A cooling system for a machine includes a radiator assembly having a tank access port, and an overflow port formed in a radiator tank. A solid cap is coupled with the radiator tank to seal the tank access port, and a valve mechanism is coupled with the radiator tank. The valve mechanism includes a pressure relief valve and a coolant return valve operable to fluidly connect the radiator tank with a recovery bottle responsive to a pressurized or a vacuum state of the radiator tank, respectively.

Equipment for transferring fluid into a reservoir or a downstream pipe includes: a piston valve having a body and a rod with a closing member; a chassis defining a housing receiving the piston valve and an upstream passage for fluid, the piston valve movable between a non-inserted and inserted positions, with the piston outside and inside the housing, respectively; and a module defining a cavity for receiving the fluid from the upstream passage and a downstream discharge passage intended to be fluidly connected to the reservoir or downstream pipe, the inlet of the discharge passage defining a valve seat intended to receive the closing member of the piston valve in the deployed position, the module being movable relative to the chassis between an open position, allowing the piston valve to be inserted in the housing, and a closed position, in which the module is fastened to the chassis.

A venting tank (1) for a cooling system of a motor vehicle includes a main wall (3), which defines an inner venting volume (V) of the venting tank, the main wall including a bottom (5) and a cover (7) opposite one another, an intake (45, 47, 49, 51, 53) for a heat transfer fluid to be vented within the interior venting volume, and a discharge (55, 57) for discharging the vented heat transfer fluid outside the inner venting volume. This venting tank (1) further includes a heat transfer fluid duct (19), which crosses through the cover (7) and the bottom (5) and includes an inner segment (29) extending within the inner venting volume (V) from the cover (7) to the bottom (5) and whereof an inner volume (V29) is separated from the inner venting volume.

One general aspect includes a cap for a the overflow reservoir bottle, including a lower cup having a syncline void, said syncline void having by a wall extending above and below at least one surface of the lower cup. The cap also includes an upper cup with an anticline projection nesting adjacent to the syncline void of the lower cup, and said upper cup affixed to the lower cup, with at least one vent to permit gas to traverse the overflow reservoir bottle.

Methods and systems are provided for a bleed valve assembly for an engine. In one example, a method (or system) may include a fastener comprising a threaded shank received within a bore of the engine, a bleed bore within the fastener, and a bleed plug including a threaded portion received within the bleed bore of the fastener. The bleed plug may include an internal passage extending from one end of the bleed plug and a side port in fluidic communication with the passage so that when the bleed plug is in an open position fluid from an engine fluid chamber may flow through the passage of the bleed plug and out of the port.

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.

The present disclosure relates to a coolant system to cool an engine assembly. The coolant system includes a coolant pump impeller with multiple concentric ribs extending axially on a first side of the coolant pump impeller and multiple vanes extending axially on a second side of the coolant pump impeller. The coolant system also includes a coolant rail to collect coolant from a water jacket that surrounds portions of cylinders and a cylinder head of the engine assembly. The coolant system further includes bleed fittings to remove trapped air as the coolant system circulates coolant through the engine assembly. First and second bleed fittings are provided on opposite corners of the engine assembly such that either the first or the second bleed fitting is at a highest point of the coolant system based on an engine orientation of the engine assembly.

A vehicle comprising an engine having a cylinder block, a cylinder head and a gasket disposed between the cylinder block and the cylinder head. The cylinder block and the cylinder head each comprising at least one bore opening leading to a casting bore within the cylinder block and cylinder head respectively. The gasket comprising a gasket opening having a control gap, said gasket opening being sized and arranged to provide a fluid pathway between the bore opening in the cylinder block and the bore opening in the cylinder head. The control gap being configured and arranged to selectively restrict that fluid pathway such that gas may freely pass through the cylinder block bore opening and into the bore opening in the cylinder head whereas coolant can only restrictively pass through the cylinder block bore opening and into the bore opening in the cylinder head.

A cooling system for a vehicle is provided. The system includes a valve that is disposed at a predetermined position in a cooling channel to discharge bubbles produced in a coolant out of the cooling channel. Additionally, a controller is configured to detect whether bubbles have been produced in the coolant using a rate of pressure change based on a temperature increase in the cooling channel and open the valve in response to detecting that bubbles have been produced.

A dual chamber coolant reservoir having a single vent neck. The coolant reservoir is for an internal combustion engine cooling system wherein the reservoir housing includes a first chamber and a second chamber formed integral thereto. A vent neck includes an aperture for accessing the first chamber with either a two or three o-ring cap to maintain pressure within the first chamber. Means for venting the second chamber when coolant exceeds a predetermined pressure level and a means for venting the first and second chamber when said cap is moved from a closed position to an open position. An inline pressure relief valve and check valve providing pressure relief and air displacement.