This disclosure relates generally to internal combustion engines, especially diesel engines in motor vehicles which use exhaust gas recirculation (EGR) as a component of tailpipe emission control strategy. The disclosure particularly relates to an EGR cooler for cooling exhaust gas being recirculated.
A typical EGR system of an engine includes one or more EGR valves for controlling the flow of engine exhaust gas from the engine's exhaust system to the engine's intake system to meter a controlled quantity of exhaust gas into fresh air passing through the intake system where the air supports combustion of fuel in the engine's cylinders. The metered exhaust gas can limit in-cylinder temperature rise during combustion and consequently limit the quantity of oxides of nitrogen (NOx) in engine-out exhaust gas.
Some EGR systems, especially those designed for compression ignition (i.e. diesel) engines, have one or more heat exchangers for cooling recirculated exhaust gas. They are sometimes referred to as EGR coolers. Cooling of exhaust gas being recirculated can further limit the quantity of NOx in engine-out exhaust gas.
An EGR cooler currently used in a production engine has a housing which comprises a wall which extends lengthwise of the housing and has a transverse cross section enclosing an interior which extends lengthwise through the housing from a first open end of the housing to a second open end of the housing. The housing also has a coolant inlet through which engine coolant enters the interior and a coolant outlet through which coolant exits the interior.
A core is housed within the housing and comprises multiple tubes which extend lengthwise through the housing interior and through which exhaust gas is conveyed through the coolant core. Heat of exhaust gas flowing through the tubes is transferred through the tube walls to coolant flowing through the housing. The tubes are separated from each other by intervening spaces so that coolant flowing through the housing interior passes along the entire exterior surface of each tube.
An inlet header plate is disposed over the first open of the housing and comprises through-openings within each of which an open inlet end of a respective tube fits. Along a lengthwise segment of each tube, the exterior tube surface has dimensional clearance to a surrounding wall surface of the respective through-opening. Material is disposed in dimensional clearance space to extend continuously around the lengthwise segment of each tube and join the lengthwise segment with the surrounding wall surface of the respective through-opening, creating a fluid-tight seal between the exterior tube surface and the through-opening.
Open outlet ends of the tubes are received in and sealed to through-openings of an outlet header plate in a similar manner at the second lengthwise end of the housing.
Each header plate has a continuous perimeter margin disposed against the wall of the housing at a respective opposite end of the housing and a central region which is bounded by the continuous perimeter margin and overlies the respective housing end.
Like other engine components, an EGR cooler is subject to stresses which are thermally and mechanically induced. Mechanical constraints on certain cooler parts may lead to cooler failure because of the cumulative effect of such stresses as engine operating time accumulates.
For example, over time the material which joins a tube to a header plate (typically brazing material) may crack due to the cumulative effect of thermal cycles which occur as an engine warms up and cools down, thereby breaking the integrity of the joint. Stress increases due to tube growth as the engine warms up and continues running at operating temperature. Stress decreases as tube growth reverses once the engine is shut off and begins to cool down.
If the lengths of the tubes between the header plates are long enough to subject them to unwanted vibration, mid-core spring clips may be employed in mitigation of the effects of mechanically induced vibration. However in doing so, the spring clips may amplify the effect of thermally induced stress on the core, especially between the spring clips and the inlet header plate. Relaxing the spring force of these clips for the purpose of attenuating the amplification is counterproductive to their effectiveness against vibration.
Stresses which tend to break the integrity of joints between the tubes and through-openings in a header plate, especially an inlet header plate, are mitigated by creating at least one endless groove in a flat zone of a central region of a header plate which contains the through-openings and which has a constant nominal thickness between opposite faces. The endless groove circumscribes the through-openings and reduces the constant nominal thickness of the flat zone along the groove without creating an opening through the flat zone between its opposite faces.
The endless groove imparts a degree of compliance to the flat zone which allows it to deform slightly and thereby mitigate stresses at the tube/header plate joints as the tubes grow. The endless groove can be created by known machining processes, such as milling for example. Various groove profiles are contemplated.
One profile is created by machining grooves into opposite faces of a header plate to establish an “S” shaped profile. As the tubes are heated by hot exhaust gas and/or engine coolant, they grow axially. With the endless groove having an “S” shaped profile, the header plate zone circumscribed by the endless groove is able to slightly deform as the tubes grow. The deformation occurs with resiliency which allows the zone to undeform as tube growth reverses with cooling.
The nominal thickness of the header plate is established by selecting a minimum surface area at each tube/header plate joint for proper brazing. Without the endless groove, the selected thickness does not allow the central region to have compliance for accommodating tube growth and consequently after a sufficient number of repeated thermal cycles, a tube, or its joint at the header plate, may eventually fail such as by the tube separating from the header plate, or breaking at or near the braze joint.
A general aspect of this disclosure relates to an EGR cooler comprising a core and a housing which houses the core. The housing comprises a wall which extends lengthwise of the housing and has a transverse cross section enclosing an interior which extends lengthwise through the housing from a first open end to a second open end.
The core comprises multiple straight tubes which extend lengthwise through the interior and are spaced apart from each other, and a header plate having a continuous perimeter margin disposed against the wall of the housing at the first open end and a central region which is bounded by the continuous perimeter margin and overlies the first open end.
The central region comprises multiple through-openings each receiving an open end of a respective tube, each through-opening presenting a wall surface surrounding, and having dimensional clearance to, an outside surface of a respective tube along a lengthwise segment of the respective tube.
