BACKGROUND
Flow control valves are well known in downhole industries and especially so in the hydrocarbon recovery industry. Commonly, valves including, but not limited to sliding sleeves are used in a downhole portion of a borehole to regulate the flow of fluids. Flow control valves include at least one port located on a tubular member that may be opened, choked and/or closed as desired. Although flow control valve configurations are many and are ubiquitous in their use within the art, the operation of some traditional flow control valve configurations is time consuming and expensive while the operation of others may not meet desired performance criteria. Reduction in costs while improving the function of flow control valves will be welcomed by the art.
SUMMARY
A flow control valve including, a tubular housing having a valve port, a piston disposed in the tubular housing having an orifice, the piston being slidable in the tubular housing to align the orifice with the valve port, a combustion portion partially defined by the tubular housing and the piston, and a propellant disposed in the combustion portion.
A flow control valve including, a port operative to transmit a fluid, a stopper portion operative to restrict the transmission of the fluid through the port, a combustion portion, a propellant disposed in the combustion portion, and a piston linked to the stopper portion and operative to be moved by a combustion of the propellant.
A method for operating a valve including triggering an actuator portion of the valve, and igniting a propellant with the actuator, the ignition of the propellant causing the movement of a piston linked to a stopper portion operative to restrict the flow of a fluid through the valve.
BRIEF DESCRIPTION OF THE DRAWINGS
Referring now to the drawings wherein like elements are numbered alike in the several figures:
FIG. 1 is a partial cross sectional view of an embodiment of a delay activated valve in a closed position;
FIG. 2 is a close up view of the delay activated valve of FIG. 1.
DETAILED DESCRIPTION
Referring to FIG. 1, an exemplary embodiment of a valve assembly 10 is illustrated. The valve assembly 10 includes a top sub portion 12 having an inner cavity 14. An actuator 16 is disposed in the inner cavity 14. The actuator 16 may include for example, a slow-set power charge, a time delay mechanism, or other type of device capable of actuating the combustion of a combustible material. This system may use a BP-3S or BP-4S igniter that is activatable pursuant to a sufficient electrical charge being passed through it, or may be activated hydraulically using a RD Firing head adapter that is activatable by sufficient hydraulic pressure applied to a rupture disc in the assembly, or may be activated using a battery powered electronic timer and trigger which is activated using coded pressure pulses, etc. Each of these actuating concepts is known and commercially available from Baker Oil Tools, Houston Tex. The top sub portion 12 is sealably engageable with a piston housing 18. The illustrated embodiment includes O-rings 20 at the seal of the top sub portion 12 and the piston housing 18, however other embodiments may include other types of sealing arrangements to affect the seal of the top sub portion 12 and the piston housing 18. The interior of the piston housing 18 includes a combustion chamber portion 22. A communication piston 24 is disposed in the piston housing 18, and partially defines the combustion chamber portion 22. The communication piston 24 includes a stopper portion 33 and orifice(s) 34 (illustrated in FIG. 2 described below). One or more release members 26 such as for example shear members, for example secure the communication piston 24 in the interior of the piston housing 18. An outer housing 30 includes ports 32. The piston housing 18 is sealably engageable with a bottom sub portion 28.
FIG. 2 is a close up view of a portion of the valve assembly 10 that illustrates the operation of the valve assembly 10. In operation, an initiator portion 3 triggers the actuator 16. In the illustrated embodiment, the initiator portion 3 includes an assembly that receives hydraulic pressure that affects the trigger of the actuator 16. Other embodiments may include an initiator portion 3 that receives, for example, an electric, optical, electromagnetic signal, or pneumatic pressure to affect the trigger of the actuator 16. The actuator 16 is operative to ignite a combustible material 5 that is disposed in the combustion chamber 22. Examples of combustible material 5 include propellants such as black powder, a solid explosive, and a combustible liquid, gas, or gel. The deflagration of the combustible material 5 increases the pressure in the combustion chamber 22 and generates a force indicated by the arrow 7. The force is sufficient to release the release member(s) 26 (of FIG. 1). Once the member(s) 26 are released, the communication piston 24 moves along the longitudinal axis of the piston housing 18. The orifice(s) 34 aligns with the ports 32 (of FIG. 1) when the communication piston 24 travels to a stopping point in the piston housing 18. The alignment of the orifice 34 with the ports 32 opens the valve assembly 10 and allows the flow of fluid through the orifice 34 and ports 32.
In operation, a plurality of valve assemblies 10 may be used. It is desirable for the initiator portion 3 to trigger the actuator 16 of each of the plurality of valve assemblies prior to the combustion of the combustible material 5. The actuator 16 may include for example, a mechanical, electrical, or chemical time delay portion. Thus, the actuator 16 may delay the ignition of the combustible material 5 for a defined time period following the trigger of the actuator 16 by the initiator portion 3. The defined time period is sufficient for the initiator portion 3 to trigger the actuator 16 of each of the plurality of the valve assemblies 10 prior to the opening of the valve assemblies 10.
Though the illustrated embodiment shows a closed valve assembly 10 that is opened by the operation described above, alternate embodiments may include a valve assembly having the orifice 34 initially aligned with the ports 32 (an open valve assembly). A similar operation described above is used to move the communication piston 24 along the longitudinal axis of the piston housing such that the orifice 34 moves out of alignment with the ports 32, closing the valve.
While one or more embodiments have been shown and described, modifications and substitutions may be made thereto without departing from the spirit and scope of the invention. Accordingly, it is to be understood that the present invention has been described by way of illustrations and not limitation.