DE102015219886A1 - Engine block of an internal combustion engine - Google Patents

Abstract

The present invention relates to an engine block (1) of an internal combustion engine comprising at least one cylinder, wherein a cylinder bore (4) for a piston of the internal combustion engine includes a volume having at least a first frusto-conical portion (9) and at least a second frusto-conical portion (10) wherein the first frusto-conical portion (9) and the second frusto-conical portion (10) directly adjoin one another, and wherein the first frusto-conical portion (9) has a higher wall slope than the second frusto-conical portion (10).

Description

The present invention relates to an engine block of an internal combustion engine. In particular, the invention relates to a shaping of a cylinder bore of a cylinder of the engine block.

Motor blocks are known from the prior art. Such engine blocks have cylinder bores in which pistons of the internal combustion engines are feasible. From the prior art it is known that such holes are made cylindrical.

However, cylindrical bores have the disadvantage that an increased friction of the piston takes place. Thus, the geometry of the cylinder bore usually changes when a cylinder head is mounted and / or the engine block is heated by the operation of the internal combustion engine. In particular, different extents of the engine block may also result from water cooling cooling only a portion of the engine block. Thus, the originally cylindrical bore deforms, resulting in increased friction of the piston.

From the DE 10 2011 117 660 A1 An internal combustion engine is known which has a cylinder bore with two different diameters. The regions of different diameters are connected by a variable diameter transition region. With such a design, the contour of the cylinder bore can be adapted to a potential different heating of the engine block. However, the molding of the lower cylindrical portion in particular is very difficult.

It is therefore an object of the invention to provide an engine block with at least one cylinder for an internal combustion engine, which reduces friction loss of a piston which can be guided in the cylinder with simple and cost-effective production and assembly.

The solution of this object is achieved by the features of claim 1. Thus, the solution of the problem by an engine block of an internal combustion engine having at least one cylinder. It is provided that a cylinder bore for a piston of the internal combustion engine includes a volume which comprises at least a first frusto-conical portion and a second frusto-conical portion. The first frusto-conical portion and the second frusto-conical portion preferably directly adjoin one another. By such a combination of frusto-conical sections, a piston clearance between the piston and the cylinder bore in the lower region of the cylinder bore is advantageously increased. At the same time, the first frusto-conical portion and the second frusto-conical portion, in particular the second frusto-conical portion, are very easily finished compared to a cylindrical shape. The first frusto-conical portion has a greater wall pitch than the second frusto-conical portion. In this way, the engine block, in particular the cylinder bore, very easily manufacturable, at the same time a friction of a piston, which is feasible within the cylinder bore, is reduced.

The dependent claims have advantageous developments of the invention to the content.

Advantageously, the cylinder bore extends between an upper end and a lower end. In this case, the second frusto-conical portion bears against the lower end. In this way, both the first frusto-conical portion and the second frusto-conical portion are very easily manufacturable.

It is preferably provided that the upper end of the cylinder bore has a smallest diameter of the cylinder bore. Thus, the upper end determines the minimum piston clearance.

Furthermore, it is preferably provided that the lower end has a largest diameter of the cylinder bore. Thus, the lower end determines the maximum piston clearance.

Particularly advantageously, a diameter of the cylinder bore between the upper end and the lower end increases steadily in sections or is constant. Thus, it is avoided that the diameter of the cylinder bore between the upper end and the lower end is reduced. In this way, the fabrication of, in particular, the first frusto-conical portion and the second frusto-conical portion is simplified. In this way, it is ensured in both the first frusto-conical portion and in the second frusto-conical portion that a diameter larger than any other diameter closer to the upper end prevails at each point.

The cylinder bore advantageously has a diameter larger than the smallest diameter in a region between the lower end and a boundary. Alternatively or additionally, in this area, the diameter of the cylinder bore steadily increases at least in sections in the direction of the lower end. At the same time it is preferably provided that the diameter does not decrease in this area in the direction of the lower end. It is envisaged that the limit at most 70%, in particular at most 60%, particularly advantageously at most 50%, of the distance between the upper end and lower end of the cylinder bore is remote from the upper end. In this way, in particular friction losses within the cylinder bore are minimized when a piston moves in the cylinder bore.

The cylinder bore encloses in particular a volume which has a different head area from the remaining volume. The head area advantageously borders directly on the upper end. Thus, the head region is in particular an area in which there is a minimal piston play.

The head region is also particularly advantageous at the first frusto-conical portion. Thus, the cylinder bore advantageously has three areas, the head area, the first frusto-conical portion and the second frusto-conical portion. In this way, the manufacture of the engine block, in particular the second frusto-conical portion of the cylinder bore compared to a cylindrical shape, simplified.

The head area is advantageously frusto-conical or cylindrical. Alternatively, it is provided that the head region is the first frusto-conical section. In both cases, it is provided in particular that the diameter of the cylinder bore does not decrease seen in the direction of the lower end. In this way, a friction of the piston is reduced within the cylinder bore.

The head portion and the first frusto-conical portion or the second frustoconical portion advantageously abut against each other at a first boundary. It is provided that the head region and the first frusto-conical portion or the second frusto-conical portion have the same diameter at the first boundary region. Thus, there are no jumps in diameter within the cylinder bore. Rather, there is a continuous transition of a course of the diameter between the upper end and lower end. Thus, in turn friction losses of a feasible within the cylinder bore piston can be reduced.

The first frusto-conical portion and the second frusto-conical portion advantageously abut against each other at a second boundary. It is provided that the first frusto-conical portion and the second frusto-conical portion have the same diameter at the second boundary region. Thus, there are no jumps in diameter within the cylinder bore. Rather, there is a continuous transition of a course of the diameter between the upper end and lower end. Thus, in turn friction losses of a feasible within the cylinder bore piston can be reduced.

