-12. Appellants also argue that the additional limitations recited in claims 4-8 are missing from the combination of Hanson and Brett. Br. 13-19. ISSUES (1) Under § 103, has the Examiner erred in rejecting claim 1 by finding that Hanson and Brett would have disclosed or suggested “calculating a dynamic response of a drilling tool assembly comprising a fixed cutter drill bit disposed at a distal end thereof” (emphases added)? (2) Under § 103, has the Examiner erred by finding that Hanson and Brett would have disclosed or suggested “adjusting”: (a) “the at least one parameter to decrease the maximum deviation of the dynamic centerline trajectory,” as recited in claim 4? (b) “the at least one parameter to produce a dynamic centerline trajectory pattern having a forward whirl,” as recited in claim 5? (c) “the at least one parameter to eliminate a reward [sic; rearward] whirl in the dynamic centerline trajectory,” as recited in claim 6? 3 We note that, in claim 1, Appellants fail to describe precisely how the dynamic centerline trajectory “pattern” displayed relates to the dynamic centerline trajectory determined. Appeal 2010-006162 Application 11/041,910 6 (d) “the at least one parameter to decrease the maximum deviation of a triangular pattern of the dynamic centerline trajectory,” as recited in claim 7? (e) “the at least one parameter to eliminate inner looping in the dynamic centerline trajectory,” as recited in claim 8? ANALYSIS 1. Claim Construction. We begin by construing the disputed term of claim 1 which calls for, in pertinent part, “calculating a dynamic response of a drilling tool assembly comprising a fixed cutter drill bit disposed at a distal end thereof” (emphasis added). [The USPTO] applies to the verbiage of the proposed claims the broadest reasonable meaning of the words in their ordinary usage as they would be understood by one of ordinary skill in the art, taking into account whatever enlightenment by way of definitions or otherwise that may be afforded by the written description contained in the applicant’s specification. In re Morris, 127 F.3d 1048, 1054 (Fed. Cir. 1997). A pertinent definition of “assembly” is “parts of a machine etc. put together to form a unit.” OXFORD AMERICAN DICTIONARY 47 (Heald Colleges ed. 1980). Thus, the ordinary and customary meaning of a drilling tool assembly is parts of a drilling tool put together to form a unit. This, however, is only the starting point of claim construction. We must consider the claim term in the context of the written description of the invention provided by the Specification, Morris, 127 F.3d at 1054, without importing limitations from the Specification into the claims, SuperGuide Corp. v. DirecTV Enters., Inc., 358 F.3d 870, 875 (Fed. Cir. 2004). Appeal 2010-006162 Application 11/041,910 7 Appellants do not provide an express definition of the term "drilling tool assembly" in the Specification. Referring to their Figure 1, Appellants state that FIG. 1 shows one example of a drilling tool assembly that may be designed, modeled, or optimized in accordance with one or more embodiments of the invention. The drilling tool assembly includes a drill string 16 coupled to a bottomhole assembly (BHA) 18. The drill string 16 includes one or more joints of drill pipe. A drill string may further include additional components, such as tool joints, a kelly, kelly cocks, a kelly saver sub, blowout preventers, safety valves, and other components known in the art. The BHA 18 includes at least a drill bit. A BHA 18 may also include one or more drill collars, stabilizers, a downhole motor, MWD tools, and LWD tools, jars, accelerators, push the bit directional drilling tools, pull the bit directional drilling tools, point stab tools, shock absorbers, bent subs, pup joints, reamers, valves, and other components. Spec. ¶ [0053] (emphases added). In Figure 1, however, Appellants merely describe “one example” of a drilling tool assembly, and, consequently, we do not limit the term to that meaning associated with that depiction. Instead, we construe the term drilling tool assembly as limited only by the presence of “a fixed cutter drill bit disposed at [its] distal end.” Referring to the portions of the Specification that Appellants identify as providing support for this clause (Br. 5), we find that, in one or more