A plate heat exchanger includes a casing in which heat transfer plates are arranged, wherein a first distribution tube and a second distribution tube that extend through respective first port openings and second port openings of the heat transfer plates includes outlets and inlets that face each other, a first passage and a second passage extend along the casing and along first sides and second sides of the heat transfer plates and comprise outlets and inlets that face each other.

A plate heat exchanger includes first and second frame plates, and a stack of heat transfer plates. Each heat transfer plate has a peripheral portion encircling a center portion. The heat transfer plates are arranged in pairs between the first and second frame plates, and formed between the pairs of heat transfer plates is a first flow path for a first fluid and a second flow path for a second fluid. One of the first and second flow paths is a free-flow path along which center portions of the heat transfer plates are completely separated from each other. A reinforcement plate is thicker than the heat transfer plates and has a center portion encircled by a peripheral portion. The reinforcement plate is arranged between the first frame plate and the stack of heat transfer plates. Permanent reinforcement joints each bond together the reinforcement plate and an outermost heat transfer plate.

A heat exchanger may include a plurality of pipe bodies arranged between two side parts. At least one side part may have at least one predetermined breaking point and at least one heat expansion compensator. The at least one side part may include at least one aperture, which may lead from the at least one predetermined breaking point to the at least one heat expansion compensator.

A bolster is provided and includes a bottom plate including a side plate extending upwards from a side of the bottom plate and a holding portion bending inwards from an edge of the side plate, a pillar vertically provided on the bottom plate and adjacent to the holding portion, and a torsion bar including two end portions and a main body portion, where one of the two end portions is fixed in the pillar and restricted by the holding portion, and the main body portion is restricted by the side plate. The bolster can effectively reduce warpage and deformation of the bottom plate.

The invention relates to a fixing device (1) for reinforcing the joint of a rotary heat exchanger (2) which has a hub part (5) and a heat storage part (6) made of corrugated and flat layers that are wound in an alternating manner. The aim of the invention is to reinforce the joint of the rotary heat exchanger with as little technical complexity as possible. This is achieved in that the rotary heat exchanger (2) can be arranged in the fixing device (1) in a stationary manner, the fixing device (1) has a screw drill device (10) which is arranged on the outer circumference of the rotary heat exchanger (2) arranged in the fixing device (1) and by means of which at least one screw spoke (17) can be drilled or screwed from the outer lateral surface (9) of the rotary heat exchanger (2) through the corrugated and flat layers of the heat storage part (6) of the rotary heat exchanger (2) and into the hub part (5) thereof.

The invention relates to a system component of an exhaust system for a combustion engine, more preferably of a motor vehicle, with at least one component portion having a closed hollow space structure (2), wherein walls of the closed hollow space structure (2) enclose a reaction chamber (5), in which at least one stationary system component (6) of a reactive heating system is arranged. By using a reactive heating system a rapid heating-up of at least one system component of the exhaust system is advantageously possible.

A method of manufacturing a heat exchanger comprising a body and a support embedded within the body. The support comprises a different material and/or a different material structure to the body and hence has at least one material property which is different to that of the body. The method comprises; forming at least a first portion of the support with a first material and a first material structure using a first additive manufacturing step; and forming at least a first portion of the body with a second material and a second material structure using a second additive manufacturing step. The first material is different to the second material and/or the first material structure is different to the second material structure.

A plate heat exchanger has openings in the plates defining supply and return ducts extending through a plate stack. The supply and return ducts are hydraulically connected to flow ducts located between the plates and to a tube arranged coaxially in each of the supply and return duct. The tubes have holes in the tube wall in order to provide the hydraulic connection to the flow ducts. A simple and cost-effective plate heat exchanger which can withstand high pressures is achieved by the tubes extending through the entire stack to form a tie rod between a top side and an underside of the plate stack. The tube has a diameter corresponding to the diameter of the openings in the plates such that the tube wall is firmly metallurgically connected to at least some edges of the openings.

A plate heat exchanger comprises plural heat exchanger plates and at least one adapter plate, which each extend parallel with a main extension plane. The heat exchanger plates form a plate package with first and second plate interspaces for first and second mediums. Each heat exchanger plate has four port holes extending through the plate package. The heat exchanger plates comprise outermost heat exchanger plates. Two of the plate interspaces form a respective outermost plate interspace at a respective side of the plate package, which are delimited outwardly by a respective one of the outermost heat exchanger plates, and the adapter plate is outside one of the outermost heat exchanger plates. A distance plate between the adapter plate and one of the outermost heat exchanger plates has at least two port holes concentric with each of the respective port holes of the outermost heat exchanger plates and the adapter plate.

A module of heat transfer plates which are welded to each other comprises a first outer heat transfer plate, at least a first and a second heat transfer plate, and a first reinforcement arrangement. Port holes form a first port channel in the module. The first reinforcement arrangement comprises a first abutment member and a first supporting member. The first abutment member is arranged on a side of the first outer heat transfer plate opposite to the first heat transfer plate. The first supporting member is arranged between the first abutment member and the first outer heat transfer plate. The first supporting member abuts against the first abutment member and the first outer heat transfer plate. Further a heat exchanger comprising such a module is provided.