Abstract: A counter-flow heat exchanger comprising a heat exchanger core including an inner wall and an outer wall radially outward and spaced apart from the inner wall. A first flow path is defined within the inner wall and a second flow path is defined between the inner wall and the outer wall. The heat exchanger core includes a primary flow inlet, a primary flow outlet and a middle portion therebetween. The inner and outer walls are concentric at the primary flow inlet of the heat exchanger core. The inner wall defines a first set of channels extending axially from the primary flow inlet to the middle portion of the heat exchanger core diverging away from a radial center of the heat exchanger core. The inner wall and the outer wall define a second set of channels extending axially from the primary flow inlet to the middle portion of the heat exchanger core converging toward the radial center of the heat exchanger core.

Abstract: An intake air filter box utilizing an intake air heater that inhibits the buildup of snow and ice within the intake air filter box, keeping the associated flow passages clear such that pressure loss is not adversely affected. This intake air heater can include an electric heater or a radiant heater coupled to the exhaust gas recirculation (EGR) system of the vehicle, or to another source of heated fluid. Preferably, the intake air heater is disposed on the “dirty” side of the filter disposed within the intake air filter box, adjacent to the intake air conduit and air intake of the vehicle. This is where the snow and ice accumulation occurs. A drain is provided in the bottom of the intake air filter box housing to allow the escape of water from the melted snow and ice, ensuring that this moisture is not delivered to the turbocharger and engine with the intake air.

Abstract: A vehicle heat exchange apparatus, including: a heat exchanger provided rearward of a front bumper formed with an air intake port, and having an air inlet member on a front face of the heat exchanger; and a duct member provided between the front bumper and the heat exchanger, and forming a passage for passing cooling air from the air intake port of the front bumper to the air inlet member of the heat exchanger, wherein the duct member has: a first intake port introducing air from a vehicle front side into the passage through the air intake port provided in the front bumper; a second intake port introducing air from a vehicle lower side into the passage; and an outlet port opened at an end portion of the passage and facing the air inlet member of the heat exchanger.

Abstract: Hydraulic fluid coolers suitable for cooling hydraulic fluid in a closed loop hydraulic circuit and capable of withstanding high hydraulic fluid pressures may include at least one heat exchanger. The at least one heat exchanger may include a header assembly having a header inlet conduit, a header outlet conduit and a fan motor outlet conduit. A plurality of primary cooling conduits may be disposed in fluid communication with and extend between the header inlet conduit and the header outlet conduit. A plurality of secondary cooling conduits may be disposed in fluid communication with and extend between the header inlet conduit and the fan motor outlet conduit. A cooling fan may be disposed adjacent to the plurality of primary cooling conduits and the plurality of secondary cooling conduits. A hydraulically-actuated cooling fan motor may drivingly engage the cooling fan. The cooling fan motor may be disposed in fluid communication with the fan motor outlet conduit of the header assembly.

Abstract: A bumper device for a motor vehicle has two bumper support members arranged parallel to the vehicle longitudinal center plane. The bumper device has a bumper crossmember arrangement arranged transversely with respect to the vehicle longitudinal center plane. The bumper crossmember arrangement has two fastening portions at which the bumper crossmember arrangement can be fastened to the associated bumper support member directly or by a respective connecting structure. A central portion between the fastening portions and two lateral end portions protrudes beyond the fastening portions. The central portion of the bumper crossmember arrangement is designed as a frame member surrounding an opening, with an upper crossmember, a lower crossmember, a left support post and a right support post.

Abstract: The present disclosure relates to a system for controlling an air flow rate into a vehicle engine room. The system includes: an air intake port receiving an exterior air at a front portion of the vehicle and supplying the air into the engine room; air ducts formed at both sides of the air intake port and introduce the exterior air into a wheel side in order to improve aerodynamic characteristic; a control valve configured to selectively convey the air flowed in the air intake port into the air ducts; a radiator disposed between the air intake port and the engine room; and a control portion configured to control the control valve based on an operating state of vehicle. The air ducts are selectively communicated with the air intake port and disposed at upstream of the radiator.