embodiments, calculating a dynamic response to a drilling tool assembly may take into account interactions between the entire drilling tool assembly and the drilling environment. Spec. ¶ [0060]. Nevertheless, “[t]he interactions may include the interaction between the drill bit at the end of the drilling tool assembly and the formation at the bottom of the wellbore.” Id. Moreover, the interactions may include interactions between the drill tool assembly and the side (or wall) of the wellbore. Id. Thus, we broadly Appeal 2010-006162 Application 11/041,910 8 construe the first clause of claim 1 as describing calculating a simulated dynamic response or simulating the dynamic response of drilling tool assembly, including, but not necessarily limited to a drill string, i.e., a drill pipe, and a fixed cutter drill bit disposed on its distal end. See Spec. ¶ [0068]. We do not, however, construe the claim language as requiring (1) a particular drilling tool assembly or (2) a particular interaction between the drilling tool assembly and the drilling environment. 2. Obviousness Rejections. a. Claims 1 and 10. As noted above, Appellants raise three arguments regarding the alleged deficiencies in the combination of Hanson and Brett. First, Appellants argue that Hanson fails to calculate a dynamic response of a drilling tool assembly, as that term is defined by Appellants. Br. 7. In particular, Appellants argue that their Figure 1 discloses a full scale-drilling simulator including a drilling tool assembly. Id. Thus, Appellants argue that “Hanson[’s] test device is not capable of measuring dynamic conditions affecting a drilling tool assembly because the Hanson device does not include drill pipe capable of responding to actual downhole conditions.” Br. 9. As noted above, however, Appellants’ Figure 1 is merely “one example” of a drilling tool assembly and does not establish the definition of that term within Appellants’ claims. Spec. ¶ [0053]. Further, Appellants’ Figure 1 does not disclose a full scale-drilling simulator including a drilling tool assembly. Instead, Figure 1 depicts a schematic of a “conventional” drilling assembly (Spec. ¶ [0022]) of the type that may be designed, modeled, or optimized according to methods described in the Specification. Appeal 2010-006162 Application 11/041,910 9 Referring to Figure 1, Hanson depicts a diagram of the full-scale drilling simulator used to test the vibration and the stability of bits. Hanson at 590; see also Ans. 7. In particular, Hanson’s drilling simulator includes a drill pipe having a fixed cutter drill bit at one end of the drill pipe; Hanson’s fixed cutter drill bit is seated in a bottom hole formed in a limestone block. Hanson at Fig. 1. Moreover, Hanson explains that, “[b]ecause its current application is to simulate full scale drilling simulator tests, the model also includes the influence of vertical vibration of the drilling simulator structure and rock support platform and torsional vibration of the drill pipe in its predictions.” Hanson at 599; see also Ans. 7. Thus, the Examiner correctly concludes that the teachings of Hanson describe a drilling tool assembly, as that term is used in the first clause of Appellants’ claim 1, and that Hanson’s simulator model calculates a dynamic response, including the torsional vibration, of the drilling tool assembly, comprising a fixed cutter drill bit. Ans. 8-9. Hanson notes that, in certain runs of the numerical bit dynamics simulator, “[s]tiffness of the crosshead beam, drill pipe, and rock support system were taken to be infinite.” Hanson at 598. Appellants argue that, if the model assumes that if these parameters were taken to be infinite, the drill pipe would be prevented from moving and the simulator could not take lateral, longitudinal, or torsional movement into account. Br. 8-9. As the Examiner correctly notes, however, these conditions apply to Hanson’s validation runs (Hanson at 598-99), rather than to Hanson’s testing scenarios (Hanson at 594-97). Ans. 9-10. Therefore, we agree with the Examiner that Hanson teaches or suggests “calculating a dynamic response of a drilling tool assembly comprising a fixed cutter drill bit disposed at a distal end Appeal 2010-006162 Application 11/041,910 10 thereof,” as that limitation is recited in Appellants’ claim 1 (emphasis