A cylinder liner for a water-cooled internal combustion engine.
The invention relates to a cylinder liner for a water-cooled combustion engine, in particular a two- stroke diesel engine, and with a cylindrical inner sur¬ face delimiting the combustion chamber of the engine and constituting a guide surface for a working piston coaxially journalled in the liner, which piston in its top dead centre position is adjacent to an upper end section of the liner, the upper end section containing a number of elongated cooling channels distributed along the circumference of the liner and being in com¬ munication with a coolant supply chamber and a coolant outlet chamber, each elongated cooling channel having an upwards extending blind end and a guide member mounted longitudinally within the channel and dividing the flow of water in the channel into a flow running upwardly towards the blind end of the channel and a flow running away from the blind end of the channel.
In such a cylinder liner, known from DE-2 149 400, the cooling channels uppermost at the highly loaded top of the liner may be positioned close to the cylindrical inner surface, because the upwards extending blind end does not give rise to too high stress concentrations. The blind channels thus offer a good cooling of the thermally and mechanically highest loaded upper part of the liner.
When the applied engine fuel is sulphurous which is inter alia the case with diesel engines run on heavy fuel oil, the temperature of the cylindrical inner sur¬ face of the liner must be controlled within a comparat- ively narrow interval which is restricted downwards by the wish to prevent sulphuric acid from condensing on the inner surface, and upwards with the view of impeding high-temperature damages to the structural
material of the liner. Experience shows that the con¬ densation of sulphuric acid resulting in intense cor¬ rosive wear both of the inner surface of the liner and of the piston proper may be avoided, if the temperature of the inner surface of the liner is kept at 200 to 230°C in the area adjacent to the upper piston ring when the piston is in its top dead centre position.
If the cylinder liner is e.g. produced from cast iron the highest desirable surface temperature is about 350°C, because higher temperatures notoriously may entail lasting swelling of the cast iron material with subsequent crack formation.
The need for cooling to control the temperature of the inner surface of the liner depends on the speci- fied power for the engine. It is well known that an engine may be specified to a lower power (be derated) in order to obtain a better specific fuel consumption. This is obtained by maintaining the maximum pressure of the engine and, therefore, the lower limit of the allowable working temperature of the inner surface of the liner will not be altered. If the cooling in a derated engine is upheld on a level with that of an engine running at full rating, the temperature of the inner surface falls so much that the previously men- tioned unwanted condensation of sulphuric acid may take place. Prior Art.
US-A-2 572 392 deals with a cylinder liner cooled by means of a surrounding cooling chamber. The external side of the liner is provided with an insula¬ tion band in order to prevent acid from condensing on the inner surface of the liner adjacent the insulation. GB-B-2 019 490 relates to a cylinder liner whose upper end section comprises a series of continuous cooling channels, in which coolant is supplied at the lower end of the channel and discharged through a
radially extending bore at the top of the channel. In order to impede acid condensation on the inner surface of the liner, an insulating tube of synthetic material is urged into the channel. The radially extending bores at the top of the channels make the liner unfitted for highly loaded uses. The invention.
It is the object of the invention to provide a cylinder liner with blind bores in which the cooling effect of the blind bores may be altered according to requirement.
With a view to this, the above mentioned cylinder liner according to the invention is charac¬ terized in that the guide member across part of the length of the channel substantially impedes the water flow at a section of the channel surface facing towards the combustion chamber, whereas at least one of the two flows running towards and away, respectively, from the blind end of the channel, is by the guide member forced to contact the section of the channel surface facing away from the combustion chamber.
Due to the fact that the guide member prevents the water flow in the channel from flowing across and thus cool a section of the channel surface facing towards the combustion chamber, the heat flowing into the inner surface of the liner has to travel a longer distance through the liner in order to be delivered to the coolant. The longer distance results in a reduced temperature gradient and thus a higher temperature on the inner surface of the liner at unaltered coolant temperature and engine yield. Conversely, one and the same cylinder may be applied at different ratings (power lay-outs) of the engine by making use merely of guide members barring a section of the cooling channels appropriate for the actual engine power. Quite apart from the fact that this offers a standardizing advant-
age in the manufacture of the liners because, as regards a specific engine size, only one type of liner has to be manufactured and not a plurality of types dependent on the specified rating of the engine, the considerable advantage is obtained that an existing engine may be specified for a new rating without having to exchange the cylinder liners, merely the guide mem¬ bers have to be changed.