The largest diameter of the cylinder bore is advantageously at most 0.5% larger than the smallest diameter of the cylinder bore. Particularly advantageously, the largest diameter is at most 0.4%, particularly advantageously at most 0.3% larger than the smallest diameter of the cylinder bore. Thus, it is ensured that a maximum piston clearance remains within a predetermined tolerance, so that the piston is guided safely and friction within the cylinder bore.

The invention further relates to a vehicle. The vehicle includes an engine block as described above.

Further details, features and advantages of the invention will become apparent from the following description and the figures. Show it:

1 a schematic illustration of an engine block according to a first embodiment of the invention,

2 a schematic illustration of an engine block according to a second embodiment of the invention,

3 a schematic illustration of an engine block according to a third embodiment of the invention,

4 a schematic illustration of an engine block according to a fourth embodiment of the invention,

5 a schematic illustration of an engine block according to a fifth embodiment of the invention,

6 a schematic illustration of an engine block according to a sixth embodiment of the invention,

7 a schematic illustration of an engine block according to a seventh embodiment of the invention,

8th a schematic illustration of an engine block according to an eighth embodiment of the invention,

9 a schematic illustration of an engine block according to a ninth embodiment of the invention,

10 1 is a schematic illustration of an engine block according to a tenth embodiment of the invention;

11 1 is a schematic illustration of an engine block according to an eleventh embodiment of the invention;

12 a schematic illustration of an engine block according to a twelfth embodiment of the invention,

13 a schematic illustration of an engine block according to a thirteenth embodiment of the invention, and

14 a vehicle according to an embodiment of the invention.

1 schematically shows an engine block 1 according to a first embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has an upper frustoconical widening area 7 on. The upper frustoconical widening area 7 is at the top 2 at. At the upper frusto-conical widening area 7 lies a cylindrical head area 5 at. At the cylindrical head area 5 In turn, there is a first frusto-conical area 9 at. At the first frusto-conical area 9 is a second frusto-conical area 10 at, wherein the second frusto-conical region 10 at the bottom 3 the cylinder bore 4 is applied.

Through the upper frustoconical widening area 7 indicates the cylinder bore 4 the smallest diameter at a boundary between the upper frusto-conical widening area 7 and the cylindrical head portion 5 on. The diameter at this limit thus represents an upper limit of the piston clearance. Starting from this limit, the diameter of the cylinder bore decreases 4 both towards the top end 2 as well as in the direction of the lower end 3 too, without taking off again.

It is provided that a diameter of the cylinder bore 4 at the top 2 a maximum of 0.3%, advantageously by a maximum of 0.2%, particularly vorteilhat by a maximum of 0.1%, is greater than the smallest diameter of the cylinder bore 4 located at the boundary between the upper frusto-conical widening area 7 and the cylindrical head portion 5 lies.

The upper frustoconical widening area 7 allows compensation for a deformation caused by the application of a cylinder head on the upper end 2 into the cylinder bore 4 is introduced. Thus, the application of the cylinder head leads to the upper end 2 to that the edges of the cylinder bore 4 pressed inward, which increases the radius of the cylinder bore 4 at the top 2 reduced. Through the upper frustoconical widening area 7 this deformation is compensated. Thus, in particular, it is not necessary to provide the piston with a contour corresponding to the deformation complementary contour, as a collision of the piston and cylinder bore 4 by the compensation function of the upper frusto-conical expansion area 7 is prevented.

The upper frustoconical widening area 7 extends in particular to one Limit which is at most 40%, preferably at most 30%, particularly preferably at most 20%, of the distance between the upper end 2 and lower end 3 from the upper end 2 away. In this way it is prevented that a volume in the upper area of the cylinder becomes too large. Due to the described dimension of the upper frusto-conical expansion area 7 is ensured that the upper frusto-conical widening area 7 merely compensates for deformations due to the application of the cylinder head.

The cylindrical head area 5 abuts the first frusto-conical region in a boundary region 9 , At this boundary region, the first frusto-conical region 9 and the cylindrical head portion 5 the same diameter, so no cracks in the wall of the cylinder bore 4 available.

The first frusto-conical area 9 is immediately adjacent to the second frusto-conical region 10 , It is provided that at a boundary region at which the first frusto-conical region 9 on the second frusto-conical area 10 meets, the first frusto-conical area 9 and the second frusto-conical portion 10 have the same diameter. Thus, a continuous wall of the cylinder bore 4 given without cracks or steps are present. The combination of the first frusto-conical area 9 and the second frusto-conical portion 10 on the one hand allows an enlargement of the piston clearance by increasing the diameter of the cylinder bore 4 , wherein at the same time the immediately adjacent arrangement of the first frusto-conical portion 9 and the second frusto-conical portion 10 very easy to manufacture. Thus, the combination allows for the first frusto-conical area 9 and second frusto-conical region 10 a low power loss of a piston due to friction within the cylinder bore 4 at the same time minimized manufacturing costs of the engine block 1 ,

2 shows an engine block 1 according to a second embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has an upper frustoconical widening area 7 on. The upper frustoconical widening area 7 is at the top 2 at. At the upper frustoconical widening area 7 closes a cylindrical head area 5 at. At the cylindrical head area 5 adjoins a lower bell-shaped expansion area 11 , The lower bell-shaped expansion area 11 again lies at the bottom 3 at.

Through the upper frustoconical widening area 7 indicates the cylinder bore 4 the smallest diameter at a boundary between the upper frusto-conical widening area 7 and the cylindrical head portion 5 on. The diameter at this limit thus represents an upper limit of the piston clearance. Starting from this limit, the diameter of the cylinder bore decreases 4 both towards the top end 2 as well as in the direction of the lower end 3 too, without taking off again. It is provided that a diameter of the cylinder bore 4 at the top 2 a maximum of 0.3%, advantageously by a maximum of 0.2%, particularly vorteilhat by a maximum of 0.1%, is greater than the smallest diameter of the cylinder bore 4 located at the boundary between the upper frusto-conical widening area 7 and the cylindrical head portion 5 lies.

