Abstract: A temperature control throttle device is provided. The temperature control throttle device includes: at least one throttle; a first pipeline and a second pipeline, wherein, the first pipeline and the second pipeline are connected to the same side of the at least one throttle in an air flow direction in parallel, and wherein the second pipeline is provided with a heat exchanger that heats air flowing through the second pipeline with engine coolant, engine oil or engine exhaust gas as a heat source.

Abstract: A system includes a reciprocating engine having a cylinder liner having an inner surface that defines a cavity and multiple slots disposed along a portion of the inner surface. The reciprocating engine also includes a piston disposed within the cylinder liner and configured to move between a first position and a second position. The reciprocating engine further includes a first ring disposed about the piston beneath a top land of the piston. The first ring, the top land, a first ring groove of the piston, and the inner surface of the cylinder liner define a top land cavity. The reciprocating engine also includes a second ring disposed about the piston below the first ring and a second land of the piston. The first and second rings, the second land, a second ring groove of the piston, and the inner surface of the cylinder liner define an interring cavity.

Abstract: An engine thermal management system for a vehicle having an exhaust gas system and an engine with an integrated exhaust manifold and a method for controlling the same are provided. The engine thermal management system may include a coolant pump, an engine water jacket, and a controller. The engine water jacket expels coolant from an IEM coolant outlet, which is directly cast into the integrated exhaust manifold. The coolant flowing through the engine water jacket and expelled from the IEM coolant outlet is in heat exchange relation with a heated exhaust gas flowing through the exhaust gas system, via an engine cylinder head and an exhaust gas septum, to thereby extract heat therefrom, resulting in a heated coolant, which is expelled from the IEM coolant outlet and selectively routed, by the controller, to one of a heater core, an engine oil heat exchanger, a transmission heat exchanger, and a radiator.

Abstract: A cooling system for an engine having a plurality of piston cylinders. The cooling system can include a liquid coolant source having liquid coolant and a cylinder cooling passage network having an inlet and an outlet for receiving and transmitting the liquid coolant. The cylinder cooling passage network having a plurality of individual upstream fluidic passages each being fluidly coupled to the inlet to directly receive the liquid coolant from the liquid coolant source in parallel flow. The cylinder cooling passage network further having a plurality of cylinder jacket passages each extending about at least a portion of a corresponding one of the plurality of piston cylinders and being positioned immediately adjacent thereto. The cylinder jacket passages are fluidly coupled directly to a corresponding one of the plurality of individual upstream fluidic passages to receive the liquid coolant and transmit the liquid coolant to the outlet for improved cooling performance.

Abstract: An internal combustion engine includes a deactivatable cylinder group, a constantly operating cylinder group, a first water passage, a second water passage, an upstream integrated water passage, a downstream integrated water passage, a connecting passage, a third water passage, and a device. The downstream integrated water passage includes a junction and an upstream end. The upstream end is closer to the second water passage than to the first water passage in the downstream integrated water passage. The third water passage connects the connecting passage and a portion provided between the junction and the upstream end in the downstream integrated water passage. The device is provided adjacent to at least a part of the third water passage to exchange heat with water flowing in the third water passage.

Abstract: Cooling circuit for an internal combustion engine, having an internal combustion engine with at least one cylinder head and one crankcase, a coolant pump, a primary heat exchanger, and a heat exchanger for an operating medium of the internal combustion engine, the cooling circuit 1 downstream of the coolant pump being divided between a branch site A and a connection site B so that at least one cylinder head is incorporated in a cylinder head branch circuit and the crankcase is incorporated in a crankcase branch circuit and the heat exchanger for an operating medium being located in the cylinder head branch circuit downstream of the at least one cylinder head

Abstract: A radiator mounting arrangement on a utility vehicle with an injection molded top tank and bottom tank, the top tank having a plurality of integrally molded features extending upwardly therefrom. A wire form is attached to a frame member of the utility vehicle and engages the integrally molded features without fasteners.

Abstract: An internal combustion engine having at least one piston cylinder comprising a housing enclosing twin gas injectors and having two inlet openings for separate supply of hydrogen gas and oxygen gas to a combustion chamber of the piston cylinder, two pressure-controlled and time-controlled, electrical inlet valves and associated nozzle needles coupled to the housing, wherein the combustion chamber has an outlet opening for ejection of a combustion product, and a thermolysis catalyst covering the combustion chamber. The thermolysis catalyst includes two hollow cylinders arranged at a distance from one another and concentrically and surrounding an intermediate space. The walls of the hollow cylinders defining the intermediate space have a metal coating for release of the heat of combustion acting on the inner hollow cylinder. The outer hollow cylinder includes an inlet opening for the supply of water, an outlet opening for the release of oxyhydrogen gas and a temperature sensor for control of water supply.

