Abstract: Electrically ignitable and electrically controllable explosive material (EIECEM) may be disposed within a shaped charge for deployment downhole. An explosion of the EIECEM is controlled by limiting the duration of excitation at the EIECEM, for example, the duration that an electrical source provides an electrical charge, electrical current or electrical signal. The shaped charge may be insulated from an electrical source to prevent explosion of the EIECEM and coupled to the electrical source to create ignite or explode the EIECEM. A plurality of shaped charges may be disposed downhole and may be ignited or exploded in any suitable order. The EIECEM may be ignited multiple times such that multiple explosions are created. The explosion of the EIECEM creates or extends a perforation or fracture in a formation. The perforation or fracture (or cavity) may be filled by a fluid to repair or plug and abandon a well.

Abstract: The present disclosure relates generally to well site operations and, more particularly, to the capture and recovery of exhaust gas from machinery located and operated at a well site. Exhaust gas comprising carbon dioxide is captured, absorbed or reacted with amine sources, and separated for reuse or further processed for use in subterranean formation operations, such as hydraulic fracturing operations.

Abstract: Methods including providing a hydrajetting tool comprising a housing having a top end and a bottom end and having a plurality of jetting nozzles disposed thereon, the top end of the housing fluidly coupled to a tool string; providing at least one sub-soil-surface cavity adjacent to or in unstable soil, the unstable soil having a plurality of channels therein; introducing the hydrajetting tool into the at least one sub-soil-surface cavity; injecting a cement slurry through at least one of the jetting nozzles and into the sub-soil-surface cavity; permeating the cement slurry into the plurality of channels in the unstable soil; filling the at least one sub-soil-surface cavity with the cement slurry; and curing the cement slurry, thereby forming a stable soil and a cement pillar in the at least one sub-soil-surface cavity.

Abstract: In accordance with presently disclosed embodiments, a collapsible and optionally stackable storage container for bulk material is provided. The disclosed storage container includes a collapsible frame defined by a rigid upper support structure, a rigid lower support structure and a support member coupled at one end to the upper support structure and coupled at another end to the lower support structure. An actuator is also provided which is coupled to the support member at one end. The disclosed storage container further includes a storage sack having an upper portion coupled to the upper support structure and a lower portion coupled to the lower support structure. The lower portion of the storage sack is generally taper-shaped and may be equipped with a discharge opening that enables release of the bulk material onto a conveyor, which may be employed when the collapsible storage container is integrated into a bulk storage system.

Abstract: A system for determining characteristics of a fracture can include electromagnetic sensors and a pressure sensor. The electromagnetic sensors can be positioned in a wellbore having a perforation to determine an amount of flow traversing the perforation into a fracture zone. The electromagnetic sensors can include a first electromagnetic sensor positioned in a first segment of the wellbore that is closer than the perforation to a surface of the wellbore. The electromagnetic sensors can also include a second electromagnetic sensor that is positioned in a second segment of the wellbore that is farther than the perforation from the surface of the wellbore. The pressure sensor can be positioned in the wellbore for detecting a pressure wave generated by the flow. The pressure wave and the amount of the flow traversing the perforation can be used to determine a characteristic of a fracture in the fracture zone.

Abstract: In downhole tools and methods related to stimulation of subterranean formations are provided. The tools and methods utilize electrically ignitable propellant to generate gas downhole that is used to generate or enhance fractures. The electrically ignitable propellant can be ignited applying electrical power to a pair of electrodes associated with the propellant. Subsequently, the ignition can be halted by ceasing to supply the electrical power. Thus, allowing for the control of the amount and location of generated gas.

Abstract: In accordance with embodiments of the present disclosure, systems and methods for using containers of bulk material along with a bucket conveyor system, instead of a pneumatic transfer process, to move the bulk material from a transportation unit to a storage/delivery system are provided. A transportation unit may deliver one or more containers full of bulk material toward a fill hopper of the bucket conveyor system. The containers may be positioned proximate the fill hopper to release the bulk material directly into the fill hopper. The bucket conveyor may deliver the bulk material from the fill hopper into the storage/delivery system. Since the containers are maneuverable into a position to output bulk material directly into the fill hopper and without pneumatic transfer, the bucket conveyor system may enable a cleaner and more efficient bulk material transfer at the site.

Abstract: Systems and methods of the present disclosure may use mechanically excitable elements and electrically ignitable fluid to generate a fracture map usable to determine a characteristic of a fracture in a subterranean formation. The mechanically excitable elements may include piezoelectric material positioned in the fracture to generate electrical pulses in response to the fracture closing onto the mechanically excitable elements. The electrical pulses may ignite the electrically ignitable fluid causing an explosion of the fluid that may be detectable by microseismic sensors of a microseismic system. The microseismic system may determine the location of each explosion and use the locations to generate the fracture map.

Abstract: Methods and apparatus are disclosed for mixing proppant and other solids with one or more fracturing fluids to form a fracturing slurry, and for delivering the fracturing slurry to a wellbore. In the example systems as described herein, the proppant is mixed with the fracturing fluids through an assembly that limits the number of pumps that are required to move the relatively abrasive proppant]containing fluids. Additionally, in the example systems, the proppant is mixed within enclosed structures, thereby minimizing the escape of dust and other particulates into the surrounding atmosphere and onto the equipment at the well site.

Abstract: In accordance with presently disclosed embodiments, systems and methods for efficiently managing bulk material are provided. The disclosure is directed to systems and methods for efficiently combining additives into bulk material being transferred about a job site. The systems may include a support structure used to receive one or more portable containers of bulk material, and a mulling device disposed beneath the support structure to provide bulk material treatment capabilities. Specifically, the mulling device may facilitate mixing of coatings or other additives with bulk material that is released from the portable containers, as well as transfer of the mixture to an outlet location.