The upper frustoconical widening area 7 allows compensation for a deformation caused by the application of a cylinder head on the upper end 2 into the cylinder bore 4 is introduced. Thus, the application of the cylinder head leads to the upper end 2 to that the edges of the cylinder bore 4 pressed inward, which increases the radius of the cylinder bore 4 at the top 2 reduced. Through the upper frustoconical widening area 7 this deformation is compensated. Thus, in particular, it is not necessary to provide the piston with a contour corresponding to the deformation complementary contour, as a collision of the piston and cylinder bore 4 by the compensation function of the upper frusto-conical expansion area 7 is prevented.

The upper frustoconical widening area 7 in particular extends to a limit which is at most 40%, preferably at most 30%, particularly preferably at most 20%, of the distance between the upper end 2 and lower end 3 from the upper end 2 away. In this way it is prevented that a volume in the upper area of the cylinder becomes too large. Due to the described dimension of the upper frusto-conical expansion area 7 is ensured that the upper frusto-conical widening area 7 merely compensates for deformations due to the application of the cylinder head.

The cylindrical head area 5 abuts the lower bell-shaped expansion area in a boundary area 11 , At this boundary region have the lower bell-shaped expansion area 11 and the cylindrical head portion 5 the same diameter, so no cracks in the wall of the cylinder bore 4 available.

Through the lower bell-shaped expansion area 11 is a widening of the cylinder bore 4 realized in a simple and inexpensive to manufacture way. In this case, the bell shape of the lower bell-shaped expansion area 11 adapted to different needs of the engine design. It is only intended that the lower bell-shaped expansion area 11 is rotationally symmetric. Furthermore, it is provided that the lower bell-shaped expansion area 11 is shaped such that the diameter of the cylinder bore 4 towards the lower end 3 steadily increasing nonlinearly. Thus, no location can be within the lower bell-shaped expansion area 11 find the same diameter as at another location of the lower bell-shaped expansion area 11 having. Through the lower bell-shaped expansion area 11 In turn, this achieves losses due to friction of a piston within the cylinder bore 4 are minimized, while the production of the cylinder bore 4 very simple and inexpensive is possible.

3 shows an engine block 1 according to a third embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has an upper frustoconical widening area 7 on. The upper frustoconical widening area 7 is at the top 2 at. At the upper frustoconical widening area 7 closes a frustoconical head area 6 at. At the cylindrical head area 6 adjoins a lower truncated conical widening area 12 , The lower frusto-conical expansion area 12 again lies at the bottom 3 at.

Through the upper frustoconical widening area 7 indicates the cylinder bore 4 the smallest diameter at a boundary between the upper frusto-conical widening area 7 and the frusto-conical head portion 6 on. The diameter at this limit thus represents an upper limit of the piston clearance. Starting from this limit, the diameter of the cylinder bore decreases 4 both towards the top end 2 as well as in the direction of the lower end 3 too, without taking off again. It is provided that a diameter of the cylinder bore 4 at the top 2 a maximum of 0.3%, advantageously by a maximum of 0.2%, particularly vorteilhat by a maximum of 0.1%, is greater than the smallest diameter of the cylinder bore 4 located at the boundary between the upper frusto-conical widening area 7 and the frusto-conical head portion 6 lies.

The upper frustoconical widening area 7 allows compensation for a deformation caused by the application of a cylinder head on the upper end 2 into the cylinder bore 4 is introduced. Thus, the application of the cylinder head leads to the upper end 2 to that the edges of the cylinder bore 4 pressed inward, which increases the radius of the cylinder bore 4 at the top 2 reduced. Through the upper frustoconical widening area 7 this deformation is compensated. Thus, in particular, it is not necessary to provide the piston with a reduced diameter in an area above the piston rings, since a collision of piston and cylinder bore 4 by the compensation function of the upper frusto-conical expansion area 7 is prevented.

The upper frustoconical widening area 7 in particular extends to a limit which is at most 40%, preferably at most 30%, particularly preferably at most 20%, of the distance between the upper end 2 and lower end 3 from the upper end 2 away. In this way it is prevented that a volume in the upper area of the cylinder becomes too large. Due to the described dimension of the upper frusto-conical expansion area 7 is ensured that the upper frusto-conical widening area 7 merely compensates for deformations due to the application of the cylinder head.

The frustoconical head area 6 abuts the lower frusto-conical expansion area in a boundary area 12 , At this boundary region, the lower frusto-conical expansion area 12 and the frusto-conical head portion 6 the same diameter, so no cracks in the wall of the cylinder bore 4 available. Due to the conical shape of the frustoconical head area 6 is an expansion of the cylinder bore already very close to the upper end 2 allows, whereby the expansion with a low slope is present.

Due to the lower frustoconical widening area 12 is a widening of the cylinder bore 4 realized in a simple and inexpensive to manufacture way. In this case, the conical shape of the lower bell-shaped expansion area 12 adapted to different needs of the engine design. The cone shape does not allow any location within the lower frusto-conical expansion area 12 find the same diameter as at another location of the lower frusto-conical expansion area 12 having. Due to the lower frustoconical widening area 12 In turn, this achieves losses due to friction of a piston within the cylinder bore 4 are minimized, while the production of the cylinder bore 4 very simple and inexpensive is possible.

4 shows an engine block 1 according to a fourth embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized.

The cylinder bore 4 of the engine block 1 has an upper frustoconical widening area 7 on. The upper frustoconical widening area 7 is at the top 2 at. At the upper frustoconical widening area 7 closes a frustoconical head area 6 at. At the cylindrical head area 6 adjoins a lower bell-shaped expansion area 11 , The lower bell-shaped expansion area 11 again lies at the bottom 3 at.

