1. Field of the Invention
The invention relates generally to cylinder liners for internal combustion engines, engine block assemblies including the cylinder liners, and methods of manufacturing the same.
2. Related Art
Engines today are preferably designed to be smaller and lighter in order to condense packaging, reduce engine mass, and improve fuel economy. However, the smaller size can cause problems and concerns for finding places and positions for various components and machining. One of the areas of concern is the smaller interbore bridge area between the piston cylinder openings in the engine block. When cooling of the interbore bridges is necessary, drilled holes and/or saw slots can be machined into the bridge areas. Given the smaller bore spacing, and if liners are positioned in the cylinders, it can be difficult to machine the saw slots and/or drill the holes without contacting the cylinder liners and damaging the cutting tools. This can cause scrappage of the engine block and/or block line downtime.
Turning down the outside surface of the cylinder liners can create some additional space in the interbore bridge regions for slot and hole machining. However, this can result in poor thermal conductivity and large magnitudes of bore distortion due to the lack of physical or mechanical bonding of the cylinder liner to the engine block. These conditions are undesirable in these critical regions of the engine block.
One aspect of the invention provides a cylinder liner for an internal combustion engine which provides for improved bonding to an engine block. The cylinder liner includes a liner member having a length extending longitudinally from a top end to a bottom end. The liner member includes an inside surface extending around a center axis and an oppositely facing outside surface. The outside surface presents a first outside diameter along a first portion of the length and a second outside diameter along a second portion of the length, wherein the first outside diameter is less than the second outside diameter. A bonding layer including aluminum is adhered to the outside surface along the first portion of the liner member.
The invention also provides a method of manufacturing the improved cylinder liner. The method includes providing the liner member with the first outside diameter along the first portion of the length and the second outside diameter along the second portion of the length. The method further includes adhering a bonding layer including aluminum to the outside surface along the first portion of the length of the liner member.
Another aspect of the invention provides an engine block assembly including a plurality of the cylinder liners. Each cylinder liner includes the liner member and a layer of a first material including aluminum applied to the outside surface along the first portion. The assembly also includes a block formed of a second material including aluminum and presenting a plurality of bores each for receiving one of the cylinder liners. The second material of the block is cast onto the first material of the bonding layers.
The invention also provides for a method of manufacturing the engine block assembly. The method includes providing the plurality of cylinder liners, and disposing the plurality of cylinder liners in a mold. The method next includes casting the second material including aluminum onto the bonding layers of the cylinder liners in the mold.
Other advantages of the present invention will be readily appreciated, as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:
One aspect of the invention provides a cylinder liner 20 for an internal combustion engine with a liner member 22 and a bonding layer 24, as shown in
The cylinder liner 20 includes a liner member 22 formed of a metal material. In an exemplary embodiment, the metal material used to form the liner member 22 is cast iron, but the liner member 22 can alternatively be formed of steel or another metal material capable of withstanding the temperature, pressures, and other conditions of an internal combustion engine. The metal material used to form the liner member 22 is different from the metal material of the surrounding engine block 26, and the metal material of the liner member 22 typically does not physically and chemically bond to the engine block 26 without the bonding layer 24.
As shown in
The outside surface 34 of liner member 22 also extends circumferentially around the center axis A and presents a cylindrical-shaped surface extending from the top end 28 to the bottom end 30. The outside surface 34 has a first outside diameter D1 along a first portion of the length L and a second outside diameter D2 along a second portion of the length L. As shown in
The first portion with the reduced first outside diameter D1 and reduced thickness t1 extends along a portion of the length L of the liner member 22 which is less than 100% of the length L of the liner member 22. The second portion also extends along a portion of the length L of the liner member 22 which is less than 100% of the length L. The first portion of the outside surface 34 is typically 10% to 50% of the length L of the liner member 22, and more typically 20 to 30% of the length L of the liner member 22. The first portion is typically located adjacent to one of the ends 28 or 30 of the liner member 22, in which case the second portion extends from the first portion to the opposite end 28 or 30. For example, the first portion can be located adjacent the top end 28 of the liner member 22, as shown in
The first outside diameter D1 along the length L of the first portion of the liner member 22 is typically constant. However, small variations in the first outside diameter D1 may be present. For example, the first outside diameter D1 may vary by not more than 1 millimeter along the length L of the first portion. In one embodiment, the first portion of the outside surface 34 is shot-blasted before the bonding layer 24 is applied. The shot-blasting process forms a plurality of depressions 36 along the outside surface 34 to assist in adhering the bonding layer 24 to the liner member 22, as shown in
The second outside diameter D2 along the length L of the second portion of the liner member 22 is also typically constant. However, small variations in the second outside diameter D2 may also be present. For example, the second outside diameter D2 may vary by not more than 1 millimeter along the length L of the second portion. In an alternate embodiment, the second outside diameter D2 varies more significantly along the second portion of the length L. For example, the outside surface 34 can present a plurality of protrusions (not shown), such as ribs or nubs, extending radially outwardly relative to the surrounding portion of the outside surface 34. The outside surface 34 along the second portion could alternatively comprise another type of engineered surface (not shown). The protrusions or other type of engineered surface can provide an improved mechanical connection between the liner member 22 and the surrounding cast engine block 26.
