The present invention relates to a vertical multicylinder straight engine.
With a conventional engine, over cooling at a front-end cylinder barrel and insufficient cooling at a rear-end cylinder barrel occur easily, and the temperature distribution of a plurality of cylinder barrels sometimes becomes an uneven state.
An object of the present invention is to provide a vertical multicylinder straight engine in which the temperature distribution of a plurality of cylinder barrels is made close to an even state.
The present invention includes a cylinder block around a plurality of cylinder barrels, the cylinder block allowing engine cooling water to pass through a cylinder jacket.
The cylinder jacket includes: a jacket inlet for introducing engine cooling water supplied from a radiator; and a plurality of separated outlets for diverting the engine cooling water toward the respective cylinder barrels.
The jacket inlet is disposed so as to be contained within an entire middle barrel side area that is lateral to middle barrels and has a front-rear length as long as a length from a front-most end to a rear-most end of the middle barrels.
It is desirable that the engine is a four-cylinder engine, and that the jacket inlet is disposed on a backward side of the entire middle barrel side area, a front-side separated outlet is disposed on a backward side of a front-end barrel side area, a rear-side separated outlet is disposed on a forward side of a rear-end barrel side area, and a pair of middle separated outlets are respectively disposed on a backward side of a pair of middle barrel side areas.
According to the present invention, the temperature distribution of the plurality of cylinder barrels is made close to an even state.
The following is an outline of this engine.
As illustrated in
The engine also includes a fuel injection device, an antivibration device, a water-cooling device, a lubricating device, and an oil-cooling device.
The fuel injection device is of a common-rail type, including a fuel supply pump (13) and a common rail (14) as illustrated in
As illustrated in
The water-cooling device includes: a radiator (not shown); a water inlet chamber (16) disposed on an intake side of the cylinder block (5), as illustrated in
The water-cooling device circulates engine cooling water after heat is dissipated therefrom by the radiator, at a pumping pressure of the water pump (17), through the water inlet chamber (16), the water pump (17), the intermediary water channel (18), the block-side water jacket (19), the head-side water jacket (20), and the radiator, in the stated order, to water-cool the engine.
The lubricating device includes: an oil pump (not shown) disposed within a rear section of the cylinder block (5); an oil cooler (21) contained within the intermediary water channel (18) as illustrated in
As illustrated in
As illustrated in
A configuration of the cylinder block (5) is as follows.
The plurality of cylinder barrels include a front-end barrel (B1), a rear-end barrel (B4), and middle barrels (B2) and (B3) disposed between these two barrels, taking a direction along which a crankshaft central axis line (8b) extends as a front-rear direction, and a side of a flywheel (10a) as a rear side.
The cylinder jacket (3) includes: a jacket inlet (3a) for introducing the engine cooling water (2) supplied from the radiator; separated channels (3b) for diverting the engine cooling water (2) introduced through the jacket inlet (3a) in the front-rear direction; a plurality of separated outlets for diverting the engine cooling water (2) diverted in the front-rear direction toward the respective cylinder barrels; and heat dissipator channels (3c) for dissipating heat of the respective cylinder barrels to the engine cooling water (2) introduced through the separated outlets.
The plurality of separated outlets include: a front-side separated outlet (b1) to the front-end barrel (B1); a rear-side separated outlet (b4) to the rear-end barrel (B4); and middle separated outlets (b2) and (b3) to the middle barrels (B2) and (B3) between the front-end barrel (B1) and the rear-end barrel (B4).
The jacket inlet (3aa) is disposed so as to be contained within an entire middle barrel side area (E23) that is lateral to the middle barrels (B2) and (B3) and has a front-rear length as long as a length from a front-most end to a rear-most end of the middle barrels (B2) and (B3).
Specifically, the jacket inlet (3a) is disposed so as not to extend on the front side or the rear side beyond the entire middle barrel side area (E23).
Therefore, according to this embodiment, the engine cooling water (2) is introduced into the cylinder jacket (3) through the jacket inlet (3a) in the entire middle barrel side area (E23), a difference between distances from the respective cylinder barrels to the jacket inlet (3a) is reduced, over or insufficient cooling of the cylinder barrels may not easily occur, and the temperature distribution of the plurality of cylinder barrels is made close to an even state.
As illustrated in
Specifically, each of the separated outlets is disposed so as not to extend on the front side or the rear side beyond corresponding one of the barrel side areas.
Therefore, according to this embodiment, relative positions of each of the separated outlets and corresponding one of the cylinder barrels become uniform, and cooling conditions of the cylinder barrels are made close to be even.
