Ex Parte Ellin et alDownload PDFPatent Trial and Appeal BoardNov 30, 201210500716 (P.T.A.B. Nov. 30, 2012) Copy Citation UNITED STATES PATENT AND TRADEMARK OFFICE ________________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ________________ Ex parte ALEXANDER DAVID SCOTT ELLIN and JAMES REYNOLDS HENSHAW ________________ Appeal 2010-009287 Application 10/500,716 Technology Center 3700 ________________ Before STEVEN D.A. McCARTHY, GAY ANN SPAHN and 1 JOHN W. MORRISON, Administrative Patent Judges. McCARTHY, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE 2 The Appellants1 appeal under 35 U.S.C. § 134 from the Examiner’s 3 final decision rejecting claims 1-36, 42 and 43. The Examiner rejects under 4 35 U.S.C. § 103(a) claims 1-14, 19-32, 42 and 43 as being unpatentable over5 1 The Appellants identify the real party in interest as Renishaw PLC. Appeal No. 2010-0009287 Application No. 10/500,716 2 the Appellants’ Admitted Prior Art (“the AAPA”), Michel (DE 196 08 937 1 A1, publ. Sep. 12, 1996)2 and Neev (US 6,156,030, issued Dec. 5, 2000); 2 claims 15-17 and 33-35 as being unpatentable over the AAPA, Michel, Neev 3 and Gallagher (US 2003/0015672 A1, publ. Jan. 23, 2003); and claims 18 4 and 36 as being unpatentable over the AAPA, Michel, Neev and Neiheisel 5 (US 5,736,709, issued Apr. 7, 1998). An oral hearing was held on 6 November 6, 2012. We have jurisdiction under 35 U.S.C. § 6(b). 7 We REVERSE. 8 Claims 1 and 19 are independent. Claim 1 is illustrative: 9 1. A method of producing precision 10 marks for a metrological scale, employing 11 apparatus including: 12 a scale substrate to be marked 13 at repeated instants by a laser and 14 thereby forming a metrological scale; 15 a laser operable so as to provide 16 light pulses for forming scale 17 markings at the substrate; 18 a displacement device for 19 causing relative displacement between 20 the substrate and the location at which 21 the light is incident on the substrate; 22 and 23 a controller for controlling the 24 relative displacement and the laser, 25 the method comprising the steps, in any 26 suitable order, of: 27 operating the displacement 28 mechanism so as to cause relative 29 2 References to Michel will be to the Official Translation prepared by FLS, Inc. in or about November 2009. Appeal No. 2010-0009287 Application No. 10/500,716 3 displacement between the substrate 1 and the light; 2 using the controller to control 3 the relative displacement and to 4 operate the laser so as to produce light 5 pulses at the substrate; 6 characterised in that: 7 the laser produces a plurality of 8 ultra-short pulses3 of a fluence at the 9 substrate such that the metrological 10 scale marks are formed by laser 11 ablation, wherein the plurality of 12 ultra-short pulses have a duration such 13 that the scale markings are formed on 14 the scale substrate by a laser ablation 15 mechanism in which the molten stage 16 is omitted. 17 Independent claim 19 recites an apparatus for producing precision marks for 18 a metrological scale including, inter alia, a laser, 19 characterised in that the pulses of light produced 20 by the laser are ultra-short pulses of a fluence at 21 the substrate such that the metrological scale 22 marks are formed by laser ablation, wherein the 23 plurality of ultra-short output pulses have a 24 duration such that the scale markings are formed 25 on the scale substrate by a laser ablation 26 mechanism in which the molten stage is omitted. 27 The AAPA appears primarily at page 1, line 31 through page 2, line 28 29 of the Specification. The Examiner summarizes the AAPA as describing 29 “[1] known production of measurement scale using a laser, [2] use of a 30 reference to correct deficiencies, [3] marking perpendicular to the laser 31 3 The Specification defines “ultra-short pulses” as pulses having pulse lengths below approximately 4 picoseconds. (See Spec. 2, ll. 21-27). Appeal No. 2010-0009287 Application No. 10/500,716 4 travel direction, and [4] known laser solid to gaseous state ablation 1 performed at below 4 picoseconds pulse length.” (Ans. 4 (reference 2 numerals added)). The Appellants’ Specification supports all four of the 3 Examiner’s findings. (See Spec. 1, ll. 31-32; Spec. 1, l. 34 – 2, l. 1; Spec. 2, 4 ll. 6-8; and Spec. 2, ll. 14-17 and 21-29). On the other hand, the Examiner 5 finds that the “AAPA does not describe forming a scale by laser ablation 6 (direct solid to vapor phase transition).” (Ans. 4). 7 Neev describes the use of a laser to ablate material. (Neev, col. 7, ll. 8 7-8). In fact, both the AAPA and Neev describe laser ablation mechanisms 9 using high energy, ultra-short pulses (that is, pulses of length less than 4 10 picoseconds). Neither suggests exploiting this mechanism to produce scale 11 markings, however. In particular, the only examples of materials which 12 Neev appears to suggest ablating with a laser producing a pulse width of 4 13 picoseconds or less are biological tissues. (See, e.g., Neev, col. 28, ll. 56-63 14 and col. 29, ll. 20-34; see also id., col. 5, ll. 3-18). 