The present disclosure relates to an internal combustion engine, and more specifically to an internal combustion engine having dual-channel cylinder liner cooling.
Internal combustion engines are typically liquid-cooled. A conventional coolant system for an internal combustion engine may include a coolant pump that pumps coolant into coolant passages of the engine. In certain internal combustion engines, replaceable cylinder liners define the cylinders and, in part, the combustion chambers of the engine.
During combustion, an internal combustion engine may generate an immense amount of heat. In certain engines, a coolant passage is provided between and around the cylinder liners. Coolant may be directed through the coolant passage to cool the liners and carry heat energy away from the cylinders. Heat energy, however, is unevenly distributed in each cylinder liner since the top portion of each cylinder liner, where combustion takes place, experiences higher temperatures.
U.S. Pat. No. 8,443,768 to Berghian et al. discloses an engine cylinder liner having a primary cooling gallery and a secondary cooling gallery about an upper portion of the cylinder liner. The secondary cooling gallery has an undulating configuration that is indicated to substantially increase contact surface of the coolant in the secondary cooling gallery.
In one aspect of the present disclosure, an internal combustion engine is provided including a cylinder head, a piston, and an engine block having a liner bore and a cylinder liner countersunk into the liner bore, wherein a first annular coolant channel having a channel top end and a channel bottom end is formed between the liner bore and the cylinder liner, the cylinder liner including a cylinder bore housing the piston, the piston slideably received within the cylinder bore for reciprocating between a top dead center position and a bottom dead center position, and a top end having an annular flange, wherein the channel top end is closer to the top end of the cylinder liner than the piston when at the top dead center position.
In another aspect of the present disclosure, a cylinder liner is provided including, a cylinder bore capable of housing a piston, a top end having an annular flange, a first cylindrical section acting as a first coolant groove, a second cylindrical section acting as a second coolant groove, and an annular ridge that separates the first cylindrical section and the second cylindrical section.
In another aspect of the present disclosure, a cooling system is provided including a coolant in fluid communication with a water pump, an oil cooler, a thermostat housing, a radiator, and an engine block and cylinder head assembly including a cylinder head, a piston, and an engine block having a liner bore and a cylinder liner countersunk into the liner bore, wherein a first annular channel having an annular channel top end and an annular channel bottom end is formed between the liner bore and the cylinder liner, the first annular channel; the cylinder liner including a cylinder bore housing the piston, the piston is capable of a piston stroke that includes a top dead center, a top end having an annular flange, a first cylindrical section, a second cylindrical section, and an annular ridge that separates the first cylindrical section and the second cylindrical section; wherein the annular channel top end is closer to the top end of the cylinder liner than the top dead center of the piston.
Other features and aspects of this disclosure will be apparent from the following description and the accompanying drawings.
Further features and advantages of the invention will become apparent from the description of embodiments using the accompanying drawings. In the drawings:
Referring to the drawings,
Returning to
When housed in the liner bore 214, the cylinder liner 100, in conjunction with the liner bore 214, forms a first annular coolant channel 250 and a second annular channel 252 below the first annular coolant channel 250 that allow for the passage of a coolant to cool the cylinder liner 100. The coolant is pumped within the internal combustion engine 10 through coolant passages and each of the first annular coolant channel 250 and a second annular coolant channel 252 may be fed from one or more coolant passages 254 (out of plane and shown in relief). The one or more coolant passages 254 may be configured to received coolant from the cylinder head 300. For example, the one or more coolant passages 254 may receive coolant from the cylinder head water jacket (not shown). Suitable coolants include, but are not limited to, water, glycol, or a mixture thereof.
The cylinder liner 100 also includes an annular ridge 112 protruding radially outward from the cylindrical body of the cylinder liner 100. The annular ridge 112 may also be referred to as the pilot diameter. The annular ridge 112 separates the cylindrical body of cylinder liner 100 to form a first cylindrical section 114 and a second cylindrical section 116. The first cylindrical section 114 spans the length of the cylinder liner 100 between the annular flange 108 and the annular ridge 112. When the cylinder liner 100 is housed in the liner bore 214 of the engine block 200, the first annular coolant channel 250 is formed to allow the passage of a coolant around the cylinder liner 100 at the first cylindrical section 114. The first cylindrical section 114 has a smooth surface. The smooth surface of the first cylindrical section 114 may transition to each of the annular flange 108 and annular ridge 112 via a radiused corner.
