An exhaust aftertreatment assembly for treating exhaust gas. According to various embodiments, a first housing has a first end and a second housing has a second end, the second end being coupled to the first end. At least one alignment bracket is coupled to the first housing proximate the first end. An annular gasket is supported on the at least one alignment bracket between the first and second ends. The at least one alignment bracket may comprise a base having a curved surface conforming to the interior surface of the housing, the base having a length that is less than a circumference of the interior surface. A stop arm extends substantially transversely from the base. A support arm extends substantially transversely from the stop arm and substantially parallel to the base. An insulation receiving space is defined between the base, stop arm, and support arm.

An assembly comprising a duct (1) for passing a flow of cryogenic fluid, and a valve (2);

the assembly being characterized in that the duct (1) includes an interface for inserting the valve, the interface forming an internal abutment (51) and an external abutment (52);

the valve (2) being configured in such a manner as to be inserted into said insertion interface by sliding, the valve (2) comprising a valve body (3) presenting a first end (31) and a second end (32), the valve body (3) being adapted to be bolted in said insertion interface in such a manner that the first end (31) and the second end (32) come into abutment respectively against the internal abutment (51) and against the external abutment (52), the assembly including an internal sealing element (61) arranged between the internal abutment (51) and the first end (31), and an external sealing element (62) arranged between the external abutment (52) and the second end (32).

A flowline branch structure (10) has at least one inner branch assembly with an inner flowline branch and at least one inner flowline pipe attached to and communicating with the inner flowline branch. At least one outer branch assembly (12) of the flowline branch structure has an outer branch housing disposed around the inner flowline branch and at least one outer pipe (14) disposed around the inner flowline pipe and attached to the outer branch housing. A generally annular space is defined between the inner and outer branch assemblies. At least one wiring element including an electrical heating element is disposed in the sealed space on an outer side of the inner branch assembly. The, or each, wiring element extends in one continuous length across an interface between the inner flowline pipe and the inner flowline branch. This reduces the number of connections necessary to create the flowline branch structure.

The thermal insulation system of the present invention is for non-vacuum applications and is specifically tailored to the ambient pressure environment with any level of humidity or moisture. The thermal insulation system includes a multilayered composite including i) at least one thermal insulation layer and at least one compressible barrier layer provided as alternating, successive layers, and ii) at least one reflective film provided on at least one surface of the thermal insulation layer and/or said compressible barrier layer. The different layers and materials and their combinations are designed to provide low effective thermal conductivity for the system by managing all modes of heat transfer. The thermal insulation system includes an optional outer casing surrounding the multilayered composite. The thermal insulation system is particularly suited for use in any sub-ambient temperature environment where moisture or its adverse effects are a concern. The thermal insulation system provides physical resilience against damaging mechanical effects including compression, flexure, impact, vibration, and thermal expansion/contraction.

A thermal insulating sleeve liner for fluid flow devices such as valves and piping used in severe industrial applications is preferably additively manufactured (e.g., by 3D printing) to fit into the bore of a protected fluid flow device. Internal interstices and/or external ribs provide added thermal insulation. An integrally formed end-lip or a separate end-cap secures and/or locates the sleeve liner within the protected fluid flow device between different diameter distal and proximal portions of the bore. If internal interstices are sealed they can be vacuumed or pressurized to enhance thermal insulating properties. Fitted dimensions are sufficiently small to prevent ingress of thermally conductive particles circulating in use within the flow path of the protected flow device. A pressure equalizing aperture can be provided on or through the sleeve if needed in some applications.

A thermal insulating sleeve liner for fluid flow devices such as valves and piping used in severe industrial applications is preferably additively manufactured (e.g., by 3D printing) to fit into the bore of a protected fluid flow device. Internal interstices and/or external ribs provide added thermal insulation. An integrally formed end-lip or a separate end-cap secures and/or locates the sleeve liner within the protected fluid flow device between different diameter distal and proximal portions of the bore. If internal interstices are sealed they can be vacuumed or pressurized to enhance thermal insulating properties. Fitted dimensions are sufficiently small to prevent ingress of thermally conductive particles circulating in use within the flow path of the protected flow device. A pressure equalizing aperture can be provided on or through the sleeve if needed in some applications.

An apparatus is provided for protecting from freezing an above-ground conduit outlet on an exterior wall of a building, the freeze protection apparatus comprising a housing including a top wall, a front wall, and a pair of opposed side walls interconnecting the top wall and the front wall. The housing partially defines an enclosed area having a rear aperture and a bottom aperture. Thermal insulating material lines the interior surface of the walls of the housing. Means are provided for mounting the housing to the exterior wall adjacent the conduit outlet. The inner edges of the side walls and the top wall contact the exterior wall and the bottom edges of the side walls and the front wall contact the ground for enclosing the conduit outlet. Heat is retained within the housing to prevent fluid within the conduit from freezing.

A heat-insulated box for insulating parallel-slide valves includes multiple sections each including an outer protective steel envelope with a heat insulation coating on an inner surface. A number and configuration of sections is determined based on geometric parameters of the insulated valve. Some sections include two semi-cylindrical segments rigidly coupled together and oriented in mutually perpendicular directions such that one segment can be installed on the valve and one segment can be installed on the pipeline. The box also includes stiffeners at the junction of the two semi-cylindrical segments. The sections include shock-absorbing sealing gaskets made of cellular rubber substance to ensure a tight seal of the box. The box includes a locking mechanism for coupling the sections together.

A thermal insulation jacket system. The thermal insulation jacket system includes a thermal insulation jacket configured to surround a valve, a plurality of detection devices and a computing device. Each detection device is configured to detect a different temperature associated with the valve. The computing device is coupled to the thermal insulation jacket and is communicably connected to the plurality of detection devices. The computing device is configured to calculate real-time energy savings attributable to the thermal insulation jacket and perform at least one diagnostic analysis associated with the valve.

A secondary containment system for a primary pipe system having primary pipes connected by a connection point having a valve. The secondary containment system having longitudinally divided first and second shells larger than and disposed around the connection point of the primary pipes. Each shell having longitudinally extended edges on opposite sides and arcuate openings at opposite ends. A sealing gasket is provided having arcuate end portions connected by longitudinally extending strips. A series of removable clamps is used for clamping the edges of the first and second shells together, with the sealing gasket being sandwiched between the two shells. A valve stem adapter extends through one of the shells and is configured to rotate the valve in the primary piping system.