In a particularly simple embodiment the guide member has at least two radially projecting ribs or legs extending in the longitudinal direction of the channel and whose free edge abuts on the channel sur¬ face, and the space defined by the ribs or legs and the channel surface faces towards the combustion chamber and is provided with a barrier member for interrupting the water flow. Since the free edges of the ribs or legs abut on the channel surface, they ensure the posi¬ tioning of the guide member in the channel and at the same time the guide member is supported through a large part of its length which is particularly important in large engines in which the cooling channels and thus the guide members may have a length/diameter ratio typically amounting to 25. The cooling effect may be regulated according to desire in that the ribs or legs enclose between them a larger or smaller angle, thereby barring a larger or smaller section of the channel sur¬ face from the coolant.
In an embodiment in which the guide member has three ribs defining, on one hand, the space that faces towards the combustion chamber and includes the barrier member and, on the other hand, two parallel flow passa¬ ges facing away from the combustion chamber, the coolant may flow upwards through one of the two parallel flow passages and return through the other passage.
In a preferred embodiment a uniform and effect¬ ive cooling effect throughout the length of the channel
is obtained in that the guide member is a tube with a smaller diameter than the channel and that the, at least two, radially projecting ribs or legs extend from the external side of the tube. An annular space is pro- vided between the external side of the tube and the channel surface and when the coolant flows through a section of said space, the flow takes place as a film flow, thereby enhancing the coefficient of heat trans¬ fer by 200 to 400% in relation to the coolant flow in traditioal cooling channels, inter alia because the film flow impedes local boiling on the surface of the cooling channel which would entail a strong decrease in the local heat transfer.
The coolant flow in the channel may also be barred from the section of the channel surface facing towards the combustion chamber by providing the tube in this section with a material layer extending substantially from the external side of the tube to the channel surface.
Brief description of the drawings.
Examples of embodiments of the invention will now be described in detail with reference to the schematical drawings, in which Fig. 1 is a cross-section through an engine cylinder with a cylinder liner according to the inven¬ tion,
Fig. 2 is an illustration of the upper end area of the cylinder liner in Fig. 1, Fig. 3 is a cross-section through a known embo¬ diment of two cooling channels,
Fig. 4 is a cross-section through two cooling channels according to the invention,
Fig. 5 is a section through a second embodiment according to the invention,
Fig. 6 is a cross-section through a cooling channel in the cylinder liner in Fig. 5, and
Fig. 7 is a perspective view of a third embodi¬ ment of a guide member.
Preferred embodiments. The upper end section of a cylinder liner 1 in a large low-speed diesel engine is illustrated in Fig.
1, in which a piston 2 is shown in its top dead centre position. The liner 1 is by a cylinder cover
3 tightened towards the cylinder frame 4. An annular water jacket 5 surrounds the upper end section and defines together with the radial external side of the liner an annular lower coolant supply chamber 6 and an annular upper coolant outlet chamber 7, designed as a circumferential groove in the external side of the liner. A number of cooling channels 8 in the liner establishes flow connection between said two chambers.
During the working of the engine coolant from a cooling chamber that surrounds the lower end section of the liner flows through a drilled connecting channel 10 and a connecting tube 11 into the lower chamber 6 and disperses around the circumference of the liner, following which the water via channels 8 flows into the upper chamber 7. From said chamber the coolant is passed through a connecting tube 14, a drilled channel 15, a distribution chamber 16 and cooling channels 17 in the engine cover and further on to the cooling chamber 18 in the valve seat from which the coolant is carried off.
As shown in Fig. 2, the liner comprises a larger number of straight, elongated cooling channels 8 uni¬ formly distributed along the circumference. The sub¬ stantially circular-cylindrical channels 8 are skewed in relation to the longitudinal axis of the liner and extend upwardly towards the upper edge portion 28 of the inner side of the liner. The blind end 25 of the channel may be hemispherical in order to diminish stress concentrations.
From the external side of the liner the cooling channels 8 are drilled into the upper end section. A water supply tube 21 with a smaller diameter than the channel projects into said channel. For the sake of clearness a tube has only been shown in one of the channels. A projecting flange 22 at the lower tube end abuts on a shoulder in a projecting collar 23 separating the chambers 6 and 7 from each other. A bushing 24 keeps the tube in sealing abutment on the shoulder, thereby forcing coolant from chamber 6 to flow through the tube prior to its penetrating into the channel 8. In view of the fact that the upper end of the tube terminates close to the blind end 25 of the channel, the coolant contacts the blind end as a con- centrated jet, following which the water flows down into a section of the annular space between the exter¬ nal side of the tube and the channel surface, said sec¬ tion facing away from the inner surface of the liner. The water flows from the annular space down into chamber 7.
