The invention relates to a coolant jacket for a liquid-cooled cylinder head for an internal combustion engine with a crankcase, wherein the cylinder head has a gas exchange intake side with two gas exchange intake valves and a gas exchange outlet side with two gas exchange outlet valves.
A coolant jacket for a cylinder head that is cooled with liquid is known from prior art document DE 102 51 360 B4, on which the present invention is based. DE 102 51 360 B4 describes a liquid-cooled cylinder head that is configured for an internal combustion engine that has multiple cylinders. The cylinder head has a coolant flow that flows from a coolant intake on an outlet side to a coolant outlet on an intake side. Furthermore, the cylinder head has a coolant chamber, which is defined by outer walls, a cylinder head bottom and a water chamber roof. The cylinder head has a rib, which hangs from the water chamber roof and, in so doing, projects, as a flow guiding element, more or less transversely to the coolant flow. Furthermore, at least one intake valve and two outlet valves with gas exchange channels are arranged in each cylinder section. Furthermore, a coolant intake is provided from the bottom in a coolant distributor channel. Starting from this coolant distributor channel, a side coolant channel passes between the gas exchange channel of an outlet valve and a screw hole of a cylinder head screw. A central coolant channel passes between the two gas exchange channels of the outlet valves. The liquid-cooled cylinder head that is described in DE 102 51 360 B4 is characterized in that the central coolant channel guides the coolant flow to the rib in the water chamber root and this rib is connected to the spark plug hole on the water chamber roof and has a flow-guiding manifold in a region of an impingement point of the coolant flow from the central coolant channel.
This type of coolant jacket, known from the prior art, does not optimally cool the cylinder head, in particular, in the region of the highest volume of heat input between the gas exchange outlet valves and the ignition device.
The object of the present invention is to provide a coolant jacket that is configured for a liquid-cooled cylinder head and that does not exhibit the aforementioned drawback.
This and other objects are achieved by providing a coolant jacket for a liquid-cooled cylinder head for an internal combustion engine with a crankcase, wherein the cylinder head has a gas exchange intake side with two gas exchange intake valves and a gas exchange outlet side with two gas exchange outlet valves. A fuel injection valve is provided on the intake side and an ignition device is provided on the outlet side between the gas exchange valves. The coolant jacket extends as a first partial coolant jacket on the outlet side, coming from the crankcase, between the gas exchange outlet valves, and then radially outside around the ignition device and the fuel injection valve and further in the direction of the intake side and the crankcase.
According to the invention, the coolant jacket is designed in such a way that the coolant flows from the outlet side from the crankcase, coming centrally relative to the cylinder into the cylinder head (optionally, also laterally next to the gas exchange outlet channels) and there in close proximity to the combustion chamber roof between the gas exchange outlet valves and around the ignition device and the fuel injection device in the direction of the intake side. In particular, the coolant jacket envelops to a large extent the threaded region of the ignition device.
In an advantageous embodiment, the cylinder head includes a gas exchange outlet channel on the gas exchange outlet side, wherein a second and a third partial coolant jacket are provided. The second and third partial cooling jackets, arranged on both sides adjacent to the first partial coolant jacket, extend, coming from the crankcase, to a large extent around the gas exchange outlet channel and merge with the first partial coolant jacket in the direction of the gas exchange intake side. In a further advantageous embodiment, the second and third partial coolant jackets extend, coming from the gas exchange outlet channel, on both the sides of the gas exchange valves, in the direction of the gas exchange intake side and on the intake side again in the direction of the crankcase. These embodiments improve once more the entire cooling of the cylinder head according to the invention, because the heat removal from the hot areas is homogenized.
According to a further preferred embodiment, an exhaust gas manifold is provided for the cylinder head on the gas exchange outlet side, wherein the second and third partial coolant jackets extend at least in sections into the exhaust gas manifold. With this embodiment, an exhaust gas manifold can also be temperature controlled in an advantageous way. This exhaust gas manifold can be either mounted on the cylinder head as a separate component or is integral with the cylinder head.
Other objects, advantages and novel features of the present invention will become apparent from the following detailed description of one or more preferred embodiments when considered in conjunction with the accompanying drawings.