Through the upper frustoconical widening area 7 indicates the cylinder bore 4 the smallest diameter at a boundary between the upper frusto-conical widening area 7 and the frusto-conical head portion 6 on. The diameter at this limit thus represents an upper limit of the piston clearance. Starting from this limit, the diameter of the cylinder bore decreases 4 both towards the top end 2 as well as in the direction of the lower end 3 too, without taking off again. It is provided that a diameter of the cylinder bore 4 at the top 2 a maximum of 0.3%, advantageously by a maximum of 0.2%, particularly vorteilhat by a maximum of 0.1%, is greater than the smallest diameter of the cylinder bore 4 located at the boundary between the upper frusto-conical widening area 7 and the frusto-conical head portion 6 lies.

The upper frustoconical widening area 7 allows compensation for a deformation caused by the application of a cylinder head on the upper end 2 into the cylinder bore 4 is introduced. Thus, the application of the cylinder head leads to the upper end 2 to that the edges of the cylinder bore 4 pressed inward, which increases the radius of the cylinder bore 4 at the top 2 reduced. Through the upper frustoconical widening area 7 this deformation is compensated. Thus, in particular, it is not necessary to provide the piston with a contour corresponding to the deformation complementary contour, as a collision of the piston and cylinder bore 4 by the compensation function of the upper frusto-conical expansion area 7 is prevented.

The upper frustoconical widening area 7 in particular extends to a limit which is at most 40%, preferably at most 30%, particularly preferably at most 20%, of the distance between the upper end 2 and lower end 3 from the upper end 2 away. In this way it is prevented that a volume in the upper area of the cylinder becomes too large. Due to the described dimension of the upper frusto-conical expansion area 7 is ensured that the upper frusto-conical widening area 7 merely compensates for deformations due to the application of the cylinder head.

The frustoconical head area 6 abuts the lower bell-shaped expansion area in a boundary area 11 , At this boundary region have the lower bell-shaped expansion area 11 and the frusto-conical head portion 6 the same diameter, so no cracks in the wall of the cylinder bore 4 available. Due to the conical shape of the frustoconical head area 6 is an expansion of the cylinder bore already very close to the upper end 2 allows, whereby the expansion with a low slope is present.

Through the lower bell-shaped expansion area 11 is a widening of the cylinder bore 4 realized in a simple and inexpensive to manufacture way. In this case, the bell shape of the lower bell-shaped expansion area 11 adapted to different needs of the engine design. It is only intended that the lower bell-shaped expansion area 11 is rotationally symmetric. Furthermore, it is provided that the lower bell-shaped expansion area 11 is shaped such that the diameter of the cylinder bore 4 towards the lower end 3 steadily increasing. Thus, no location can be within the lower bell-shaped expansion area 11 find the same diameter as at another location of the lower bell-shaped expansion area 11 having. Through the lower bell-shaped expansion area 11 In turn, this achieves losses due to friction of a piston within the cylinder bore 4 are minimized, while the production of the cylinder bore 4 very simple and inexpensive is possible.

5 shows an engine block 1 according to a fifth embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a border, at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has an upper frustoconical widening area 7 on. The upper frustoconical widening area 7 is at the top 2 at. At the upper frusto-conical widening area 7 lies a frustoconical head area 6 at. At the frusto-conical head area 6 In turn, there is a first frusto-conical area 9 at. At the first frusto-conical area 9 is a second frusto-conical area 10 at, wherein the second frusto-conical region 10 at the bottom 3 the cylinder bore 4 is applied.

Through the upper frustoconical widening area 7 indicates the cylinder bore 4 the smallest diameter at a boundary between the upper frusto-conical widening area 7 and the frusto-conical head portion 6 on. The diameter at this limit thus represents an upper limit of the piston clearance. Starting from this limit, the diameter of the cylinder bore decreases 4 both towards the top end 2 as well as in the direction of the lower end 3 too, without taking off again. It is provided that a diameter of the cylinder bore 4 at the top 2 a maximum of 0.3%, advantageously by a maximum of 0.2%, particularly vorteilhat by a maximum of 0.1%, is greater than the smallest diameter of the cylinder bore 4 located at the boundary between the upper frusto-conical widening area 7 and the frusto-conical head portion 6 lies.

The upper frustoconical widening area 7 allows compensation for a deformation caused by the application of a cylinder head on the upper end 2 into the cylinder bore 4 is introduced. Thus, the application of the cylinder head leads to the upper end 2 to that the edges of the cylinder bore 4 pressed inward, which increases the radius of the cylinder bore 4 at the top 2 reduced. Through the upper frustoconical widening area 7 this deformation is compensated. Thus, in particular, it is not necessary to provide the piston with a contour corresponding to the deformation complementary contour, as a collision of the piston and cylinder bore 4 by the compensation function of the upper frusto-conical expansion area 7 is prevented.

The upper frustoconical widening area 7 in particular extends to a limit which is at most 40%, preferably at most 30%, particularly preferably at most 20%, of the distance between the upper end 2 and lower end 3 from the upper end 2 away. In this way it is prevented that a volume in the upper area of the cylinder becomes too large. Due to the described dimension of the upper frusto-conical expansion area 7 is ensured that the upper frusto-conical widening area 7 merely compensates for deformations due to the application of the cylinder head.

The frustoconical head area 6 abuts the lower bell-shaped expansion area in a boundary area 11 , At this boundary region have the lower bell-shaped expansion area 11 and the frusto-conical head portion 6 the same diameter, so no cracks in the wall of the cylinder bore 4 available. Due to the conical shape of the frustoconical head area 6 is an expansion of the cylinder bore already very close to the upper end 2 allows, whereby the expansion with a low slope is present.

