A two part curable composition comprising organosiloxane polymer; water; an organosilane such as hexamethyldisilazane (HMDS) or vinyltrimethoxysilane; crosslinker; adhesion promoter and catalyst; and optionally comprising plasticizer; colorant and filler. The first part can comprise organosiloxane polymer and water. The second part can comprise crosslinker; adhesion promoter and catalyst. Either or both parts can optionally further comprise an organosilane such as hexamethyldisilazane (HMDS) or vinyltrimethoxysilane; plasticizer; colorant and filler. Cured reaction products of the two part curable organosiloxane composition has good adhesion to metallic sealing surfaces and good resistance engine oil and other automotive fluids. Cured reaction products of the two part curable organosiloxane composition can surprisingly retain physical properties after long-term exposure to temperatures between 200° C. and 250° C. and can retain physical properties after exposure to temperatures between 250° C. to 300° C. for short periods.

A two part curable composition comprising organosiloxane polymer; water; an organosilane such as hexamethyldisilazane (HMDS) or vinyltrimethoxysilane; crosslinker; adhesion promoter and catalyst; and optionally comprising plasticizer; colorant and filler. The first part can comprise organosiloxane polymer and water. The second part can comprise crosslinker; adhesion promoter and catalyst. Either or both parts can optionally further comprise an organosilane such as hexamethyldisilazane (HMDS) or vinyltrimethoxysilane; plasticizer; colorant and filler. Cured reaction products of the two part curable organosiloxane composition has good adhesion to metallic sealing surfaces and good resistance engine oil and other automotive fluids. Cured reaction products of the two part curable organosiloxane composition can surprisingly retain physical properties after long-term exposure to temperatures between 200° C. and 250° C. and can retain physical properties after exposure to temperatures between 250° C. to 300° C. for short periods.

Systems and methods for sealing bolted flange joints to stop or prevent leakage are disclosed. The system includes a sealant injection nut. The sealant injection nut generally comprises a threaded nut configured to be threaded onto a stud bolt of a flange joint. The nut is configured to inject sealant into the internal passages of the flange joint. The nut includes a passageway drilled through the sidewall. Fitted to the passageway is a high-pressure sealant-compatible injection fitting and an internal check-valve. Provided within the central cavity of the nut, at the flange-facing end, is a groove that facilitates the flow of sealant injected through the passageway into the passages of the bolted flange. A method is also provided for manufacturing the sealant injection nut. A method is also provided for repairing leaking bolted flange joints using the sealant injection nut.

The present invention provides methods and systems for sealing at least one leak in at least one of at least one premise-side pipe and a premise-side pipe network, the method including passing at least one of a pig train and a sealant composition under pressure along at least one of said premises-side pipeline and at least part of said premises-side pipe network such that a portion of the sealant composition enters at least one leakage site to seal and cure the at least one leak on said premise-side.

A liquid seal mating system to accommodate thermal expansion during elevated-temperature operation, including a collar, sized and shaped to receive a discharge end of a gas-delivery conduit and a fence that surrounds the collar and is attached thereto, wherein when installed, the collar accommodates thermal expansion of the gas-delivery conduit along a longitudinal axis of the gas-delivery conduit and limits movement of the gas-delivery conduit perpendicular to the longitudinal axis. A method for suppressing bulk fluid motion in an elevated-temperature liquid seal, including attaching a mount to an outer shell of a liquid seal and receiving, within a mating collar, a discharge end of a gas-delivery conduit, the mating collar attached to the mount and being sized and shaped to accommodate thermal expansion of the gas-delivery conduit, filling the outer shell with liquid to submerge the discharge end of the gas-delivery conduit, and flowing gas through the gas-delivery conduit.

Systems and methods for sealing bolted flange joints to stop or prevent leakage are disclosed. The system includes a sealant injection nut. The sealant injection nut generally comprises a threaded nut configured to be threaded onto a stud bolt of a flange joint. The nut is configured to inject sealant into the internal passages of the flange joint. The nut includes a passageway drilled through the sidewall. Fitted to the passageway is a high-pressure sealant-compatible injection fitting and an internal check-valve. Provided within the central cavity of the nut, at the flange-facing end, is a groove that facilitates the flow of sealant injected through the passageway into the passages of the bolted flange. A method is also provided for manufacturing the sealant injection nut. A method is also provided for repairing leaking bolted flange joints using the sealant injection nut.

A device includes a cover and a base. The base is coupled to the cover to create an enclosure. The device also includes a form-in-place-gasket. The form-in-place-gasket is positioned between the cover and the base to create a seal. The form-in-place-gasket includes an acid-absorbing material.

Embodiments of the invention provide a knife gate valve for flow along a flow path. The knife gate valve can include a body structure that includes a gate passage, a gate disposed to move within the gate passage between open and closed positions to selectively open or close a fluid aperture, and a gate seat configured to engage a free end and lateral edges of the gate. A transverse element can be formed from resilient material and can extend laterally across the gate passage to form a seal with a first side of the gate and with the gate seat.

An application system includes one or more flow control mechanisms controlling a flow path to a dispenser device, one or more position control mechanisms controlling a position of the dispenser device, and a memory device storing data associated with the flow control mechanisms, the position control mechanisms, one or more target areas, and computer-executable instructions. The computer-executable instructions may be executed to identify a target area, actuate the position control mechanisms to move the dispenser device toward the target area, actuate the flow control mechanisms to channel the sealant materials toward the dispenser device, dispense one or more first shots of the sealant materials onto the target area using the dispenser device for forming a dollop at the target area, and dispense one or more second shots of the sealant materials onto the target area using the dispenser device for forming a sealant layer that overlies the dollop.

An application system includes one or more flow control mechanisms controlling a flow path to a dispenser device, one or more position control mechanisms controlling a position of the dispenser device, and a memory device storing data associated with the flow control mechanisms, the position control mechanisms, one or more target areas, and computer-executable instructions. The computer-executable instructions may be executed to identify a target area, actuate the position control mechanisms to move the dispenser device toward the target area, actuate the flow control mechanisms to channel the sealant materials toward the dispenser device, dispense one or more first shots of the sealant materials onto the target area using the dispenser device for forming a dollop at the target area, and dispense one or more second shots of the sealant materials onto the target area using the dispenser device for forming a sealant layer that overlies the dollop.