Abstract: A controller includes a forced-induction-device controlling section, an obtaining section that is configured to repeatedly obtain a temperature of the coolant in the intake-air cooling system, a determining section that is configured to determine whether the temperature obtained by the obtaining section is higher than or equal to a forced-induction limiting control starting temperature. On condition that the temperature of the coolant has risen to a value at which the determining section determines that the temperature obtained by the obtaining section is higher than or equal to the forced-induction limiting control starting temperature, the forced-induction-device controlling section starts a forced-induction limiting control to lower a forced-induction pressure. In the forced-induction limiting control, the forced-induction-device controlling section increases an extent of limiting of the forced induction as the temperature obtained by the obtaining section becomes closer to the boiling point.

Abstract: An engine assembly includes a turbocharger and a fluid conduit. The fluid conduit is thermally coupled to the turbocharger such that the coolant flowing through the fluid conduit can extract heat from the turbocharger. The engine assembly includes a surge tank and an engine head defining a coolant gallery. Further, the engine assembly includes an exhaust manifold integrated with the engine head. The coolant gallery is thermally coupled to the exhaust manifold such that the coolant can extract heat from the exhaust manifold. The engine assembly further includes a coolant manifold in fluid communication with the fluid conduit and the coolant gallery. The coolant manifold defines a venting orifice in fluid communication with the surge tank. Further, the coolant manifold defines a joint passageway in fluid communication with the fluid conduit. Moreover, the coolant manifold defines an interconnection passageway fluidly interconnecting the joint passageway and the coolant gallery.

Abstract: For a technical object whose temperature is to be controlled, in particular a battery for an electric vehicle drive, there is provided a heat exchanger arrangement, the heat exchanger of which is in the form of a heat-exchanging pouch which has an inflow and outflow duct and which is in heat-conducting contact with internal surfaces of the object whose temperature is to be controlled. The heat-exchanging pouch is produced in a simple manner by means of edge welding of two foil pieces arranged one above the other. The mounting of said heat-exchanging pouch in a narrow gap space of a heat exchanger arrangement, and good heat transfer to adjacent walls, are made possible by means of a pressure pouch which is likewise formed from a foil material and which is filled with a compressible medium.

Abstract: A compact multi-unit vehicle cooling system for reducing heat toward the engine of a vehicle. The compact multi-unit vehicle cooling system generally includes a radiator, an air charge cooler, a transmission oil cooler, an engine oil cooler and a power steering oil cooler. Each of the components of the present invention is secured in a compact package for installation in a vehicle such as a HUMMER or the like. By utilizing a modulated, compact design, the present invention may more easily be installed and serviced while significantly reducing heat towards the vehicle's engine and thus increasing horsepower.

Abstract: An exhaust fan chamber is defined with a belt cover and a fan cover provided over the belt cover, and an exhaust fan is accommodated in the exhaust fan chamber. The fan cover has an air intake port for sucking air within an engine cover into the exhaust fan chamber and an exhaust outlet port for discharging air within the exhaust fan chamber to outside of the exhaust fan chamber. The exhaust outlet port is in communication with an exhaust opening formed in an upper portion of the engine cover so that the air discharged through the exhaust outlet port is discharged to outside of the engine cover through the exhaust opening.

Abstract: A cooling apparatus includes an electric water pump that circulates a coolant, a radiator that radiates heat of the coolant, an electric fan that cools the radiator, a control device, and first flow rate correction means. The control device controls the discharge flow rate of the electric water pump based on a target flow rate set based on an amount of heat generated in an engine, and controls operation of the electric fan based on a coolant temperature. When the coolant temperature is equal to or higher than a fan operation temperature at which the operation of the electric fan is started, the first flow rate correction means increases the discharge flow rate of the electric water pump in accordance with an increase in the coolant temperature.

Abstract: A radiator is provided within an engine room and in front of an engine for cooling engine cooling water. A shutter is provided in front of the radiator and covers a portion of a core surface of the radiator for adjusting an amount of cooling air to be directed toward the radiator. A baffle plate is provided behind a remaining portion of the core surface, which is not covered with the shutter, for directing the air, having passed through the remaining portion, to outside the engine room.

Abstract: A vehicle front structure including: a heat exchanger placed upright in a vehicle front part; a left air guide plate formed upright on a left side of the heat exchanger to extend frontward therefrom; a right air guide plate formed upright on a right side of the heat exchanger to extend frontward therefrom; a drain opening formed at a bottom of only one of the left and right air guide plates; and an air intake port for an engine formed above the heat exchanger, and arranged closer to the one of the left and right air guide plates in which the drain opening is formed, from a center of the heat exchanger in a left-right direction.