Abstract: Device for air intake of a heat engine including: —a main circulation system (105) which connects a supercharging apparatus (106) or an air intake manifold (107) which incorporates a heat exchanger (108), —a bypass system (109) linked to the main circulation system along the exchanger, the bypass system incorporating a heating apparatus (29), —a circuit selection device mounted between the main circulation system and the bypass system to channel at least some of the air into one or the other system.

Abstract: Exhaust ports and an exhaust gas gathering portion are formed within a cylinder head. A main passage is formed within an engine body. Through the main passage, a coolant is introduced from the inside of a cylinder block into the inside of the cylinder head at portions near exhaust valves, flows in portions near intake valves and portions near intake ports toward a side wall face of the cylinder head in the lateral direction of the engine body, and then flows into the cylinder block. A portion of the coolant, which is introduced into the portions near the exhaust valves, is caused to flow in portions near the exhaust ports toward a side wall face of the cylinder head, and then flows along the side wall face toward a coolant outlet.

Abstract: A vehicle temperature control system comprising an internal combustion engine with an engine block and with a cylinder head, a heat source for heating a heat transfer medium, a heat exchanger arrangement for the transfer of heat transported in the heat transfer medium to air to be introduced into a vehicle interior, and a valve arrangement, by means of which the heat transfer medium heated by the heat source can be fed selectively, at least in part, to a first heat transfer region, provided in the region of the cylinder head, of the internal combustion engine, without being conducted into a second heat transfer region, provided in the region of the engine block, of the internal combustion engine.

Abstract: Heat transfer members (H4, H3, H2, H1) are sequentially disposed within an exhaust port (18), within a pre-catalytic device (34), and on the downstream of a main catalytic device (35); the exhaust port (18), the pre-catalytic device (34), and the main catalytic device (35) being provided in an exhaust passage (33) of an internal combustion engine. The heat transfer surface density (heat transfer area/volume) of the heat transfer members (H4) on the upstream side of the exhaust passage (33) is the lowest, and that of the heat transfer members (H1) on the downstream side is the highest. Thus, even though the temperature of the exhaust gas is higher on the upstream side of the exhaust passage (33) than it is on the downstream side of the exhaust passage (33), a uniform heat transfer performance across all of the heat exchangers (H4, H3, H2, H1) may be maintained.

Abstract: An engine of reciprocating piston type includes a cylinder block (4) with one or more cylinders (2), each of which receives a respective piston (10) and is defined by a respective cylinder barrel (8), which is integral with the reminder of the cylinder block. The outer surface of each cylinder barrel (8) carries a plurality of substantially circumferential discontinuous reinforcing ribs, each comprising a plurality of elongate projections (12) spaced apart by gaps (14). Each projection (12) in each rib is in registry with a gap in the or each adjacent rib, when viewed in the direction of the length of the associated cylinder barrel.

Abstract: Heat exchangers (H4, H3, H2, H1) are sequentially disposed within an exhaust port (18), within a pre-catalytic device (34), and on the downstream of a main catalytic device (35); the exhaust port (18), the pre-catalytic device (34), and the main catalytic device (35) being provided in an exhaust passage (33) of an internal combustion engine. With regard to the heat transfer surface densities (heat transfer area/volume) of these heat exchangers (H4, H3, H2, H1), that of the heat exchanger (H4) on the upstream side of the exhaust passage (33) is the lowest, and that of the heat exchanger (H1) on the downstream side is the highest.

Abstract: An inverted aircraft internal combustion engine, such as a two-stroke compression-ignition (diesel) engine, incorporates a lubricant (oil) and/or coolant heat exchanger mounted upon the engine below an exposed crankshaft and/or enclosed crankshaft housing and adjacent a propeller mounting location.

Abstract: The invention provides a reserve tank for engine coolant formed by a blow molding method in which an external surface of the reserve tank is colored simultaneously with blow molding process and thus painting is unnecessary, and a straddle-type all terrain vehicle equipped with the reserve tank. The method comprises the steps of placing a thermoplastic tube, called a “parison”, between halves of an open mold, closing the mold halves, blowing the parison to expand the parison to the cavities of the mold halves, and cooling the parison to set the material, thereby forming the reserve tank. The method further comprises the steps of placing a thermoplastic film with a color which is different from that of the parison so that it covers at least one of the cavities before closing the molds, and expanding the thermoplastic film to the cavities along with the parison so that the film sticks thereto.

Abstract: A water reservoir is provided for use in conjunction with the engine of a marine propulsion system. The water reservoir is shaped to comprise two or more water containment cavities that can be located in positions which absorb heat from various heat producing components of the engine and, in addition, serve as sound barriers to attenuate noise emanating from the engine. The water reservoir is connected in fluid communication with the water pump of the marine propulsion system and in fluid communication with a cooling system of the engine.

Abstract: The present invention provides an airtight reservoir in fluid communication with a cooling system of an internal combustion engine. This cooling system allows coolant to flow into the overflow bottle, thereby compressing air therein, and causing increases pressure. When the coolant again cools, the pressurized coolant flows back into the cooling system, thereby maintaining the system pressure above ambient.