Abstract: Increasing the diameter of cylinder bores in a cylinder block requires a longer and heavier cylinder block to accommodate the larger bores. If the cylinder block is not lengthened it is difficult to accommodate the water jacket between the outermost cylinder bore and the cylinder block end wall. The cylinder block of the present invention has an upper part including a number of cylinder bores surrounded by a water jacket. The upper part also has first and second end walls which are generally co-planar with first and second end walls of a lower part of the block, but include projecting portions adjacent the top deck. The projecting portions may curve outwardly from the first and second end walls and generally follow the curvature of the two outermost cylinder bores on the block. By providing the projecting portions on the first and second end walls, a minimum width of water jacket can be accommodated without significantly increasing the length and overall size of the block.

Abstract: A cooling apparatus of an internal combustion engine includes a closed deck-type cylinder block and an insert. The cylinder block includes a water jacket and an upper deck including a water hole formed therein. The insert is disposed in the water jacket and inserted into the water jacket through the water hole. The insert is fixed relative to the cylinder block at a water hole portion such that the insert is fixed in position in a flow direction of the cooling water. A stopper for preventing the insert from moving downstream in a flow direction of the cooling water may be formed, and the insert engages the stopper such that the insert is fixed in position in the flow direction of the cooling water.

Abstract: The present invention, in one aspect, is a pressure responsive valve for a marine engine that facilitates balanced operation of the engine. In an exemplary embodiment, the valve includes a first chamber and a second chamber. Coolant is in flow communication with the valve first chamber, and the engine cylinder head water jackets are in flow communication with the valve second chamber. A flow channel is between the valve first and second chambers, and a plunger is biased to close the flow channel to normally prevent flow from the first chamber to the second chamber. A diaphragm is coupled to the plunger and is responsive to pressure in the first chamber. During operation of the engine at low revolutions per minute (rpm), the pressure of the coolant in the valve first chamber is not sufficient to cause the diaphragm to move the plunger to the open position. As the engine speed increases, the pressure of the coolant also increases.

Abstract: An engine is provided having a cylinder head and a cylinder block. The cylinder head has a head water-jacket for circulating coolant, and the cylinder block has a block water-jacket for circulating the coolant. Coolant flow is blocked between the block and head water-jackets except through a primary pathway or an additional one or more secondary pathways. First and second thermostats are equipped to respectively control coolant flow from the head and block water-jackets, such that the coolant flow through the head and block water-jackets are respectively controlled based on respectively preset temperatures of the first and second thermostats.

Abstract: A power tool includes a combustion chamber (1; 54), a drive piston (8) adjoining the combustion chamber (1; 54) and displaceable upon combustion of fuel in the combustion chamber, an ignition device (52) for igniting the fuel in the combustion chamber (1; 54), and a cooling device (2a, 6a; 64; 70) connected with the combustion chamber (1; 54) for cooling the combustion chamber (1; 54) with a liquid cooling medium.

Abstract: A cooling system for cooling an interbore bridge of a cylinder block of a water cooled engine, the interbore bridge having a top surface and a central region of minimum width; the cylinder block having a water jacket; the cooling system including at lest one water passage extending from the top of the interbore bridge adjacent the central region to the water jacket. A method of forming the cooling system, and a cylinder block so formed, are also disclosed.

Abstract: In an engine of a cylinder-head first cooling type, cooling performance for a cylinder head and a cylinder block is enhanced. Cooling water from a water pump is supplied via a water jacket in a cylinder head to a water jacket in a cylinder block. The water jacket in the cylinder head is defined to extend along opposite sides of a plurality of cylinders disposed in a row, and has a cooling-water inlet and a cooling-water outlet provided at lengthwise one end thereof and the lengthwise other end thereof, respectively. The water jacket in the cylinder block is defined to surround outer peripheries of the plurality of cylinders disposed in the row, and is shielded at one point by a shield member, and has a cooling-water inlet provided on one side of the shield member to communicate with the cooling-water outlet in the water jacket.

Abstract: A coolant circuit and method of operating a coolant circuit is provided for a multi-cylinder internal-combustion engine. A cooling jacket which surrounds a cylinder head housing and a cylinder block and is supplied with cooling liquid by way of a pump. The cylinder cooling jacket and the cylinder head cooling space are provided with a connection for feeding the cooling liquid and with the cooling liquid flowing parallel through the cylinder head housing and the cylinder block. Thus, a cooling of the cylinder block and the cylinder head which meets the requirements takes place without any additional control devices. The engine rapidly reaches its operating temperature, thereby reducing the cold running phase. As a result, the fuel consumption and the crude emissions can be reduced.

