EP3003714A2 - Sliding bearing composite comprising an aluminium bearing metal layer - Google Patents

Abstract

The invention relates to a sliding bearing composite comprising a carrier layer made of steel, an intermediate layer arranged on the carrier layer and made of aluminium or an aluminium alloy that is lead-free except for impurities, and a bearing metal layer arranged on the intermediate layer and made of an aluminium alloy that is lead-free except for impurities. Said aluminium alloy contains 6.0-10.0 wt.% tin, 2.0-4.0 wt.% silicon, 0.7-1.2 wt.% copper, 0.15-0.25 wt.% chromium, 0.02-0.20 wt.% titanium, 0.1-0.3 wt.% vanadium and optionally less than 0.5 wt.% other elements, the remaining portion being aluminium.

Description

 Sliding bearing composite material with aluminum bearing metal layer

description

The invention relates to a sliding bearing composite material with a support layer made of steel, an aluminum on the support layer disposed intermediate layer, preferably from a lead-free impurities aluminum alloy, and arranged on the intermediate layer bearing metal layer of a lead-free impurities aluminum alloy.

Such plain bearing composite materials are being developed in particular for bearing shells or bushings or thrust washers for use in internal combustion engines of motor vehicles. They are the subject of a variety of print fonts. With an improvement of the bearing metal composition, the documents EP 1 334 285 A1, DE 10 201 1 003 797 B3, DE 102 46 848 B4 or EP 2 105 518 A2, for example, differ. The aluminum bearing alloy known from the latter specification comprises 1.5 to 8 wt.% Si, 3 to 40 wt.% Sn, one or more elements from the group consisting of Cu, Zn and Mg in a total amount of 0.1 to 6 wt .-%, optionally one or more elements from the group consisting of Mn, V, Mo, Cr, Ni, Co and B, in a total amount of 0.01 to 3 wt .-% and the rest aluminum. The focus of the investigation in that document is on the particle size distribution of the Si particles contained in the finished aluminum bearing alloy product, which has both a proportion of small Si particles having a particle size of less than 4 μιτι and larger Si particles having a particle size of 4 to 20 μιτι should contain in a certain, but very wide distribution. With the specified distribution, the tendency of the material to be bonded to the sliding partner (tendency to seize) is reduced and the incorporation of the particles into the material is improved. To achieve the required particle size distribution According to the teaching of that document, the sequence of an annealing step at a temperature of 350 ° C to 450 ° C over a period of 8 to 24 hours and a subsequent rolling step at. From DE 10 201 1 003 797 B3 a sliding bearing composite material with a carrier layer made of steel, an intermediate layer arranged on the carrier layer and a bearing metal layer arranged on the intermediate layer is known from an aluminum alloy which is lead-free to impurities. The aluminum alloy of the bearing metal layer contains 10.5-14 wt.% Tin, 2-3.5 wt.% Silicon, 0.4-0.6 wt.% Copper, 0.15-0.25 wt. % Chromium, 0.01-0.08 wt% strontium and 0.05-0.25 wt% titanium. The silicon is distributed in the form of particles in the bearing metal layer of the shape before that, based on a surface of the bearing metal layer, the area ratio of visible in this surface silicon particles with a diameter of 4 μιτι to 8 μιτι at least 2.5%. Here, the chemical composition and the hard particles were improved in view of high wear resistance.

Wear resistance is still an important factor for the mixed friction conditions prevailing in start-stop applications, so there is always a need for optimization here. Furthermore, however, the inventors have taken on the task at the same time to increase the fatigue strength of the bearing material.

The object is achieved by a sliding bearing composite material with the features of claim 1.

In a sliding bearing composite material of the aforementioned type, the invention provides that the aluminum alloy of the bearing metal layer 6.0 - 10.0 wt .-% tin, 2.0 - 4.0 wt .-% silicon, 0.7 - 1, 2 wt. -% copper, 0.15 - 0.25 Wt% chromium, 0.02-0.20 wt% titanium 0.1-0.3 wt% vanadium and optionally less than 0.5 wt% of other elements, balance aluminum.

