An unloading plunger having a chamber for compressed gas and a method for unloading liquid from a wellbore via ascending of the unloading plunger including ascending via formation pressure the unloading plunger from the bottom portion of the wellbore to a rest position at a wellhead and releasing compressed gas from the chamber into the wellbore during the ascending to decrease hydrostatic pressure of liquid in the wellbore above the unloading plunger.

A bypass plunger combines a unitary or one-piece hollow body-and-valve cage, retains a dart valve within the valve cage portion of the hollow body using a threaded retaining nut secured by crimple detents. A series of helical grooves surround the central portion of the outer surface of of the hollow body of the plunger to control spin during descent. A canted-coil-spring disposed within the retaining nut functions as a clutch. The valve cage includes ports that may be configured configured to control flow through the plunger during ascent. Other embodiments include clutch assemblies using canted-coil springs with split bobbins, and valve sterns surfaced to achieve specific functions. Combinations of these features provide enhanced performance, durability and reliability at reduced manufacturing cost, due primarily to the simplicity of its design.

A bypass plunger formed as an integral one-piece hollow body-and-valve cage unit retains a dart valve within a valve cage section of the hollow body with a threaded retaining nut that may be secured by crimple means. A boundary zone, defined along the plunger body, where the integral valve cage section adjoins the plunger body, is configured with a uniform outer diameter to maximize the plunger body wall thickness and durability of the one-piece bypass plunger. The valve cage may have flow ports configured with ramps at an angle with the longitudinal axis to control flow through the flow ports during descent of the bypass plunger. A clutch assembly using garter springs with split bobbins may be disposed within the valve cage portion of the one-piece bypass plunger.

Artificial lift systems, methods, and apparatuses are described. An example artificial lift system may include a plunger have an energy-storing component to store energy as the plunger descends through a wellbore and release the stored energy as the plunger ascends through the wellbore. The energy-storage component may be a spring. The spring may be compressed in response to rotation of a propeller coupled to the spring. The propeller may rotate in a first direction in response to interaction of the propeller and a liquid in the wellbore as the plunger descends. The spring may expand during uphole movement of the plunger to rotate the propeller in a second direction, opposite the first direction, and assist in lifting the plunger to the surface.

Artificial lift systems, methods, and apparatuses are described. An example artificial lift system may include a plunger have an energy-storing component to store energy as the plunger descends through a wellbore and release the stored energy as the plunger ascends through the wellbore. The energy-storage component may be a spring. The spring may be compressed in response to rotation of a propeller coupled to the spring. The propeller may rotate in a first direction in response to interaction of the propeller and a liquid in the wellbore as the plunger descends. The spring may expand during uphole movement of the plunger to rotate the propeller in a second direction, opposite the first direction, and assist in lifting the plunger to the surface.

A plunger for moving up and down in a tubing string in a plunger lift system includes an elongated body having an upper end, a lower end and a longitudinal axis, an upper passage extending axially in the body from a top opening located toward the upper end, and a liquid cross-hole extending from the upper passage to an outer circumferential surface of the body. The upper passage is closed to the exterior of the lower end at least when the plunger is located at or proximate to the bottom end of the tubing string. In some embodiments the upper passage extends from the top opening to a terminal end or position located inside the body and not in communication with the exterior of the lower end. The upper passage may extend from the top opening to a bottom opening toward the lower end and include a valve element to selective close the bottom opening.

A plunger for moving up and down in a tubing string in a plunger lift system includes an elongated body having an upper end, a lower end and a longitudinal axis, an upper passage extending axially in the body from a top opening located toward the upper end, and a liquid cross-hole extending from the upper passage to an outer circumferential surface of the body. The upper passage is closed to the exterior of the lower end at least when the plunger is located at or proximate to the bottom end of the tubing string. In some embodiments the upper passage extends from the top opening to a terminal end or position located inside the body and not in communication with the exterior of the lower end. The upper passage may extend from the top opening to a bottom opening toward the lower end and include a valve element to selective close the bottom opening.

Embodiments of well plunger systems, assemblies, and apparatuses are described. In an embodiment, the apparatus includes a body having a first open end, a second open end, and a channel extending from the first open end through the body to the second open end, the channel for passing fluid from an oil or gas well. The apparatus may also include a receiver disposed at the first open end, the receiver configured to receive a stopper configured to at least partially seal off the channel, the first open end comprising a retention member receiver configured to receive one or more specially adapted retention members for applying a retention force to the stopper when the stopper is engaged with the receiver.

A method of lifting liquids from a formation using a plunger lift assembly. The method includes dropping a multi-component plunger lift assembly from a wellhead and into a wellbore. This is done in response to a release signal or in response to a wellhead being shut in. The wellbore has a deviated section which may extend to horizontal. The multi-component plunger lift assembly includes a cylindrical plunger and a sphere. These components are released into the wellbore simultaneously. In response to reservoir formation gases passing into the wellbore, the method also includes allowing the plunger lift assembly to move up the wellbore and to the wellhead, thereby pushing liquids upwardly towards the wellhead.

A method of lifting liquids from a formation using a plunger lift assembly. The method includes dropping a multi-component plunger lift assembly from a wellhead and into a wellbore. This is done in response to a release signal or in response to a wellhead being shut in. The wellbore has a deviated section which may extend to horizontal. The multi-component plunger lift assembly includes a cylindrical plunger and a sphere. These components are released into the wellbore simultaneously. In response to reservoir formation gases passing into the wellbore, the method also includes allowing the plunger lift assembly to move up the wellbore and to the wellhead, thereby pushing liquids upwardly towards the wellhead.