Abstract: A temperature regulator includes at least one electrically conductive carbon foam element. The foam element includes at least two locations adapted for receiving electrical connectors thereto for heating a fluid, such as engine oil. A combustion engine includes an engine block and at least one carbon foam element, the foam element extending into the engine block or disposed in thermal contact with at least one engine fluid.

Abstract: A water jacket for a cylinder head is disclosed. The water jacket comprises a coolant flow channel formed between a coolant inlet and a coolant outlet for allowing the coolant to flow in the cylinder head. Coolant flow regulation parts are provided in the coolant flow channel for accomplishing smooth flow of the coolant between exhaust ports corresponding to respective combustion chambers, and a coolant flow distribution part is provided in the coolant flow channel for uniformly distributing flow of the coolant between the exhaust ports corresponding to the respective combustion chambers. According to the present invention, delay of the coolant flowing between the exhaust ports corresponding to the respective combustion chambers is prevented, and thus a cooling efficiency of the cylinder head is improved.

Abstract: An outboard motor includes a water-cooled V-engine. The engine includes right and left cylinder block portions each having plural cylinders formed therein. The cylinders of each cylinder block portion are vertically juxtaposed. Cylinder heads are disposed behind the cylinder block portions. The outboard motor has horizontal and vertical shafts. The outboard motor can tilt up on the horizontal shaft and pivot sideways on the vertical shaft. The cylinders of each cylinder block portion have a cooling jacket formed therein. The lowermost cylinder has a discharge portion formed at an outermost part thereof. The discharge portion is designed to discharge out cooling water remaining in the cooling jacket.

Abstract: The invention relates to a cylinder block of the closed-deck type, which can be produced by die-casting. The cylinder block includes a water jacket surrounding the cylinders adapted to be open to the side. The lateral opening can be closed by a cover, which is additionally shaped on its inside in such a way as to promote flow distribution or heat dissipation.

Abstract: A cooling system is provided for an engine utilizing a parallel flow configuration such that coolant flows from the outer regions of the engine block into the engine block's inner core. Parallel flow is used to maintain equivalent cylinder temperatures.

Abstract: An engine is provided having a cylinder head and a cylinder block. The cylinder head has a head water-jacket for circulating coolant, and the cylinder block has a block water-jacket for circulating the coolant. Coolant flow is blocked between the block and head water-jackets except through a primary pathway or an additional one or more secondary pathways. First and second thermostats are equipped to respectively control coolant flow from the head and block water-jackets, such that the coolant flow through the head and block water-jackets are respectively controlled based on respectively preset temperatures of the first and second thermostats.

Abstract: Improved internal combustion engine, particularly, an improved two-stroke, diesel aircraft engine. The invention includes a new wrist pin/connecting rod connection, a new cooling system for fuel injectors, a new cylinder head cooling arrangement, a new cooling jacket cross-feed arrangement, and a new combustion seal arrangement.

Abstract: A spark-ignition rotary internal-combustion engine, having a plurality of pistons (7) which perform a reciprocating motion inside cylinders (6) arranged so as to be equally angularly spaced on a same circumference, the cylinders (6) being formed in a rotating body or rotor (2) which rotates coaxially inside a fixed body or stator (1), in which the inlet duct (9) for the air-fuel mix, the burnt gas exhaust duct (8) and the spark-plug recess (10) are provided.

Abstract: A temperature regulator includes at least one electrically conductive carbon foam element. The foam element includes at least two locations adapted for receiving electrical connectors thereto for heating a fluid, such as engine oil. A combustion engine includes an engine block and at least one carbon foam element, the foam element extending into the engine block or disposed in thermal contact with at least one engine fluid.

Abstract: The invention relates to an apparatus (10) for cooling an internal combustion engine (11), preferably a 4-cylinder in-line engine, having coolant connections (13, 13′, 14, 14′; 17, 17′-24, 24′) to a cooling loop, the coolant connections being connected to at least one cooling jacket region (12′, 12″, 12′″) of the engine (11). The invention provides that as the coolant connections, a group of inflow lines (17-24) and outflow lines (17′-24′), paired with one another, is provided, and each pair of inflow and outflow lines, because of its respective flow direction, defines a flow path, and each cylinder (15, 15′, 15″, 15′″) is assigned at least one flow path supplying it. The flow directions of these flow paths extend transversely to the longitudinal direction of the crankshaft defined by the in-line arrangement of individual cylinders (15, 15, 15″, 15′″).