The first frusto-conical area 9 is immediately adjacent to the second frusto-conical region 10 , It is provided that at a boundary region at which the first frusto-conical region 9 on the second frusto-conical area 10 meets, the first frusto-conical area 9 and the second frusto-conical portion 10 have the same diameter. Thus, a continuous wall of the cylinder bore 4 given without cracks or steps are present. The combination of the first frusto-conical area 9 and the second frusto-conical portion 10 on the one hand allows an enlargement of the piston clearance by increasing the diameter of the cylinder bore 4 , where at the same time the immediately adjacent arrangement of the first frusto-conical region 9 and the second frusto-conical portion 10 very easy to manufacture. Thus, the combination allows for the first frusto-conical area 9 and second frusto-conical region 10 a low power loss of a piston due to friction within the cylinder bore 4 at the same time minimized manufacturing costs of the engine block 1 ,

6 shows an engine block 1 according to a sixth embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has an upper bell-shaped expansion area 8th on. The upper bell-shaped expansion area 8th is at the top 2 at. At the upper bell-shaped widening area 8th closes a cylindrical head area 5 at. At the cylindrical head area 5 adjoins a lower bell-shaped expansion area 11 , The lower bell-shaped expansion area 11 again lies at the bottom 3 at.

Through the upper bell-shaped expansion area 8th indicates the cylinder bore 4 the smallest diameter at a boundary between the upper bell-shaped expansion area 8th and the cylindrical head portion 5 on. The diameter at this limit thus represents an upper limit of the piston clearance. Starting from this limit, the diameter of the cylinder bore decreases 4 both towards the top end 2 as well as in the direction of the lower end 3 too, without taking off again. It is provided that a diameter of the cylinder bore 4 at the top 2 a maximum of 0.3%, advantageously by a maximum of 0.2%, particularly vorteilhat by a maximum of 0.1%, is greater than the smallest diameter of the cylinder bore 4 located at the boundary between the upper bell-shaped widening area 8th and the cylindrical head portion 5 lies.

The upper bell-shaped expansion area 8th allows compensation for a deformation caused by the application of a cylinder head on the upper end 2 into the cylinder bore 4 is introduced. Thus, the application of the cylinder head leads to the upper end 2 to that the edges of the cylinder bore 4 pressed inward, which increases the radius of the cylinder bore 4 at the top 2 reduced. Through the upper bell-shaped expansion area 8th this deformation is compensated. Thus, in particular, it is not necessary to provide the piston with a contour corresponding to the deformation complementary contour, as a collision of the piston and cylinder bore 4 by the compensation function of the upper bell-shaped expansion area 8th is prevented.

The upper bell-shaped expansion area 8th in particular extends to a limit which is at most 40%, preferably at most 30%, particularly preferably at most 20%, of the distance between the upper end 2 and lower end 3 from the upper end 2 away. In this way it is prevented that a volume in the upper area of the cylinder becomes too large. Due to the described dimension of the upper bell-shaped expansion area 8th is ensured that the upper bell-shaped expansion area 8th merely compensates for deformations due to the application of the cylinder head.

The bell shape of the upper bell-shaped expansion area 8th can be adapted to different needs of engine design. It is only intended that the upper bell-shaped expansion area 8th is rotationally symmetric. Furthermore, it is provided that the upper bell-shaped expansion area 8th is shaped such that the diameter of the cylinder bore 4 towards the top end 2 steadily increasing. Thus, no position can be within the upper bell-shaped expansion area 8th find the same diameter as at another location of the upper bell-shaped expansion area 8th having.

The cylindrical head area 5 abuts the lower bell-shaped expansion area in a boundary area 11 , At this boundary region have the lower bell-shaped expansion area 11 and the cylindrical head portion 5 the same diameter, so no cracks in the wall of the cylinder bore 4 available.

Through the lower bell-shaped expansion area 11 is a widening of the cylinder bore 4 realized in a simple and inexpensive to manufacture way. In this case, the bell shape of the lower bell-shaped expansion area 11 adapted to different needs of the engine design. It is only intended that the lower bell-shaped expansion area 11 is rotationally symmetric. Furthermore, it is provided that the lower bell-shaped expansion area 11 is shaped such that the diameter of the cylinder bore 4 towards the lower end 3 steadily increasing. Thus, no location can be within the lower bell-shaped expansion area 11 find the same diameter as at another location of the lower bell-shaped expansion area 11 having. Through the lower bell-shaped expansion area 11 In turn, this achieves losses due to friction of a piston within the cylinder bore 4 are minimized, while the production of the cylinder bore 4 very simple and inexpensive is possible.

7 shows an engine block 1 according to a seventh embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has an upper frustoconical widening area 7 on. The upper frustoconical widening area 7 is at the top 2 at. At the upper frustoconical widening area 7 closes a cylindrical head area 5 at. At the cylindrical head area 5 adjoins a lower truncated conical widening area 12 , The lower frusto-conical expansion area 12 again lies at the bottom 3 at.

Through the upper frustoconical widening area 7 indicates the cylinder bore 4 the smallest diameter at a boundary between the upper frusto-conical widening area 7 and the cylindrical head portion 5 on. The diameter at this limit thus represents an upper limit of the piston clearance. Starting from this limit, the diameter of the cylinder bore decreases 4 both towards the top end 2 as well as in the direction of the lower end 3 too, without taking off again. It is provided that a diameter of the cylinder bore 4 at the top 2 a maximum of 0.3%, advantageously by a maximum of 0.2%, particularly vorteilhat by a maximum of 0.1%, is greater than the smallest diameter of the cylinder bore 4 located at the boundary between the upper frusto-conical widening area 7 and the cylindrical head portion 5 lies.

The upper frustoconical widening area 7 allows compensation for a deformation caused by the application of a cylinder head on the upper end 2 into the cylinder bore 4 is introduced. Thus, the application of the cylinder head leads to the upper end 2 to that the edges the cylinder bore 4 pressed inward, which increases the radius of the cylinder bore 4 at the top 2 reduced. Through the upper frustoconical widening area 7 this deformation is compensated. Thus, in particular, it is not necessary to provide the piston with a contour corresponding to the deformation complementary contour, as a collision of the piston and cylinder bore 4 by the compensation function of the upper frusto-conical expansion area 7 is prevented.

