A production tubing is disposed in a wellbore. Hydrocarbons entrapped in a subterranean zone enter the wellbore. Multiple valves are disposed in the production tubing at respective multiple tubing locations. The multiple valves divide the production tubing into multiple stages. A presence of hydrocarbons in a first stage terminating at a first valve is determined and gas is injected into the first stage causing the hydrocarbons in the first stage to flow uphole through the first valve into a second stage uphole of the first stage. It is determined that the second stage is filled with the hydrocarbons and injection of the gas into the first stage is ceased. Multiple side chambers are disposed in the respective multiple stages. Determining the presence of hydrocarbons in the first stage incudes detecting a fluidic level of the hydrocarbons inside the first side chamber.

A flow control system selectively regulates production of a fluid from a well. The flow control system includes a plurality of flow control devices, each flow control device rotatable by a portion of the fluid and selectively directing the portion of the fluid through an outlet of the flow control device based on the density of the fluid. The system further includes a regulator valve controlled at least in part by the portion of fluid exiting the outlet of the flow control device. The regulating valve regulates production of a remaining portion of the fluid from the well.

A flow control system selectively regulates production of a fluid from a well. The flow control system includes a plurality of flow control devices, each flow control device rotatable by a portion of the fluid and selectively directing the portion of the fluid through an outlet of the flow control device based on the density of the fluid. The system further includes a regulator valve controlled at least in part by the portion of fluid exiting the outlet of the flow control device. The regulating valve regulates production of a remaining portion of the fluid from the well.

A method and downhole apparatus including a downhole indexer for cyclically varying a configuration or operational mode of a downhole tool according to a predetermined sequence. The apparatus includes tubular body, an indexing member, and a balance piston. The indexing member is selectively moveable relative to the tubular body between a first axial position and a second axial position in response to a signal. The balance piston supports the indexing member at the second position.

A method and downhole apparatus including a downhole indexer for cyclically varying a configuration or operational mode of a downhole tool according to a predetermined sequence. The apparatus includes tubular body, an indexing member, and a balance piston. The indexing member is selectively moveable relative to the tubular body between a first axial position and a second axial position in response to a signal. The balance piston supports the indexing member at the second position.

The present invention applies to flowing wells. Within a flowing well, production tubing moves fluid upward under immense pressures and is greatly exposed to damage, either accidental, or intentional. Recently, there is increased concern in protecting our production wells from damage, either natural or man-made. The present invention is designed to address the problems of controlling hydrocarbon, and fluid flow, through production tubing after the production tubing is compromised by penetration or severance.

A method to produce in-situ steam comprising the steps of producing a laser beam in a steam generator segment positioned in a wellbore in a formation; introducing the laser beam to an activated carbon container, where the activated carbon container comprises activated carbon; increasing a temperature of the activated carbon with the laser beam to produce a hot activated carbon; introducing water to the activated carbon container through a water supply line; producing steam in the activated carbon container when the water contacts the hot activated carbon; increasing pressure in the activated carbon container as steam is produced until a pressure set point of an inter-container valve is reached; releasing steam through the inter-container valve to a steam container; increasing a pressure in the steam container until a release set point of one or more release valves is reached; and releasing steam through the release valve to the formation.

A method of blowing out debris or sand from a separation device comprises opening a second valve assembly such that the second valve assembly is not exposed to pressurized fluid from the separation device when opening. A first valve assembly is opened, wherein the first valve assembly is downstream of the separation device and upstream of the second valve assembly. Debris or sand from the separation device is blown through the first and second valve assemblies, and through a choke port of a third valve assembly. A method of closing fluid flow through a high integrity pressure protection system comprises closing a primary valve in response to detecting the over pressurization of fluid in the fluid line, and closing at least one secondary valve in response to detecting the closing of the primary valve.

A method of blowing out debris or sand from a separation device comprises opening a second valve assembly such that the second valve assembly is not exposed to pressurized fluid from the separation device when opening. A first valve assembly is opened, wherein the first valve assembly is downstream of the separation device and upstream of the second valve assembly. Debris or sand from the separation device is blown through the first and second valve assemblies, and through a choke port of a third valve assembly. A method of closing fluid flow through a high integrity pressure protection system comprises closing a primary valve in response to detecting the over pressurization of fluid in the fluid line, and closing at least one secondary valve in response to detecting the closing of the primary valve.

A method of conditioning a well bore featuring an annulus (50) between a bore-lining tubing (20) and a surrounding bore wall (110) comprises pumping conditioning fluid through an inner tubing (10) located within the bore-lining tubing (20) and into a portion of the well bore containing the bore-lining tubing to affect the temperature of the portion of the well bore containing the bore-lining tubing. The annulus (50) between the bore-lining tubing (20) and the surrounding bore wall (110) is at least partially filled with settable material (54). The affected temperature of the portion of the well bore containing the bore-lining tubing influences the setting of the settable material. For example, heating the bore may accelerate setting of the material, while cooling the bore may retard setting of the material.