William Bernard Krantz
Engineers at Laguna Pl No 304, Boulder, CO

6387334, May 14, 2002

Dec 18, 1998

09/216268

William B. Krantz - Boulder CO
David E. Earls - Pinole CA
Harold J. Trimble - Panama City Beach FL
Julie Chabot - Novato CA
Krishniah Parimi - Concord CA

Chevron U.S.A. Inc. - San Francisco CA

B01J 808

422143, 422220, 422311

The invention comprises an OCR catalyst reactor which includes passive spheres and catalyst particles having substantially the same size and separated on opposite sides of a distributor cone by a screen. The use of passive spheres of substantially the same size to the catalyst particles provides for a more uniform distribution of the gas liquid reactants charged into the reactor vessel. The screen is configured such that it provides a separation of the catalyst and the passive spheres while being sized to prevent plugging.

2013004, Feb 21, 2013

May 2, 2011

13/695251

Alan R. Greenberg - Boulder CO, US
William B. Krantz - Boulder CO, US
Elmira Kujundzic - Erie CO, US
Adrian Yeo - Singapore, SG
Seyed Saeid Hosseini - Singapore, SG

NATIONAL UNIVERSITY OF SINGAPORE - Singapore

G01N 15/08

73 38

A method for determination of pore-size distribution in a porous material called evapo porometry (EP) is capable of determining pore sizes from approximately the nanometer scale up to the micron scale. EP determines the pore size based on the evaporative mass loss at constant temperature from porous materials that have been pre-saturated with either a wetting or non-wetting volatile liquid. The saturated porous material is placed in an appropriate test cell on a conventional microbalance to measure liquid mass loss at a constant temperature as a function of time. The mass-loss rate is then related to the pore-size distribution. The microbalance permits measuring the mass as a function of time. The slope of the mass versus time curve is the evaporation rate. The evaporation rate is related to the vapor pressure at the interface between the liquid in the porous material and the ambient gas phase. The vapor pressure in turn is related to the pore diameter.

6161435, Dec 19, 2000

Jul 21, 1999

9/358733

Leonard J. Bond - Richmond WA
Guo Yong Chai - Boulder CO
Alan Richard Greenberg - Boulder CO
William Bernard Krantz - Boulder CO

University Technology Corporation - Boulder CO

G01D 700, B01D 1706, B01D 3300

73587

The fouling state of a polymeric membrane within the high pressure housing of a spiral wound or a hollow fiber membrane module is determined. An ultra sonic transducer positioned with its emitting face in physical engagement with the outer surface of the housing is pulse energized by a pulser/receiver device. A membrane echo signal is detected by a receiver of the pulser/receiver device. A reference echo signal indicative of a fouled or an unfouled state of the membrane is compared to the echo signal to determine the membrane fouling state. The echo to reference comparing step can be based upon comparing amplitude domain signals, comparing time-domain signals, comparing combinations of amplitude domain and time-domain signals, and comparing transformations of amplitude domain and time-domain signals. A clean or a fouled reference echo can be provided from a clean or a fouled membrane and then stored for use during a liquid separation process, or a clean reference echo signal can be obtained on-line from a second transducer whose echo signal is derived from an area of the membrane known to remain relatively unfouled during the liquid separation process, or a clean or fouled reference echo signal can be provided for later use during a cleaning process or during a liquid separation process. Multiple transducers and a switching network can sample the fouling state at different positions within the membrane module.

5626759, May 6, 1997

Aug 1, 1994

8/284057

William B. Krantz - Boulder CO
Robert R. Bilodeau - Old Towne ME
Roger J. Elgas - Lakewood CO
Marc E. Voorhees - Arvada CO

Regents of the University of Colorado - Boulder CO

A61M 114, B01D 6100, C02F 144

210645

A medical device and method for affecting mass transfer between blood and a fluid. In one application, this mass transfer is an oxygenation of the blood. Generally, a membrane which separates the blood and fluid is moved in a predetermined manner and in a direction which is substantially parallel to that of the primary direction of the flow to augment the mass transfer efficiency/rate. Importantly, this movement of the membrane is relative to the blood mass transfer boundary layer which steepens or increases the oxygen concentration gradient and decreases the thickness of the blood mass transfer boundary layer and thereby improves upon the mass transfer efficiency/rate of oxygen into the blood.

4755297, Jul 5, 1988

Nov 14, 1986

6/931328

Bruce A. Nerad - Longmont CO
William B. Krantz - Boulder CO

University Patents, Inc. - Westport CT

B01D 1300

210637

A reverse osmosis membrane process or hybrid membrane - complementary separator process for producing enriched product or waste streams from concentrated and dilute feed streams for both solvent/solvent and solute/solvent systems is described.