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A device for recovering heat from a hot gas stream comprises a gas diverter valve and a gas/liquid heat exchanger. The diverter valve comprises a valve body; a valve element movable between a bypass position and a heat exchange position; and a gas inlet and a gas outlet formed in the valve body. The

A device for recovering heat from a hot gas stream comprises a gas diverter valve and a gas/liquid heat exchanger. The diverter valve comprises a valve body; a valve element movable between a bypass position and a heat exchange position; and a gas inlet and a gas outlet formed in the valve body. The heat exchanger comprises a heat exchanger core comprised of a stack of core plates arranged parallel to the exhaust gas flow path, and the heat exchanger is located outside the exhaust gas flow path and may be spaced therefrom so as to avoid unwanted heat transfer with the valve in bypass mode. The heat exchanger may include a bottom-most gas flow path adjacent to the bottom plate, and may include a mounting plate which is mechanically secured to the valve body, with a thermally insulating gasket provided between the mounting plate and the valve body.

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1. A heat recovery device comprising a gas diverter valve and a gas/liquid heat exchanger; the gas diverter valve comprising a valve body; a valve element movable between a bypass position and a heat exchange position; and a gas inlet and a gas outlet formed in the valve body;the gas/liquid heat exc

1. A heat recovery device comprising a gas diverter valve and a gas/liquid heat exchanger; the gas diverter valve comprising a valve body; a valve element movable between a bypass position and a heat exchange position; and a gas inlet and a gas outlet formed in the valve body;the gas/liquid heat exchanger comprising a heat exchanger core comprised of a stack of core plates, the core comprising a plurality of gas flow passages and a plurality of liquid flow passages arranged in alternating order, a gas inlet manifold and a gas outlet manifold in flow communication with said plurality of gas flow passages, and a liquid inlet manifold and a liquid outlet manifold in flow communication with said plurality of liquid flow passages;wherein a bypass gas flow path extends between the gas inlet and the gas outlet of the valve body and the heat exchanger is located outside the bypass gas flow path;wherein, with the valve element in the bypass position, the bypass gas flow path is substantially completely open and flow communication between the gas inlet and the heat exchanger is substantially completely blocked by the valve element; andwith the valve element in the heat exchange position, the bypass gas flow path is substantially completely blocked by the valve element, and the gas inlet is in flow communication with the heat exchanger;wherein the core includes a plurality of core plates, each of the core plates having two liquid manifold openings and two gas manifold openings, wherein each of the core plates has a gas side and a liquid side, and wherein the core plates are sealed together in the core such that each of the gas flow passages is defined between the gas sides of two adjacent core plates and each of the liquid flow passages is defined between the liquid sides of two adjacent core plates, and such that the manifold openings in the plates align to form said manifolds, with the gas inlet and outlet manifolds in flow communication with the gas flow passages and the liquid inlet and outlet manifolds in flow communication with the liquid flow passages;wherein a bottom of said core is proximate to the valve body and a top of said core is distal to the valve body, and wherein the core includes a bottom core plate located at the bottom of the core;wherein the bottom core plate includes one of said gas inlet manifold openings and one of said gas outlet manifold openings;wherein a bottom-most gas flow passage is defined between the bottom plate and an adjacent one of said core plates; and wherein said bottom-most gas flow passage is in direct heat exchange contact with only one of said liquid flow passages. 2. The heat recovery device according to claim 1, wherein all of the core plates except the core plates at the top and bottom of the stack are identical. 3. The heat recovery device according to claim 1, wherein the bottom plate forms a closed bottom of the liquid inlet manifold and a closed bottom of the liquid outlet manifold. 4. The heat recovery device according to claim 1, wherein a bottom of said core is proximate to the valve body and a top of said core is distal to the valve body, and wherein the core includes a top core plate located at the top of the core; wherein the top core plate includes a liquid inlet manifold opening and a liquid outlet manifold opening and forms a closed top of the gas inlet manifold and a closed top of the gas outlet manifold; andwherein the liquid inlet manifold opening of the top core plate is provided with a liquid inlet fitting and the liquid outlet manifold opening of the top core plate is provided with a liquid outlet fitting. 