Case Name: In re William L. Albrecht and Morris Mindick
Court: United States Court of Customs and Patent Appeals
Jurisdiction: United States
Decision Date: 1967-03-16
Citations: 54 C.C.P.A. 1209
Docket Number: No. 7695
Parties: In re William L. Albrecht and Morris Mindick
Judges: Before Worley, Chief Judge, Rich, Smith, Almqnd, Associate Judges, and William H. Kirkpatrick
Reporter: Court of Customs and Patent Appeals Reports
Volume: 54
Pages: 1209–1213

Head Matter:
373 F. 2d 1020; 153 USPQ 70
In re William L. Albrecht and Morris Mindick
(No. 7695)
United States Court of Customs and Patent Appeals,
March 16, 1967
Herbert B. Keil (Richard L. Johnson, of counsel) for appellants.
Joseph Schimmel (Raymond E. Martin, of counsel) for the Commissioner of Patents.
[Oral argument November 10,1966, by Mr. Kell and Mr. Martin]
Before Worley, Chief Judge, Rich, Smith, Almqnd, Associate Judges, and William H. Kirkpatrick
Senior District Judge, Eastern District of Pennsylvania, sitting by designation.

Opinion:
Rich, Judge,
delivered the opinion of the court:
This appeal is from a decision of the Patent Office Board of Appeals, adhered to ,on reconsideration, affirming the final rejection of claims 12-22 in application serial No. 81,474, filed January 9, 1961, entitled "Non Aqueous Silica Sols and Method for Preparing Same."
Silica sols are colloidal dispersions of silica particles in water or an organic medium. In the latter, the sols are useful as thickening agents and as water repellants. The organosols can be prepared by heating an aqueous salt-free silica sol under vacuum and slowly adding an alcohol. When the water has been replaced, the vacuum is removed and at least some of the silanol (SiOH) groups on the surface of the silica particles are esterfied with an alcohol.
Appellant's invention requires that the esterfication be effected in the presence of 'hydrogen bonding agents with dipole moments in excess of 3.0 Debye units. These hydrogen bonding agents protect 50-95% of the surface silanol groups from esterification and thereby eliminate precipitation during the critical esterification steps. This improvement makes it possible to convert relatively concentrated aqueous silica sols into non-aqueous sols, i.e., .organosols. The resultant non-aqueous silica sols and their method of preparation are claimed. Claims 12 and 18 are illustrative:
12. A non-aqueous silica sol consisting essentially of, as the continuous phase, a water miscible mono-hydric alcohol having a boiling point greater than 50° C., and as the dispersed phase 20-60% by weight of colloidal, discrete dense particles of salt-free silica which have an average particle diameter of 5-150 millimicrons, and a specific surface area of at least 20m2/g, which silica particles have from about 50% to about 95% of their surface silanol groups hydrogen bonded by an organic water miscible hydrogen bonding agent and from about 5% to about 50% of their surface silanol groups esterfied with the same water miscible alcohol which corresponds to the continuous phase, said hydrogen bonding agent having a dipole moment of at least 3.0 Debye units, and being present in a mol ratio per mol of hydrogen bonded and surface esterified silanol groups of from 10:1 to 1:1.
18. The process of producing a non-aqueous silica sol which comprises the steps of adding an organic water miscible hydrogen bonding agent which has a dipole moment of at least 3.0 Debye units to an aqueous salt-free silica sol -containing from 20% to 60% by weight of silica to form a reaction system, with the amount of hydrogen bonding agent being present in a mol ratio per mol of surface silanol groups present in the silica particles of the silica sol of from 10:1 to 1:1, adding under vacuum to the reaction system a water miscible mono-hydric alcohol in an amount of from 1 to 7 volumes per volume of water present in the aqueous salt-free silica sol, said alcohol having a boiling point greater than 50° O., maintaining said vacuum and heating the reactants under conditions whereby substantially all the water is removed from the reaction system, releasing the vacuum, heating the water miscible alcohol of the formed non-aqueous silica sol containing 20^60% by weight of silica to its reflux temperature at ambient pressure and maintaining said temperature for at least ¼ hour.
The examiner relied on the following references:
Iler, 2,974,105, Mar. 7,1961.
Kirk, 2,383,653, Aug. 28,1945.
The claims were rejected "as unpatentable over Iler in view of Kirk."
Iler discloses somewhat similar sols and methods of preparation. He utilizes as a stabilizer "an alkali of the class consisting nf water-soluble monovalent metal silicates and basic hydroxides of monovalent cations These apparently impart stability and other desirable properties to the non-aqueous silica sols prepared by Iler's processes. They apparently do not give the stability during preparation which permits esterification of concentrated sols. The esterification reactions disclosed are in dilute sols.
Kirk teaches the modification of silicic acid sols with hydrogen bonding agents. Am,ong the advantages recited is increased stability:
I have found that when silicic acid is mixed with an organic hydrogen bonding donor compound it exhibits characteristics unexplainable upon the basis of ordinary chemical reaction and unexpected from a consideration óf the characteristics of the materials mixed. Apparently silicic acid has an acceptor hydrogen atom and forms some type of compound with a hydrogen bonding donor. Among the characteristics of these silicic acid-hydrogen bonding donor combinations is a decreased tendency to precipitate gelatin and an increase in the time required for the sol to be converted to the gel.
Kirk lists about sixty hydrogen bonding donors.
The question is whether it would have been obvious within the meaning of 35 USC 103 to substitute those hydrogen bonding agents of Kirk which have a dipole moment in excess of 3.0 Debye units in the Iler process.
It is agreed by the Patent Office solicitor and appellants that precipitation of silica during the esterification step was an art-recognized problem. It seems to be agreed that this problem persists in the Iler process despite its stabilizers. The only issue before us is whether Kirk's disclosure made obvious appellants' claimed solution of the problem.
The solicitor acknowledges that Kirk's silicic acid sols and ller's silica sols are different but argues that they are "sufficiently closely related that a person skilled in the art would expect that at least some of Kirk's hydrogen bonding donors would render more stable ller's organosols In support of this proposition he points to common generic nomenclature. The solicitor also concedes that the specific purposes for which the hydrogen bonding agents are used are dissimilar. But he urges that each is used for stabilization and that reaction details are, therefore, not controlling. The solicitor further observes that the Patent Office has placed both the Iler and Kirk patents in the same sub-class of the Patent Office classification.
We are hot convinced by these arguments. We would suppose that one skilled in the art would be much more interested in similarity of the compounds than in common nomenclature and in similarity of reaction than in common purpose. We do not think that the stabilization with hydrogen bonding agents of one sol by one reaction would lead him to expect stabilization of a dissimilar sol by another reaction.
Indeed, it appears from the record (and the solicitor's comments at oral argument) that only 11 of the sixty hydrogen bonding agents of Kirk actually effect the necessary stabilization in the Iler process. Only these have been shown to have the requisite dipole moment of at least 3.0 Debye units. The solicitor does not find this determinative, urging that an exferimenter would soon come upon an agent that was effective, particularly if he tried first the compounds disclosed in Kirk'? examples. Essentially the solicitor's position is that one skilled in the art would err in his analysis of the references and presume that all Kirk's agents would work and, in the course of experimentation based on this error would stumble upon some of the 11 hydrogen bonding-agents which do meet appellants' specifications.
As indicated above, we do not think that one skilled in the art would make this error. Nor, even assuming such an error, do we think that a finding of obviousness may be built in this manner upon it. The decision of the board is reversed.