Abstract: In accordance with presently disclosed embodiments, a method for creating vertical mini-holes in a subterranean formation while creating multi-directional Bernoulli-induced factures therein is provided. The method is particularly useful in horizontal or deviated wells. The method includes forming a mini-hole in the subterranean formation perpendicular to the deviated wellbore. The mini-hole is in fluid communication with the deviated wellbore at a proximal end and has a tip located at a distal end. The method further includes injecting fluid into the mini-hole with a maximum pressure forming at the tip so as to initiate a fracture along local formation stresses proximate the tip of the mini-hole.

Abstract: In accordance with presently disclosed embodiments, a collapsible and optionally stackable storage container for bulk material is provided. The disclosed storage container includes a collapsible frame defined by a rigid upper support structure, a rigid lower support structure and a support member coupled at one end to the upper support structure and coupled at another end to the lower support structure. An actuator is also provided which is coupled to the support member at one end. The disclosed storage container further includes a storage sack having an upper portion coupled to the upper support structure and a lower portion coupled to the lower support structure. The lower portion of the storage sack is generally taper-shaped and may be equipped with a discharge opening that enables release of the bulk material onto a conveyor, which may be employed when the collapsible storage container is integrated into a bulk storage system.

Abstract: A multi-oriented hydraulic fracturing (MOHF) model may incorporate the pseudo-plastic properties of the formation and tiny tectonic motions from fracturing to enhance MOHF operations.

Abstract: In accordance with presently disclosed embodiments, systems and methods for using containers, instead of pneumatic transfer, to move bulk material from a transportation unit to a blender receptacle of a blender are provided. A transportation unit may deliver one or more containers of bulk material to the well site, where one or more conveyors may deliver the containers to a location proximate the blender receptacle. A chute may extend from the bottom of each container to route bulk material from the one or more containers directly into the blender receptacle. Since the transportation unit is able to unload the containers of bulk material without pneumatic transfer, the containers may enable a cleaner and more efficient bulk material transfer at the site.

Abstract: In accordance with embodiments of the present disclosure, systems and methods for using containers of bulk material along with a bucket conveyor system, instead of a pneumatic transfer process, to move the bulk material from a transportation unit to a storage/delivery system are provided. A transportation unit may deliver one or more containers full of bulk material toward a fill hopper of the bucket conveyor system. The containers may be positioned proximate the fill hopper to release the bulk material directly into the fill hopper. The bucket conveyor may deliver the bulk material from the fill hopper into the storage/delivery system. Since the containers are maneuverable into a position to output bulk material directly into the fill hopper and without pneumatic transfer, the bucket conveyor system may enable a cleaner and more efficient bulk material transfer at the site.

Abstract: In accordance with presently disclosed embodiments, systems and methods for using containers, instead of pneumatic transfer, to move bulk material from a transportation unit to a blender receptacle (e.g., hopper or mixer of a blender) are provided. A transportation unit may deliver multiple containers of bulk material to the well site, where multiple conveyors may deliver the containers to a location proximate the blender receptacle. Openings at the bottom of the containers are arranged adjacent one another so that the load of two containers may be delivered to the tight space occupied by the blender receptacle. Since the transportation unit is able to unload the containers of bulk material without pneumatic transfer, the containers may enable a cleaner and more efficient bulk material transfer at the site.

Abstract: In accordance with presently disclosed embodiments, systems and methods for managing bulk material efficiently at a well site are provided. The disclosure is directed to a container support frame that is integrated into a blender unit. The support frame is used to receive one or more portable containers of bulk material, and the blender unit may include a gravity feed outlet for outputting bulk material from the containers directly into a mixer of the blender unit. The blender unit with integrated support frame may eliminate the need for any subsequent mechanical conveyance of the bulk material (e.g., via a separate mechanical conveying system or on-blender sand screws) from the containers to the mixer. As such, the integrated blender unit may be lighter weight, take up less space, and have a lower cost and complexity than existing blenders.

Abstract: Systems and methods for placing proppant in a portion of a subterranean formation (e.g., in a fracturing operation) using two or more immiscible fluids are provided. In certain embodiments, the methods comprise: introducing into a well bore penetrating a portion of a subterranean formation alternating stages of a first treatment fluid comprising one or more proppants, and a second treatment fluid comprising a lesser concentration of proppants than the first fluid, wherein the first fluid and the second fluid are substantially immiscible in one another, and wherein the alternating stages of the first and second treatment fluids are introduced into the well bore at or above a pressure sufficient to create or enhance one or more fractures in the subterranean formation.

Abstract: In accordance with presently disclosed embodiments, systems and methods for using one or more pre-filled, portable containers, instead of pneumatic transfer, to move bulk material from a transportation unit to a blender receptacle of a blender are provided. A transportation unit may deliver one or more containers of bulk material to the well site, where the containers may be disposed in an elevated position around the blender receptacle. A gravity feed outlet may extend from one or more containers to route bulk material from the one or more containers directly into the blender receptacle. Since the transportation unit is able to unload the portable containers of bulk material without pneumatic transfer, the stackable containers may enable a cleaner and more efficient bulk material transfer at the site.

Abstract: Well systems including a wellbore lined with a wellbore lining and a pressure booster extendable within the wellbore on a conveyance whereby an annulus is defined between the conveyance and the wellbore lining. The pressure booster includes a body having a first end coupled to the conveyance, a jetting chamber defined within the body, one or more flow ports defined in the body and providing fluid communication between the jetting chamber and the annulus, and a jet nozzle in fluid communication with the conveyance. The pressure booster receives a first fluid through the conveyance and a second fluid from the annulus and mixes the first and second fluids to discharge a fracturing fluid below the pressure booster at a pressure greater than a pressure within the annulus above the pressure booster.