15 Michel describes forming tags (that is, index markings) using high-16 energy laser from an excimer laser. (Michel 2, l. 20 – 3, l. 2). Michel 17 discloses applying the tag (or scale marked) layer T1 “in the usual way” as a 18 gold layer on a steel strip as S1 or, alternatively, on a highly polished surface 19 T2 on the steel strip. (Michel 3, ll. 16-20). Michel teaches that: 20 The high-energy radiation can be generated with 21 the use of the previously mentioned excimer laser. 22 For manufacturing the separating structure [or 23 divisional structure] TS1 or TS2 in the form of a 24 grid, the highly reflective surface of the gold layer 25 T1 or the polished surface T2 of the substrate S2 is 26 melted with the use of short laser pulses with a 27 duration of about 20 ns [that is, about 20,000 28 picoseconds], after which, in the pulse pause, the 29 Appeal No. 2010-0009287 Application No. 10/500,716 5 surface T1, T2 immediately solidifies again. In 1 order to prevent energy dissipation from the 2 processing area during the duration of the laser 3 pulse, pulses of a clearly shorter duration can be 4 used. The solidified melt has a different roughness 5 and thus different optical properties than the highly 6 reflective surfaces T1, T2 and a separating structure 7 TS1, TS2 with reduced reflectivity develops. 8 (Michel 3, l. 21 – 4, l. 7 (italics added)). 9 In other words, Michel teaches forming scale markings by melting 10 and re-solidifying portions of the polished surface of a marked layer in order 11 to change the optical properties of the marked layer. (See Michel 3, l. 21 – 12 4, l. 7 (italics added)). On the other hand, the Examiner cites the AAPA and 13 Neev as teaching the use of lasers to ablate materials. (Ans. 4). Neev, in 14 fact, suggests that one advantage of Neev’s teachings is that melting and 15 boiling are minimized. (See, e.g., Neev, col. 24, ll. 10-15). 16 As the Appellants point out, Michel appears to teach the desirability 17 of what, in other contexts, might have been viewed as product defects. (See 18 Br. 16). In view of these differences, the Examiner’s conclusion that the 19 “use of a low thermal transfer to the workpiece by performing ultra-short 20 pulse laser ablation would have been obvious at the time applicant’s 21 invention was made to a person having ordinary skill in the art in order to 22 minimize the heat affected zone (HAZ) and thereby reduce product defects” 23 (Ans. 4) is not persuasive. 24 Based on this reasoning, we do not sustain the rejection of claims 1-14 25 and 42 under § 103(a) as being unpatentable over the AAPA, Michel and 26 Neev. In addition, the Examiner has not provided reasoning with some 27 rational underpinning to show that one of ordinary skill would have reason 28 to provide an apparatus for producing precision marks for a metrological 29 Appeal No. 2010-0009287 Application No. 10/500,716 6 scale with a laser capable of producing ultra-short pulses, we do not sustain 1 the rejection of claims 19-32 and 43 under § 103(a) as being unpatentable 2 over the AAPA, Michel and Neev. 3 With respect to the rejection of claims 15-17 and 33-35, the Examiner 4 finds that “[d]isplacement is described by Gallagher.” (Ans. 5). The 5 Examiner concludes that the “the use thereof in displacement for laser 6 ablation of marks” would have been obvious “because automated movement 7 control provides controlled regular ablation.” (Id.) This finding and 8 reasoning does not remedy the deficiencies in the combined teachings of the 9 AAPA, Michel and Neev as applied to independent claims 1 and 19. We do 10 not sustain the rejection of claims 15-17 and 33-35 under § 103(a) as being 11 unpatentable over the AAPA, Michel, Neev and Gallagher. 12 With respect to the rejection of claims 18 and 36, the Examiner finds 13 that “Neiheisel describes laser ablation and shows (Figure 10b) the well 14 known elliptical spot.” (Ans. 6). The Examiner concludes that the 15 “elliptical spot” would have been obvious “because it provides a narrower 16 profile for precision shaped etching.” (Id.) This finding and reasoning does 17 not remedy the deficiencies in the combined teachings of the AAPA, Michel 18 and Neev as applied to independent claims 1 and 19. We do not sustain the 19 rejection of claims 15-17 and 33-35 under § 103(a) as being unpatentable 20 over the AAPA, Michel, Neev and Neiheisel. 21 DECISION 22 We REVERSE the Examiner’s decision rejecting claims 1-36, 42 and 23 43. 24 REVERSED 25 Klh 26 Copy with citationCopy as parenthetical citation
