KR20180010134A - Internal combustion engine having at least one cylinder, the cylinder liner of which is coolable via a liquid coolant - Google Patents

Abstract

Disclosed is an internal combustion engine having a cylinder crankcase (8) and one or more cylinders. Each cylinder includes a cylinder liner (1) housed in the cylinder crankcase (8), wherein the cylinder liner (1) of each cylinder can be cooled via a liquid coolant, and the liquid coolant can be supplied to the cylinder liner (1) through a supply line and discharged from the cylinder liner (1) through a discharge line. A coolant supply line device (2) functions in the circumferential position of the cylinder liner (1) of each cylinder. The coolant supply line device (2) provides a supply line duct (5), and communicates with an inlet bore (6) of the cylinder liner (1) formed in the circumferential position of the cylinder liner (1) by using the supply line duct (5), The inlet bore (6) of the cylinder liner (1) of each cylinder (6) opens into a first annular space (7) extending into the circumferential periphery of the cylinder liner (1). The first annular space (7) communicates with a second annular space (9) extending in the circumferential periphery of the cylinder liner (1) via a plurality of bores (10, 10a, 10b) existing in the cylinder liner (1). A cooling medium can be supplied from the second annular space to the discharge line.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an internal combustion engine having at least one cylinder capable of cooling a cylinder liner through a liquid coolant. BACKGROUND OF THE INVENTION 1. Field of the Invention < RTI ID = 0.0 >

The present invention relates to an internal combustion engine having at least one cylinder capable of cooling a cylinder liner through a liquid coolant.

From WO 2013/190175 A1, an internal combustion engine having a cylinder crankcase and at least one cylinder is known. Each cylinder of the internal combustion engine includes a cylinder liner accommodated in a cylinder crankcase and guiding a cylinder piston of each cylinder. To cool the cylinder liners of each cylinder of the internal combustion engine during operation, a cooling jacket is assigned to the cylinder liners, which, when viewed in the circumferential direction, is circumferential around the upper section of the cylinder liner extending from the cylinder crankcase , And this cooling jacket, together with the cylinder liner, defines a range of annular spaces extending around the cylinder liner in the circumferential direction to guide the liquid refrigerant. The integral part of this circumferential cooling jacket is a supply line for the refrigerant through which the refrigerant can be supplied from the outside to the annular space. Through the discharge line, the refrigerant can be discharged from the cylinder liner, that is, discharged from the annular space defined by the cylinder liner and the cooling jacket.

From EP 2 224 119 A1 an additional internal combustion engine with at least one cylinder is known, in which case the cooling jacket also extends around a section of the cylinder liner in the circumferential direction. According to the above-mentioned conventional technique, the cylinder liner and the cooling jacket form two annular spaces extending in the circumferential direction around the cylinder liner, and these annular spaces are coupled to each other through bores.

Internal combustion engines known from the prior art require major design effort to cool the cylinder liners of each cylinder. A water-guiding jacket extending around the cylinder liners of each cylinder in the circumferential direction causes a dimensional increase in the area of the cylinder and enlarges the space for the cylinder. Further, such a water guiding jacket increases the weight of the internal combustion engine.

Starting from this, the present invention is based on the object of forming a new type of internal combustion engine, which permits effective cooling of each cylinder liner with a simple structure.

This object is achieved through the internal combustion engine according to claim 1.

According to the present invention, a supply line device for the refrigerant acts in the circumferential position of the cylinder liners of each cylinder, which supply line duct provides the supply line to the cylinder liner The inlet bore of the cylinder liner of each cylinder opens into a first annular space extending around the circumferential direction of the cylinder liner, and the first annular space Through a plurality of bores of the cylinder liner, communicates with a second annular space extending around the circumferential direction of the cylinder liner from which the cooling medium can be supplied to the exhaust line.

In the internal combustion engine according to the present invention, the supply line device for the refrigerant is responsible for the supply line of the refrigerant in the direction of the cylinder liner, in the region of each cylinder, Only in the circumferential position, thereby acting on the cylinder liner at the above-mentioned predetermined circumferential position.

Through the supply line duct provided by this supply line device and the inlet bore of the cylinder liner communicating with this supply line duct, the coolant can be provided to the cylinder liner, that is, the cylinder liner in the annular space extending around the cylinder liner The annular space is not provided through a separate component but rather is an integral part of the cylinder liner. Starting from this first annular space, the coolant can be supplied to the second annular space through a plurality of bores of the cylinder liner, and the second annular space is also provided with a plurality of bores, Extends around the cylinder liner, and this second annular space is also at least partially confined by each cylinder liner.

The present invention has the advantage that the water content jacket can be omitted. Because of this, more compact dimensions in the region of the cylinder can be realized, and as a result, fewer cylinder spacings are possible for the internal combustion engine. Further, the weight of the internal combustion engine can be reduced.

