Abstract: A method of producing a well fluid includes securing a motor to a string of outer tubing and lowering the outer tubing and motor into the well. A rotary pump is secured to a string of inner tubing and lowered into the outer tubing. The pump stabs into cooperative engagement with the motor. Supplying power to the motor rotates the pump, causing well fluid to flow into the outer tubing to an intake of the pump, which pumps the well fluid through the inner tubing to an upper end of the well. Removing the well fluid allows gas to flow up an annulus surrounding the outer tubing to the upper end of the well.

Abstract: A method of producing a well fluid includes securing a motor to a string of outer tubing and lowering the outer tubing and motor into the well. A rotary pump is secured to a string of inner tubing and lowered into the outer tubing. The pump stabs into cooperative engagement with the motor. Supplying power to the motor rotates the pump, causing well fluid to flow into the outer tubing to an intake of the pump, which pumps the well fluid through the inner tubing to an upper end of the well. Removing the well fluid allows gas to flow up an annulus surrounding the outer tubing to the upper end of the well.

Abstract: A submersible pump assembly suspended on a string of tubing in a well has a valve that drains the tubing above the pump when the pump shuts down. The valve includes a valve housing installed with the tubing string above the submersible pump assembly. The valve housing has an interior in communication with fluid in the string of tubing above the valve housing, and a shunt port communicating the interior of the valve housing with an annulus surrounding the string of tubing. A valve cage is slidably received within the valve housing for movement between upper and lower positions. The valve cage blocks communication through the shunt port while in the upper position, and while in the lower position, opens the shunt port. A valve seat is located in the valve cage, and a valve member moves between a lower position, sealingly engaging the valve seat, and an upper position, allowing flow through the valve seat from the pump to the tubing string.

Abstract: A progressive cavity pump housing is secured to the lower end of a string of tubing. A motor is secured to the progressive cavity housing. An electrical power cable is strapped to the motor alongside the tubing. The pump has a pump rotor located within a stator. The pump rotor has a driven shaft extending downward from its lower end which mates with a drive shaft extending upward from the motor. When the pump reaches the motor, the driven shaft will stab into the drive shaft. The upper end of the pump rotor extends above the stator and is configured to engage an overshot retrieval tool. To retrieve the rotor, the operator lowers an overshot retrieval tool through the production tubing and latches it to the upper end of the pump rotor. The operator pulls the rotor out of the pump, thereby disengaging the rotor from the drive shaft of the motor, and leaving the remainder of the pump and the motor in place.

Abstract: A well pump assembly has a pressure relief valve in the tubing string for avoiding excessive discharge pressure on a progressing cavity pump. The pressure relief valve is mounted in the string of tubing downstream of the pump. The valve assembly has a main flow passage through it for fluid being pumped by the pump through the tubing. The valve assembly has a valve seat and a spring-biased valve element which is urged by the spring against the downstream end of the valve seat to maintain the valve seat closed. The upstream end of the valve seat is in communication with the pressure in the tubing. If the tubing pressure exceeds a selected level, the valve element moves to an open position, discharging well fluid into the casing.

Abstract: A perforation trigger bypass conduit assembly (10) for a well perforation gun (17) positioned in a well casing (12) at a down-hole location below a tubular completion assembly (16). A pressure sensing device (20) senses a detonation pressure of fluid communicated from a pump (21) through bypass conduit assembly (10) to the sensor (20). The sensing device (20) triggers the gun upon sensing a pressure surpassing a predetermined value, which perforates the casing (12). The bypass conduit assembly (10) is formed to enable blocking of the bypass conduit assembly (10) after triggering of the perforation gun (17) to prevent pumping of production and power fluid back into the formation upon severing of a portion (34) of the conduit assembly (10). Blocking can be effected by removing a member (25) which contains a passageway (51) forming part of the bypass conduit assembly (10) and replacing the removable member (25) with a passageway-free insert member (35).

Abstract: A deep well pump for positioning in a bottom hole assembly and having at least one fluid pump and at least two fluid powered motors with the pump and motor pistons carried in alignment on the piston rod. The pump includes passages for delivering a power fluid to one end of each of the motor cylinders and for receiving exhaust fluid from the other end of the motor cylinders, and a valve for reversing this operation. A first sleeve is positioned around the first motor cylinder defining a power fluid path from one end of the first cylinder to one end of the second cylinder, a second sleeve is positioned around the first sleeve defining an exhaust fluid path from the other end of the first motor cylinder, and a third sleeve is positioned around the second motor cylinder defining an exhaust fluid path from the other end of the second motor cylinder, with the first and second exhaust fluid paths interconnected.

Abstract: A deep well pump for positioning in a bottom hole assembly and having at least one fluid pump and at least two fluid powered motors with the pump and motor pistons carried in alignment on the piston rod. The pump includes passages for delivering a power fluid to one end of each of the motor cylinders and for receiving exhaust fluid from the other end of the motor cylinders, and a valve for reversing this operation. A first sleeve is positioned around the first motor cylinder defining a power fluid path from one end of the first cylinder to one end of the second cylinder, a second sleeve is positioned around the first sleeve defining an exhaust fluid path from the other end of the first motor cylinder, and a third sleeve is positioned around the second motor cylinder defining an exhaust fluid path from the other end of the second motor cylinder, with the first and second exhaust fluid paths interconnected.

Abstract: An Air Deployed Oceanographic Mooring when assembled for deployment has a multitude of components suitable for separation by explosive bolts upon deployment of the system. A parachute system is connected to a surface buoy. The components that separate from each other upon deployment comprise a parachute system, a surface float, a subsurface buoy, an anchor shell and a bottom finder. All components except for the parachute system have interconnecting flexible lines upon deployment. A novel locking mechanism for limiting the paying out of the line between the anchor shell and subsurface buoy is triggered by the slackening of the line between the bottom finder and anchor shell when the bottom finder hits the bottom of the ocean.