For the purposes of this document, the term "lead-free except for impurities" is understood to mean that a lead content which could possibly be present due to contamination of individual alloying elements is at least less than 0.1% by weight.

The inventors have recognized that the bearing metal layer, in particular when using a ductile intermediate layer, can be designed significantly in the direction of increased fatigue strength by the specific choice of the tin content in combination with adapted microalloying elements, as was customary in the prior art. Therefore, the bearing is not only suitable for use in the main bearing area, where mixed friction conditions occur more frequently during start-stop operation, under which there is no (hydrodynamic) oil lubrication of the bearing, but also as a connecting rod bearing material.

The addition of Ti improves grain refining of the matrix material during the casting process, regardless of suitable temperature control and suitable degrees of forming in the manufacture of the sliding bearing composite. By exact adherence to the Ti content of 0.02-0.2 wt.%, Preferably 0.04-0.1 wt.%, In the case of the low cooling rates of the casting process aimed at with regard to the Si particle size distribution, a sufficiently fine grain size of the Al matrix material can be adjusted, which ensures high strength with good stretching properties of the matrix material. The particle size distribution of the matrix material in turn has an influence both on the distribution of the Si particles, since the Si dissolves in the Al matrix, and on the incorporation of the soft phase, ie the insoluble Sn along the grain boundaries. Therefore, the Ti content requires a very precise coordination with the proportion of Si and Sn. According to the invention, the latter is present in a range from 6.0% by weight to 10.0% by weight, preferably from 8.0 to 10.0% by weight. It is precisely in this area that the alloy system of the bearing metal layer has the excellent sliding properties and has due to a relatively low content of tin as a soft phase, the necessary strength for higher loads, which makes it possible to use in mixed friction conditions.

The Si content, with an upper limit of 4% by weight, preferably 3% by weight, is set so low in accordance with the invention that the ductility of the bearing metal layer required in view of the high degree of deformation of the rolling steps is given. On the other hand, a minimum content of Si particles of 2.0 wt .-% is necessary in order to adjust a sufficient wear resistance of the bearing metal material it can. By offering Si or Si particles and their size controlled by the heat treatment, the seizure tendency can be considerably reduced, which again is advantageous in mixed-friction conditions. In contrast to pure Al interlayers, the Si content is not critical with regard to diffusion processes and brittle phase formation. The Cr content must be considered in the context of the Cu content. Both elements have proven to be particularly important in the aluminum matrix with regard to the heat resistance of the material. This is always required for heavily loaded applications. The Cr content of 0.15 to 0.25 wt .-% has proved to be favorable with simultaneous addition of Cu with a content of 0.7 to 1, 2 wt .-%, in order to increase sufficient strength in the matrix To make excretions. On the other hand, a content of 0.25 wt .-% Cr and 1, 2 wt .-% Cu should not be exceeded, again to not adversely affect the formability. Finally, the combination of Cr and Cu also has the positive effect that an upper limit of the used Cu of 1, 2 wt .-% reduces the cost and increases the recyclability of the material.

Finally, the aluminum alloy of the bearing metal layer has 0.1 to 0.3% by weight of vanadium. Vanadium has an inhibiting effect on the recrystallization of the matrix material because it raises its recrystallization temperature. Vanadium thus serves to increase the heat resistance, which, in conjunction with the Ti, allows problem-free adjustment of a grain size matched to the soft phase and the Si.

The aluminum alloy of the bearing metal layer preferably has a 0.2% yield strength R _p , o, 2 of more than 90 MPa and a tensile strength R _m of more than 145 MPa, the material parameters being tensile tested at room temperature in accordance with DIN EN ISO 6892- 1 are determined.

It has surprisingly been found that the addition of vanadium only in conjunction with a relatively low tin content of 6 to 10 wt .-%, a significant increase in strength, in particular an increase in the 0.2% yield strength R _p , o, 2 of 60% and the tensile strength R _m of over 15% causes. The astonishing thing is that this significant change already at low-content 0.2% vanadium and a slight reduction of the tin content of 12% to 8 wt .-%, starting from the known from DE 10 201 1 003 797 B3 material, ie takes place within a small margin.