According to a further advantageous development of the invention, a plurality of bores extend from the first annular space in the direction of the second annular space, starting from the second annular space, Which in each case is set obliquely with respect to the axial direction of the respective cylinder liner, which in each case is such that during operation the cylinder liner is preferably exposed to maximum heating In the region of the cylinder liner where one of the first bores intersects one of the second bores. This further improvement of the invention is particularly desirable since it allows for effective cooling of the cylinder liners of each cylinder of the internal combustion engine with a particularly small weight without any additional components.

According to a further advantageous variant of the invention, a plurality of bores extending substantially in the axial direction of each cylinder liner extend between the first annular space and the second annular space, And a bottleneck is formed between the end of the second annular space facing the cylinder head and at least one adjacent blind hole bore of the cylinder liner, Flow into each blind hole bore forming loop scavenging. Each blind hole bore is introduced into the region of the cylinder liner where the cylinder liner is preferably exposed to maximum heating during operation. Using this further refinement of the invention, jacket tubes are required as additional components for each cylinder, although effective cooling of the cylinder liners of each cylinder with small dimensions and low weight can also be ensured.

Further desirable improvements of the invention can be obtained from the dependent claims and the following description. BRIEF DESCRIPTION OF THE DRAWINGS Exemplary embodiments of the present invention are described in greater detail in the drawings, but are not limited thereto.

1 is a detailed perspective view of an internal combustion engine according to the present invention in the region of a cylinder liner of a cylinder of an internal combustion engine.
2 is a detailed sectional view of the internal combustion engine according to the present invention in the region of the cylinder liner of the cylinder according to the first aspect of the present invention.
3 is a detailed sectional view of the internal combustion engine according to the present invention in the region of the cylinder liner of the cylinder according to the second aspect of the present invention.
4 is a detailed sectional view of the internal combustion engine according to the present invention in the region of the cylinder liner of the cylinder according to the third aspect of the present invention.

The present invention relates to an internal combustion engine having at least one cylinder. Each cylinder includes a cylinder liner received in a cylinder crankcase of an internal combustion engine, wherein the cylinder piston of each cylinder is guided in a cylinder liner, and the cylinder liner must be cooled during operation. The present invention relates to the details of an internal combustion engine that enables efficient cooling of the cylinder liners of each cylinder using a simple structure, with minimum installation space and minimum weight. Fig. 1 shows a detailed view of an internal combustion engine, that is, a cylinder liner 1 is shown in a perspective view. Figs. 2 to 4 show cross sections of aspects of the cylinder liner 1 in a state in which the cylinder liner is inserted into the cylinder crankcase. Fig.

The supply line device 2 for the coolant acts on the cylinder liner 1 in the circumferential position of the cylinder liner 1. [ 1, this supply line device 2 comprises a flange section 3 through which a supply line device 2 is mounted to the cylinder liner 1 at a predetermined circumferential position of the cylinder liner 1, Is fastened to the corresponding flange section (4) of the housing (1) and is fastened, in particular via a screw connection.

A supply line device (2) positioned at a predetermined circumferential position of the cylinder liner (1) and connected to the cylinder liner (1) at this predetermined circumferential position provides a supply line duct (5) for the coolant, The refrigerant can be carried in the direction of the cylinder liner 1 through the supply line duct 5 of the device 2 and the inflow bore 6 of the cylinder liner 1 can be supplied to the supply line device Wherein the inlet bore is formed in the region of the flange section (4) of the cylinder liner (1) in the circumferential position, wherein the feed line device (2) is connected to the cylinder liner 1).

Mentioned inlet bore 6 of the cylinder liner 1 which is formed in the circumferential position of the cylinder liner 1 and communicates with the supply line duct 5 of the supply line device 2 fastened to the cylinder liner 1, Is opened into a first annular space (7) extending in the circumferential direction around the cylinder liner (1), and the first annular space is provided by a cylinder liner (1) and partly in the cylinder liner And the range is limited in part by the cylinder crankcase 8 into which the cylinder liner 1 is inserted.

Starting from this first annular space 7, the liquid refrigerant can be guided in the direction of the second annular space 9, that is to say through a bore 10 formed in the cylinder liner 1. Is located closer to the cylinder head (not shown) than the first annular space (7) which is spaced from the first annular space as viewed in the axial direction of the cylinder liner (1) and which is adjacent to the cylinder crankcase The second annular space 9 is likewise confined by the cylinder liner 1 and in the preferred exemplary embodiment of figure 3 it is provided with a cylinder head 1 which is adjacent to the cylinder liner 1 and which is not shown, The range is limited.

