The invention relates to a cylinder head for an internal combustion engine having liquid cooling, comprising at least two outlet valves for controlling outlet openings and at least one inlet valve for controlling at least one inlet opening per cylinder, having at least one cooling jacket through which cooling medium flows, wherein an outlet valve bridge is arranged between two adjacent outlet valves and a respective inlet/outlet valve bridge is arranged between at least one outlet valve and an adjacent inlet valve, and wherein a first cooling channel is arranged in the region of at least one outlet valve bridge and a second cooling channel is arranged in the region of at least one inlet/outlet valve bridge, and the first and second cooling channels are flow-connected to one another in a central cooling region of the cylinder.
AT 506 473 B1 describes a cylinder head for an internal combustion engine, comprising several cylinders with a coolant jacket surrounding the outlet valves, which has a coolant collection channel extending in the longitudinal direction of the cylinder head on the outlet side. Cooling channels are arranged in the area of the outlet valve bridge and in the region of the inlet/outlet valve bridges. Since the coolant flow takes place in the region of the cooling channel of the inlet/outlet valve bridge on either side of each outlet valve, flow stagnation and thus overheating can occur in the region of the inlet/outlet valve bridges and the outlet valve guides.
Internal combustion engines with exhaust gas collectors integrally formed with the cylinder heads are known from the publications US 2005/0087154 A1, EP 0 856 650 A1, U.S. Pat. No. 7,051,685 B2, AT 500 442 B1.
Particularly in the case of high-performance internal combustion engines, sufficient cooling of the region of the inlet/outlet valve bridges and the outlet valve guides is not ensured.
It is the object of the invention to improve the cooling in the region of the inlet/outlet valve bridges and in the region of the outlet valve guides.
According to the invention, this is achieved by at least one second cooling channel having a flow-dividing device which subdivides the second cooling channel at least in sections into a first partial channel and a second partial channel. Preferably, the first partial channel is arranged in the region of an outlet valve guide and the second partial channel is arranged in the region of an outlet valve seat of the adjacent outlet valve. This makes it possible to improve the cooling both in the region of the outlet valve guide and in the region of the outlet valve seat.
Preferably, the first partial channel and the second partial channel are merged both upstream and downstream of the flow-dividing device. In detail, it can be provided that the first and second partial channels are merged in the region of the first cooling channel. Furthermore, the first and the second partial channel can be merged in the region of a connecting channel of the cooling jacket, which is arranged in the region of a motor transverse plane between two adjacent cylinders or on at least one end face of the cylinder head. The connecting channel mutually connects two outlet-side and/or two inlet-side cooling jacket sections of two adjacent cylinders and/or at least one outlet-side cooling jacket section to an inlet-side cooling jacket section.
The flow division of the second cooling channel thus occurs essentially only in the region of the inlet/outlet valve bridge. The coolant flow in the region of the inlet/outlet valve bridge is thus divided into two partial streams, wherein the first partial flow through the first partial channel flows around the outlet valves and thus cools the corresponding outlet valve seat. The second partial flow of the second partial channel cools the transition region between inlet and outlet valves. The two partial channels allow a directed flow and point-precise cooling of regions of the inlet/outlet valve bridge, which are subjected to high thermal stress, and in particular the adjacent outlet valve seat.
In addition, or alternatively to the flow-dividing device, it can be provided according to the invention that the first cooling channel is flow-connected to the second cooling channel only via the central cooling region and at least one flow interruption device is arranged in a region diametrically opposite the first and/or second cooling channel with respect to the outlet valve centre. Flow interruption means both a complete interruption of the cooling channel, e.g. through a material entry or a cover device, as well as a throttling point or apparatus which interrupts the flow. It is particularly advantageous if the first cooling channel and at least one second cooling channel—preferably the first cooling channel and the first partial channel—together surround at least one outlet valve guide over an angular range between 180° and 300°, preferably about 210° to 240°. The second cooling channel is thus exposed by the flow interruption device in a region facing the outlet longitudinal side wall of the cylinder head, opposite the first cooling channel. Thus, a complete flow around the outlet valves is prevented. Thereby, it can be prevented that there is a bypass flow between first and second cooling channel of the coolant in the region of the outer side of the cylinder, and that stagnation and/or overheating occurs in the region of the second cooling channel. On account of the higher flow velocities, increased heat dissipation can be achieved from the area of the outlet valve guides on the one hand and an improved cooling of the outlet valve seats on the other hand.
The cylinder head can have an integrated coolant collecting channel extending at least over two cylinders and/or at least one integrated exhaust gas collector extending over at least two cylinders, which is at least partially surrounded by an exhaust gas cooling jacket. The first cooling channel of each cylinder can be connected to the coolant collecting channel and/or to the exhaust gas cooling jacket via at least one transfer channel. The main flow from or to the coolant collecting channel or coolant distribution channel and from or to the exhaust gas cooling jacket of the exhaust manifold takes place via the transfer channel connected to the first cooling channel.