Preferably, the aluminum alloy of the bearing metal layer comprises at least one of the elements selected from the group consisting of 0.01-0.08 wt% strontium, 0.1-0.2% zirconium and 0.1-0.2 scandium. In addition to the Si content, the particle size distribution of the Si in the bearing metal layer, which in turn is influenced by the chemical composition, is decisive for the wear resistance. The inventors have recognized that the targeted addition of a small amount Sr in the range of 0.03 to 0.08 wt .-% in the above-mentioned Si content favors the adjustability of the particle size distribution. Together with a low cooling rate after the casting process of <75 K / sec, preferably <50 K / sec, the Sr ensures an optimized particle size distribution with regard to minimizing wear. At the same time, it affects the shape of the Si particles which, on account of the Sr content after casting, on average have a finer and rounder appearance than could be observed without the addition of Sr. In this way, with regard to the subsequent heat treatment and rolling steps, the formability of the matrix material does not deteriorate significantly due to the addition of Si. The Sr content is exactly matched to the Si content.

Preferably, the intermediate layer of rolled to final dimension sliding bearing element has a thickness 02 of 25 μιτι to 70 μιτι and preferably from 25 μιτι to 50 μιτι on.

The intermediate layer preferably has a microhardness of 40 HV 0.01 to 90 HV 0.01.

The Vickers hardness test is carried out according to the European standard EN 6507-1 on the intermediate layer of the finished (formed) plain bearing element. The test probe (the indenter) is in this case pressed in the plane direction of the intermediate layer in this in the region of a prepared cutting edge of the sliding bearing element. The cutting edge is preferably prepared by grinding. The silicon in the bearing metal layer in the form of particles in the bearing metal layer is preferably distributed in such a way that 30-70 Si particles> 5 μιτι can be found on an area of 0.04 mm ² . This particle size distribution has been found to be particularly advantageous because the Si hard particles> 5 μιτι are sufficiently large to ensure a high wear resistance of the material as hard carrier crystals.

To determine the particle size distribution, a surface section of the bearing metal layer of a specific dimension under a microscope, preferably at 500 × magnification, is considered. The bearing metal layer can be considered in any plane, since it is assumed that a substantially homogeneous distribution of the Si particles in the layer or at least that a distribution that is intentionally or unintentionally inhomogeneous, that is, for example gradually in one direction. or decreases, at least does not leave the claimed limits. The bearing metal layer is preferably prepared to the shape that first a flat cut is made. The visible in the surface section Si particles are measured to the shape that their longest recognizable extent is determined and equated to the diameter. Finally, all Si particles are added in the surface section with a diameter> 5 μιτι and the number thereof in the examined total measuring surface based on a standard surface. It is also possible to ascertain and add up the diameters of all Si particles falling into such a class (> 5 μιτι) and to calculate an average value from them

Particularly preferably, the average Si particle size of all Si particles thus measured> 5 μιτι is 6 to 8 μιτι. A diameter of 6 to 8 μm ensures that the particles in turn do not become so large that they lead to a reduction in the strength of the matrix, in particular under dynamic load. As already mentioned above, the size distribution of the silicon particles is preferably set by a cooling rate after the casting process of less than 75 K / s, more preferably less than 50 K / s.

Furthermore, it has surprisingly been found to be advantageous when the tin is present distributed in the bearing metal layer in the form of particles or inclusions in the matrix so that on a measuring area of 1 42 mm ² not more than 50 Sn particles having a surface area of more than 100 μιτι ² present.