As already described, a plurality of bores 10 extend between the first annular space 7 and the second annular space 9. 3, a plurality of first bores 10a starting from a first annular space 7 extend in the direction of a second annular space 9, and a second annular space 10, Starting from the space 9 a plurality of second bores 10b extend in the direction of the first annular space 7 and these bores are in each case arranged in the cylinder liner 1 of each cylinder Which is in each case an area 11 in which the cylinder liner 1 of the internal combustion engine is preferably exposed to a high heat load, in particular a maximum heat load and thus heating, In the axial direction of the cylinder liner 1 and in the axial section of the cylinder liner 1 one of the first bores 10a intersects one of the second bores 10b .

The inclination angles of the bores 10a and 10b described above start from the respective annular spaces 7 and 9 when the bores 10a and 10b are viewed in the direction of the longitudinal center axis of each cylinder liner 1 So that the intersection points of the bores 10a and 10b indicate the predetermined distance from the inner outer tube 12 of the cylinder liner 1 and the bores 10a and 10b in the region 11 where the bores 10a and 10b intersect Are selected in such a way that they are positioned adjacent to the so-called flame ring 13 of the cylinder liner 1 of each cylinder.

The first bore 10a starting from the first annular space 7 and extending in the direction of the second annular space 9 is set obliquely with respect to the axial direction of the cylinder liner 1 by the angle alpha 1 On the other hand, the second bore 10b extending from the second annular space 9 in the direction of the first annular space 7 is extended in the axial direction of the cylinder liner 1 by an angle? As shown in FIG.

The preferred exemplary embodiment of Fig. 3 allows effective cooling of the cylinder liners 1 of each cylinder, with a simple construction and with a small weight and small dimensions. The liquid refrigerant is provided through a supply line device 2 positioned only at a predetermined circumferential location so that each supply line duct (not shown) intersecting each supply line bore 6 of each cylinder liner 1 5 are provided. In the preferred exemplary embodiment of Fig. 3, between the two annular spaces 7 and 9, all of which are provided at least partly by the cylinder liner 1 and of which the range is limited, the cylinder liner 1 of each cylinder Bores 10a and 10b, which are each set obliquely with respect to the axial direction and intersect with each other in the region of the predetermined heating or heat load of each cylinder liner 1, are extended.

Fig. 4 is based on the embodiment of Fig. 3, but additionally uses jacket tube 14 in the region of each cylinder, and with cylinder liner 1 and cylinder head of an internal combustion engine not shown, Lt; RTI ID = 0.0 > a < / RTI > second annular space (9). Although such a jacket tube 14 constitutes an additional component, in this case, the cylinder liner 1 can be implemented more simply while reducing the material thickness at the end facing the cylinder head. 4 relate to the exemplary embodiment of FIG. 3, and thus the same reference numerals are used for the same assemblies to avoid unnecessary repetitions, and the exemplary embodiment of FIG. 3 See the description of the example.

A further exemplary embodiment of the present invention is shown in Fig. 2 also shows a cylinder liner 1 received in a cylinder crankcase 8 of an internal combustion engine. In this aspect of the invention, in accordance with the exemplary embodiment of Figures 3 and 4, the supply line device 2 for the refrigerant is also positioned in the circumferential position of the cylinder liner 1, (2) acts on the corresponding flange (4) of the cylinder liner (1) through the flange (3) and the supply line duct (5) of the supply line device for the coolant is formed in the aforementioned circumferential position And the supply line bore 6 of the cylinder liner 1 for the refrigerant. Using this aspect, the refrigerant is introduced into the first annular space 7, starting from the supply line duct 5 of the supply line device 2 and through the supply line bore 6 of the cylinder liner 1, And the first annular space is limited in range by the cylinder liner 1 and the cylinder crankcase 8. Starting from this first annular space 7, the refrigerant can again be conveyed in the direction of the second annular space 9 through the bore 10 and the second annular space can be conveyed through the bore 10 in the example shown in FIG. 2 The range is limited by the cylinder liner 1 and the jacket tube 14 following the cylinder liner 1. In the embodiment shown in Fig.

In the exemplary embodiment of FIG. 2, the bore 10 through which the refrigerant, which can be fed into the second annular space 9, starting from the first annular space 7, passes through the cylinder liner 1).

In the exemplary embodiment of Figure 2 the second annular space 9 is defined by a jacket tube 14 adjacent to at least one blind hole 15 introduced into the cylinder liner 1, In such a manner that the second annular space 9 is tapered in the direction of the cylinder head, which is defined and not shown, and which blind hole is provided for guiding the refrigerant between the jacket tube 14 and the cylinder liner 1 Thereby forming the bottleneck 16. The refrigerant guided through the bottleneck 16 between the cylinder liner 1 and the jacket tube 14 undergoes an increase in the flow velocity in the region of the bottleneck 16 and forms a loop scavenging Wherein each blind hole 15 is in fluid communication with a respective blind hole 15 in the region where the cylinder liner 1 is exposed to the maximum heat load or heating, And introduced into the cylinder liner 1. In this way, the cylinder liner 1 can also be effectively cooled during operation. Accordingly, the refrigerant starts from the second annular space 9, flows into each of the blind hole bores 15, and starts and flows in the direction of the unillustrated refrigerant discharge line.

