Robert Eugene Mcdaniel
Engineers at Lamar, Houston, TX

6406789, Jun 18, 2002

May 22, 2000

09/486144

Robert R. McDaniel - Houston TX
Johannes A. Geraedts - Roggel, NL

Borden Chemical, Inc. - Columbus OH

B32B 516

428402, 166295, 427136, 427181, 427195, 427197, 427198, 427215, 427221, 427222, 427244, 4273855, 4273897, 4273935, 4273936, 4273977, 427421, 427424, 4274301, 4274432, 428407, 428426, 428429, 428447, 428448, 428451, 428454, 428524, 428688, 428689, 428702, 428704, 523130, 523131, 523132, 523139, 523145, 523205, 523206

Composite particles made of a resin and filler material are provided for use in subterranean formations. The filler is finely divided mineral and optional fiber. The particles are proppants useful to prop open subterranean formation fractures. The particles are also useful for water filtration. Methods of making the composite particles are also disclosed.

8096355, Jan 17, 2012

May 6, 2009

12/436217

Robert R. McDaniel - Houston TX, US
Michael Lynn Sheriff - Plano TX, US
Eric E. Funk - Ouray CO, US
Ethan A. Funk - Ouray CO, US

Momentive Specialty Chemicals Inc. - Columbus OH

E21B 49/00

1662501

Radar ranging data are collected from a down hole tool at various depths in a fractured well bore, and analyzed to provide a profile of the length of each wing of the fracture as a function of depth. The height of the fracture is determined from the vertical positions where the fracture is just observed or no longer observed as the tool is raised or lowered. For consecutive depths along the fracture (and for selected elevations from each depth for the case of a switchable antenna beam), reflection intensity as a function of range is measured. Simulated radar data are computed from a fracture model having the height of the fracture begin measured. The fracture model is varied and the resulting simulated data are correlated with the survey data until a match of minimal error is determined.

7424911, Sep 16, 2008

Oct 4, 2005

11/242745

Scott M. McCarthy - Fulshear TX, US
Robert R. McDaniel - Houston TX, US
Michael L. Sheriff - Plano TX, US
James E. Flowers - Dallas TX, US

Hexion Specialty Chemicals, Inc. - Columbus OH

E21B 47/00

16625012, 1662501, 1662801, 1662802

Disclosed herein is a method of determining the fracture geometry of a subterranean fracture comprising introducing into the fracture a target particle and/or proppant; transmitting into the fracture electromagnetic radiation having a frequency of about 300 megahertz to about 100 gigahertz; and analyzing a reflected signal from the target particle to determine fracture geometry. Disclosed herein too is a method of determining the fracture geometry of a subterranean fracture comprising introducing into the fracture a target particle and/or proppant; wherein the target particle and/or proppant comprises a high dielectric constant ceramic having a dielectric constant of greater than or equal to about 2; transmitting into the fracture electromagnetic radiation having a frequency of less than or equal to about 3 gigahertz; and analyzing a reflected signal from the target particle and/or proppant to determine fracture geometry.

7450053, Nov 11, 2008

Sep 13, 2006

11/520234

Eric E. Funk - Ouray CO, US
Ethan A. Funk - Ouray CO, US
Michael L. Sheriff - Plano TX, US
Scott M. McCarthy - Fulshear TX, US
Robert R. McDaniel - Houston TX, US

Hexion Specialty Chemicals, Inc. - Columbus OH

G01V 3/30, G01V 3/18, G01V 3/00, G01S 13/00

342 22, 342 27, 342 52, 342 54, 342175, 342195, 3408531, 3408543, 3408546, 3408547, 324323, 324332, 324333, 324334, 324337, 324338, 324344

A logging radar system and method for measuring propped fractures and down-hole formation conditions in a subterranean formation including: a radar source; an optical source; an optical modulator for modulating an optical signal from the optical source according to a signal from the radar source; a photodiode for converting the modulated optical signal output from the optical modulator to the source radar signal; a transmitter and receiver unit; and a mixer. The transmitter and receiver unit receives the source radar signal from the photodiode, transmits the source radar signal into the formation and receives a reflected radar signal. The mixer mixes the reflected radar signal with the source radar signal to provide an output. This technology can be used to describe all fractures connected to the wellbore and differentiate between the dimensions of the two vertical wings of a propped fracture.