As illustrated in
Therefore, according to this embodiment, the diverted distance to cylinder barrels of two cylinders on the rear side from which heat dissipation is easily hindered by the flywheel (10a) is short, and the diverted distance to cylinder barrels of two cylinders on the front side from which heat is easily dissipated is long. Thus, the temperature distribution of the cylinder barrels of four cylinders is made close to the even state.
As illustrated in
The partition walls (3d) are bended along concavity and convexity of side-projecting curved sections (C2) and (C3) of a pair of the middle barrels (B2) and (B3) and a side-depression section (D23) between the side-projecting curved sections (C2) and (C3), and the partition walls (3d) include screw bosses (3e) at both ends and at bended portions, the screw bosses (3e) being for screw fitting with head bolts (3h) for fastening the cylinder head (6) to the cylinder block (5).
Therefore, according to this embodiment, the screw bosses (3e) increase rigidity of the partition walls (3d), the partition walls (3d) do not easily oscillate, combusting noise and piston slap noise laterally emitted from the cylinder barrels are reflected on the partition walls (3d), and engine noise emitted on the lateral side of the cylinder block (5) is reduced.
As illustrated in
Therefore, according to this embodiment, the engine cooling water (2) flowed into the heat dissipator channel (3c) is guided by the screw bosses (3e) toward the transverse channel (3f), and thus cooling efficiency of the cylinder barrels is increased.
As illustrated in
Therefore, according to this embodiment, the engine cooling water (2) flowed into the heat dissipator channel (3c) is guided by the screw bosses (3e) toward the side-projecting curved sections (C2) and (C3) of the middle barrels (B2) and (B3), and thus cooling efficiency of the middle barrels (B2) and (B3) is increased.
As illustrated in
Therefore, according to this embodiment, the engine cooling water (2) is introduced through the separated outlet to an upper half of the cylinder barrel, insufficient cooling of the upper half of the cylinder barrel and over cooling of a lower half of the cylinder barrel are avoided, and temperature distribution of the cylinder barrels in a vertical direction is made close to an even state.
As illustrated in
Therefore, according to this embodiment, it is possible to avoid insufficient cooling of a raised portion of the cylinder barrel that is susceptible to heat from the pressure ring (26b), as well as over cooling of a lowered portion of the cylinder barrel from which heat is not easily dissipated by the piston (26), and temperature distribution of the cylinder barrels in a vertical direction is made close to an even state.
There are two pressure rings (26b) one above the other, and a lower end of the lower one of the pressure rings (26b) forms the lowermost position (26c).
An oil ring (27) is disposed under the lower one of the pressure rings (26b), and the opening lower edge (bu) of each of the separated outlets is disposed at a position lower than a lower end of the oil ring (27) of the piston (26) at the top dead point within the cylinder barrel to which the separated outlet faces.
As illustrated in
The oil delivery channels (25) are directed in the front-rear direction, and the plurality of the diverting oil outlets include: a front diverting oil outlet (h1) and a rear diverting oil outlet (h4) that are respectively disposed on the front side and the rear side of the oil delivery channel (25); and intermediate diverting oil outlets (h2) and (h3) that are disposed between the front diverting oil outlet (h1) and the rear diverting oil outlet (h4).
As illustrated in
Specifically, when viewed along a plane parallel with the cylinder central axis line (CC), the oil inlet (25b) is disposed in a region overlapping and immediately under the entire middle barrel side area (E23).
Therefore, according to this embodiment, a difference between distances from the oil inlet (25b) to the oil diverting points is reduced, over or insufficient cooling of the pistons (26) may not easily occur, and the temperature distribution of the plurality of cylinder barrels is made close to an even state.
When viewed parallelly with the cylinder central axis line (CC), each of the diverting oil outlets is disposed at a position overlapping the corresponding one of the barrel side areas.
Specifically, each of the diverting oil outlets is disposed at a position overlapping and immediately under the corresponding one of the barrel side areas.
The intermediary water channel (18) shown in
It is configured such that an entire amount of the engine cooling water (2) from the radiator is supplied to the jacket inlet (3a) via the intermediary water channel (18).
Therefore, according to this embodiment, cooling efficiency of the cylinder barrels is increased by a large amount of the engine cooling water (2) supplied from the radiator.
As illustrated in
As illustrated in
Therefore, according to this embodiment, the oil cooler (21) is inserted into the intermediary water channel (18) depressed by the cylinder block (5), and positioning of the oil cooler (21) may not increase a width of the engine to a large extent.
As illustrated in
Therefore, by covering the intermediary water channel (18) with the supplementary-unit attachment base (22) to which the oil cooler (21) and the oil filter (23) are attached, the oil cooler (21) and the oil filter (23) are attached to the cylinder block (5), and thus attachment of the oil cooler (21) and the oil filter (23) is facilitated.
As illustrated in
Number | Date | Country | Kind |
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2017-129912 | Jun 2017 | JP | national |