1 to 4, the supply line devices 2 acting on the cylinder liners 1 of the cylinders are connected to respective supply lines 2 extending in the direction of the inlet bores 6 of the respective cylinder liners 1, Not only provides a duct 5 but also provides a further connecting section 17 through which the supply line devices 2 of the plurality of cylinders 1 are connected to a common supply line for the refrigerant . The duct section 18 provided by this connection section 17 is on the one hand communicated with the inlet line duct 5 of each supply line device 2 and on the other hand with the It communicates with the refrigerant duct.

Compared to the prior art, all of the illustrated arrangements of the present invention have the advantage of enabling effective cooling of the cylinder liners 1 of the cylinders of the internal combustion engine with equally less effort, less weight and smaller installation space.

1: Cylinder liner
2: supply line device
3: Flange
4: Flange
5: Supply line duct
6: Supply line bore
7: annular space
8: Cylinder crankcase
9: Annular space
10: Boer
10a: Bohr
10b: Boer
11: area
12: Inner appearance
13: Flame ring
14: jacket tube
15: blind hole bore
16: bottleneck
17: Connection section
18: Connection duct

Claims (9)

An internal combustion engine having a cylinder crankcase (8) and at least one cylinder, wherein each cylinder includes a cylinder liner (1) received in a cylinder crankcase (8), and each cylinder cylinder liner The liquid refrigerant can be supplied to the cylinder liner 1 through the supply line and discharged from the cylinder liner 1 through the discharge line, and the liquid refrigerant supply line device 2 Wherein the supply line device for liquid coolant 2 supplies the supply line duct 5 and the cylinder liner 1 is operated by means of the supply line duct 5 at a position in the circumferential direction of the cylinder liner 1 of the cylinder of the cylinder ) Of the cylinder liner (1) formed at the circumferential position of the cylinder liner (1)
The inlet bore 6 of the cylinder liner 1 of each cylinder is opened into the annular space 7 extending around the circumferential direction of the cylinder liner 1,
The first annular space 7 has a second annular space 9 extending around the circumferential direction of the cylinder liner 1 through a plurality of bores 10, 10a, 10b in the cylinder liner 1, And the cooling medium can be supplied to the discharge line from the second annular space. 2. An internal combustion engine according to claim 1, characterized in that said first annular space (7) and said second annular space (9) are each at least partially delimited by their respective cylinder liners (1). 3. An internal combustion engine according to claim 1 or 2, characterized in that said first annular space (7) is limited by each cylinder liner (1) and by the cylinder crankcase (8). Method according to any one of claims 1 to 3, characterized in that the second annular space (9) is formed by the jacket tube (14) and / or the cylinder head of each cylinder and to the respective cylinder liner (1) And the range is limited. A method according to any one of claims 1 to 4, characterized in that a plurality of bores (10a) extend in the direction of the second annular space (9) starting from the first annular space (7) A plurality of bores 10b extend in the direction of the first annular space 7 starting from the annular space 9 of each cylinder liner 1 in each case, In each case in the region 11 of the cylinder liner 1, in which the cylinder liner 1 is exposed to the main heating during operation, in each case the first bore 10a, Of the first bores (10b) intersect one of the second bores (10b) in each case. 5. A cylinder bore according to any one of claims 1 to 4, characterized in that a plurality of bores (10) extending substantially in the axial direction of each cylinder liner (1) are arranged in a first annular space (7) And the second annular space 9 tapers in the direction of the cylinder head and extends between the end of the second annular space 9 facing the cylinder head and at least one of the cylinder liner 1 A bottleneck 16 is formed between neighboring blind hole bores 15 of the blind hole bore 10. The refrigerant flows into each of the blind hole bores 10 while forming loop scavenging And the internal combustion engine. 7. An internal combustion engine as claimed in claim 4 or 6, characterized in that the bottleneck (16) is limited in scope by a respective cylinder liner (1) and a respective jacket tube (14). 8. A method according to claim 6 or 7, characterized in that each blind hole bore (15) is introduced into a region (11) of the cylinder liner (1) in which the cylinder liner (1) Internal combustion engine. 9. A method as claimed in any one of the preceding claims, characterized in that the supply line device (2) is fastened to the cylinder liners (1) of the respective cylinders via neighboring flanges (3, 4) Agency.

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