5. The heat recovery device according to claim 1, wherein the gas inlet and outlet manifolds and the liquid inlet and outlet manifolds are substantially perpendicular to the bypass gas flow path, and wherein the gas flow passages and the liquid flow passages are substantially parallel to the bypass gas flow path. 6. The heat recovery device according to claim 1, wherein the liquid inlet manifold opening and the liquid outlet manifold opening are provided along one side of the core plate, wherein the liquid flow passages are U-shaped, and wherein a rib separates the liquid inlet and outlet manifold openings to prevent short-circuiting flow between the manifold openings; and wherein the rib is discontinuous, and provides gaps through which a portion of the liquid is able to flow through the rib. 7. The heat recovery device according to claim 1, wherein surfaces of the valve body extending between the gas inlet and the heat exchanger, and between the heat exchanger and the gas outlet, are smoothly rounded. 8. The heat recovery device according to claim 7, wherein said valve element engages said smoothly rounded surfaces with the valve element in the bypass position. 9. The heat recovery device according to claim 7, wherein at least one of said smoothly rounded surfaces is provided with an indentation to receive an edge of the valve element when the valve element is in the bypass position. 10. The heat recovery device according to claim 1, wherein the valve body has a sealing surface along which it is secured to the heat exchanger, said sealing surface surrounding an opening in said valve body through which flow communication is provided between an interior of the valve body and the heat exchanger; and with the valve element in the bypass position, the sealing surface of the valve body is spaced from the valve element such that a closed chamber is formed inside the valve body between the bypass gas flow path and the sealing surface. 11. A heat recovery device comprising a gas diverter valve and a gas/liquid heat exchanger; the gas diverter valve comprising a valve body; a valve element movable between a bypass position and a heat exchange position; and a gas inlet and a gas outlet formed in the valve body;the gas/liquid heat exchanger comprising a heat exchanger core comprised of a stack of core plates, the core comprising a plurality of gas flow passages and a plurality of liquid flow passages arranged in alternating order, a gas inlet manifold and a gas outlet manifold in flow communication with said plurality of gas flow passages, and a liquid inlet manifold and a liquid outlet manifold in flow communication with said plurality of liquid flow passages;a mounting plate secured to the bottom plate of the heat exchanger;wherein a bypass gas flow path extends between the gas inlet and the gas outlet of the valve body and the heat exchanger is located outside the bypass gas flow path;wherein, with the valve element in the bypass position, the bypass gas flow path is substantially completely open and flow communication between the gas inlet and the heat exchanger is substantially completely blocked by the valve element; andwith the valve element in the heat exchange position, the bypass gas flow path is substantially completely blocked by the valve element, and the gas inlet is in flow communication with the heat exchanger;wherein the core includes a plurality of core plates, each of the core plates having two liquid manifold openings and two gas manifold openings, wherein each of the core plates has a gas side and a liquid side, and wherein the core plates are sealed together in the core such that each of the gas flow passages is defined between the gas sides of two adjacent core plates and each of the liquid flow passages is defined between the liquid sides of two adjacent core plates, and such that the manifold openings in the plates align to form said manifolds, with the gas inlet and outlet manifolds in flow communication with the gas flow passages and the liquid inlet and outlet manifolds in flow communication with the liquid flow passages;wherein the valve body has a sealing surface along which it is secured to the mounting plate, said sealing surface surrounding an opening in said valve body through which flow communication is provided between an interior of the valve body and the heat exchanger; andwherein the mounting plate is provided with a gas inlet manifold opening in alignment with said gas inlet manifold and a gas outlet manifold opening in alignment with said gas outlet manifold, and wherein the gas inlet and outlet manifold openings of the mounting plate are spaced apart from one another along the bypass gas flow path. 12. The heat recovery device according to claim 11, wherein a thermally insulating gasket is provided between the sealing surface of the valve body and the mounting plate. 13. The heat recovery device according to claim 11, wherein the valve body is secured to the mounting plate by mechanical fasteners. 14. The heat recovery device according to claim 11, wherein the sealing surface of the valve body, the mounting plate, and a sealing surface of the bottom plate are planar; and wherein the sealing surface of the bottom plate surrounds the gas inlet and outlet manifolds of the bottom plate. 