Similar to the first cylindrical section 114, when the cylinder liner 100 is housed in the liner bore 214 of the engine block 200, a second annular coolant channel 252 is formed to allow the passage of a coolant around the cylinder liner 100 at the second cylindrical section 116. The second cylindrical section 116 has a smooth surface. The smooth surface of the second cylindrical section 116 may taper to meet the annular ridge 112. The cylinder liner 100 may be made from any suitable material or materials, such as for example, from an alloyed gray iron, aluminum, or steel (e.g., stainless steel).
The annular flange 108 of the cylinder liner 100 includes a lower face 110. When the cylinder liner 100 is inserted into the liner bore 214, the lower face 110 of the cylinder liner 100 engages the a radially-extending, upward facing shoulder 206 of the engine block 200. Further, the annular ridge 112 of the cylinder liner 100 engages the liner bore ridge 218. The first annular coolant channel 250 is formed between the first cylindrical section 114 of the cylinder liner 100 and the cylinder bore groove 208. In certain embodiments, the first cylindrical section 114 and the cylinder bore groove 208 do not come into contact with each other within the first annular coolant channel 250. The radially-extending, upward facing shoulder 206 and the lower face 110 engage to form an interface that defines the top of the top of the first annular coolant channel 250. The lower face 110 of the cylinder liner 100 and the radially-extending, upward facing shoulder 206 of the engine block 200 are machined to form smooth surfaces. Accordingly, when coolant flows through the first annular coolant channel 250, coolant is retained within the first annular coolant channel 250 without the need for a secondary seal (e.g., sealing is provided only by the interfaces between the cylinder liner and the cylinder bore). This provides the ability for the first annular coolant channel 250 to be situated closer to the top end 102.
The second annular coolant channel 252 is formed between the second cylindrical section 116 of the cylinder liner 100 and the inner surface of the liner bore 210. When the cylinder liner 100 is inserted into the liner bore 214, an interface is formed between the liner bore ridge 218 and the annular ridge 112 of the cylinder liner 100. The interface between the liner bore ridge 218 and the annular ridge 112 forms a seal and separates the first annular coolant channel 250 and second annular coolant channel 252. While liner bore ridge 218 and the annular ridge 112 forms a seal, in certain conditions, for example during use in extremely cold temperatures, the seal may allow some cross talk of coolant between the first annular coolant channel 250 and the second annular coolant channel 252. In certain embodiments, an incomplete seal may be desired if cross talk of coolant between channels 250 and 252 is desired to prevent stagnation. The second annular coolant channel 252 may terminate at the bottom with an external seal (not shown).
The disclosed cylinder liner or cylinder liner and engine block assembly may be used in any application where it is desired to increase the reliability and operating life of the associated engine. In the disclosed embodiment, the cylinder liner includes a first coolant channel and a second coolant channel. Due to the location of the first channel being in particularly close proximity to the top of the cylinder, the coolant can achieve better access to locations on the cylinder liner that are exposed to higher levels of heat from combustion. The second channel may provide cooling to the remaining portions of the cylinder liner. Accordingly, the disclosed cylinder liner allows for the management and removal of heat generated during combustion without the need for sacrificing the durability of the cylinder liner.
It will be appreciated that the foregoing description provides examples of the disclosed system and technique. However, it is contemplated that other implementations of the disclosure may differ in detail from the foregoing examples. All references to the disclosure or examples thereof, are intended to reference the particular examples being discussed at that point and are not intended to imply any limitation as to the scope of the disclosure more generally. All language of distinction and disparagement with respect to certain features is intended to indicate a lack of preference for those features, but not to exclude such from the scope of the disclosure entirely unless otherwise indicated.