11457157 (P.T.A.B. Mar. 7, 2014)

Ex Parte Junge

Patent Trial and Appeal BoardMar 7, 2014

11457157 (P.T.A.B. Mar. 7, 2014)

UNITED STATES PATENT AND TRADEMARK OFFICE ____________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ____________ Ex parte BRENT A. JUNGE ____________ Appeal 2012-000950 Application 11/457,157 Technology Center 3700 ____________ Before MEREDITH C. PETRAVICK, GAY ANN SPAHN, and MICHAEL C. ASTORINO, Administrative Patent Judges. ASTORINO, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE The Appellant appeals under 35 U.S.C. § 134 from the Examiner’s decision finally rejecting claims 1, 4, 6-8, 11, 13, and 14. We have jurisdiction over the appeal under 35 U.S.C. § 6(b). We REVERSE. Appeal 2012-000950 Application 11/457,157 2 Claimed Subject Matter Claims 1 and 8 are the independent claims on appeal. Claim 1, reproduced below, is illustrative of the subject matter on appeal. 1. A refrigeration appliance comprising: a cabinet having a first compartment and a second separate compartment, a refrigeration system including a compressor, an evaporator and a condenser, the evaporator being associated with the first compartment to lower a temperature of the first compartment air, a heat exchanger being exposed to the temperature of the first compartment and having a surface area in the form of a flat plate with a plurality of ribs exposed to second compartment air, an air moving device associated with the second compartment to direct a flow of second compartment air over the heat exchanger surface area and circulate the second compartment air within the second compartment, the air moving device arranged to operate at a speed to produce a volume flow rate of air greater than 8 cfm and not greater than about 25 cfm in the second compartment, the ribs on the plate being oriented in a direction of air flow of the second compartment air over the plate, the cabinet, compartments and heat exchanger being configured such that first compartment air is completely isolated from second compartment air. Claim 8 is similar to claim 1 in that it recites: A refrigeration appliance comprising . . . a second fan in air flow communication with the second compartment to direct a flow of second compartment air over the heat exchanger second surface area and circulate the second compartment air within the second compartment, the second fan arranged to operate at a speed to produce a volume flow rate of air in the range of 20 to 25 cfm in the second compartment . . . . App. Br., Clms. App’x. Appeal 2012-000950 Application 11/457,157 3 Rejections Claims 1, 4, 7, 8, 11, and 14 are rejected under 35 U.S.C. § 103(a) as unpatentable over Wurtz (US 2,982,115, iss. May 2, 1961), Frohbieter (US 4,722,200, iss. Feb. 2, 1988), and Baker (US 5,588,484, iss. Dec. 31, 1996). Claims 6 and 13 are rejected under 35 U.S.C. § 103(a) as unpatentable over Wurtz, Frohbieter, Baker, and Stevens (US 3,359,751, iss. Dec. 26, 1967). OPINION The Examiner finds that Wurtz discloses an air moving device (impeller) 94, a first compartment 20, a second compartment 24, and a heat exchange surface area (drip pan) 30. Ans. 5. The Examiner finds that Wurtz, as modified by Frohbieter’s teachings1, would not have resulted in an “air moving device . . . arranged to operate at a speed to produce a volume flow rate of air greater than 8 cfm and not greater than about 25 cfm in the second compartment,” as recited in claim 1. Ans. 6. The Examiner relies on Baker to help remedy this deficiency of Wurtz’s disclosure with regard to claim 1. The Examiner finds that Baker discloses an air moving device that operates at 40 cubic feet per minute (cfm). Id. Further, the Examiner concludes: In view of Baker[’s] . . . teaching, it would have been obvious to one of ordinary skill in the art at the time of invention to modify the fan [(air moving device)] of Wurtz to operate at a given speed as described by Baker . . . in order to 1 The Examiner finds that Wurtz lacks, and Frohbieter teaches, “a flat plate with a plurality of ribs, the ribs on the plate being oriented in a direction of air flow of the second compartment air over the plate” and then modifies Wurtz’s refrigerator appliance in view of Frohbieter’s teaching. Ans. 5-6. Appeal 2012-000950 Application 11/457,157 4 optimize the efficiency of the refrigeration system and provide a uniform air flow throughout the refrigeration device. It would have been obvious to one having ordinary skill in the art at the time the invention was made to determine the optimal fan operating speed, since it has been held that discovering an optimum value of a result effective variable involves only routine skill in the art. Id. (citing In re Boesch, 617 F.2d 272 (CCPA 1980)) (emphasis added); see also Ans. 14 (citing In re Aller, 220 F.2d 454 (CCPA 1955)). The Examiner explains that: . . . the fan speed is related to the cooling the efficiency of the refrigerator. Thus, the variable is the fan speed and the result is efficiency. By experimenting with different fan speeds, one of ordinary skill in