Thermal insulating system for high temperature industrial tanks and equipment, comprising thermal insulating material, a covering system and a support system. The covering system has covering sheets fixed only to the support system. Adjacent covering sheets overlap longitudinally giving rise to overlapped sections comprising an upper part from one of the adjacent covering sheets and a lower part from the other adjacent covering sheet. At least a substantially omega-shaped longitudinal assembly clip is placed at each overlapped section, on the interior sides of the covering sheets, which has a first end attached to the upper part, a central portion separated from the covering sheets, and a second end contacting the lower part of the overlapped section and pressing said lower part.

A system includes a plurality of a clip, the clip comprises a securing mechanism, a first side, a second side, a bottom end, and a top end. During installation of an insulation system a plurality of the clip are coupled to a support beam and disposed within a plurality of notches of a second insulation board. The plurality of clips further include a width that is substantially equal to a width of the plurality of notches such that during the installation of the insulation system the plurality of clips are disposable within the plurality of notches to allow a second side of a first insulation board to contact a first side of the second insulation board and the securing mechanism secures a back surface of the first insulation board against the plurality of clips.

A heat transfer control structure includes: an outer shell having an outer surface and an inner surface, the outer shell being heated by airflow along the outer surface; an inner shell disposed opposed to the inner surface of the outer shell, the inner shell being configured to accommodate a payload therein; and a plate coupled to the inner shell such that the plate is opposed to the inner shell across a gap. The outer shell is coupled to the plate.

A gas station for delivery of gas to appliances comprising a casing and a gas regulation device comprising at least a gas regulator and a filter. The gas regulation device is mounted within the casing which comprises a ground plate and a cover element secured onto the ground plate. The ground plate is configured for mounting to a wall or an external mounting post and comprises at least one spacer, so that the ground plate is attached to the wall or the external mounting post in such a way that a predefined gap is maintained between the ground plate and the wall or between the ground plate and the mounting post. The ground plate includes a flap which supports the gas regulation device and the cover element and a hook configured to hook the cover element in the ground plate via a locking element.

A method of installing an exhaust tube is implemented by inserting an exhaust tube into an exhaust pipe that leads from the inside of a building to the outside thereof. Utilizing an already-placed exhaust pipe, a new exhaust tube is inserted into this exhaust pipe. The exhaust tube is installed according to a procedure of: performing, on the inside of the building, an operation of inserting a new exhaust tube into the already-placed exhaust pipe; performing, on the outside of the building, an operation of fixing the inserted exhaust tube to the exhaust pipe; and performing, on the inside of the building, an operation of connecting the fixed exhaust tube to an exhaust vent of a combustion apparatus.

An exhaust duct includes a duct plate (21) having a cylindrical shape, a heat insulation panel (23) disposed at a predetermined interval on an inner surface side of the duct plate (21), a heat insulation material (22) disposed between the duct plate (21) and the heat insulation panel (23), and a connecting member (24) configured to connect the duct plate (21) to the heat insulation panel (23) and also including a first plate portion (31) and a second plate portion (32) as a stress absorption unit capable of absorbing stress in two directions intersecting in a longitudinal direction. With this structure, durability is improved by preventing damage of the connecting member between the duct plate and the heat insulation panel.

Support element and method for a cryogenic fluid circuit comprising a plurality of orifices intended for the passage of cryogenic-fluid transfer pipes, said support element comprising at least one thermal path formed between two adjacent orifices, the thermal path comprising a blind opening, the opening being delimited by two spaced-apart walls extending between two ends in a longitudinal direction perpendicular to the plane of the orifices, the two walls being joined together by an end wall, the support element being characterized in that it comprises a first set of orifices which is surrounded by a first thermal path and a second set of orifices, the first thermal path being situated between the first set of orifices and the second set of orifices, which means to say that the first thermal path is in thermal and mechanical connection with, on the one hand, all the orifices of the first set of orifices and, on the other hand, all the orifices of the second set of orifice.

Systems and methods are provided for insulating and heating a subsea pipeline. A system may comprise a subsea pipeline including a lower portion embedded in a seafloor and an upper portion above the seafloor. The system may include an insulating layer. The insulating layer may include a middle portion covering the upper portion of the subsea pipeline. The insulating layer may further include an end portion covering the seafloor. The insulating layer may form a cavity adjacent to the seafloor, the subsea pipeline, and the insulating layer. The system may further include a plurality of heater cables within the cavity. The plurality of heater cables may be configured to heat a fluid within the subsea pipeline. The plurality of heater cables may be separated from the subsea pipeline only by seawater or by soil of the seafloor within the cavity.