The bonding layer 24 applied to the liner member 22 is formed of a material which includes aluminum. The bonding layer 24 typically covers the entire first portion of the outside surface 34, but could cover only a section of the first portion. The material applied to the liner member 22 is typically the same as or similar to a second material used to form the engine block 26. Thus, a strong bond is formed when the second material is cast around the first material. The bonding layer 24 also has a thickness t3 which can vary. Preferably, the bonding layer 24 provides an outside diameter D3 which is not greater than the second outside diameter D2 of the liner member 22, as shown in
In one exemplary embodiment, the aluminum-containing material used to form the bonding layer 24 is an aluminum alloy, including aluminum in an amount of 85 to 90 weight percent (wt. %), silicon in an amount of 10 to 15 wt. %, oxygen in an amount of 0.05 to 0.15 wt. %, and optionally Fe, Mg, Zn, and Mn in a total amount less than 1 wt. %, based on the total weight of the aluminum alloy. In this exemplary embodiment, the bonding layer 24 also has a porosity of less than 5%, a thermal conductivity of 80 to 120 W/mK at 50 to 400° C., a thermal expansion coefficient of 20 to 24×10−6/K at 20 to 150° C., a tensile strength of at least 170 MPa, and an elastic modulus of 40 to 70 GPa. However, other compositions which include aluminum in various different amounts, and which are not necessarily aluminum-based, can be used to form the bonding layer 24.
In the exemplary embodiment, the bonding layer 24 is applied to the outside surface 34 by thermal spraying, such as plasma spraying. However, other methods can be used to apply the bonding layer 24 to the liner member 22.
Another aspect of the invention provides a method of manufacturing the cylinder liner 20. The method first includes providing the liner member 22, such as the liner member 22 described above. The geometry of the liner member 22, however, can vary. The method next includes preparing the liner member 22 for application of the bonding layer 24. This typically includes radially machining a portion of the outside surface 34 of the liner member 22 to form the first portion having the reduced first outside diameter D1. However, other methods besides machining can be used to form the reduced first outside diameter D1.
To further prepare liner member 22 for application of the bonding layer 24, the method typically includes activating the outside surface 34 along the machined first portion. This step includes removing any contaminants, oil, or corrosion from the outside surface 34. The method can also include forming a rough texture along the first portion, for example by shot-blasting, as described above. The shot-blasting process forms a plurality of depressions 36 which assist in adhering the bonding layer 24 to the liner member 22.
The step of applying the bonding layer 24 to the outside surface 34 along the first portion preferably includes thermal spraying. Any type of thermal spraying technique can be used, for example plasma spraying.
Another aspect of the invention provides an engine block assembly 38 for an internal combustion engine including the cylinder liner 20 with the bonding layer 24, and a method of manufacturing the engine block assembly 38, as shown in
The liner member 22 is formed of a metal material different from the materials of the bonding layer 24 and the block 26. In the exemplary embodiment, the liner member 22 is formed of the first material and is physically and chemically bonded to the second material of the block 26 along the bores 40. The second material of the engine block 26 is preferably the same as or similar to the first material of the bonding layer 24 and thus the two materials form an intermetallic bond including a homogeneous mixture of the first material and the second material during the casting process. The intermetallic bond increases thermal conductivity of the resulting engine block assembly 38 because heat from the liner member 22 can flow through the liner member 22 and through the bonding layer 24 to the block 26. The bonding layer 24 also reduces any distortion of the bore 40 and bridges areas.
The engine block 26 of the exemplary embodiment presents a cooling chamber 44, also referred to as a water jacket, spaced from each of the bores 40 by the second material of the block 26, as shown in
The upper surface 48 of the engine block 26 presents a plurality of bridge areas 42, and each bridge area 42 is planar and located between adjacent bores 40. The width of each bridge area 42 located between adjacent bores 40 and used to form the cooling chamber 44 and cooling passages 46 is increased when the machined cylinder liner 20 with the bonding layer 24 is used, compared to cylinder liners without the bonding layer 24.
Another aspect of the invention provides a method of manufacturing an engine block assembly 38. The method generally includes providing a plurality of the cylinder liners 20 including the bonding layer 24 formed of the first material applied to the machined first portion of the liner member 22, disposing the cylinder liners 20 in a mold 50, and casting the second material around the plurality of cylinder liners 20 in the mold 50. An example of the method steps are disclosed in
The first step of providing the cylinder liners 20 can be conducted as described above. As disclosed in
The coated cylinder liners 20 are then positioned in the mold 50. The casting step includes providing the second material in molten form and pouring the second material into the mold 50 to form the engine block 26. The second material physically and chemically bonds to the first material of the bonding layer 24 during the casting step. The mechanical and intermetallic bond created during the casting step helps ensure that the cylinder liner 20 is strongly bonded to the engine block 26.
After the engine block 26 is cooled and solidified, it is removed from the mold 50. Thereafter, the engine block 26 is machined and/or drilled as desired or required, typically to form the bridge areas 42, cooling chamber 44, and cooling passages 46, as described above.
Obviously, many modifications and variations of the present invention are possible in light of the above teachings and may be practiced otherwise than as specifically described while within the scope of the appended claims.
This U.S. continuation patent application claims the benefit of U.S. utility patent application Ser. No. 14/332,586, filed Jul. 16, 2014, which claims the benefit of U.S. provisional patent application Ser. No. 61/846,973, filed Jul. 16, 2013, the entire contents of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
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61846973 | Jul 2013 | US |
Number | Date | Country | |
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Parent | 14332586 | Jul 2014 | US |
Child | 14922657 | US |