The arrows A in Fig. 3 illustrate how the heat in a known embodiment of a cooling channel during the working of the engine flows from the inner surface of the liner to the annular space surrounding the tube. It will appear that the heat has a comparatively short distance of travel, thereby offering a high temperature gradient and thus a strong cooling. If a smaller cooling effect of the cooling channels is desired with one and the same cylinder liner, the cooling channels may instead be provided with a guide member according to the invention.
A cross-section through a cooling channel with such a guide member in the form of tube 21 is illus¬ trated in Fig. 4. The tube has two radially projecting protuberances or ribs 30 extending in the longitudi¬ nal direction of the tube and having such a height that
their free edge which may be smoothly rounded in order to diminish the stress concentrations in the liner, exactly abuts on the channel surface and divides the annular space surrounding the tube into two sections of which section 32 facing the inner surface of the liner (and marked in black) is provided with at least one barrier member designed as a horizontally posi¬ tioned collar extending about the tube from the first to the second rib 30, thereby barring section 32 to prevent water flow. The coolant runs down towards chamber 7 through the second section 33 of the annular space and effects thus a cooling of the liner. In view of the fact that the heat substantially is only conducted away in section 33, the heat has to travel a longer distance, as shown by arrows B, which, as stated above, results in less cooling. Instead of providing the tube with ribs 30 the tube may alternatively in section 32 be provided with a material layer 34 extending from the external side of the tube to the channel surface, thereby causing the passage through section 32 to be blocked. This embodiment of the guide member is illustrated in more detail in Fig. 7. The material layer may be made from polytetra-fluoro- ethylene (PFTE) that is "self-lubrifying" when pushing the tube into the channel. The material layer may be adhered to the tube and/or fixed by means of a locking pin inserted in associated bores in the jacket and the tube. The jacket only covers part of the length of the tube and the upwards facing tube end may be jacket-free across a distance of 1 to 2 pipe diameters. Moreover, it is not a prerequisite of obtaining the reduced cooling of the liner aimed at by the invention that the jacket perfectly engages the internal side of the bore. Figs 5 and 6 illustrate a further embodiment according to the invention in which the coolant outlet
chamber 71 is positioned above a projecting flange 35 on the external side of the liner and in which a transverse hole 36 establishes connection between the cooling channel 8• and chamber 7' . A guide member 38 is composed of three radially projecting protuberances or legs 39 that extend in the longitu¬ dinal direction of the channel and divides the channel into three sections of which the section 40 facing towards the inner surface of the liner at least at the top of the guide member and possibly also at its bottom is blocked by a barrier member in the form of a hori¬ zontally positioned plate member 41. The second sec¬ tion 42 is open at the top as well as at the bottom so that the coolant may flow upwards from chamber 6' towards the blind end of the channel through said sec¬ tion, whereas the third section 43 is closed at the bottom by a horizontally positioned plate member 44, said section thereby constituting a return flow passage communicating through the transverse hole 36 with chamber 7* .
The guide members 21, 38 may have a bypass hole 45 connecting chamber 6 with chamber 7. In the embodiment illustrated in Figs l and 2, the bypass hole in tube 21 is on a level with chamber 7, while in the embodiment in Fig. 5 it is adjacent to the trans¬ verse hole 36. The bypass hole will pass part of the coolant, e.g. two thirds of the water, directly into chamber 7 so that the use of the guide member according to the invention does not alter the quantity of coolant flowing through the cylinder frame.
The described embodiments may of course be modi¬ fied in different ways without falling outside the scope of the patent claims. For example, the ribs or legs may have the shape of a circular arc and the channel as well as the tube may have a non-circular cross-section, e.g. an oval cross-section. Plate mem-
bers 41, 44 may have a collar that is shaped like a circular arc and abutting on the channel surface, or the plate members may have a comparatively large thickness in the longitudinal direction of the channel so that the plate members lean against the channel sur¬ face across such a large area that no considerable stress concentrations occur in the liner. The barrier member may also consist of a heat-resistant, water-in¬ soluble and comparatively soft material, such as foam plastics, which in section 32 or 41 is fastened to the guide member.