Abstract: An outside air temperature of a vehicle is detected, an operating time of a fan is set in accordance with the detected outside air temperature based on a fan operating time map, and an idle speed increase time is set in accordance with the an operating time based on an idle speed increase time map.

Abstract: A method of controlling a cooling fan for an engine of a vehicle may entail determining an engine coolant temperature, providing a normal load operation mode for the cooling fan and a high load operation mode for the cooling fan, determining whether a tow-haul operation is selected within the vehicle, determining a vehicle load of the vehicle by detecting whether a towing load sensor is activated or not activated, determining whether a vehicle load threshold is reached based upon activation of the towing load sensor, and operating the cooling fan. Operating the cooling fan may be based on the coolant temperature and one of the normal load operation mode and the high load operation mode. Operating the cooling fan in the normal load operation mode may mean reducing a cooling fan operation frequency and decreasing a cooling fan operation percentage over a predetermined coolant temperature range.

Abstract: A reserve tank structure for enhancing the degree of freedom in the layout of the filling portion of the reserve tank and the mounting bracket and the degree of freedom in the layout of parts around the reserve tank. A reserve tank structure includes a reserve hose for connecting a reserve tank to a radiator. The reserve tank includes a tank body portion for reserving a cooling water with a filling portion that extends upwardly from the tank body portion and includes a water supply port on an upper end thereof. A hose plug is connected to an end portion of the reserve hose. Mounting brackets support an intermediate portion of the reserve hose wherein the mounting bracket is mounted on the filling portion.

Abstract: An air-cooled general-purpose engine includes: a cooling fan fixed to one end portion, protruding outward from one end wall of an engine main body, of a crankshaft; and a shroud which is mounted to the engine main body, and which defines a cooling-air path between the shroud and the one end wall, the cooling-air path guiding a cooling air blown under pressure from the cooling fan. The air-cooled general-purpose engine includes: an oil pump which pumps up an oil from an oil reservoir; and an oil-supply path which is formed in the one end wall, facing the cooling-air path, of the engine main body, and configured to guide the oil discharged from the oil pump to a valve operating chamber in a head portion of the engine main body, and a jet for jetting the oil is provided in an opening of the oil-supply path, the opening being open to the valve operating chamber.

Abstract: The invention relates to a heat exchanger for cooling a fluid for an internal combustion engine, in particular, a gas, for example, in the form of a charge fluid such as exhaust gas, charge air, mixtures thereof or similar, in particular for an internal combustion engine on a motor vehicle, said exchanger preferably being a gas cooler, comprising an inner tubular piece (1) with a least one channel (3) and an outer tubular piece (2). According to the invention, a web (7) is arranged on at least one of the inner tubular piece (1), or outer tubular piece (2), said web (7) running to the other of the inner tubular piece (1) or outer tubular piece (2).

Abstract: A cooling system (100) for an engine (150), comprising at least one coolant pump (120) for pumping a coolant through the engine (150) and a thermostat (140) operable to selectively direct said coolant from said engine (150) via a bypass (115) back to said engine (150) or via a main radiator (110) back to said engine (150) in response to a temperature of said coolant from said engine (150), and an expansion vessel (130) for deaerating said cooling system (100). The system (100) includes a first deaeration conduit (13V) connecting a high point of said engine (150) to said expansion vessel (130), and a second deaeration conduit (138?) connecting a high point of said main radiator (110) to said expansion vessel, and said first and second deaeration conduits (137?, 138?) are provided with at least one heat exchanger (145, 145?) for cooling coolant flowing through said deaeration conduits (137?, 138?).

Abstract: A dual drive radiator fan and coolant pump system for a liquid-cooled reciprocating internal combustion engine includes a coolant pump with an impeller shaft driven by a first drive extending between the engine's crankshaft and a pump pulley and hub mounted upon the impeller shaft. A second drive extends between the crankshaft and a fan hub journaled upon the pump hub, so that the coolant pump and fan hub are driven independently.

Abstract: An arrangement structure for a radiator reservoir tank for a motorcycle that makes it possible to appropriately dispose a reservoir tank of a radiator in the vicinity of an engine. A main frame is provided that extends to the rear side from a head pipe disposed at the front of a main body. An engine is disposed under the main frame, the engine includes a cylinder extending upward from a crankcase with an intake port open at the rear side of the cylinder. A throttle body is connected to the intake port with a reservoir tank of a radiator being disposed in a space S above the crankcase, behind the cylinder, and under the throttle body.