Abstract: The invention relates to a cooling circuit arrangement for a multicylinder internal combustion engine with V-shaped cylinder banks and cooling jackets (16, 18, 20, 22), which surround the cylinder banks and which are provided with cooling liquid by means of a pump, arranged between the two cylinder banks on one of their face sides. It is proposed that the pressure-sided connection (30) of the coolant pump, arranged on the one face side of the two cylinder banks, be connected by means of a coolant pipe (32) to a distributor pipe (34), arranged on the other face side of the cylinder banks, for the purpose of feeding cooling liquid; and that a return flow chamber (28, 56) for the coolant from the cooling jackets (16, 18, 20, 22) be arranged between the two cylinder banks adjacent to the pump housing (26).

Abstract: An outboard motor includes a water-cooled V-engine. The engine includes right and left cylinder block portions each having plural cylinders formed therein. The cylinders of each cylinder block portion are vertically juxtaposed. Cylinder heads are disposed behind the cylinder block portions. The outboard motor has horizontal and vertical shafts. The outboard motor can tilt up on the horizontal shaft and pivot sideways on the vertical shaft. The cylinders of each cylinder block portion have a cooling jacket formed therein. The lowermost cylinder has a discharge portion formed at an outermost part thereof. The discharge portion is designed to discharge out cooling water remaining in the cooling jacket.

Abstract: An engine block having a cooling system includes a body, a plurality of cylinder bores formed on the body, cylinder liners each coaxially fitted in a corresponding cylinder bore, and at least one coolant channel formed between the cylinder bores, wherein each cylinder liner has recesses on an outer surface facing other cylinder bores for securing space for forming the coolant channels.

Abstract: An outboard motor includes a housing unit adapted to be mounted on an associated watercraft. An engine is mounted on the housing unit. The housing unit defines a water delivery passage and a water discharge passage. Both the passages communicate with each other through a lower opening. The water delivery passage is arranged to deliver cooling water to the engine. The water discharge passage is arranged to discharge the cooling water from the engine. The discharge passage communicates with a location out of the housing unit through an upper opening. A pressure relief valve unit extends through the lower and upper openings. The pressure relief valve unit allows the cooling water in the delivery passage to move to the discharge passage when a pressure of the delivery passage becomes greater than a preset pressure.

Abstract: A water pump P is provided in a cover 20 attached to a crank case 22 of an engine E or in the vicinity of the cover 20 and a coolant passage 20A is provided in the cover 20 for introducing the coolant from the water pump P to water jackets 25(25A, 25B) respectively formed in cylinders S of the engine E.

Abstract: A cooling system for cooling an interbore bridge of a cylinder block of a water cooled engine, the interbore bridge having a top surface and a central region of minimum width; the cylinder block having a water jacket; the cooling system including at lest one water passage extending from the top of the interbore bridge adjacent the central region to the water jacket. A method of forming the cooling system, and a cylinder block so formed, are also disclosed.

Abstract: A cooling water circulating structure in an internal combustion engine is to be provided wherein cooling water can flow to every corner through a water jacket in a cylinder block and a water jacket in a cylinder head without being localized and thereby can cool the whole efficiently and which permits an easy layout of the water piping. A cooling water circulating structure in a multi-cylinder type internal combustion engine wherein a cooling water inlet and a cooling water outlet are formed side by side respectively in a side face of a cylinder block and a side face of a cylinder head both on the same side of the internal combustion engine close to a water pump, and a cylinder block-side water jacket and a cylinder head-side water jacket are brought into communication with each other through communication paths and are formed on the side opposite to the side close to the water pump, thereby allowing cooling water to circulate.

Abstract: A fluid cooled cylinder liner for mounting in a cylinder of an internal combustion engine is provided. The fluid cooled cylinder liner includes a collar and a seal element. The collar has an outer circumferential surface dimensioned with respect to the inner circumference of the cylinder so as to be in substantially fluid sealing contact therewith, an annular cooling fluid channel formed radially inwardly of the outer circumferential surface, and a radial bore extending radially from the fluid channel through the outer circumferential surface and having one end communicated with the fluid channel and an opposite end communicated with a branch bore of the crankcase of the engine. The seal element substantially seals the interface between the branch bore of the crankcase and the radial bore of the collar of the cylinder liner against the leakage of cooling fluid.

Abstract: The present invention relates to multiple integrated fluid passages for a internal combustion engine which allow for economical and convenient means for routing fluids in relation to an engine block. For example, the molded passages of the present invention allow coolant to be applied directly to areas needing heat transfer, without requiring the provision of large areas in the engine block to accommodate such cooling fluid. Also, the molded passages of the present invention do not require circular internal passages, so that space-critical items can receive proper distribution of fluid. Also, the molded passages of the present invention allow for economical velocity control of fluids by controlling the sizes of the fluid passage. In a preferred embodiment, the molded passages are formed in a clam shell configuration having an open side and are attached to an exterior surface of the cylinder block, thereby forming an enclosed pathway for fluid flow.