The preparation of the bearing metal layer for the purpose of measuring the tin distribution is carried out here as described above. The Sn particles visible in a surface section with a scanning electron microscope are identified by means of EDX analysis by searching for a gray value range associated with the tin within the surface section. Subsequently, the area proportions of the individual tin particles are determined. For this purpose, coherent pixels of the scanning electron micrograph, which fall within the grayscale range assigned to the tin, are counted. With known size of the surface section and known resolution of the recording with the scanning electron microscope and the size of a single pixel is known. From the number of contiguous pixels and the pixel size, the area of a tin particle can be determined. Finally, the determined on the surface cut tin particles in size classes such as <100 μιτι ² and> 100 μιτι ² or divided into size classes of other gradation. In the case according to the invention, all Sn particles in the surface section with a surface area> 100 μιτι ^{2 are} added up and the number thereof normalized to said standard measurement area of 1.42 mm ² , provided that the surface section of interest does not already coincide with the measurement area.

Advantageously, in particular in the case of particularly highly stressed bearing applications in internal combustion engines, a polymer-based covering layer is arranged on the bearing metal layer.

The polymer layer results in a more uniform load distribution over the entire bearing width, especially at high loads. As a result of the elastic and plastic adaptability of the polymer layer, the reliability of the entire bearing can be increased even further.

Figure 1 shows a basic layer structure of a first embodiment of the sliding bearing composite material according to the invention;

Figure 2 shows a basic layer structure of a second embodiment of the sliding bearing composite material according to the invention;

FIG. 3 shows an illustration of the determination of the Si particle size distribution;

4 shows a diagram for comparing the strength values and elongation at break of the bearing metal alloy as a function of the vanadium and tin content and

FIG. 5 shows a diagram for comparing the size distribution of the tin phases in the bearing metal alloy. Figure 1 shows schematically a cross section through a sliding bearing composite material according to a first embodiment of the invention. He has a total of 3 layers. The uppermost layer shown in FIG. 1 is a bearing metal layer 10 which has the Al-based composition according to the invention. The bearing metal layer 10 is applied via an intermediate layer 12 on a support or support layer 14 made of steel. The intermediate layer serves as a bonding agent between the bearing metal layer 10 and the steel layer. It consists of pure aluminum or an aluminum alloy. Furthermore, a surface section 20 is shown symbolically in FIG. 1, which has the inner structure illustrated in FIG. 3 enlarged. In order to produce an image of such a surface cutout, preferably a flat cut is prepared at a suitable point of the bearing metal layer. Notwithstanding the illustration in Figure 1, the surface section can for example also be considered parallel to the sliding surface.

The layer thickness of the intermediate layer in the sliding bearing composite material according to the invention is preferably 25 μm to 70 μm and particularly preferably not more than 50 μm.

The second exemplary embodiment according to FIG. 2 has a different layer structure in that a polymer coating 16 is applied to the bearing metal layer 10 ', which is particularly advantageous in bearing applications which are particularly stressed.

The invention is not limited to the two embodiments shown. It is equally possible to provide a multilayer arrangement with further functional layers. Gradient layers are also not excluded. Basically, the number and shape of the layers is therefore not limited. Above all, for the above-mentioned reason of cost savings, however a sliding bearing composite are preferred, which has as few layers as a safe operation allows.

The method for determining the Si particle size distribution in the bearing metal layer will be explained below with reference to FIG. After initially a flat surface grinding was prepared by the bearing metal layer, which extends for example to the sliding surface, a surface section 20 of the bearing metal layer is selected and marked with a certain edge length and width under a microscope, for example at 500-fold magnification. Let this example be a rectangle with edge lengths of 500 μιτι and 800 μιτι, so the measuring surface of 400,000 μιτι. ² In this surface section can be seen a variety of Si particles 22, which can be distinguished from other inclusions, in particular by the soft phase, but also by foreign particles, both not shown here, can be distinguished by a certain gray or color value range. The detection of Si particles is preferably carried out automatically in an electronic imaging system. The Si particles 22 are measured in the shape that regardless of the shape of their longest detectable extent is determined. This extension is called the diameter. Corresponding to their diameter, the Si particles are classified into classes, such as, for example,> 5 μm and / or 2 μm, 2-4 μm, 4-6 μm, 6-8 μm, etc.

