Hisako Kurebayashi from Charlottesville, VA, age 55

Hisako Kurebayashi Phones & Addresses

Charlottesville, VA
541 Bridge St APT 305, Danville, VA 24541
Griffin, GA
Raleigh, NC

Work

Company:

Virdia
2011
Position:

Process engineer

Education

Degree:

B.S.
School / High School:

North Carolina State University
2007 to 2010
Specialities:

Chemical Engineering

Skills

Process Engineering • Chemical Engineering • Process Optimization • Catalysis • R&D • Chromatography • Factory • Process Improvement • P&Id • Purification • Instrumentation • Validation • Management • Commissioning • Design of Experiments • Technology Transfer • Ssmb Chromatography • Biomass Deconstruction • Sugar Purification • Matlab • Spc

Languages

English • Japanese

Industries

Renewables & Environment

Resumes

Process Engineer

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Location:

Atlanta, GA

Industry:

Renewables & Environment

Work:

Virdia since 2011
Process engineer
Henkel 2010 - 2010
Intern
NCSU Chemical Engineering Dept Aug 2009 - May 2010
Undergraduate Research Assistant
YAZAKI Co Sep 2000 - Dec 2004
Supply Chain Analyst

Education:

North Carolina State University 2007 - 2010
B.S., Chemical Engineering Harrisburg Area Community College 2005 - 2007
Associate degree, Engineering

Skills:

Process Engineering
Chemical Engineering
Process Optimization
Catalysis
R&D
Chromatography
Factory
Process Improvement
P&Id
Purification
Instrumentation
Validation
Management
Commissioning
Design of Experiments
Technology Transfer
Ssmb Chromatography
Biomass Deconstruction
Sugar Purification
Matlab
Spc

Languages:

English
Japanese

Us Patents

Processes For Producing High-Viscosity Compounds As Rheology Modifiers, And Compositions Produced Therefrom
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US Patent:

20190185730, Jun 20, 2019
Filed:

Jul 13, 2018
Appl. No.:

16/034845
Inventors:

- Minnetrista MN, US
Hisako KUREBAYASHI - Griffin GA, US
International Classification:

C09K 8/035
C08B 37/00
C09K 8/62
C04B 28/02
C08B 15/00
C09K 8/90
C09K 8/68
C08H 8/00
Abstract:

A process is provided for producing a biomass-derived rheology modifier, comprising: providing a pretreated feedstock comprising cellulose-rich solids; refining the cellulose-rich solids in a first high-intensity refining unit, generating refined cellulose solids; gelling the refined cellulose solids in a second high-intensity refining unit, thereby generating gelled cellulose solids; and homogenizing the gelled cellulose solids in a high-shear homogenizer, thereby generating a biomass-derived rheology modifier. The pretreated feedstock may include kraft pulp, sulfite pulp, AVAP pulp, soda pulp, mechanical pulp, thermomechanical pulp, and/or chemimechanical pulp, derived from wood or lignocellulosic biomass. The pretreated feedstock may be GP3+ pulp, obtained from steam or hot-water extraction of lignocellulosic biomass. These rheology modifiers may be utilized in a wide variety of applications, including water-based or oil-based hydraulic fracturing fluid formulations, as gelling agents. These rheology modifiers are biodegradable, and their production does not directly involve chemicals other than biomass and water.

Processes For Producing High-Viscosity Compounds As Rheology Modifiers, And Compositions Produced Therefrom
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US Patent:

20170183554, Jun 29, 2017
Filed:

Aug 4, 2016
Appl. No.:

15/228070
Inventors:

- Atlanta GA, US
Hisako KUREBAYASHI - Griffin GA, US
International Classification:

C09K 8/035
C08B 15/00
C09K 8/62
Abstract:

A process is provided for producing a biomass-derived rheology modifier, comprising: providing a pretreated feedstock comprising cellulose-rich solids; refining the cellulose-rich solids in a first high-intensity refining unit, generating refined cellulose solids; gelling the refined cellulose solids in a second high-intensity refining unit, thereby generating gelled cellulose solids; and homogenizing the gelled cellulose solids in a high-shear homogenizer, thereby generating a biomass-derived rheology modifier. The pretreated feedstock may include kraft pulp, sulfite pulp, AVAP pulp, soda pulp, mechanical pulp, thermomechanical pulp, and/or chemimechanical pulp, derived from wood or lignocellulosic biomass. The pretreated feedstock may be GP3+ pulp, obtained from steam or hot-water extraction of lignocellulosic biomass. These rheology modifiers may be utilized in a wide variety of applications, including water-based or oil-based hydraulic fracturing fluid formulations, as gelling agents. These rheology modifiers are biodegradable, and their production does not directly involve chemicals other than biomass and water.

Hisako Kurebayashi