A contoured branch fitting for reducing stress in a header pipe caused by acoustic induced vibration that includes a maximum width, a maximum length, a thickness that is greater along the maximum length and a constant radius between the branch connection and the header connection.

The present invention relates to a heat exchanger apparatus for a combustion engine. The apparatus comprises a heat exchanger comprising at least one magnetic component; and an induction heater positioned adjacent at least one magnetic component of the heat exchanger. The induction heater is connectable to a power supply to provide inductive heating to the heat exchanger.

The production method for producing a rifled tube, which includes a plurality of first helical ribs on its inner surface, includes: a steps of: preparing a steel tube; and producing a rifled tube by performing cold drawing on a steel tube by using a plug which includes a plurality of second helical ribs, the plug satisfying Formulae and:
0.08 <W(AB)N/(2A)<0.26(1)
0.83<S(AB)N/(2M)<2.0(2)
where, W is a width of a groove bottom surface of the helical groove; A is a maximum diameter of the plug; B is a minimum diameter of the plug; N is a number of the second helical ribs; S is the width of the groove bottom surface; and M is a pitch of adjacent second helical ribs.

A stainless steel that includes chromium and other alloying element as a plurality of alloying elements including: a base material layer including chromium of a specified chromium content necessary for forming a passive film or more; and a superficial layer including chromium at a lower chromium content than the chromium content contained in the base material layer, and the superficial layer including the other alloying elements at a same content of the other alloying element as the content of the other alloying element contained in the base material layer.

A printed circuit heat exchanger is provided. The printed circuit heat exchanger may include: a first bonding plate configured to include two plates bonded to each other and zigzag-shaped flow channels formed adjacent to each other between the two plates such that some sections of each of the plurality of flow channels are formed to overlap with adjacent flow channels; and a second bonding plate configured to include two plates bonded to each other and zigzag-shaped flow channels formed adjacent to each other between the two plates such that some sections of each of the plurality of flow channels are formed to overlap with adjacent flow channels, wherein the first bonding plate and the second bonding plate are alternately stacked.

A heat exchanger includes a plurality of first and second fluid passages. The first fluid passages are defined by a pair of opposing first fluid passage walls and a plurality of first fluid diverters disposed between the first fluid passages walls. The second fluid passages are defined by a pair of opposing second fluid passage walls and a plurality of second fluid diverters disposed between the second fluid passage walls. The second fluid diverters include a body portion and a leading edge portion. The first fluid passage walls form a first fluid leading edge that extends upstream of the leading edge portion of the second fluid diverters. The second fluid passages extend in a direction perpendicular to the direction of the first fluid passages.

A vertical seed conditioner may be formed of a plurality of sections that can be individually removed for repair and/or replacement without requiring the entire seed conditioner be permanently decommissioned. For example, the seed conditioner may be formed of a plurality of heat transfer sections stacked vertically with respect to each other to form the conditioning vessel. Each heat transfer section may include an inlet manifold, an outlet manifold, and multiple heat transfer tubes extending from the inlet manifold to the outlet manifold. The multiple heat transfer tubes may be spaced from each other to provide a gap between adjacent tubes through which the granular solid can travel.

Provided is a connection element comprising a tubular first part with a first ring-shaped connection face for connection with a highly heat resistant steel pipe and a tubular second part with a second ring-shaped connection face for connection with a first ferritic steel pipe; wherein the first part is of a corrosion resistant steel material and wherein the second part is of a ferritic steel material; wherein the first and second parts are in one-piece and formed such that a passage between the first and second ring-shaped connection faces is formed; and wherein the first and second parts are produced by an additive manufacturing process. Further provided are a pipe arrangement and a heat exchanger.

A contained thermal interface material for pluggable applications, structures, and a method for implementing thermal coupling between components with a contained thermal interface material for pluggable applications are provided. A thermal interface material is combined with a metal member providing effective thermal coupling between components for plugging and unplugging thermal management applications.

A clustered heat dissipation device and a chassis are provided. The clustered heat dissipation device includes a heat-absorbing manifold, plural heat-absorbing heads and plural connection pipes. The heat-absorbing manifold includes an inlet chamber and an outlet chamber. The inlet chamber includes at least one first liquid inlet and plural first liquid outlets. The outlet chamber includes plural second liquid inlets and at least one second liquid outlet. The heat-absorbing manifold is in thermal contact with a first heat source. The plural connection pipes are connected with the heat-absorbing heads and the corresponding first liquid outlets and connected with the heat-absorbing heads and the corresponding second liquid inlets.