Abstract: An embodiment of a method of stimulating an earth formation includes: disposing a stimulation device at a borehole in an earth formation, the earth formation having been stimulated by an initial stimulation operation; subsequent to the stimulation operation, performing a probe operation configured to cause movement of existing fractures in the formation; and measuring microseismic events occurring in the formation by one or more seismic receivers. The method further includes: identifying one or more target zones in the formation based on the measuring, the one or more target zones exhibiting a reduced micro seismicity relative to another zone in the formation; and designing a re-stimulation operation configured to stimulate the one or more target zones to increase hydrocarbon production from the formation.

Abstract: A method is disclosed of dispersing conductive particles within a polymer. The method includes the steps of providing dry polymer particles, adding conductive material to the dry polymer particles to coat the dry polymer particles, and hot melt pressing the coated polymer particles.

Abstract: An embodiment of a method of stimulating an earth formation includes: disposing a stimulation device at a borehole in an earth formation, the earth formation having been stimulated by an initial stimulation operation; subsequent to the stimulation operation, performing a probe operation configured to cause movement of existing fractures in the formation; and measuring microseismic events occurring in the formation by one or more seismic receivers. The method further includes: identifying one or more target zones in the formation based on the measuring, the one or more target zones exhibiting a reduced micro seismicity relative to another zone in the formation; and designing a re-stimulation operation configured to stimulate the one or more target zones to increase hydrocarbon production from the formation.

Abstract: An improved drainage catheter having one or more inlet holes along the length of the catheter is described whereby the cross-sectional areas of the successive inlet holes decreases, the decrease first occurring at the inlet hole immediately following the most proximal inlet hole. This change in cross-sectional area alters the typical inflow of fluid into the catheter such that a disproportionately high volume of fluid no longer enters the most proximal inlet hole. This decrease in inflow at the most proximal inlet hole results in less deposition of debris within the catheter at that position. With less deposition of debris at this location, the likelihood of complete catheter failure is reduced. A preferred embodiment is described wherein the change in cross-sectional area results in approximately uniform inflow into all inlet holes.

Abstract: A new thermodynamic cycle engine consisting of six events repeated continuously. Event 1 is adiabatic compression of a carrier gas to raise its temperature. Event 2 is liquid Injection into the hot carrier gas near the end of event 1. Event 3 is temperature equalization between the carrier gas and injected liquid with the liquid's full or partial vaporization. Event 4 is adiabatic expansion of the mixture. Event 5 exhausts the mixture. Exhaust should be captured to save and separate the mixture into its components to increase efficiency. Event 6 is the induction of a new charge of carrier gas, bringing the cycle back to initial conditions of event one. This cyclical sequence of six events numbered from any starting point in an engine will be referred to as the RAKH CYCLE Engine. Devices reversing this cycle using compression to concentrate heat, and injecting water to cool the carrier gas are RAKH CYCLE Refrigerators.

Abstract: A thermodynamic cycle consisting of six events repeated continuously. Event 1 is adiabatic compression of a carrier gas to raise its temperature. Event 2 is liquid Injection into the hot carrier gas near the end of event 1. Event 3 is temperature equalization between the carrier gas and injected liquid with the liquid's full or partial vaporization. Event 4 is adiabatic expansion of the mixture. Event 5 exhausts the mixture. Exhaust should be captured to save and separate the mixture into its components to increase efficiency, however, this cycle may be either an open or closed cycle. Event 6 is the induction a new charge of carrier gas, which brings the cycle back to the initial conditions of event one. This cyclical sequence of six events numbered from any starting point will be referred to as the RAKH CYCLE. Engines using it are RAKH engines. Refrigeration machines using it are RAKH refrigerators.

Abstract: An apparatus and method for improving the properties of carbon-containing fly ash through ozonation is described. The apparatus includes a chamber for containing the fly ash and an ozonator that generates an ozone-containing gas. The ozonator supplies the ozone-containing gas such that it enters the chamber with the fly ash and deactivates carbon within the fly ash. Afterwards, the fly ash will have decreased surfactant adsorptivity so that it can be effectively mixed with cement or whatever other materials may require fly ash with passivated carbon.