John Robert Burleson, 54141 Centennial Pl, Crowley, TX 76036

6708761, Mar 23, 2004

Nov 13, 2001

10/010357

Flint R. George - Flower Mound TX
John D. Burleson - Denton TX
Roger L. Schultz - Aubrey TX

Halliburton Energy Services, Inc. - Dallas TX

E21B 1207

166297, 175321, 188376

An apparatus ( ) for absorbing a shock comprises a first tubular member ( ) and a second tubular member ( ) that are slidable positioned relative to one another. A plurality of layers ( ) of energy absorbing members ( ) extend radially from the second tubular member ( ) such that movement of the second tubular member ( ) in a first direction relative to the first tubular member ( ) sequentially deforms the layers ( ) of energy absorbing members ( ). As the layers ( ) are sequentially deformed, a subsequent layer ( ) of energy absorbing members ( ) begins to deform before the previous layer ( ) of energy absorbing members ( ) is completely deformed. The deformation of the energy absorbing members ( ) absorbs the shock.

8393393, Mar 12, 2013

Dec 14, 2011

13/325726

John P. Rodgers - Roanoke TX, US
Marco Serra - Winterthur, CH
Timothy S. Glenn - Dracut MA, US
John D. Burleson - Denton TX, US

Halliburton Energy Services, Inc. - Houston TX

E21B 43/11

166297, 166 551, 175 2, 89 115, 102302

A method of mitigating perforating effects produced by well perforating can include causing a shock model to predict perforating effects for a proposed perforating string, optimizing a compliance curve of at least one proposed coupler, thereby mitigating the perforating effects for the proposed perforating string, and providing at least one actual coupler having substantially the same compliance curve as the proposed coupler. A well system can comprise a perforating string including at least one perforating gun and multiple couplers, each of the couplers having a compliance curve, and at least two of the compliance curves being different from each other. A method of mitigating perforating effects produced by well perforating can include interconnecting multiple couplers spaced apart in a perforating string, each of the couplers having a compliance curve, and selecting the compliance curves based on predictions by a shock model of shock generated by the perforating string.

8397800, Mar 19, 2013

Dec 14, 2011

13/325866

John P. Rodgers - Roanoke TX, US
John D. Burleson - Denton TX, US
Marco Serra - Winterhur, CH
Timothy S. Glenn - Dracut MA, US
Edwin A. Eaton - Grapevine TX, US

Halliburton Energy Services, Inc. - Houston TX

E21B 43/11
E21B 17/07

166 55, 166178, 1662421, 166297, 175 2

A shock de-coupler for use with a perforating string can include perforating string connectors at opposite ends of the de-coupler, a longitudinal axis extending between the connectors, and a biasing device which resists displacement of one connector relative to the other connector in both opposite directions along the longitudinal axis, whereby the first connector is biased toward a predetermined position relative to the second connector. A perforating string can include a shock de-coupler interconnected longitudinally between components of the perforating string, with the shock de-coupler variably resisting displacement of one component away from a predetermined position relative to the other component in each longitudinal direction, and in which a compliance of the shock de-coupler substantially decreases in response to displacement of the first component a predetermined distance away from the predetermined position relative to the second component.

8397814, Mar 19, 2013

Dec 14, 2011

13/325909

John P. Rodgers - Roanoke TX, US
Timothy S. Glenn - Dracut MA, US
Marco Serra - Winterthur, CH
Edwin A. Eaton - Grapevine TX, US
John D. Burleson - Denton TX, US

Halliburton Energy Serivces, Inc. - Houston TX

E21B 43/11
E21B 29/02
E21B 17/02

166297, 166 55, 175 452

A bending shock de-coupler for use with a perforating string can include perforating string connectors at opposite ends of the de-coupler. A bending compliance of the de-coupler may substantially increase between the connectors. A well system can include a perforating string including at least one perforating gun and multiple bending shock de-couplers, each of the de-couplers having a bending compliance, and at least two of the bending compliances being different from each other. A perforating string can include a bending shock de-coupler interconnected longitudinally between two components of the perforating string. A bending compliance of the bending shock de-coupler may substantially decrease in response to angular displacement of one of the components a predetermined amount relative to the other component.

