Norman Michael Culp from 1002 Walnut Pointe, League City, TX 77573, age 54, Phone: 2815571676

Resumes

Project Engineer V At Jacobs Engineering

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Position:

Sr. Project Engineer V at Jacobs

Location:

Houston, Texas Area

Industry:

Oil & Energy

Work:

Jacobs - Houston, Texas Area since Jul 2012
Sr. Project Engineer V
Champion Technologies - Fresno, Texas Jul 2011 - Jul 2012
GBU Central Engineering Manager
Dixie Chemical Co. Jan 2010 - Aug 2011
Director of Engineering, Maintenance & Reliability
Jacobs Engineering 2006 - Jan 2010
Sr. Project Engineer/Manager
BEI Engineers 2005 - 2006
Sr. Project Engineer

Education:

Colorado State University 1993 - 1996
B.S., Chemical Engineering Texas A&M University 1990 - 1992

Skills:

Project Engineering
Process Engineering
Petrochemical
Process Simulation
Engineering
Petroleum
Chemical Engineering
EPC
Refinery
Factory
P&ID
Refining
Process Control
Commissioning
Manufacturing
Instrumentation
Gas Processing
Engineering Management
Contract Management
Automation
Project Management

Honor & Awards:

TAP Award for work on IPOH project (Lyondell - 2008) Dale Carnegie - Top Performer Award (2009) Multiple Client Recognitions both Lyondel and BP (BP Shining Star Award, 2008)

Norman Culp

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Location:

Houston, TX

Industry:

Security And Investigations

Work:

Dallas Microelectronics
President
Texas Instruments Aug 2005 - Sep 2006
Dmts
Texas Instruments 2003 - 2005
Distinguished Member of the Technical Staff
Benchmarq Microelectronics Oct 1997 - Jan 1999
Engineer

Education:

Trine University 1961 - 1965
Bachelors, Bachelor of Science In Electrical Engineering

Skills:

Analog Design
Mixed Signal
Power Management
Analog
Ic
Cmos
Analog Circuit Design
Electronics
Semiconductors
Circuit Design
Asic
Eda
Soc
Hardware Architecture
Digital Signal Processors
Verilog
Cadence Virtuoso
Spice
Simulations
Embedded Systems
Pcb Design
Semiconductor Industry
Rf
Debugging
Fpga
Integrated Circuit Design
Sensors
Power Electronics
Vhdl

Engineering Manager

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Location:

5211 Pilgrim Oaks Ln, League City, TX 77573

Industry:

Oil & Energy

Work:

Jacobs Feb 2017 - Apr 2019
Project Engineering Manager
Ineos Oxide Limited Feb 2017 - Apr 2019
Engineering Manager
Nalco Champion, An Ecolab Company Jul 2011 - Jul 2012
Global Supply Chain Engineering Manager
Dixie Chemical Co. Jan 2010 - Aug 2011
Director of Engineering, Maintenance, and Reliability
Jacobs May 2006 - Feb 2010
Senior Project Engineer and Manager

Education:

Colorado State University 1993 - 1996
Bachelors, Bachelor of Science, Chemical Engineering Texas A&M University 1990 - 1992

Skills:

Engineering
Process Engineering
Refinery
Project Engineering
Epc
Factory
Petrochemical
Project Management
Feed
Contract Management
Petroleum
Manufacturing
Gas
Inspection
Engineering Design
Commissioning
Piping
Oil and Gas
Materials
Engineering Management
Energy Industry
Chemical Engineering
Process Control
Project Control
Instrumentation
Pipelines
Process Simulation
Hazop
Oil/Gas
P&Id
Onshore
Refineries
Root Cause Analysis
Pumps
Process Safety
Refining
Downstream Oil and Gas
Upstream
Primavera P6
Gas Processing
Automation
Dcs
Capital Projects
Lng
Process Optimization
Safety Management Systems
Maintenance Management
Oil and Gas Industry
Plant Design
Oil

Interests:

Science and Technology
Social Services
Children
Disaster and Humanitarian Relief

Certifications:

Project Management Professional (Pmp)

Norman Culp

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Location:

Houston, TX

Industry:

Semiconductors

Us Patents

Dc/Dc Power Converter
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US Patent:

7400064, Jul 15, 2008
Filed:

Apr 22, 2005
Appl. No.:

11/112266
Inventors:

Siew Kuok Hoon - Dallas TX, US
Norman L. Culp - Montgomery TX, US
Jun Chen - Allen TX, US
Franco Maloberti - Torre D'Isola, IT
Assignee:

Texas Instruments Incorporated - Dallas TX
International Classification:

H02J 1/00
G05F 1/56
H02M 3/335
US Classification:

307 39, 307 31, 323284, 363 2111, 363 2117, 363 2118, 363 25
Abstract:

A switching regulation system and control scheme efficiently enables driving multiple loads from a common energy storage element, such as an inductor. The control scheme operates to store energy in the energy storage element over a first portion of a cycle, such as by ramping up current through an inductor, according to energy requirements of the multiple loads. After storing the energy in the storage element during the first portion of the cycle, the stored energy is delivered consecutively to each of the multiple loads over a subsequent portion of the cycle.

Battery Charger And System And Method For Use Of Same
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US Patent:

20140042959, Feb 13, 2014
Filed:

Oct 16, 2012
Appl. No.:

13/653244
Inventors:

Norman L. Culp - Montgomery TX, US
International Classification:

H02J 7/00
US Classification:

320107, 320162
Abstract:

A battery charger and system and method for use of the same are disclosed for increasing a charge of a battery. In one embodiment of the battery charger, an input for an electric charging power source is configured to supply electrical charging power to a rechargeable battery via an output circuit portion interposed therebetween. A transfer function circuit portion is configured to sense the voltage of the rechargeable battery as a sensing voltage such that the change in the sensing voltage is directly proportional to the internal impedance of the rechargeable battery. A control logic circuit portion is configured to select between a constant current, variable voltage operational mode, a constant current, scalable voltage operational mode, and a variable current, constant voltage operational mode to furnish rapid recharging of the rechargeable battery.

Battery Charger And System And Method For Use Of Same
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US Patent:

20140042960, Feb 13, 2014
Filed:

Aug 8, 2013
Appl. No.:

13/962661
Inventors:

Norman L. Culp - Montgomery TX, US
International Classification:

H02J 7/00
US Classification:

320107, 320162
Abstract:

A battery charger and system and method for use of the same are disclosed for increasing a charge of a battery. In one embodiment of the battery charger, an input for an electric charging power source is configured to supply electrical charging power to a rechargeable battery via an output circuit portion interposed therebetween. A transfer function circuit portion is configured to sense the voltage of the rechargeable battery as a sensing voltage such that the change in the sensing voltage is directly proportional to the internal impedance of the rechargeable battery. A control logic circuit portion is configured to select between a constant current, variable voltage operational mode, a constant current, scalable voltage operational mode, and a variable current, constant voltage operational mode to furnish rapid recharging of the rechargeable battery.