A valve assembly may provide a body comprising a bottom portion and a top portion having a threaded region, a closing mechanism situated above the top portion of the body, an actuator in communication with the closing mechanism, a nut configured to attach to the threaded region, and a threaded hole extending into at least one of the bottom portion of the body or the nut.

A plug for isolating and pressure testing a hollow piece of equipment (e.g., a container or tubular) comprises a compression nut, a semi-conical mandrel shaft (which may be one or two pieces), and a compression member. The compression nut and the semi-conical mandrel shaft are threaded together, directly or indirectly via a spacer and plug body, such that the rotation of the compression nut forces the mandrel shaft through the compression member, and the semi-conical surface expands the compression member against an interior surface of the hollow piece of equipment to anchor in place and seal off a testing space. Internal channels running through the compression nut (and if present, the plug body) permit externally pressurized fluid and sensors to communicate with the testing space. The compression member can be configured to test either one end of the piece of hollow equipment or a particular region between the two seals.

A plug for isolating and pressure testing a hollow piece of equipment (e.g., a container or tubular) comprises a compression nut, a semi-conical mandrel shaft (which may be one or two pieces), and a compression member. The compression nut and the semi-conical mandrel shaft are threaded together, directly or indirectly via a spacer and plug body, such that the rotation of the compression nut forces the mandrel shaft through the compression member, and the semi-conical surface expands the compression member against an interior surface of the hollow piece of equipment to anchor in place and seal off a testing space. Internal channels running through the compression nut (and if present, the plug body) permit externally pressurized fluid and sensors to communicate with the testing space. The compression member can be configured to test either one end of the piece of hollow equipment or a particular region between the two seals.

A gripper assembly for a pipeline plug includes an actuator plate that includes at least two actuator wedges, a bowl that includes at least two bowl wedges, circumferential wedge sets, and gripper units. Each circumferential wedge set and gripper unit is positioned between the actuator plate and the bowl. Each circumferential wedge set includes a first circumferential wedge and a second circumferential wedge. Each circumferential wedge set is positioned such that an actuator wedge and a bowl wedge engage between the first and second circumferential wedges. Each gripper unit includes a gripper body positioned between and abutting a first circumferential wedge of a first circumferential wedge set and a second circumferential wedge of a second circumferential wedge set. Linear compression between the actuator plate and bowl causes circumferential movement of the circumferential wedges, which in turn causes radial expansion of the gripper units.

A gripper assembly for a pipeline plug includes an actuator plate that includes at least two actuator wedges, a bowl that includes at least two bowl wedges, circumferential wedge sets, and gripper units. Each circumferential wedge set and gripper unit is positioned between the actuator plate and the bowl. Each circumferential wedge set includes a first circumferential wedge and a second circumferential wedge. Each circumferential wedge set is positioned such that an actuator wedge and a bowl wedge engage between the first and second circumferential wedges. Each gripper unit includes a gripper body positioned between and abutting a first circumferential wedge of a first circumferential wedge set and a second circumferential wedge of a second circumferential wedge set. Linear compression between the actuator plate and bowl causes circumferential movement of the circumferential wedges, which in turn causes radial expansion of the gripper units.

The invention relates to a sealing device for cylindrical or conical orifices, which is composed of an elongate sealing body made from elastically deformable material, the following components being provided for the deformation of the sealing body: a tension bolt extending through the middle, free passage region of the sealing body, a pressure sleeve seated at the inner end of the tension bolt, a brace which is arranged at the outer end of the tension bolt and through which the tension bolt engages, and an actuation element which acts upon the outer end, projecting through the brace, of the tension bolt and which, when a tensile force is exerted upon the tension bolt, enlarges the sealing body and at the same time its outer circumference.

The invention relates to a sealing device for cylindrical or conical orifices, which is composed of an elongate sealing body made from elastically deformable material, the following components being provided for the deformation of the sealing body: a tension bolt extending through the middle, free passage region of the sealing body, a pressure sleeve seated at the inner end of the tension bolt, a brace which is arranged at the outer end of the tension bolt and through which the tension bolt engages, and an actuation element which acts upon the outer end, projecting through the brace, of the tension bolt and which, when a tensile force is exerted upon the tension bolt, enlarges the sealing body and at the same time its outer circumference.

A pipeline isolation tool (10) with a circumferential seal (30) having a T-shaped cross section. The seal has a radially oriented lower seal profile (36) and an axially oriented upper seal profile (38). Pressure heads (40, 50) are located on either side (32, 34) of the lower profile. Overlapping structural elements (60, 80) are located on either side (32, 34) of the upper profile and include a concave area (70, 90) for receiving a portion of the upper seal profile. The inner face (64, 84) of the structural elements contact the outer surfaces (42, 52) of the pressure heads. Angle plates (100, 110) define an inner face (102, 112) that contacts an outer face (66, 86) of each of the structural elements. The tool may be configured as an intrusive tool or as a non-intrusive tool.

A pipeline isolation tool (10) with a circumferential seal (30) having a T-shaped cross section. The seal has a radially oriented lower seal profile (36) and an axially oriented upper seal profile (38). Pressure heads (40, 50) are located on either side (32, 34) of the lower profile. Overlapping structural elements (60, 80) are located on either side (32, 34) of the upper profile and include a concave area (70, 90) for receiving a portion of the upper seal profile. The inner face (64, 84) of the structural elements contact the outer surfaces (42, 52) of the pressure heads. Angle plates (100, 110) define an inner face (102, 112) that contacts an outer face (66, 86) of each of the structural elements. The tool may be configured as an intrusive tool or as a non-intrusive tool.

A watertight testing device includes a cylindrical core fit into a pipe joint part, a first seal member for sealing between the outer surface of the core and the inner surface of one pipe, a second seal member for sealing between the outer surface of the core and the inner surface of the other pipe, a first pressing member for pressing and compressing the first seal member into a first seal-member insertion space, a second pressing member for pressing and compressing the second seal member into a second seal-member insertion space, a moving device for moving the first and second pressing members in a pipe axial direction, and a test fluid feeder for feeding a test fluid into a test space.