8408286, Apr 2, 2013

Jun 13, 2012

13/495035

John P. Rodgers - Roanoke TX, US
John D. Burleson - Denton TX, US
Marco Serra - Winterthur, CH
Timothy S. Glenn - Dracut MA, US
Edwin A. Eaton - Grapevine TX, US

Halliburton Energy Services, Inc. - Houston TX

E21B 43/11
E21B 17/07

166 55, 166178, 1662421, 166297, 175 2

A shock de-coupler for use with a perforating string can include perforating string connectors at opposite ends of the de-coupler, a longitudinal axis extending between the connectors, and a biasing device which resists displacement of one connector relative to the other connector in both opposite directions along the longitudinal axis, whereby the first connector is biased toward a predetermined position relative to the second connector. A perforating string can include a shock de-coupler interconnected longitudinally between components of the perforating string, with the shock de-coupler variably resisting displacement of one component away from a predetermined position relative to the other component in each longitudinal direction, and in which a compliance of the shock de-coupler substantially decreases in response to displacement of the first component a predetermined distance away from the predetermined position relative to the second component.

2013004, Feb 28, 2013

Jun 11, 2012

13/493327

John P. RODGERS - Roanoke TX, US
Timothy S. GLENN - Dracut MA, US
Marco SERRA - Winterthur, CH
Edwin A. EATON - Grapevine TX, US
John D. BURLESON - Denton TX, US
John H. HALES - Choctaw OK, US

HALLIBURTON ENERGY SERVICES, INC. - Houston TX

E21B 43/116

175 46

A perforating gun can include at least one explosive component, and a shock mitigation device including a shock reflector which indirectly reflects a shock wave produced by detonation of the explosive component. Another perforating gun can include a gun housing, at least one explosive component, and a shock mitigation device in the gun housing. The shock mitigation device can include a shock attenuator which attenuates a shock wave produced by detonation of the explosive component. Yet another perforating gun can include a shock mitigation device with an explosive material which produces a shock wave that interacts with another shock wave produced by detonation of an explosive component in a gun housing.

2013004, Feb 28, 2013

Jun 26, 2012

13/533600

John P. RODGERS - Roanoke TX, US
Timothy S. GLENN - Dracut MA, US
Marco SERRA - Winterthur, CH
Edwin A. EATON - Grapevine TX, US
John D. BURLESON - Denton TX, US
John H. HALES - Choctaw OK, US

HALLIBURTON ENERGY SERVICES, INC. - Houston TX

E21B 43/116
E21B 43/11

175 46, 175 2

A perforating gun can include at least one explosive component, and a shock mitigation device including a shock reflector which indirectly reflects a shock wave produced by detonation of the explosive component. Another perforating gun can include a gun housing, at least one explosive component, and a shock mitigation device in the gun housing. The shock mitigation device can include a shock attenuator which attenuates a shock wave produced by detonation of the explosive component. Yet another perforating gun can include a shock mitigation device with an explosive material which produces a shock wave that interacts with another shock wave produced by detonation of an explosive component in a gun housing.

2013024, Sep 26, 2013

May 15, 2013

13/895032

John P. Rodgers - Keller TX, US
Jeff A. Nelson - Houston TX, US
John D. Burleson - Denton TX, US
Marco Serra - Dinhard, CH
John H. Hales - Frisco TX, US

Halliburton Energy Services, Inc. - Houston TX

E21B 43/11
G06F 17/50

166297, 703 1

A perforation tool assembly is provided. The perforation tool assembly comprises an energy train, a first perforation gun, and a second perforation gun. The energy train comprises a moderator to reduce the speed of propagation of a detonation in a direction parallel to the axis of the perforation tool assembly. The first perforation gun comprises a plurality of explosive charges coupled to a first portion of the energy train. The second perforation gun comprises a plurality of explosive charges coupled to a second portion of the energy train, wherein the second portion of the energy train is coupled to the first portion of the energy train.