The coolant can flow into the cooling jacket of the cylinder head via flow transfer openings in the area of the cylinder head plane from the cooling jacket of the cylinder block or flow into the cooling jacket of the cylinder block from the cooling jacket of the cylinder head, as is customary in the case of top down cooling systems.
The production effort can be kept extremely small when the flow-dividing device and/or the flow interruption device is formed by a cast wall section of the cylinder head. The flow-dividing device and the flow interruption device are thus formed by the casting material of the cylinder head itself, wherein only slight modifications of the casting mould or of the cast cores are necessary.
The heat dissipation from thermally highly stressed areas of the valve bridges, in particular of the inlet/outlet valve bridges, as well as of the outlet valve guides, can be significantly improved by the flow-dividing device and/or the flow interruption device, in particular in high-performance internal combustion engines.
The invention is explained in more detail below with reference to the non-limiting drawings, wherein:
The cylinder head 4 has an integrated exhaust gas collector 16 (see
The cooling jacket 3 of the cylinder head 4 has an outlet-side cooling jacket section 3a and an inlet-side cooling jacket section 3b which are flow-connected to each other in the region of the motor transverse planes 23 between adjacent cylinders 2 and at the end faces 4a, 4b of the cylinder head 4 via connecting channels 22. In this case, the motor transverse plane 23 denotes a plane extending normally to the motor longitudinal plane 2b between adjacent cylinders 2, said motor longitudinal plane being defined by the cylinder axes 2a.
The second cooling channel 19 is designed to be divided in the region of each inlet/outlet valve bridge 8, wherein a first partial channel 19a and a second partial channel 19b are arranged on one respective side of a flow-dividing device 21. The flow-dividing device 21, which is designed in the shape of a crescent or kidney-shaped in a top view of the cylinder axis indicated by reference numeral 2a, thus divides the second cooling channel 19 into two partial channels, namely into a first partial channel 19a shown in
The flow from the first cooling channel 18 into the second cooling channel 19 or from the second cooling channel 19 into the first cooling channel 18 takes place depending on whether a top-down cooling concept—with flow from the cooling jacket 3 of the cylinder head 2 into the block cooling jacket 10—or a conventional cooling concept with flow from the block cooling jacket 10 into the cooling jacket 3 of the cylinder head 2 is implemented. In this case, the flow occurs at least in the regions of the motor transverse planes 23 essentially transversely to the motor longitudinal plane 2b which is defined by the cylinder axes 2a.
In order to prevent stagnation of the flow in the second cooling channel 19, the first cooling channel 18 is flow-connected to the second cooling channel 19 only via the central cooling region 20, wherein, in a region of the cylinder head 2 which is diametrically opposite the first and/or second cooling channel 19 with respect to the outlet opening 14, a flow interruption device 24 is arranged (see
By means of the flow interruption device 24, bypass flows between the first cooling channel 18 and the second cooling channel 19 around the outlet valve on the side of the outlet valve guide 14a remote from the first cooling channel 18 can be avoided. Thus, in the region of every other second cooling channel 19, a defined radial flow occurs locally in the longitudinal direction of the motor at high speeds and throughputs.
The cooling in the region of the corresponding inlet/outlet valve bridge 8 can be improved both with the flow-dividing device 21 and also with the flow interruption device 24. Particularly good heat dissipation can be achieved by combining the flow-dividing device 21 and the flow interruption device 24.
Number | Date | Country | Kind |
---|---|---|---|
A 50376/2015 | May 2015 | AT | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/AT2016/050127 | 5/4/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/176710 | 11/10/2016 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5970926 | Tsunoda et al. | Oct 1999 | A |
7051685 | Hayman et al. | May 2006 | B2 |
7234422 | Schlautman | Jun 2007 | B2 |
8151743 | Reustle | Apr 2012 | B2 |
8662028 | Knollmayr | Mar 2014 | B2 |
8875670 | Brewer | Nov 2014 | B2 |
9562493 | Wakiya | Feb 2017 | B2 |
20050087154 | Hayman et al. | Apr 2005 | A1 |
20090126659 | Lester | May 2009 | A1 |
20100242869 | Knollmayr | Sep 2010 | A1 |
20110315098 | Kosugi | Dec 2011 | A1 |
20130192546 | Ruffing | Aug 2013 | A1 |
Number | Date | Country |
---|---|---|
500442 | Jun 2008 | AT |
69910249 | Apr 2004 | DE |
102005050510 | Apr 2007 | DE |
102008047185 | Apr 2010 | DE |
102008047185 | Apr 2010 | DE |
102008047185 | Apr 2010 | DE |
1884647 | Feb 2008 | EP |
2002256966 | Sep 2002 | JP |
Entry |
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English Abstract of DE102005050510. |
English Abstract of JP2002256966. |
English Abstract of DE102008047185. |
English Abstract of EP1884647. |
English Abstract of DE69910249. |
Number | Date | Country | |
---|---|---|---|
20180106213 A1 | Apr 2018 | US |