The upper frustoconical widening area 7 in particular extends to a limit which is at most 40%, preferably at most 30%, particularly preferably at most 20%, of the distance between the upper end 2 and lower end 3 from the upper end 2 away. In this way it is prevented that a volume in the upper area of the cylinder becomes too large. Due to the described dimension of the upper frusto-conical expansion area 7 is ensured that the upper frusto-conical widening area 7 merely compensates for deformations due to the application of the cylinder head.

The cylindrical head area 5 abuts the lower frusto-conical expansion area in a boundary area 12 , At this boundary region, the lower frusto-conical expansion area 12 and the cylindrical head portion 5 the same diameter, so no cracks in the wall of the cylinder bore 4 available.

Due to the lower frustoconical widening area 12 is a widening of the cylinder bore 4 realized in a simple and inexpensive to manufacture way. In this case, the conical shape of the lower bell-shaped expansion area 12 adapted to different needs of the engine design. The cone shape does not allow any location within the lower frusto-conical expansion area 12 find the same diameter as at another location of the lower frusto-conical expansion area 12 having. Due to the lower frustoconical widening area 12 In turn, this achieves losses due to friction of a piston within the cylinder bore 4 are minimized, while the production of the cylinder bore 4 very simple and inexpensive is possible.

8th shows an engine block 1 according to an eighth embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has an upper frustoconical widening area 7 on. The upper frustoconical widening area 7 is at the top 2 at. Likewise, the upper frusto-conical expansion area is located 7 a cylindrical head area 5 at. At the cylindrical head area 5 lies with a middle truncated cone area 13 at. At the middle truncated cone area 13 lies a lower cylinder area 14 at. The lower cylinder area 14 in turn, lies at the bottom 3 at.

Through the upper frustoconical widening area 7 indicates the cylinder bore 4 the smallest diameter at a boundary between the upper frusto-conical widening area 7 and the cylindrical head portion 5 on. The diameter at this limit thus represents an upper limit of the piston clearance. Starting from this limit, the diameter of the cylinder bore decreases 4 both towards the top end 2 as well as in the direction of the lower end 3 too, without taking off again. It is envisaged that a Diameter of the cylinder bore 4 at the top 2 a maximum of 0.3%, advantageously by a maximum of 0.2%, particularly vorteilhat by a maximum of 0.1%, is greater than the smallest diameter of the cylinder bore 4 located at the boundary between the upper frusto-conical widening area 7 and the cylindrical head portion 5 lies.

The upper frustoconical widening area 7 allows compensation for a deformation caused by the application of a cylinder head on the upper end 2 into the cylinder bore 4 is introduced. Thus, the application of the cylinder head leads to the upper end 2 to that the edges of the cylinder bore 4 pressed inward, which increases the radius of the cylinder bore 4 at the top 2 reduced. Through the upper frustoconical widening area 7 this deformation is compensated. Thus, in particular, it is not necessary to provide the piston with a contour corresponding to the deformation complementary contour, as a collision of the piston and cylinder bore 4 by the compensation function of the upper frusto-conical expansion area 7 is prevented.

The upper frustoconical widening area 7 in particular extends to a limit which is at most 40%, preferably at most 30%, particularly preferably at most 20%, of the distance between the upper end 2 and lower end 3 from the upper end 2 away. In this way it is prevented that a volume in the upper area of the cylinder becomes too large. Due to the described dimension of the upper frusto-conical expansion area 7 is ensured that the upper frusto-conical widening area 7 merely compensates for deformations due to the application of the cylinder head.

The cylindrical head area 5 abuts the middle truncated cone area in a boundary area 13 , At this boundary area, the middle truncated cone area 13 and the cylindrical head portion 5 the same diameter, so no cracks in the wall of the cylinder bore 4 available.

The middle truncated cone area 13 allows widening of the cylinder bore 4 , Thus, a diameter of the cylinder bore can be 4 easy and inexpensive to enlarge. To prevent the diameter of the cylinder bore 4 increases too much, is the lower cylinder area 14 available. Within the lower cylinder area 14 remains the diameter of the cylinder bore 4 constant. It is provided that at a boundary region at which the mean truncated cone area 13 and the lower cylinder area 14 meet each other, the diameter of the central truncated cone area 13 and the lower cylinder area 14 are identical. Thus, a strong expansion of the cylinder bore can be 4 in the middle area of the cylinder bore 4 realize, being in the lower part of the cylinder bore 4 a constant diameter remains.

9 shows an engine block 1 according to a ninth embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has a cylindrical head area 5 on. The cylindrical head area 5 is at the top 2 at. At the cylindrical head area 5 adjoins a lower bell-shaped expansion area 11 , The lower bell-shaped expansion area 11 again lies at the bottom 3 at.

The cylindrical head area 5 abuts the lower bell-shaped expansion area in a boundary area 11 , At this border area have the lower bell-shaped expansion area 11 and the cylindrical head portion 5 the same diameter, so no cracks in the wall of the cylinder bore 4 available.

Through the lower bell-shaped expansion area 11 is a widening of the cylinder bore 4 realized in a simple and inexpensive to manufacture way. In this case, the bell shape of the lower bell-shaped expansion area 11 adapted to different needs of the engine design. It is only intended that the lower bell-shaped expansion area 11 is rotationally symmetric. Furthermore, it is provided that the lower bell-shaped expansion area 11 is shaped such that the diameter of the cylinder bore 4 towards the lower end 3 steadily increasing. Thus, no location can be within the lower bell-shaped expansion area 11 find the same diameter as at another location of the lower bell-shaped expansion area 11 having. Through the lower bell-shaped expansion area 11 In turn, this achieves losses due to friction of a piston within the cylinder bore 4 are minimized, while the production of the cylinder bore 4 very simple and inexpensive is possible.

10 shows an engine block 1 according to a tenth embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has a frustoconical head portion 6 on. The frustoconical head area 6 is at the top 2 at. At the cylindrical head area 6 adjoins a lower bell-shaped expansion area 11 , The lower bell-shaped expansion area 11 again lies at the bottom 3 at.