Abstract: The invention relates to an internal combustion engine comprising a cylinder block with cooling fins cast integral therewith, and a cylinder head bolted on top of the cylinder block, first coolant passages being provided in the area of at least one cylinder contained in the cylinder block, which passages are connected to second coolant passages located in the cylinder head. Cooling efficiency is increased by providing heat exchange passages in the outer region of the cooling fins, which together with the first coolant passages and the second coolant passages form a closed loop system within the engine.

Abstract: A direct-fuel-injection-type spark-ignition internal combustion engine has a fuel injection valve which directly injects fuel into a cylinder. A nozzle hole of the fuel injection valve directs fuel toward an impingement portion of the cylinder bore located opposed to the nozzle hole in a lower section of the cylinder bore so that fuel can be injected into a cavity formed in a top face of a piston from an upper section of the cylinder bore during the latter half of a compression stroke. A cooler located at least in the neighborhood of the impingement portion in the lower section of the cylinder bore has a lower cooling capacity than a cooler located in the neighborhood of the upper section of the cylinder bore. Thus, fuel injected during the latter half of an intake stroke that adheres to the cylinder bore can be effectively gasified.

Abstract: A fluid cooled cylinder liner for mounting in a cylinder of an internal combustion engine is provided. The fluid cooled cylinder liner includes a collar and a seal element. The collar has an outer circumferential surface dimensioned with respect to the inner circumference of the cylinder so as to be in substantially fluid sealing contact therewith, an annular cooling fluid channel formed radially inwardly of the outer circumferential surface, and a radial bore extending radially from the fluid channel through the outer circumferential surface and having one end communicated with the fluid channel and an opposite end communicated with a branch bore of the crankcase of the engine. The seal element substantially seals the interface between the branch bore of the crankcase and the radial bore of the collar of the cylinder liner against the leakage of cooling fluid.

Abstract: A cooling water circulating structure in an internal combustion engine is to be provided wherein cooling water can flow to every corner through a water jacket in a cylinder block and a water jacket in a cylinder head without being localized and thereby can cool the whole efficiently and which permits an easy layout of the water piping. A cooling water circulating structure in a multi-cylinder type internal combustion engine wherein a cooling water inlet and a cooling water outlet are formed side by side respectively in a side face of a cylinder block and a side face of a cylinder head both on the same side of the internal combustion engine close to a water pump, and a cylinder block-side water jacket and a cylinder head-side water jacket are brought into communication with each other through communication paths and are formed on the side opposite to the side close to the water pump, thereby allowing cooling water to circulate.

Abstract: An internal combustion engine includes a siamese engine block having cylinders defined by cylinder walls arranged in series with adjoining cylinders sharing a common wall. The engine block has a coolant jacket defined by a coolant jacket wall radially positioned parallel to and outboard of the cylinder walls to define a coolant passage for coolant flow through the engine block. The coolant passage includes an arc passage and a V-bend passage where the V-bend passage is adjacent the common wall of the adjoining cylinders. The V-bend passage is configured as a narrow rectangular portion having a coolant pocket projecting inboard from the rectangular portion into the common wall to provide heat transfer from the common wall of the cylinder. The cylinder wall includes a protrusion extending into the arc passage and disrupts flow from about the upper one-half of the coolant pocket.

Abstract: The present invention concerns an engine block (1) of a metal material for a multicylinder internal combustion engine, with a housing (2), in which cylinder boreholes (5) are provided, whereby the outer surfaces of side walls (6) of cylinder boreholes (5) are distanced from the wall (3) of housing (2), so that cooling channels (9) arranged between wall (3) and cylinder boreholes (5) result. It is provided according to the invention that cylinder boreholes (5′) are shortened such that the height (h2) of the shortened cylinder boreholes (5′) is smaller than the height (h1) of the unshortened cylinder boreholes (5). The present invention also concerns a cylinder bushing (10) with a sleeve (11) and a collar (12), whose outer diameter is larger than the outer diameter of sleeve (11).

Abstract: In an engine block having cylinder cavities arranged close together, a cooling duct is produced in an intermediate wall between the cylinders by pouring the casting material around a mold core made preferably from a material that is soluble in a liquid, combustible and/or brittle, so that the mold core can easily be removed from the duct once the casting has solidified. In the casting mold, the duct mold core is secured solely at its ends so that a cooling duct is formed that is bordered exclusively by a skin of casting material.