Joining material which extends continuously around the lengthwise segment of each tube joins the lengthwise segment of each tube with the surrounding wall surface of the respective through-opening and creates a fluid-tight seal between the tube and the through-opening.
The central region comprises a flat zone, of constant nominal thickness as measured lengthwise of the housing between opposite faces of the central region, the flat zone containing at least one endless groove which circumscribes the through-openings while reducing the constant nominal thickness of the flat zone along the groove without creating an opening through the flat zone between opposite faces of the central region.
The foregoing summary is accompanied by further detail of the disclosure as presented in the Detailed Description below with reference to the following drawings which are part of the disclosure.
The tubes 48 of each tube set 44, 46 are banded together by bands 52 to convert each tube set into a banded tube bundle. Each tube set 44, 46 has a generally rectangular-shape comprising a top, a bottom, and two sides.
Tubes 48 are identical flat-walled tubes arranged side-by-side with their flat walls separated from flat walls of adjacent tubes by intervening spaces. The flat parallel sides of each tube are joined by rounded ends at top and bottom. At inlets 40, 42, an entrance end of each tube 48 in each tube set 44, 46 is disposed within a respective through-opening 56 in an inlet header plate 58 which has opposite faces 60, 62 (see
Through-openings 56 take the shapes of through-slots which conform to the cross sections of tubes 48, but are slightly larger to provide dimension clearance which allows tubes 48 to be inserted into them and thereafter joined to the header plates by brazing. Along a lengthwise segment of each tube 48 disposed within a through-opening 56, the exterior tube surface has dimensional clearance to a surrounding wall surface of the through-opening Material (braze 64 seen in
Inlet header plate 58 has a continuous perimeter margin 66 which is disposed against a flange 68 at the inlet end of cooler housing 32 and held between it and a flange 70 of valve housing 26 by fasteners (not shown) passing through aligned holes in perimeter margin 66 and flanges 68, 70, gaskets 80 providing sealing between perimeter margin 66 and the housing flanges. Each respective valve outlet 36, 38 is open to the entrances of the tubes 48 in the respective tube set 44, 46.
Perimeter margin 66 circumscribes a central region 72 of inlet header plate 58 which overlies the open inlet end of cooler housing 32 and contains through-openings 56. Inlet header plate 58 is fabricated from flat material which has a constant nominal thickness as measured lengthwise of cooler housing 32 between opposite faces 60, 62. A flat zone 74 within central region 72 contains at least one endless groove 76 which circumscribes through-openings 56 while reducing the constant nominal thickness between faces 60, 62 along the length of the groove without creating an opening through flat zone 74 between opposite faces 60, 62. The endless groove is shown in
As viewed in
An end cap (not shown) fits over and is joined to the outlet header plate opposite tube sets 44, 46 for communicating the outlet ends of tubes 48 in each set to exhaust outlet openings in a cover covering the far end of coolant housing 32 in
Along the lengths of tube sets 44, 46, the interior of coolant housing 32 has a uniform rectangular cross section bounded by interior surfaces of a top wall, a bottom wall, and side walls of cooler housing 32. Exhaust gas which has entered EGR cooler 24 from EGR valve 22 flows through tubes 48 to exit EGR cooler 24 through the end cap and the exhaust outlet openings in the cover. Engine coolant which has entered EGR cooler 24 from the engine coolant system through coolant inlet 34 flows concurrently through the interior of cooler housing 32 and leaves through the coolant outlet openings in the cover. Exhaust gas and liquid coolant flow through EGR cooler 24 in parallel directions without mixing but in heat transfer relation through the thermally conductive walls of tubes 48.
Collectively, tube sets 44, 46 have a rectangular cross section smaller than that of the interior of cooler housing 32. In addition to support for the tube sets provided by the attachment of their tubes 48 to the header plates, tube sets 44, 46 may be supported at locations along their length on the housing walls by spring clips 77 which bear against the interior surface of a respective wall and are intended to aid in attenuating vibration.
Portions 76A, 76B are machined in inlet header plate 58 prior to assembly of tubes 48.
The result of the milling gives each groove portion a respective concave transverse cross section which is at least partially spherical. The concave transverse cross section of groove portion 76A which is at least partially spherical has a partially spherical surface 82 which begins at face 60 and ends at a depth from face 60. The concave transverse cross section of groove portion 76A further comprises a flat surface 84 which extends from the end of its partially spherical surface 82 to face 60 to form an obtuse angle with face 60.
The concave transverse cross section of groove portion 76B which is at least partially spherical has a partially spherical surface 86 which begins at face 62 and ends at a depth from face 62. The concave transverse cross section of groove portion 76B further comprises a flat surface 88 which extends from the end of its partially spherical surface 86 to face 62 to form an obtuse angle with face 62.
Flat surface 84 is disposed more distant from tubes 48 than is partially spherical surface 82, and flat surface 88 is disposed less distant from tubes 48 than is partially spherical surface 86. The apex of the obtuse angle which flat surface 84 makes with face 60 is disposed more distant from tubes 48 than is the apex of the obtuse angle which flat surface 88 makes with face 62. That creates the “S” shaped profile. A mirror image of the “S” shaped profile results when the groove portions are reversed by machining groove portion 76A in face 62 and groove portion 76B in face 60. Functionally, the mirror image is the same as shown in
When an endless groove 76 such as the one shown in
Various other embodiments of endless grooves 76 are shown in
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