The frustoconical head area 6 abuts the lower bell-shaped expansion area in a boundary area 11 , At this boundary region have the lower bell-shaped expansion area 11 and the frusto-conical head portion 6 the same diameter, so no cracks in the wall of the cylinder bore 4 available. Due to the conical shape of the frustoconical head area 6 is an expansion of the cylinder bore already very close to the upper end 2 allows, whereby the expansion with a low slope is present.

Through the lower bell-shaped expansion area 11 is a widening of the cylinder bore 4 realized in a simple and inexpensive to manufacture way. In this case, the bell shape of the lower bell-shaped expansion area 11 adapted to different needs of the engine design. It is only intended that the lower bell-shaped expansion area 11 is rotationally symmetric. Furthermore, it is provided that the lower bell-shaped expansion area 11 is shaped such that the diameter of the cylinder bore 4 towards the lower end 3 steadily increasing. Thus, no location can be within the lower bell-shaped expansion area 11 find the same diameter as at another location of the lower bell-shaped expansion area 11 having. Through the lower bell-shaped expansion area 11 In turn, this achieves losses due to friction of a piston within the cylinder bore 4 are minimized, while the production of the cylinder bore 4 very simple and inexpensive is possible.

11 shows an engine block 1 according to an eleventh embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has a cylindrical head area 5 on. The cylindrical head area 5 is at the top 2 at. At the cylindrical head area 5 In turn, there is a first frusto-conical area 9 at. At the first frusto-conical area 9 is a second frusto-conical area 10 at, wherein the second frusto-conical region 10 at the bottom 3 the cylinder bore 4 is applied.

The cylindrical head area 5 abuts the first frusto-conical region in a boundary region 9 , At this boundary region, the first frusto-conical region 9 and the cylindrical head portion 5 the same diameter, so no cracks in the wall of the cylinder bore 4 available.

The first frusto-conical area 9 is immediately adjacent to the second frusto-conical region 10 , It is provided that at a boundary region at which the first frusto-conical region 9 on the second frusto-conical area 10 meets, the first frusto-conical area 9 and the second frusto-conical portion 10 have the same diameter. Thus, a continuous wall of the cylinder bore 4 given without cracks or steps are present. The combination of the first frusto-conical area 9 and the second frusto-conical portion 10 on the one hand allows an enlargement of the piston clearance by increasing the diameter of the cylinder bore 4 , wherein at the same time the immediately adjacent arrangement of the first frusto-conical portion 9 and the second frusto-conical portion 10 very easy to manufacture. Thus, the combination allows for the first frusto-conical area 9 and second frusto-conical region 10 a low power loss of a piston due to friction within the cylinder bore 4 at the same time minimized manufacturing costs of the engine block 1 ,

12 shows an engine block 1 according to a twelfth embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 one maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has a frustoconical head portion 6 on. The frustoconical head area 6 is at the top 2 at. The frustoconical head area 6 is at the same time a first frusto-conical area 9 , At the first frusto-conical area 9 is a second frusto-conical area 10 at, wherein the second frusto-conical region 10 at the bottom 3 the cylinder bore 4 is applied.

The frustoconical head area 6 abuts the lower bell-shaped expansion area in a boundary area 11 , At this boundary region have the lower bell-shaped expansion area 11 and the frusto-conical head portion 6 the same diameter, so no cracks in the wall of the cylinder bore 4 available. Due to the conical shape of the frustoconical head area 6 is an expansion of the cylinder bore already very close to the upper end 2 allows, whereby the expansion with a low slope is present.

The first frusto-conical area 9 is immediately adjacent to the second frusto-conical region 10 , It is provided that at a boundary region at which the first frusto-conical region 9 on the second frusto-conical area 10 meets, the first frusto-conical area 9 and the second frusto-conical portion 10 have the same diameter. Thus, a continuous wall of the cylinder bore 4 given without cracks or steps are present. The combination of the first frusto-conical area 9 and the second frusto-conical portion 10 on the one hand allows an enlargement of the piston clearance by increasing the diameter of the cylinder bore 4 , wherein at the same time the immediately adjacent arrangement of the first frusto-conical portion 9 and the second frusto-conical portion 10 very easy to manufacture. Thus, the combination allows for the first frusto-conical area 9 and second frusto-conical region 10 a low power loss of a piston due to friction within the cylinder bore 4 at the same time minimized manufacturing costs of the engine block 1 ,

13 shows an engine block 1 according to a thirteenth embodiment. The engine block 1 has a cylinder passing through a cylinder bore 4 is shown. The cylinder bore 4 extends between an upper end 2 and a lower end 3 , The upper end corresponds to this 2 the end to which a cylinder head can be placed. The lower end 3 corresponds to that end to which a crankcase is placed. Inside the cylinder bore 4 a piston can be arranged, which is used to operate the internal combustion engine within the cylinder bore 4 is movable up and down.

The cylinder bore 4 points in an area between the lower end 3 and a limit of at most 70%, preferably at most 60%, particularly preferably at most 50%, of the distance between the upper end 2 and lower end 3 from the upper end 2 is removed, a diameter larger than the smallest diameter. In addition, it is provided that in the described range of diameter in the direction of the lower end 3 at least in sections increases. At the same time it is provided that the diameter does not decrease in this area. Thus, the expansion is present to affect the piston clearance, but not to influence the volume of the combustion chamber.

It is envisaged that the diameter of the cylinder bore 4 at the bottom 3 a maximum diameter of the cylinder bore 4 is. In particular, the diameter of the cylinder bore 4 at the bottom 3 by a maximum of 0.5%, preferably by a maximum of 0.4%, more preferably by a maximum of 0.3%, greater than a smallest diameter of the cylinder bore 4 , In this way it is achieved that the frictional performance of a piston during movement within the cylinder bore 4 performs, is minimized. At the same time, the cylinder bore 4 very easy and inexpensive to manufacture.