On this basis, two quantities can preferably be determined: The number of Si particles assigned to this class is simply counted and then converted to a standard surface area of, for example, 0.04 mm ² for comparability. Alternatively or additionally, the particle surfaces of all the particles assigned to the class can also be determined and added up and an average value calculated therefrom. 4 shows bar graphs comparing the strength values "yield strength Rp _, o, 2" and "tensile strength R _m " and the elongation at break "A" for three different compositions of the aluminum alloy of the bearing metal layer at two different test temperatures The alloys include those shown in Table 1 Compositions in% by weight:

Table 1

As a prior art (1st comparative example), a bearing metal alloy is chosen, as is known from the document DE 1 0 201 1 003 797 B3. Based on this, vanadium was added to the alloy and this new alloy was tested as a second comparative example. Both examples were compared with an embodiment of the inventive composition with increased Cu content and reduced Sn content. The first comparative example is represented by the left-hand bar graph, the second comparative example by the middle bar graph, and the embodiment according to the invention by the right-hand bar graph. The comparisons were performed once at room temperature, left half of Figure 4, and at a test temperature of 175 ° C, right half of Figure 4.

It can be seen that a composition of the alloying elements in the context of the invention leads to a significant increase of the tensile strength R _m by more than 40%, in particular with an elevated test temperature of 175 ° C., whereby the elongation is still sufficiently high at about 30% , It also shows that this behavior results from a combination of the addition of vanadium with a moderate increase of the Cu content and reduction of the Sn content. Surprisingly, it has also been found that a finer tin distribution is produced in the composition range of the bearing metal alloy according to the invention. This is demonstrated by the two diagrams of FIG. 5, which show the measured size distribution of the soft phase in the aluminum matrix in the three examples discussed above. The soft-phase distribution was determined by scanning electron microscopy (SEM) using EDX measurement. First, the Sn phase in the cut is identified, which takes place on the basis of its characteristic, defined gray value on a defined surface. The chemical composition of the Sn phase determined by its gray value is verified by means of EDX analysis. All particles matching the gray value and the EDX analysis are then recorded in terms of their size (area) and classified into freely selectable size classes. The result is a microstructural characterization of the Sn phase size and its distribution within the classes. The respective left-hand bar in FIG. 5 represents the number of sizes of the soft-phase particles for Comparative Example 1 according to Table 1, the average for Comparative Example 2 according to Table 1 and the right-hand example for Table 1 according to the invention. Under the information on the size class, the number is again tabulated. The upper diagram of FIG. 5 shows the classes of <1 μηη ² to 20 μηη ² and in the lower diagram the classes of 20 μηη ² to> 150 μηη ² , it being noted that the lower diagram has a different scaling of the ordinate , The counting and measurement of the Sn phases refers in each case to an area with a size of 1.42 mm ² . It can be seen that in the alloy according to the invention significantly more particles in the classes <10 μιτι ² are present, whereas particles in the classes> 100 μιτι ^{2 are} significantly reduced. This is partly attributed to the improved strength. This is because larger contiguous Sn regions or particles within the AI matrix weaken the microstructure, as they are present as a soft, separate phase (Sn or soft phase), resulting in mechanical stress, especially at elevated temperature , adversely affects. Therefore, the tin in the bearing metal layer is preferably distributed so that on an area of 1, 42 mm ² not more than 50 Sn particles having an area of more than 100 μιτι ² can be seen.

The special choice of the alloying elements of the bearing metal alloy surprisingly also has an influence on the Si precipitates in the bearing metal layer. The Si size distribution, which, as explained with reference to Figure 3, has been determined, in turn, has a direct impact on the strength and the wear resistance. Too coarse Si particles act as internal notches and reduce strength. At the same time, however, sufficient Si particles in a size range between 2 and 8 μm are required to ensure the known wear resistance of AISnSi alloys, because Si hard particles> 5 μm are sufficiently large, which are hard support crystals for the wear resistance of the material contribute. This requirement can be parameterized as follows in a suitable manner: The silicon particles in the bearing metal layer are distributed with respect to their diameter so that 30-70 Si particles> 5 μιτι are to be found on an area of 0.04 mm ² , preferably the average Si particle size of all measured Si particles with a diameter> 5μηη at 6.0-8.0μηη. Thus, these alloys make an excellent compromise for a bearing metal alloy with increased strength due to the special selection of alloying elements combined with a finer Sn distribution and a Si distribution which further ensures good wear resistance.