Abstract: A method of using an engine cooling system with a bus includes providing a horizontal rooftop engine cooling system including a radiator unit through which coolant fluid flows for removing heat from the radiator unit, a fan to assist in removing heat from the radiator unit, and a continuously variable power drive and speed control system for controlling power to and the speed of the fan; horizontally locating the rooftop engine cooling system on a rooftop of the bus; interconnecting the radiator unit of the rooftop engine cooling system to a passage of an engine of the bus to allow coolant to flow between the engine and the rooftop cooling system to cool the engine; and controlling power to and the speed of the fan with the continuously variable power drive and speed control system using pulse width modulation.

Abstract: This invention relates to a lawn mower. In certain example embodiments, the lawn mower includes one or more of: (a) a cooling baffle for efficiently cooling a hydraulic fluid tank and/or fluid therein using air flow caused by a combustion engine used for driving mower cutting blade(s); (b) improved cockpit structure including fenders; (c) improved drive wheel(s) adjustment structure or assembly; (d) improved idler arm assembly for use in connection with the cutter deck and/or pump driving belt; and/or (e) improved hose routing structure.

Abstract: An off-road vehicle includes an engine compartment with an engine disposed therein and a cooling assembly which includes a source of liquid and a cooling location disposed external to the engine compartment for cooling the liquid. One or more heat exchangers is disposed at the cooling location for cooling the liquid, which may include engine coolant, hydraulic fluid or air conditioning coolant. Preferably, the cooling assembly includes a fan which is elevated to minimize the intake of dust and other debris created during operation of the vehicle.

Abstract: A control arrangement (10) comprises a first selectable controller (12) for controlling an action, and a second selectable controller (14) for controlling the action. The arrangement also includes a selector (22) for selecting one of the controllers (12, 14) to control the action. The arrangement (10) further includes a first heat exchanger (16) associated with the first controller (12) to effect a transfer of heat between the first controller (12) and the first heat exchanger (16). The arrangement also includes a second heat exchanger (18) associated with the second controller (14) to effect a transfer of heat between the second controller (14) and the second heat exchanger (18).

Abstract: A cooling unit includes a radiator and an axial flow blower that draws air through the radiator along a longitudinal axis and a cross-flow fan that draws air along a lateral axis. The cross-flow fan forces air through the radiator along the longitudinal axis. The axial flow fan draws air through the radiator long the longitudinal axis. A moveable baffle is operable to selectively block air flow from the cross-flow fan.

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: A water-cooled remote fan assembly 59, 100 having an extra pulley set mounted between a water drive mechanism 81, 122 and a cooling fan 68, 114 for creating a second overdrive mechanism used to increase the rotational speed of the fan 68, 114 relative to the engine input speed. This provides the pulley-driven engine cooling system with improved cooling capabilities at low engine speeds. By decreasing the radius of one of the pair of auxiliary pulleys 62, 102, 87, 104 mounted to a transfer drive mechanism 66, 116 relative to the radius of a crankshaft pulley 80, 130, the transfer drive mechanism 66, 116 can rotate at a faster rate than the crankshaft pulley 80, 130. One or both of the pair of auxiliary pulleys 102, 104 may be mounted on a shroud 106 of the radiator 108 to provide better fan orientation and higher efficiencies for fan performance.

Abstract: A water-cooled remote fan assembly 59, 100 having an extra pulley set mounted between a water drive mechanism 81, 122 and a cooling fan 68, 114 for creating a second overdrive mechanism used to increase the rotational speed of the fan 68, 114 relative to the engine input speed. This provides the pulley-driven engine cooling system with improved cooling capabilities at low engine speeds. By decreasing the radius of one of the pair of auxiliary pulleys 62, 102, 87, 104 mounted to a transfer drive mechanism 66, 116 relative to the radius of a crankshaft pulley 80, 130, the transfer drive mechanism 66, 116 can rotate at a faster rate than the crankshaft pulley 80, 130. One or both of the pair of auxiliary pulleys 102, 104 may be mounted on a shroud 106 of the radiator 108 to provide better fan orientation and higher efficiencies for fan performance.

Abstract: In an arrangement for mounting a fan motor on a heat exchanger comprising a body extending between two heat-exchange fluid tanks connected together by tubes carrying cooling fins and in which a heat-exchange fluid flows, the motor is fixed to a support at least one portion of which is molded onto the body. The motor is preferably fixed to the support by at least one screw, for example a self-tapping screw, screwed into the support. The molded material is preferably a plastics material.