DE10232318A1 - Machine housing for an internal combustion engine - Google Patents

Abstract

Machine housing (1), in particular a cylinder crankcase for an internal combustion engine, in which at least one bearing bracket (2, 2 ') for a shaft extends between two opposite housing walls (3, 3') and the housing walls (3, 3 ') via a connecting element ( 4, 4 ') are stiffened in the direction of the bearing bracket (2, 2'), the machine housing (1) being made of a material with a greater coefficient of thermal expansion than the connecting element (4, 4 '). DOLLAR A Due to the configuration according to the invention, a higher internal cylinder pressure is permissible for the internal combustion engine, with the same bearing dimensions.

Description

The invention relates to a machine housing for an internal combustion engine according to the characteristics in the preamble of claim 1.

It is based on the German patent specification DE 34 44 838 C2 out. In this a machine housing, a cylinder crankcase for an internal combustion engine in V-type is described. Around the intersection of the two V-shaped cylinder axes is the crankshaft bearing, consisting of a bearing bracket with a bearing cap. The storage chair is one-story and made of the same material with the cylinder crankcase. In order to minimize the tensile and compressive stresses in the bearing bracket during operation of the internal combustion engine, the bearing bracket is designed such that it merges with a radius into the side walls of the cylinder crankcase. To further reduce the tensile and compressive stresses that occur during operation of the internal combustion engine, a stiffening element is arranged on these two oppositely arranged housing walls, which is arched from one housing wall to the other housing wall and is screwed to the respective housing wall on both sides. In addition to the stiffening, this connecting element serves as an oil squeegee to calm the oil that is collected in the oil pan below the connecting element.

As is well known, one is measure to increase performance in modern internal combustion engines the internal cylinder pressure during combustion. An increase in Cylinder pressure means better efficiency, and therefore more efficient internal combustion engines. In addition to other factors, the maximum cylinder pressure today due to the crankshaft bearing limited.

Object of the present invention is to show a generic cylinder crankcase, which higher Cylinder internal pressures with an unchanged Dimensioning of the warehouse.

This task is characterized by the feature solved in the characterizing part of claim 1.

By the difference in the coefficient of thermal expansion of the machine housing and the connecting element is in the warm operating state Internal combustion engine a static compressive stress in the transition radius on both sides of the camp chair at the transition generated to the housing walls. This static pressure preload enables a significantly higher dynamic Pressure or train operating load, whereby with a permanent design of the machine housing the design ignition pressure, the maximum cylinder pressure, can be raised accordingly. With a given installation space and weight, the power density can be reduced of internal combustion engines can be increased significantly, making them more advantageous Way the efficiency of the internal combustion engine is improved.

Depending on the load on the machine housing or the bearing bracket by the cylinder pressure can according to claim 2 a connecting element for a single storage area of a storage chair can be provided or a common connecting element for several storage areas. By covering up Multiple storage areas with a connecting element are easy connecting elements to be assembled achieved.

The design according to claim 3 allows easy assembly and disassembly of the connecting element from the machine housing.

According to claim 4 and claim 5, both the machine housing and the connecting element can be made from materials that are commercially available today and are common for internal combustion engines. For example, for the machine housing, cast aluminum with a linear coefficient of thermal expansion (coefficient of linear expansion) α = 21.7 × 10 ^–6 [1 / K], or Alusil with a coefficient of thermal expansion α = 19.2 × 10 ^–6 [1 / K] or magnesium casting with a thermal expansion coefficient α = 26.7 × 10 ^–6 [1 / K] can be used. In contrast, the connecting element z. B. from forged steel C45, with a coefficient of thermal expansion α = 11.7 × 10 ^-6 [1 / K] or gray cast iron with a coefficient of thermal expansion α = 11.0 × 10 ^-6 [1 / K] or chrome molybdenum steel with a coefficient of thermal expansion α = 12.0 x 10 ^-6 [1 / K]. In addition, glass fiber reinforced plastic with a coefficient of thermal expansion α = 5.2 × 10 ⁻⁶ [1 / K] can also be used for the connecting element if a gray cast iron machine housing with a coefficient of thermal expansion α = 11.0 × 10 ⁻⁶ [1 / K] is used. With these material combinations, which are mentioned here by way of example and are not fully mentioned, many materials which are common today for machine housings are advantageously covered.

The invention is described below of a preferred embodiment closer in a single figure explained.

1 shows the three-dimensional view of a machine housing 1 , here a cylinder crankcase for an internal combustion engine with not directly recognizable cylinders in a V arrangement. The top view shows a crankshaft bearing area with a view through an oil pan, not shown. The machine housing 1 has four camp chairs 2 . 2 ' . 2 '' . 2 ''' each with a corresponding bearing cap 5 . 5 ' . 5 '' . 5 ''' on. The four storage areas, each consisting of a storage chair 2 . 2 ' . 2 '' . 2 ''' and a bearing cap 5 . 5 ' . 5 '' . 5 ''' , serve to support a crankshaft, not shown. Parallel to the alignment of the crankshaft, two opposite housing walls are located on both sides of the bearing areas 3 . 3 ' of the machine housing 1 , The housing walls 3 . 3 ' are used to attach the oil pan, not shown. The camp chair 2 '' is from a connector 4 and the camp chair 2 ''' from a fastener 4 ' spans. Any fastener 4 . 4 ' is on the one hand on the housing wall 3 and on the other hand on the housing wall 3 ' with two screws each 6 . 6 ' attached.

