Disclosed is a liquefied natural gas production train, comprising at least one integrated process unit having a structural frame forming multiple process equipment floors. The at least one integrated process unit extends in vertical direction, wherein a height of the at least one integrated process unit is substantially equal to or larger than a width and a length of the at least one integrated process unit. The disclosure also provides a method of producing liquefied natural gas, using the LNG production train.

A baffle support and a baffle for a block-type heat exchanger. The baffle support comprises a base plate extending in a first direction and a transverse second direction. The baffle support comprises a first pair and a second pair of projections extending from the front surface of the base plate to engage the baffle. The first pair of projections is located further in the first direction than the second pair of projections. The baffle comprises a mounting member at each transverse edge of a baffle plate. Each mounting member comprises at least one stop surface) facing a first longitudinal edge of the baffle plate. A baffle assembly comprising two baffle supports and a baffle.

Systems and apparatus are provided for thermal cooling of integrated circuits, such as dual in-line memory modules (DIMMs). The apparatus includes a plurality of rows pieces that include individual leaf springs. Each of the leaf springs can exert compression to support thermal contact and a stable coupling with a received DIMM. The plurality of row pieces can be assembled to form a single structure, having a space to receive an individual DIMM for insertion. Further, each of the leaf springs are structured to allow a portion of its surface, having a conductive material disposed thereon, to support transfer of heat away from the DIMM at a point of thermal contact. The apparatus can be coupled to a printed circuit assembly (PCA) having additional cooling mechanisms installed thereon, in a manner that allows the additional cooling mechanisms to be integrated with the apparatus and provide increased thermal cooling for the DIMMs.

The present invention relates to a method for connecting tubes (221) of a shell and tube heat exchanger (200) to a tube bottom (230) of the shell and tube heat exchanger (200), wherein the tubes (221) and the tube bottom (230) are each made of aluminum or an aluminum alloy, and wherein the tubes (221) are connected to the tube bottom (230) by means of laser welding in a bonded manner.

A cooling mechanism of high mounting flexibility includes a heat sink including a heat sink body defining an accommodation portion and position-limit sliding grooves and stop blocks fastened to the heat sink body, heat pipes positioned in the position-limit sliding grooves and stopped against the stop blocks, each heat pipe having a hot interface accommodated in the accommodation portion and an opposing cold interface positioned in one position-limit sliding groove, heat transfer blocks each defining a recessed insertion passage for accommodating the hot interfaces of the heat pipes and an opposing planar contact surface for the contact of a heat source of an external circuit board, and an elastic member elastically positioned between the heat sink and the heat transfer blocks.

An exhaust gas heat exchanger may include a housing and a heat exchanger block arranged therein, the heat exchanger block including tube plates and a tube bundle having a plurality of flat tubes held at longitudinal ends of the flat tubes in rim holes formed in a complementary manner thereto in the tube plates. A first flow path for exhaust gas may extend in the flat tubes, and a second flow path for coolant may extend around the flat tubes and within the housing. The housing may include a plurality of latching contours, which interact with a plurality of counterpart latching contours arranged on an associated tube plate to fix the tube plates and the heat exchanger block on the housing.

Provided is a heat exchanger automatic assembly apparatus including: a fin distribution unit distributing fins; a fin transfer unit including two or more fin trays and a driving means connected to the fin trays, respectively, to selectively transfer the fin trays to a predetermined position; and a fin discharge unit discharging the fins stored in the fin trays of the fin transfer unit to the predetermined position. The fins may be continuously supplied to the fin trays without stopping the supply of the fins to the fin trays and the plurality of fins may be discharged at one time to allow the fins to be interposed between the tubes arranged to be spaced apart from each other, thereby reducing a supply time of the fin to improve productivity, and reducing discarded fins to reduce the manufacturing cost.

An end tab for a heat exchanger frame includes a plate, an end, an expansion portion, and a bent portion. The plate has a first width, and the end has a second width larger than the first width. The expansion portion increases the width from the first width to the second width. The bent portion connects the plate and the end and includes at least one window.

The present invention relates to an integrally supported cooling device for mounting to a wind turbine nacelle without a mounting frame, the wind turbine nacelle having a first face with a longitudinal extension in a wind direction, whereby the cooling device comprises at least one heat exchanger core configured to extend across the wind direction and to define a cooling area of the cooling device, the heat exchanger core having a first side and a second side arranged opposite the first side in relation to the heat exchanger core, a first manifold being arranged along the first side and a second manifold being arranged along the second side, each in fluid communication with the at least one heat exchanger core, the pair of manifolds extending parallel along the cooling area, whereby the second manifold comprises suspension means and the cooling device is adapted to be mounted to the wind turbine nacelle by suspension of the second manifold to the first face of the wind turbine nacelle via said suspension means.

Various embodiments of the present disclosure provide a heat sink for a plug-in storage card and a plug-in storage card including the heat sink. The heat sink comprises a first part secured to a surface of the plug-in storage card and a second part coupled to the first part and being movable relative to the first part in a first direction, wherein the first direction is perpendicular to the surface of the plug-in storage card. In this way, when the second part and the first part have a larger overlap in the first direction, the heat sink has a smaller first height and when the second part and the first part have a smaller overlap in the first direction, the heat sink has a greater second height.