the art would be able to determine the optimal speed with witch [sic, which] to operate the fan at to achieve the highest efficiency from the system. Ans. 14 (emphasis added). However, the Examiner’s conclusion of obviousness, based on the optimization of a result effective variable, is flawed for the following reasons. See App. Br. 13-16, Reply Br. 7-8. As discussed above, the Examiner supports the obviousness rejection by citing to case law concerning the optimization of ranges, e.g., In re Aller. Aller established two conditions for a conclusion of obviousness: 1) the general conditions of the claim must be disclosed in the prior art and 2) discovery of the optimum or workable range must be a matter of routine experimentation for a person of ordinary skill in the art. Aller, 220 F.2d at 456 (citations omitted). Aller does not apply in this case at least because the general conditions of the claim were not disclosed in the prior art. First, the prior art does disclose an air flow moving device having a volume flow rate range that overlaps with the air moving device’s claimed Appeal 2012-000950 Application 11/457,157 5 volume flow rate, i.e., “a volume flow rate of air greater than 8 cfm and not greater than about 25 cfm in the second compartment” (App. Br., Clms. App’x. (emphasis added)). As discussed above, the Examiner finds that Wurtz, as modified by Frohbieter, does not disclose the claimed range. Ans. 6. Although the Examiner offers as evidence the Appellant’s acknowledgement that refrigerator appliances typically have volume flow rates of 5 to 8 cfm (Ans. 13; see Spec. para. [0028])), due to Wurtz’s silence concerning the volume flow rate of its air moving device it is unclear if it is in the range of 5 to 8 cfm. Moreover, assuming Wurtz’s air moving device does operate at a fan speed that produces a typical volume flow rate of 5 to 8 cfm, it is unclear where exactly within the range Wurtz’s air moving device operates. As for Baker, its refrigerator fan system delivers at least 40 cfm of air. App. Br. 13 and 15 (citing Baker, col. 1, ll. 56-57 and col. 3, ll. 64-65). As such, the prior art, as applied by the Examiner, does not overlap with the claimed range, i.e., “a volume flow rate of air greater than 8 cfm and not greater than about 25 cfm in the second compartment.” Second, “Baker does not teach or suggest the use of a fan to direct a flow of air over a flat plate heat exchanger, with the air being circulated through the second compartment of a refrigeration appliance.” App. Br. 13; see App. Br. 16. As such, the modification of Wurtz’s air moving device 94 in view of Baker’s teachings is not based on an air moving device that circulates air flow through a compartment of a refrigeration appliance. Hence, it is unclear how Baker’s air moving device would help teach an air moving device arranged to operate at a speed to produce a volume flow rate of air in the claimed range. Appeal 2012-000950 Application 11/457,157 6 Additionally, the Examiner appears to support the further modification of Wurtz in view of Baker by finding that increasing fan speed increases air speed and improves the thermal efficiency of a heat exchanger. See Ans. 13. More specifically, the Examiner determines “it is well known in thermodynamics that an increased air speed across a heat exchanger will result in the predictable result of increased heat transfer of the heat exchanger, therefore improving the thermal efficiency of the heat exchanger.” Ans. 13. This finding by the Examiner does not appear to support the Examiner’s further modification of Wurtz in view of Baker, because Baker teaches improving efficiency by using a fan that is different than a conventional fan so that its fan operates at lower speeds of rotation to meet performance standards. See Baker, col. 4, ll. 1-12. Accordingly, Baker’s teaching concerning efficiency is not based on increasing fan speed but decreasing fan speed and using a fan that is different than a conventional fan. Thus, the Examiner’s rejection of claim 1, and its dependent claims, as unpatentable over Wurtz, Frohbieter, and Baker is not sustained. The Examiner’s rejection of claim 8 is similar to the Examiner’s rejection of claim 1. See Ans. 4-9. For similar reasons to those discussed above with respect to the rejection of claim 1, we do not sustain the rejection of claim 8, and its dependent claims, as unpatentable over Wurtz, Frohbieter, and Baker. As for the rejection of claims 6 and 13 over Wurtz, Frohbieter, and Baker, in combination with Stevens, this rejection relies on the same unsupported conclusion as discussed above. Additionally, the Examiner does not point out how the teachings of Stevens might remedy the Appeal 2012-000950 Application 11/457,157 7 unsupported conclusion in the rejection of claims 1 and 8. Thus, we do not sustain the rejection of claims 6 and 13, which depend from claims 1 and 8, respectively, as unpatentable over Wurtz, Frohbieter, Baker, and Stevens. DECISION We REVERSE the rejections of claims 1, 4, 6-8, 11, 13, and 14. REVERSED Klh