The connecting element 4 . 4 ' has both high material strength and a cross-section that can absorb tensile or compressive stresses particularly well. In the middle of each connector 4 . 4 ' , in the installed position in the internal combustion engine the lowest point, there is a hole through which one on the connecting element 4 . 4 ' accumulated lubricant can drip off.

1 shows a machine housing or cylinder crankcase for an internal combustion engine with cylinders in a V-arrangement. Deviating from this, the connecting element 4 . 4 ' can also be used in in-line engines. Which combustion process, gasoline or diesel combustion process, the internal combustion engine has is irrelevant.

In the exemplary embodiment, the cylinder crankcase is made of cast aluminum, with a coefficient of thermal expansion α = 21.7 × 10 ⁻⁶ [1 / K], while the connecting element 4 . 4 ' is made from a forged steel C45 with a thermal expansion coefficient α = 11.7 × 10 ^–6 [1 / K]. When operating the internal combustion engine, the connecting elements 4 . 4 ' heated, due to the different coefficients of thermal expansion α between the machine housing 1 and the connecting elements 4 . 4 ' static compressive stress in the transition area from the storage chairs to the housing walls 3 . 3 ' build up. The statically generated compressive stresses act on the dynamic tensile stresses that occur during combustion in the transition radius from the bearing bracket 2 . 2 ' to the housing wall 3 . 3 ' counter and thus enable the increase in the cylinder pressure for a significantly higher dynamic operating load. The increased internal cylinder pressure increases the efficiency of the internal combustion engine, which reduces fuel consumption. The power density of the internal combustion engine can thus be increased for a given installation space and weight.

• – Alusil mit einem Wärmeausdehnungskoeffizienten α = 19,2 × 10^–6 [1/K] in Verbindung mit einem Verbindungselement 4, 4' aus einem Gussmaterial mit einem Wärmeausdehnungskoeffizienten α = 11,0 × 10^–6 [1/K], oder
• – Magnesiumguss mit einem Wärmeausdehnenskoeffizienten α = 26,7 × 10^–6 [1/K] in Verbindung mit einem Verbindungselement 4, 4' aus Chrommolybdänstahl mit einem Wärmeausdehnungskoeffizienten α = 12,0 × 10^–6 [1/K] sein.

In other versions, the machine housing material can also consist of:

• - Alusil with a coefficient of thermal expansion α = 19.2 × 10 ^–6 [1 / K] in connection with a connecting element 4 . 4 ' from a cast material with a coefficient of thermal expansion α = 11.0 × 10 ^-6 [1 / K], or
• - Magnesium casting with a thermal expansion coefficient α = 26.7 × 10 ^–6 [1 / K] in connection with a connecting element 4 . 4 ' made of chromium molybdenum steel with a coefficient of thermal expansion α = 12.0 × 10 ^-6 [1 / K].

Another technically relevant variant is the material pairing for a machine housing material made of:
- Gray cast iron with a coefficient of thermal expansion α = 11.0 × 10 ^–6 [1 / K] in connection with a connecting element 4 . 4 ' made of a glass fiber reinforced plastic with a thermal expansion coefficient α = 5.2 × 10 ^–6 [1 / K].

In addition, the connecting element 4 . 4 ' also from a sintered material with a coefficient of thermal expansion that is variable over the material composition? his.

In the present exemplary embodiment there is a separate connecting element for each storage area 4 . 4 ' provided, in other embodiments, a single connecting element 4 . 4 ' extend over several storage areas.

In addition to a screw connection between the connecting element 4 . 4 ' and housing walls 3 . 3 ' positive or non-positive connections are also conceivable. Furthermore, the connecting element 4 . 4 ' be designed such that it also functions as an oil plane and takes over the task of calming the lubricant during operation of the internal combustion engine in the crankcase.

1

machine housing

2, 2 '

bearing block

3, 3 '

housing wall

4, 4 '

connecting element

5, 5 '

bearing cap

6 6 '

screw

Claims (6)

Machine housing ( 1 ), in particular a cylinder crankcase, for an internal combustion engine in which there are between two opposite housing walls ( 3 . 3 ' ) at least one camp chair ( 2 . 2 ' ) for a shaft and the housing walls ( 3 . 3 ' ) via a connecting element ( 4 . 4 ' ) towards the camp chair ( 2 . 2 ' ) are stiffened, characterized in that the machine housing ( 1 ) made of a material with a greater coefficient of thermal expansion than the connecting element ( 4 . 4 ' ) is. Machine housing according to claim 1, characterized in that the connecting element ( 4 . 4 ' ) for at least one storage area ( 2 . 2 ' ) is provided. Machine housing according to one of the aforementioned claims, characterized in that the connecting element ( 4 . 4 ' ) detachable with the housing walls ( 3 . 3 ' ) connected is. Machine housing according to one of the ge mentioned claims, characterized in that the connecting element ( 4 . 4 ' ) is made of a steel, plastic or sintered material. Machine housing according to one of the aforementioned claims, characterized in that the machine housing ( 1 ) is made of a light metal. machine housing according to one of the aforementioned claims, characterized in that the shaft is a crankshaft.