Abstract: A liner (18) for a shaped-charge (10) that is compressively formed from a mixture of powdered metal, powdered metal binder, and a selected quantity of nanoparticle material, is used to achieve improved penetration depths during perforation of a wellbore. Exemplary nanoparticles include lead, tin, copper, molybdenum, etc. Such nanoparticles increase the density, sound speed, or acoustic impedance of the liner. In another embodiment, the added nanoparticles comprise reactive materials which, after penetration into the formation, cause secondary reactions in the perforations.

Abstract: A liner (18) for a shaped-charge (10) that is compressively formed from a mixture of powdered metal, powdered metal binder, and a selected quantity of nanoparticle material, is used to achieve improved penetration depths during perforation of a wellbore. Exemplary nanoparticles include lead, tin, copper, molybdenum, etc. Such nanoparticles increase the density, sound speed, or acoustic impedance of the liner. In another embodiment, the added nanoparticles comprise reactive materials which, after penetration into the formation, cause secondary reactions in the perforations.

Abstract: A non-destructive inspection method that comprises obtaining one or more images corresponding to an X-ray, scanning electron microscope, or CT scan of an object, assigning numeric values to pixels of the images, comparing the numeric values to reference numeric values, and identifying an anomaly in the object based on the comparison. A non-destructive inspection system that comprises at least one processor, a memory in communication with the processor and storing instructions that causes the processor to obtain an image corresponding to an X-ray, scanning electron microscope, or CT scan of an object, assign numeric values to pixels of the image, compare the assigned numeric values to reference numeric values, and identify an anomaly in the object based on the comparison.

Abstract: A non-destructive inspection method that comprises obtaining one or more images corresponding to an X-ray, scanning electron microscope, or CT scan of an object, assigning numeric values to pixels of the images, comparing the numeric values to reference numeric values, and identifying an anomaly in the object based on the comparison. A non-destructive inspection system that comprises at least one processor, a memory in communication with the processor and storing instructions that causes the processor to obtain an image corresponding to an X-ray, scanning electron microscope, or CT scan of an object, assign numeric values to pixels of the image, compare the assigned numeric values to reference numeric values, and identify an anomaly in the object based on the comparison.

Abstract: A method may include positioning at least one calibration disk in a computed tomography (CT) scanner and positioning a pellet in the CT scanner. The at least one calibration disk and the pellet may both be made of a same powder exhibiting a known density. The method may further include scanning the at least one calibration disk and the pellet using the CT scanner to obtain one or more CT images of the pellet and the at least one calibration disk, and comparing a density of the pellet with the known density of the at least one calibration disk based on the one or more CT images.

Abstract: A method may include positioning at least one calibration disk in a computed tomography (CT) scanner and positioning a pellet in the CT scanner. The at least one calibration disk and the pellet may both be made of a same powder exhibiting a known density. The method may further include scanning the at least one calibration disk and the pellet using the CT scanner to obtain one or more CT images of the pellet and the at least one calibration disk, and comparing a density of the pellet with the known density of the at least one calibration disk based on the one or more CT images.

Abstract: A liner (18) for a shaped-charge (10) that is compressively formed from a mixture of powdered metal, powdered metal binder, and a selected quantity of nanoparticle material, is used to achieve improved penetration depths during perforation of a wellbore. Exemplary nanoparticles include lead, tin, copper, molybdenum, etc. Such nanoparticles increase the density, sound speed, or acoustic impedance of the liner. In another embodiment, the added nanoparticles comprise reactive materials which, after penetration into the formation, cause secondary reactions in the perforations.