In the following, identical reference numerals are used for the same elements in both figures.
Furthermore, the cylinder head includes a gas exchange outlet channel 9 on the outlet side. Between the gas exchange valves 2, 3 there is a fuel injection valve 4 on the intake side and an ignition device 5 on the outlet side. Furthermore,
The coolant jacket 1 consists in essence of a first partial coolant jacket 6, which is arranged in a largely centered manner between the gas exchange outlet valves 3; a second partial coolant jacket 7 and a third partial coolant jacket 8 arranged adjacent to the first partial coolant jacket 6 on both sides. Each of these partial coolant jackets 6, 7, 8 has, coming from the crankcase on the outlet side, its own inflow point. The inflow of a coolant is depicted symbolically with three arrows. The essential flow directions of the coolant in the cylinder head are also depicted symbolically by use of arrows. According to an embodiment of the invention, the coolant jacket 1 is configured to extend as a first partial coolant jacket 6 on the outlet side, coming from the crankcase, between the gas exchange outlet valves 3 and then radially outside around the ignition device 5 and the fuel injection valve 4 and further in the direction of the gas exchange intake side (ES) and back into the crankcase. An overflow back into the crankcase at two outflow points is shown once again symbolically by means of two arrows.
The second and third partial coolant jackets 7, 8 extend on both sides adjacent to the first partial coolant channel 6, coming from the crankcase, to a large extent around the gas exchange outlet channel 9 and further in the direction of the gas exchange intake side (ES) and then extend into the first partial coolant channel 6. The second and the third partial coolant jackets 7, 8 extend further, coming from the gas exchange outlet channel 9, on both sides of the gas exchange valves 2, 3 in the direction of the gas exchange intake side (ES) and at the two outflow points again back into the crankcase.
In an additional, particularly preferred design variant, which is not depicted, an exhaust gas manifold is provided for the cylinder head on the gas exchange outlet side (AS). In this case the second and the third partial coolant jackets 7, 8 extend at least in sections into the exhaust gas manifold. In this embodiment, it is possible to control the temperature of the exhaust gas manifold in an advantageous way. In this case the exhaust gas manifold can be a separate component or can be constructed in one piece with the cylinder head.
The coolant jacket 1 is designed in such a way that the coolant flows from the gas exchange outlet side (AS) from the crankcase, coming centrally relative to the cylinder into the cylinder head (optionally, also laterally next to the gas exchange outlet channels) and from there in close proximity to the combustion chamber roof between the gas exchange outlet valves 3 and around the ignition device 5 and the fuel injection valve 4 in the direction of the gas exchange intake side (ES). In particular, the first partial coolant jacket 6 envelops to a large extent the threaded region of the ignition device 5.
Optimal cooling of the cylinder head according to the invention enables high specific power outputs and high pressure levels, even in the case of high coolant temperatures and an economical cylinder head alloy that is less temperature resistant. This feature leads to a distinct advantage with respect to both the fuel consumption and the cost.
1. coolant jacket
2. gas exchange intake valves
3. gas exchange outlet valves
4. fuel injection valve
5. ignition device
6. first partial coolant jacket
7. second partial coolant jacket
8. third partial coolant jacket
9. gas exchange outlet channel
AS gas exchange outlet side
ES gas exchange intake side
The foregoing disclosure has been set forth merely to illustrate the invention and is not intended to be limiting. Since modifications of the disclosed embodiments incorporating the spirit and substance of the invention may occur to persons skilled in the art, the invention should be construed to include everything within the scope of the appended claims and equivalents thereof.
Number | Date | Country | Kind |
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10 2010 041 105.1 | Sep 2010 | DE | national |
This application is a continuation of PCT International Application No. PCT/EP2011/004450, filed Sep. 2, 2011, which claims priority under 35 U.S.C. §119 from German Patent Application No. DE 10 2010 041 105.1, filed Sep. 21, 2010, the entire disclosures of which are herein expressly incorporated by reference.
Number | Date | Country | |
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Parent | PCT/EP2011/004450 | Sep 2011 | US |
Child | 13826819 | US |