7598898, Oct 6, 2009

Sep 13, 2006

11/520229

Eric E. Funk - Ouray CO, US
Ethan A. Funk - Ouray CO, US
Michael L. Sheriff - Plano TX, US
Scott M. McCarthy - Fulshear TX, US
Robert R. McDaniel - Houston TX, US

Hexion Specialty Chemicals, Inc. - Columbus OH

G01S 13/88, G01V 3/30, G01V 3/18

342 22, 342 54, 342175

A logging radar system and method for measuring propped fractures and down-hole formation conditions in a subterranean formation including: a radar source; an optical source; an optical modulator for modulating an optical signal from the optical source according to a signal from the radar source; a photodiode for converting the modulated optical signal output from the optical modulator to the source radar signal; a transmitter and receiver unit; and a mixer. The transmitter and receiver unit receives the source radar signal from the photodiode, transmits the source radar signal into the formation and receives a reflected radar signal. The mixer mixes the reflected radar signal with the source radar signal to provide an output. This technology can be used to describe all fractures connected to the wellbore and differentiate between the dimensions of the two vertical wings of a propped fracture.

7624802, Dec 1, 2009

Mar 22, 2007

11/726573

Avis Lloyd McCrary - Montgomery TX, US
Michael Anthony Barajas - Houston TX, US
Robert Ray McDaniel - Houston TX, US

Hexion Specialty Chemicals, Inc. - Columbus OH

E21B 43/267, E21B 43/247, E21B 43/04

1662802, 1662722, 166278, 166281, 166288, 1663083, 427221, 428407

Disclosed herein are free flowing coated particles and low temperature methods of making same. Each particle has a curable coating disposed upon a substrate. The substrate is a particulate substrate including an inorganic material, a particulate substrate including an organic material, a composite substantially homogeneous formed particle including a first portion of an at least partly cured binder and filler particles, or a hybrid particle having an inorganic particle as a core and a composite coating including at least partially cured resin and filler. The curable coating includes a continuous phase including resole resin and reactive powder particles embedded or adhered to the continuous phase. The reactive powder particles typically include resole resin, novolak resin, polyester, acrylic and/or urethane. A method including applying a coating including the continuous phase including resole resin and reactive or non-reactive powder particles embedded or adhered to the continuous phase.

2012013, May 31, 2012

Feb 2, 2012

13/364848

Robert R. McDaniel - Houston TX, US
Scott M. Mccarthy - Fulshear TX, US
Michael Smith - Montgomery TX, US

C09K 8/92, C09K 8/80

507220, 507270, 507219, 507224

Disclosed herein is a method comprising disposing in a formation fracture, a proppant and/or a fracturing fluid that comprises a radiation susceptible material that comprises indium and/or vanadium; irradiating the radiation susceptible material with neutrons; measuring gamma-radiation emitted from the radiation susceptible material in a single pass; wherein the single pass does not involve measuring of background radiation from previous or subsequent logging passes; and determining formation fracture height from the measured gamma-radiation.

8129318, Mar 6, 2012

May 27, 2010

12/789094

Robert R. McDaniel - Houston TX, US
Scott M. McCarthy - Fulshear TX, US
Michael Smith - Montgomery TX, US

Momentive Specialty Chemicals Inc. - Columbus OH

C23F 11/18

507271, 507270, 250253, 250260

Disclosed herein is a method comprising disposing in a formation fracture, a proppant and/or a fracturing fluid that comprises a radiation susceptible material that comprises indium and/or vanadium; irradiating the radiation susceptible material with neutrons; measuring gamma-radiation emitted from the radiation susceptible material in a single pass; wherein the single pass does not involve measuring of background radiation from previous or subsequent logging passes; and determining formation fracture height from the measured gamma-radiation.