Since the bearing metal surface comes into contact with the counter-rotor, the feeding behavior and the fatigue strength are controlled to a first approximation via the bearing metal. The inventors have found that but also the intermediate layer contributes to the load capacity of the bearing. Cracks run from the surface to the weakest part of the composite under classic fatigue when the bearing fails. Due to its good adaptability, the intermediate layer ensures that there are no bonding problems even when roll-bonding the bearing metal to the intermediate layer (cladding) and the bearing metal / intermediate layer layer system on the steel (bonding). In addition, the intermediate layer improves the performance of the plain bearing especially at higher loaded start-stop motors, because they no aging phenomena, especially no temperature-induced formation of brittle intermetallic AlFe phases at the phase boundary between the steel of the support layer and the intermediate layer undergoes, which is why their mechanical properties in terms of strength and ductility are ideally matched to the bearing metal layer, permanently preserved.

Claims

claims

1 . Sliding bearing composite material with a support layer made of steel, an intermediate layer of aluminum arranged on the carrier layer or an aluminum alloy which is lead-free up to impurities and a bearing metal layer arranged on the intermediate layer and made of an aluminum alloy which is lead-free to impurities

6.0-10.0% by weight of tin,

 2.0-4.0 wt.% Silicon,

 0.7-1.2% by weight of copper,

 0.15-0.25% by weight of chromium,

 0.02-0.20% by weight of titanium

 0.1 - 0.3 wt .-% vanadium and optionally less than 0.5 wt .-% of other elements, balance aluminum.

2. Sliding bearing composite material according to claim 1, characterized in that the aluminum alloy of the bearing metal layer has a 0.2% yield strength R _p , o, 2 of more than 90 MPa and a tensile strength of more than 145 MPa.

3. plain bearing composite material according to claim 1 or 2, characterized

the aluminum alloy of the bearing metal layer comprises at least one of the elements selected from the group consisting of 0.01-0.08 wt% strontium 0.1-0.2% zirconium and 0.1-0.2 scandium.

4. plain bearing composite material according to one of the preceding claims, characterized

 the proportion of tin in aluminum alloy of the bearing metal layer is 8.0-10.0% by weight.

5. plain bearing composite material according to any one of the preceding claims, characterized

 the proportion of silicon in aluminum alloy of the bearing metal layer is 2.0-3.0% by weight.

6. plain bearing composite material according to one of the preceding claims, characterized

 the proportion of titanium in aluminum alloy of the bearing metal layer is 0.04-0.10% by weight.

7. plain bearing composite material according to one of the preceding claims, characterized

the silicon in the bearing metal layer is distributed in the form of particles so that 30-70 Si particles> 5 μιτι are present on an area of 0.04 mm ² .

8. Sliding bearing composite material according to one of the preceding claims, characterized in that

 that the mean Si particle size of all measured Si particles in the bearing metal layer> 5 μιτι at 6.0-8.0 μιτι.

9. plain bearing composite material according to one of claims 7 or 8, characterized in that the size distribution of the silicon particles in the bearing metal layer is set by a cooling rate after the casting process of less than 75 K / s, preferably 50 K / s.

Sliding bearing composite material according to one of the preceding claims, characterized

that the tin is present distributed in the bearing metal layer in the form of particles so that no more than 50 Sn particles are present in an area of 1 42 mm ² with an area of more than 100 μιτι. ²

Sliding bearing composite material according to one of the preceding claims, characterized

the intermediate layer has a thickness O 2 of 25 to 70 μιτι.

Sliding bearing composite material according to one of the preceding claims, characterized

the intermediate layer has a microhardness of 40 HV 0.01 - 90 HV 0.01.

Sliding bearing composite material according to one of the preceding claims, characterized

in that a polymer-based top layer is arranged on the bearing metal layer.