The cylinder bore 4 of the engine block 1 has a frustoconical head portion 6 on. The frustoconical head area 6 is at the top 2 at. At the frusto-conical head area 6 In turn, there is a first frusto-conical area 9 at. At the first frusto-conical area 9 is a second frusto-conical area 10 at, wherein the second frusto-conical region 10 at the bottom 3 the cylinder bore 4 is applied.

The frustoconical head area 6 abuts the lower bell-shaped expansion area in a boundary area 11 , At this boundary region have the lower bell-shaped expansion area 11 and the frusto-conical head portion 6 the same diameter, so no jumps in the wall of the cylinder bore 4 available. Due to the conical shape of the frustoconical head area 6 is an expansion of the cylinder bore already very close to the upper end 2 allows, whereby the expansion with a low slope is present.

The first frusto-conical area 9 is immediately adjacent to the second frusto-conical region 10 , It is provided that at a boundary region at which the first frusto-conical region 9 on the second frusto-conical area 10 meets, the first frusto-conical area 9 and the second frusto-conical portion 10 have the same diameter. Thus, a continuous wall of the cylinder bore 4 given without cracks or steps are present. The combination of the first frusto-conical area 9 and the second frusto-conical portion 10 on the one hand allows an enlargement of the piston clearance by increasing the diameter of the cylinder bore 4 , wherein at the same time the immediately adjacent arrangement of the first frusto-conical portion 9 and the second frusto-conical portion 10 very easy to manufacture. Thus, the combination allows for the first frusto-conical area 9 and second frusto-conical region 10 a low power loss of a piston due to friction within the cylinder bore 4 at the same time minimized manufacturing costs of the engine block 1 ,

14 shows a vehicle 15 according to an embodiment of the invention. The vehicle 15 includes an engine block 1 according to one of the preceding embodiments. Thus, a piston must be inside the engine block 1 moving, a reduced friction work, causing the vehicle 15 is very energy efficient operable.

LIST OF REFERENCE NUMBERS

1

block

2

top end

3

lower end

4

bore

5

cylindrical head area

6

conical head area

7

Upper conical widening area

8th

upper bell-shaped expansion area

9

first frusto-conical area

10

second frusto-conical area

11

lower bell-shaped expansion area

12

lower conical area

13

middle cone area

14

lower cylinder area

15

vehicle

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102011117660 A1 [0004]

Claims (14)

Engine block ( 1 ) of an internal combustion engine comprising at least one cylinder, wherein a cylinder bore ( 4 ) includes, for a piston of the internal combustion engine, a volume comprising at least a first frusto-conical portion ( 9 ) and at least one second frusto-conical section ( 10 ), wherein the first frusto-conical portion ( 9 ) and the second frusto-conical section ( 10 ) directly adjoin one another, and wherein the first frusto-conical section ( 9 ) has a higher wall slope than the second frusto-conical section ( 10 ). Engine block ( 1 ) according to claim 1, characterized in that the cylinder bore ( 4 ) between an upper end ( 2 ) and a lower end ( 3 ), wherein the second frusto-conical section (FIG. 10 ) at the lower end ( 3 ) is present. Engine block ( 1 ) according to claim 2, characterized in that the upper end ( 2 ) a smallest diameter of the cylinder bore ( 4 ) having. Engine block ( 1 ) according to claim 2 or 3, characterized in that the lower end ( 3 ) a largest diameter of the cylinder bore ( 4 ) having. Engine block ( 1 ) according to one of claims 2 to 4, characterized in that the diameter of the cylinder bore ( 4 ) between the upper end ( 2 ) and lower end ( 3 ) steadily increases in sections or is constant. Engine block ( 1 ) according to one of claims 2 to 5, characterized in that the cylinder bore ( 4 ) in an area between lower end ( 3 ) and a limit not exceeding 70%, in particular 60%, especially advantageously 50%, of the distance between the upper end ( 2 ) and lower end ( 3 ) from the upper end ( 2 ) is located, has a diameter which is larger than the smallest diameter and / or in the direction of the lower end ( 3 ) increases at least in sections. Engine block ( 1 ) according to one of claims 2 to 6, characterized in that the cylinder bore ( 4 ) encloses a volume having a header area ( 5 . 6 ), wherein the header area ( 5 . 6 ) immediately at the top ( 2 ) is present. Engine block ( 1 ) according to claim 7, characterized in that the head area ( 5 . 6 ) directly on the first frusto-conical section ( 9 ) or at the second frusto-conical portion ( 10 ) is present. Engine block ( 1 ) according to one of claims 7 or 8, characterized in that the head area ( 5 . 6 ) the first frusto-conical section ( 9 ). Engine block ( 1 ) according to one of claims 7 or 8, characterized in that the head area ( 5 . 6 ) is frusto-conical or cylindrical. Engine block ( 1 ) according to one of claims 7 to 10, characterized in that the head area ( 5 . 6 ) and the first frusto-conical section ( 9 ) or the second frusto-conical section ( 10 ) adjoin one another at a first boundary area, the head area ( 5 . 6 ) and the first frusto-conical section ( 9 ) or the second frusto-conical section ( 10 ) at the first boundary region have the same diameter. Engine block ( 1 ) according to one of the preceding claims, characterized in that the first frusto-conical section ( 9 ) and the second frusto-conical section ( 10 ) adjoin one another at a second boundary region, wherein the first frustoconical section ( 9 ) and the second frusto-conical section ( 10 ) at the second boundary region have the same diameter. Engine block ( 1 ) according to one of the preceding claims, characterized in that a largest diameter of the cylinder bore ( 4 ) by a maximum of 0.5%, in particular 0.4%, particularly preferably 0.3% is greater than a smallest diameter of the cylinder bore ( 4 ). Vehicle ( 15 ) comprising an engine block ( 1 ) according to any one of the preceding claims.

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