A gate valve includes a solid wedge-shaped disc integrated with a cartridge at opposite ends thereof. Each cartridge includes rollers, guides and scrapers therein to roll along respective internal ribs while cleaning the ribs. The disc moves back and forth within the gate valve via the cartridges along ribs to open and close a water passage way formed in the gate.

A gate valve includes a solid wedge-shaped disc integrated with a cartridge at opposite ends thereof. Each cartridge includes rollers, guides and scrapers therein to roll along respective internal ribs while cleaning the ribs. The disc moves back and forth within the gate valve via the cartridges along ribs to open and close a water passage way formed in the gate.

This specification discloses a Valve designed to be used in systems wherein it is desirable to activate and close the valve in response-to changes in pressure inside a pipeline downstream of the valve, without any dependency on electronic communications or external power, relying solely on the energy within the pipeline for sensing the differences and for closing the valve. The present invention is specifically targeted to petroleum pipelines, but is applicable to fluid pipelines and piping systems for any fluid, liquid or gaseous. The Valve functions by utilizing a lowered pressure downstream of the Valve in opposition to the full pipeline pressure on the upstream side of the Valve. The pressure downstream is typically lowered by providing a flow restrictor on the downstream side of the Valve, or incorporated into the downstream side of the Valve, in a system with a pump on the downstream side of the section of the pipeline it is intended to protect. A flapper, or hinged gate, is held in the open position by exposing said gate to the full line pressure on the side where the line pressure enters the Valve, while the side of the flapper opposite the flow is exposed to the lowered pressure or the pipeline downstream of the restrictor through a connection with the downstream pipeline. The differential pressure holds the hinged gate in the open position so long as the required differential is maintained. When a pre-determined compromise of the differential pressure occurs, the magnitude of which is designed into the Valve for each application or installation, and/or adjusted in the field by means provided, the hinged gate is freed from the open position and moves into sealing contact with the closed position seat.

This specification discloses a Valve designed to be used in systems wherein it is desirable to activate and close the valve in response-to changes in pressure inside a pipeline downstream of the valve, without any dependency on electronic communications or external power, relying solely on the energy within the pipeline for sensing the differences and for closing the valve. The present invention is specifically targeted to petroleum pipelines, but is applicable to fluid pipelines and piping systems for any fluid, liquid or gaseous. The Valve functions by utilizing a lowered pressure downstream of the Valve in opposition to the full pipeline pressure on the upstream side of the Valve. The pressure downstream is typically lowered by providing a flow restrictor on the downstream side of the Valve, or incorporated into the downstream side of the Valve, in a system with a pump on the downstream side of the section of the pipeline it is intended to protect. A flapper, or hinged gate, is held in the open position by exposing said gate to the full line pressure on the side where the line pressure enters the Valve, while the side of the flapper opposite the flow is exposed to the lowered pressure or the pipeline downstream of the restrictor through a connection with the downstream pipeline. The differential pressure holds the hinged gate in the open position so long as the required differential is maintained. When a pre-determined compromise of the differential pressure occurs, the magnitude of which is designed into the Valve for each application or installation, and/or adjusted in the field by means provided, the hinged gate is freed from the open position and moves into sealing contact with the closed position seat.

A method of modifying an existing valve assembly has the step of placing a supplemental sleeve within a housing. The housing has a housing inlet window and a housing outlet window, and the supplemental sleeve has a sleeve inlet window and a sleeve outlet window. The method includes the step of placing an existing piston/sleeve set within the supplemental sleeve. A spool valve is also disclosed.

A method of modifying an existing valve assembly has the step of placing a supplemental sleeve within a housing. The housing has a housing inlet window and a housing outlet window, and the supplemental sleeve has a sleeve inlet window and a sleeve outlet window. The method includes the step of placing an existing piston/sleeve set within the supplemental sleeve. A spool valve is also disclosed.

A gate valve for a pressurized pipe includes a paddle member with a lower proximal portion and a pair of spaced-apart and leg portions that form an outer edge and an inner edge. A cartridge includes a valve stem channel extending through a distal portion and through a conduit and terminating at a proximal opening in a proximal portion of the cartridge. The proximal portion of the cartridge includes a slot for accommodating the inner edge of the paddle member. In a pre-compression configuration, the inner edge of the paddle member is spaced-apart from the proximal opening of the conduit and in a post-compression configuration, the inner edge of the paddle member engages and seals the proximal opening resulting in a built-in check-valve that is open when the paddle member is in the pre-compression configuration and closed when the paddle member is in the post-compression configuration.

A gate valve for a pressurized pipe includes a paddle member with a lower proximal portion and a pair of spaced-apart and leg portions that form an outer edge and an inner edge. A cartridge includes a valve stem channel extending through a distal portion and through a conduit and terminating at a proximal opening in a proximal portion of the cartridge. The proximal portion of the cartridge includes a slot for accommodating the inner edge of the paddle member. In a pre-compression configuration, the inner edge of the paddle member is spaced-apart from the proximal opening of the conduit and in a post-compression configuration, the inner edge of the paddle member engages and seals the proximal opening resulting in a built-in check-valve that is open when the paddle member is in the pre-compression configuration and closed when the paddle member is in the post-compression configuration.

A lock valve including a poppet valve element which is disposed within a spring chamber, a spring which biases the poppet valve element leftward, and a valve seat which comes into contact with the poppet valve element is disposed in a cavity formed in a valve body to mount a relief valve therein and is positioned further inward than the sleeve of the relief valve. The outer peripheral portion of the poppet valve element has hole portions formed therein at regular intervals. The outer peripheral portion of the valve seat, too, has hole portions formed therein at regular intervals. The valve portion of a solenoid valve is disposed between a passage which is in communication with the spring chamber and a passage which is in communication with a second flow passage open to a low-pressure region such as a hydraulic tank.

The invention relates to a drive device for activating a rotary slide for a fluid system of an at least in part electrically operated motor vehicle. The drive device comprises an electric motor having a motor output shaft, a rotary slide output shaft configured for activating a rotary slide, wherein the rotary slide output shaft is aligned so as to be orthogonal to the motor output shaft, and a magnet is disposed on an end region of the rotary slide output shaft, and a sensor unit which is configured for detecting a rotary position of the magnet and thus of the rotary slide output shaft.