added). Second, Appellants argue that, because Hanson does not calculate the same dynamic response described in Appellants’ claim 1, Hanson does not teach or suggest (1) determining a dynamic centerline trajectory based on the dynamic response or (2) displaying a dynamic centerline trajectory pattern based on the determined dynamic centerline trajectory. Br. 10. Because we find that Hanson teaches calculating a dynamic response of a drilling tool assembly, as described in claim 1, Appellants do not persuade us that the Examiner erred in finding that Hanson also teaches or suggests the subsequent steps of determining a dynamic centerline trajectory based on the dynamic response or displaying a dynamic centerline trajectory pattern, as recited in claim 1. Third, Appellants argue that, because Brett does not teach or suggest calculating a dynamic response of a drilling tool assembly, Brett fails to teach or suggest the limitations of claim 1 that allegedly are missing from Hanson. Br. 11-12. Referring to Figure 17A, Appellants argue that Brett discloses “a method for generating a geometric model representing cutter coordinates on a bit, and makes no mention of calculating a dynamic centerline in a trajectory.” Id. (emphasis added). Further, Appellants argue that Brett’s geometric model or description of a drill bit is not a “dynamic model of a bit drilling in an earth formation.” Br. 12. Appellants misunderstand the Examiner’s combination of the teachings of Hanson and Brett. As noted above, the Examiner relies on Hanson to teach the calculation of a dynamic response and the determination of a dynamic Appeal 2010-006162 Application 11/041,910 11 centerline trajectory. Ans. 3-4, 7-12. As the Examiner correctly explains, “[i]t is the Examiner’s position that the calculation of a dynamic centerline trajectory is clearly taught by the teachings of Hanson as cited (as shown for example in Figures 9-12).” Ans. 12; see also Ans. 13. We agree with the Examiner’s finding that, because Brett describes the determination of drill bit design parameters based on offsets or disturbing displacements to the drill bit, Brett teaches that these offsets or displacements affect the ability of the drill bit to maintain contact with the borehole wall and change or affect the centerline trajectory of the drill bit. Ans. 12-13. The Examiner correctly finds that Hanson teaches calculating of a dynamic response, determining a dynamic centerline trajectory from that dynamic response, and displaying a dynamic centerline trajectory (Ans. 12) and that Brett teaches the design and simulation of drill bits and the importance of dynamic centerline trajectory, e.g., avoiding offsets or disturbances, in bit design (Ans. 12-13). Thus, because Brett also teaches the use of iterative steps in producing a drill bit design and the output of a drill bit design, Hanson and Brett teach or suggest all of the limitations of Appellants’ claim 1. Ans. 6 (citing Brett, Fig. 17A (loops 320 and 321)); see also Ans. 15-16. For the foregoing reasons, Appellants have not persuaded us of error in the rejection of independent claim 1 or of claim 10, which is not argued separately, and we sustain these rejections. b. Claim 4. With respect to claim 4, Appellants argue that Brett does not discuss adjusting a bit design parameter to decrease maximum deviation of a dynamic centerline trajectory. Br. 14. In particular, Appellants argue that Brett only teaches disposing a cutter devoid region and bearing means on a Appeal 2010-006162 Application 11/041,910 12 drill bit to body to decrease a net radial imbalance force vector. Id. As noted above, however, the Examiner finds that Brett teaches the advantages of reducing offsets or displacements in bit design and that such offsets or displacements affect the dynamic centerline trajectory of the bit. Ans. 18- 19. Moreover, Appellants fail to demonstrate why the reduction in radial imbalance force vectors and the return of the drill bit to an equilibrium position in response to offsets or disturbing displacements does not achieve the function recited in Appellants’ claim 4, namely, the decrease maximum deviation of a dynamic centerline trajectory. For the foregoing reasons, Appellants have not persuaded us of error in the rejection of claim 4, and we sustain that rejection. c. Claims 5 and 6. Claims 5 