15. The heat recovery device according to claim 14, wherein the valve element pivots along a pivot axis extending through the valve body at an angle of about 90 degrees to the bypass gas flow path, and wherein an edge of the valve element engages a surface of the mounting plate with the valve element in the heat exchange position. 16. The heat recovery device according to claim 15, said surface of the mounting plate is provided with an upstanding flange which engages and overlaps an edge of the valve element when the valve element is in the heat exchange position. 17. A heat recovery device comprising a gas diverter valve and a gas/liquid heat exchanger; the gas diverter valve comprising a valve body; a valve element movable between a bypass position and a heat exchange position; and a gas inlet and a gas outlet formed in the valve body;the gas/liquid heat exchanger comprising a heat exchanger core comprised of a stack of core plates, the core comprising a plurality of gas flow passages and a plurality of liquid flow passages arranged in alternating order, a gas inlet manifold and a gas outlet manifold in flow communication with said plurality of gas flow passages, and a liquid inlet manifold and a liquid outlet manifold in flow communication with said plurality of liquid flow passages;wherein a bypass gas flow path extends between the gas inlet and the gas outlet of the valve body and the heat exchanger is located outside the bypass gas flow path;wherein, with the valve element in the bypass position, the bypass gas flow path is substantially completely open and flow communication between the gas inlet and the heat exchanger is substantially completely blocked by the valve element; andwith the valve element in the heat exchange position, the bypass gas flow path is substantially completely blocked by the valve element, and the gas inlet is in flow communication with the heat exchanger;wherein the core includes a plurality of core plates, each of the core plates having two liquid manifold openings and two gas manifold openings, wherein each of the core plates has a gas side and a liquid side, and wherein the core plates are sealed together in the core such that each of the gas flow passages is defined between the gas sides of two adjacent core plates and each of the liquid flow passages is defined between the liquid sides of two adjacent core plates, and such that the manifold openings in the plates align to form said manifolds, with the gas inlet and outlet manifolds in flow communication with the gas flow passages and the liquid inlet and outlet manifolds in flow communication with the liquid flow passages;wherein all of the core plates except the core plates at the top and bottom of the stack are identical; andwherein the heat transfer requirements of the device are adjustable simply by adding or removing one or more of said identical core plates to or from the core of the heat exchanger. 18. A gas/liquid heat exchanger for a heat recovery device, comprising a heat exchanger core comprised of a stack of core plates, the core comprising a plurality of gas flow passages and a plurality of liquid flow passages arranged in alternating order, a gas inlet manifold and a gas outlet manifold in flow communication with said plurality of gas flow passages, and a liquid inlet manifold and a liquid outlet manifold in flow communication with said plurality of liquid flow passages; wherein the core includes a plurality of core plates, each of the core plates having two liquid manifold openings and two gas manifold openings, wherein each of the core plates has a gas side and a liquid side, and wherein the core plates are sealed together in the core such that each of the gas flow passages is defined between the gas sides of two adjacent core plates and each of the liquid flow passages is defined between the liquid siillustdes of two adjacent core plates, and such that the manifold openings in the plates align to form said manifolds, with the gas inlet and outlet manifolds in flow communication with the gas flow passages and the liquid inlet and outlet manifolds in flow communication with the liquid flow passages;wherein the core includes a bottom core plate located at the bottom of the core, the bottom core plate including one of said gas inlet manifold openings and one of said gas outlet manifold openings and forming a closed bottom of the liquid inlet manifold and a closed bottom of the liquid outlet manifold; andwherein a bottom-most gas flow passage is defined between the bottom plate and an adjacent one of said core plates, said bottom-most gas flow passage being in direct heat exchange contact with only one of said liquid flow passages. 19. The gas/liquid heat exchanger according to claim 18, wherein the liquid inlet manifold opening and the liquid outlet manifold opening are provided along one side of the core plate, wherein the liquid flow passages are U-shaped, and wherein a rib separates the liquid inlet and outlet manifold openings to prevent short-circuiting flow between the manifold openings; and wherein the rib is discontinuous, and provides gaps through which a portion of the liquid is able to flow through the rib.