A box by pin perforating gun system using swaged down gun bodies, a removable cartridge to hold a detonator and switch, and an insulated charge holder as an electrical feed-through.

One embodiment of a wellbore to fracture connectivity apparatus comprises an opening portion representing an opening in a wellbore for receiving fluid, proppant, or any combination thereof to generate at least one fracture in a formation; a fracture portion representing the at least one fracture in the formation; and a coupling portion representing wellbore to fracture connectivity between the opening portion and the fracture portion. The coupling portion couples the opening portion and the fracture portion.

A bridge plug for deployment in a well defined by casing has a stackable tubular body having a front portion, a middle portion, a back portion, and an internal bore extending therethrough with the front portion having a first opening in fluid communication with the internal bore and the back portion having a second opening in fluid communication with the internal bore. The stackable tubular body has an outer configuration shaped to receive another adjacent bridge plug when the adjacent bridge plug is stacked within the well. The middle portion includes an expandable component that can frictionally engage the casing to hold the bridge plug in a fixed position within the well. The expandable component can be destroyed, at least partially, to facilitate movement of the bridge plug within the well while maintaining fluid communication between the first opening and the second opening.

An improved perforating gun. The perforating gun includes an internal charge holder formed from a conductive material and comprising a grounding tab. The grounding tab protrudes through a first end cap and is in direct electrical contact with a tandem for grounding the internal charge holder. An optional second grounding tab protrudes through a second end cap and is in direct electrical contact with a second tandem. Each end cap includes a contact pin that engages a signal transfer pin contained within a tandem. The contact pins are biased outwardly by respective compression springs, and each compression spring comprises a portion of an electrical path for a firing signal.

An improved perforating gun. The perforating gun includes an internal charge holder formed from a conductive material and comprising a grounding tab. The grounding tab protrudes through a first end cap and is in direct electrical contact with a tandem for grounding the internal charge holder. An optional second grounding tab protrudes through a second end cap and is in direct electrical contact with a second tandem. Each end cap includes a contact pin that engages a signal transfer pin contained within a tandem. The contact pins are biased outwardly by respective compression springs, and each compression spring comprises a portion of an electrical path for a firing signal.

An improved perforating gun is provided. The perforating gun includes an outer loading tube, an internal charge holder, an addressable switch housing, and a detonator housing. In some embodiments, the addressable switch housing and the detonator housing are separate components that are joined to the outer loading tube. In other embodiments, the addressable switch housing is integrally joined to a first portion of the internal charge holder and the detonator housing is integrally joined to a second portion of the internal charge holder. When detonated, a plurality of shaped charges create a plurality of perforations through a wellbore casing, the perforations being angularly offset from each other within a single perforation plane, optionally followed by a hydraulic fracturing stage.

An improved perforating gun is provided. The perforating gun includes an outer loading tube, an internal charge holder, an addressable switch housing, and a detonator housing. In some embodiments, the addressable switch housing and the detonator housing are separate components that are joined to the outer loading tube. In other embodiments, the addressable switch housing is integrally joined to a first portion of the internal charge holder and the detonator housing is integrally joined to a second portion of the internal charge holder. When detonated, a plurality of shaped charges create a plurality of perforations through a wellbore casing, the perforations being angularly offset from each other within a single perforation plane, optionally followed by a hydraulic fracturing stage.

A perforating gun assembly for use within a borehole. The perforating gun assembly may include a first perforating charge section, a second perforating charge section, and a tandem coupling the first perforating charge section to the second perforating charge section. The tandem may include a first sensor package that may be operable to determine a flowrate of formation fluid flowing around the tandem and a second sensor package that may be operable to identify the formation fluid.

A perforating gun assembly for use within a borehole. The perforating gun assembly may include a first perforating charge section, a second perforating charge section, and a tandem coupling the first perforating charge section to the second perforating charge section. The tandem may include a first sensor package that may be operable to determine a flowrate of formation fluid flowing around the tandem and a second sensor package that may be operable to identify the formation fluid.

An apparatus for perforating a subterranean formation comprises a first perforating gun (33b) having a box end (112) having a nose, a second perforating gun (33a) having a pin end (118) having a shoulder (124); and an alignment assembly. The alignment assembly includes internal threads formed on the box end, external threads formed on the pin end, and an alignment member (120) positioned between the box end nose and the pin end shoulder. The internal threads and the external threads are specified to form an angular alignment between the first perforating gun and the second perforating gun within a first specified angular tolerance. The alignment member has at least one characteristic selected to vary the angular alignment within the first specified angular tolerance without degrading a locking force connecting the first perforating gun to the second perforating gun.