and 6 recite adjusting the at least one parameter “to produce a dynamic centerline trajectory pattern having a forward whirl” or “to eliminate a reward [sic; rearward] whirl in the dynamic centerline trajectory,” respectively. Appellants argue that, regarding the Examiner’s rejection of these claims, the portion of Brett cited by the Examiner fails to mention bit whirl, and the portions of Hanson cited by the Examiner do not describe how a bit design parameter may be adjusted to produce a particular dynamic centerline trajectory producing forward bit whirl or eliminating rearward bit whirl. Br. 15. With respect to the alleged absence of a mention of bit whirl in Brett, we do not agree with Appellants. In support of the rejection, the Examiner cites page 4, lines 20-33, of Brett. Ans. 6, 19. Brett there describes that “[t]he center of rotation of the drill bit remains at a substantially fixed location on the drill bit body during drilling, and backward whirling and its Appeal 2010-006162 Application 11/041,910 13 damaging effects can be avoided.” Brett, p. 4, ll. 31-33 (emphasis added). Thus, Brett clearly describes the damaging effects of backward or rearward whirling and suggests the advantages of its elimination. Further, Brett states that by designing the drill bit to control the magnitude and direction of the radial imbalance force vector, and by disposing a cutter devoid region and a bearing means on a selected location on the drill bit body corresponding to the direction of the net radial imbalance force vector, stable drill bit rotation . . . can be achieved. Brett, p. 4, ll. 28-31. Thus, contrary to Appellants’ argument, we agree with the Examiner that Brett describes at least rearward whirling and parameters that may be adjusted to eliminate it. As noted above, the Examiner does not rely on Hanson to teach or suggest how a bit design parameter may be adjusted to produce a particular dynamic centerline trajectory producing forward bit whirl or eliminating rearward bit whirl. Ans. 12, 20. Nevertheless, referring to Figures 11 and 12, the Examiner correctly notes that Hanson describes that the depicted bit trajectories show the transition of the bit from unstable (rearward whirling) drilling to stable (forward whirling) drilling. Ans. 18-19 (citing Hanson at 596). Thus, we agree with the Examiner that Hanson and Brett teach or suggest all of the limitations of claims 5 and 6. For the foregoing reasons, Appellants have not persuaded us of error in the rejection of claims 5 and 6, and we sustain these rejections. d. Claims 7 and 8. With respect to claim 7, the Examiner acknowledges that “Brett does not specifically describe or show in figures a ‘triangular’ pattern” of the dynamic centerline trajectory. Ans. 20. Similarly, the Examiner Appeal 2010-006162 Application 11/041,910 14 acknowledges that “Brett does not specifically describe or show in figures an ‘inner looping’ pattern” in the dynamic centerline trajectory pattern. Ans. 21. Moreover, the Examiner does not contend that this deficiency in Brett is satisfied by Hanson. The Examiner’s reliance on Brett’s general teaching regarding the avoidance of “unstable” bit designs is insufficient to demonstrate the obviousness of the subject matter of Appellants’ claims 7 and 8.4 For the foregoing reasons, Appellants have persuaded us of error in the rejection of claims 7 and 8, and we do not sustain these rejections.5 CONCLUSION The Examiner did not err in rejecting claims 1, 4-6, and 10 under § 103. The Examiner, however, erred in rejecting claims 7 and 8 under § 103. DECISION Accordingly, we affirm the Examiner’s rejection of claims 1, 4-6, and 10 and reverse the Examiner’s rejection of claims 7 and 8. 4 We note that Hanson appears to depict an “inner looping” pattern in Figure 11. 5 If prosecution is reopened to consider further claim 7 or 8, the Examiner may consider whether either of these claims satisfies the requirements of 35 U.S.C. § 112, fourth paragraph. We note that Appellants fail to identify bit design parameters which would satisfy claim 7 or claim 8. Alternatively, claims 7 and 8 appear only to differ in the result achieved by the claimed invention. See MPEP§ 2173.05(g). Appeal 2010-006162 Application 11/041,910 15 No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a)(1)(iv). AFFIRMED-IN-PART babc