DE102007040128B4 - Disc brake with two ceramic brake discs - Google Patents

Abstract

Disc brake with two brake discs made of carbon fiber reinforced SiC, C / SiC or C / C-SiC, which slide axially via a brake disc spline (11) on the inside edge of the brake disc and a corresponding wheel hub spline profile (10) on the outer edge of the wheel hub to the wheel hub are, and with a fixed caliper with a plurality of brake pads, of which two brake pads (1, 2) arranged on the outside are each assigned to a friction ring on each brake disc and are axially movably attached via brake pistons and at least one brake pad arranged between the brake discs, characterized in that that at least the sliding surface of the wheel hub spline (10) consists of corrosion-resistant stainless steel, corrosion-resistant tempering steel or a nickel-based alloy, and that the sliding surface of the wheel hub spline (10) is formed by sliding sleeves (14) that clamp on the teeth of the wheel spline (10) attached nd and have a radial bias to the brake disc spline (11), wherein the sliding sleeves are connected to form a coherent ring spanning the entire wheel hub.

Description

The invention relates to a disc brake with two brake discs, which are mounted axially movable on a wheel hub and a fixed caliper with three brake pads, two of which are arranged outside brake pads each associated with a friction ring and axially movable via brake piston and of which an inner lying between the two brake discs arranged brake pad is stationary or axially movable connected to the fixed caliper. In particular disc brakes are affected with ceramic discs.

Disc brakes with ceramic brake discs are gaining in importance for high-performance braking systems of sports vehicles. In addition to the restricted to racing C / C ceramics (carbon / carbon ceramics) play for series or road vehicles essentially only carbon fiber reinforced SiC ceramics a role, as they, in contrast to the C / C materials a high inherent protection against oxidation have at the occurring high brake temperatures. Such composite ceramics are known in different material characteristics as C / SiC or C / C-SiC and are described for example in the EP 1 070 027 B1 . DE 44 38 455 A1 or the DE 197 11 829 C1 described.

Due to the high thermal loads and compared to conventional gray cast iron brake discs low heat capacity, it is also customary to perform ceramic brake discs ventilated, such as in DE 44 38 455 A1 described. The 198 16 381 A1 shows a brake disc for a motor vehicle, which consists of a fiber composite material and is composed of two friction rings, both friction rings are provided with a plurality of involute curved ribs which form air channels in the connected state.

Frequently, the ceramic brake discs are constructed as a gradient material by having an oxidation-protective friction layer of special C / SiC or SiC. Such brake disk now their production are for example in the DE 103 48 123 B3 or the DE 100 66 044 B4 described.

The known brake systems have the disadvantage that the ceramic brake discs are highly loaded and due to which require ventilation ducts and / or friction layers. These additional embodiments make the production process of the brake discs more expensive.

In order to compensate for the low heat capacity compared to the cast iron brake discs, ceramic brake discs must have relatively large diameters. A further increase in performance, such as required for SUVs or VANs, therefore, is often not feasible due to the limited space in the vehicle.

The concept of the double brake disc is in principle suitable to increase the performance of a brake, without increasing the diameter. A brake unit with double brake disc is for example from the DE 19859616 A1 known. Here, inter alia, a brake unit is disclosed in which two friction rings are connected to a hub by means of a splined shaft profile. The ceramic friction rings are connected via fastening bolts or by means of a splined connection directly to a wheel hub. To ensure good thermal insulation between friction ring and hub, and to achieve a uniform torque transmission between the friction ring and the hub, the contact surface between the friction ring and the fastening elements of the hub with a plastically deformable, heat-insulating layer ( 15 ) Mistake.

The disclosed brakes have the disadvantage that the fasteners for the brake discs and also for the brake pads are exposed to high thermal wear or corrosion. As a result, movably designed connections can be restricted in their function or completely seize. The reliability of the brake can thereby suffer significantly.

It is therefore an object of the invention to provide a high-performance disc brake with improved braking performance with high reliability of the connection of brake discs or brake pads ready, the design concept should allow low manufacturing costs and easy maintenance.

The object is achieved by a disc brake with two brake discs made of fiber-reinforced ceramic, in particular carbon fiber reinforced SiC, C / SiC or C / C-SiC, axially sliding over a brake disk spline on the inner edge of the brake discs and a corresponding hub splines on the outer edge the wheel hub are connected to the wheel hub and of a fixed caliper with a plurality of brake pads, two of which are arranged outside brake pads each associated with a friction ring and axially movable via brake piston and at least one disposed between the brake discs inner pad, at least the sliding surface of the wheel hub Spline shaft profile of the corrosion-resistant metal alloys-corrosion-resistant stainless steel, corrosion-resistant tempering steel or nickel-based alloy consists, with the features of claim 1.

According to the invention, it is thus assumed that a brake comprises two ceramic brake disks, which are arranged axially movably on a wheel hub. The brake type corresponds to the design of a fixed caliper brake, because the caliper with the piston is firmly connected to the wheel suspension. Therefore, in contrast to the caliper brake, the pistons of the outer linings must press the linings against the brake discs from both sides. The saddle is firmly connected to the suspension. By the choice of material according to the invention for the sliding surface, on which the corresponding splines can slide axially along each other, from the corrosion-resistant metal alloys (corrosion-resistant stainless steel, corrosion-resistant tempered steel or nickel-based alloy) ensures that no aggravating the mobility aggravated corrosion products are formed even at maximum thermal stress. Both a high corrosion resistance and a high mechanical strength are required for the selected materials to allow a secure hold of the brake discs and the transmission of high braking forces. The corrosion resistance is to be understood in particular rust resistance and a scale strength, since the temperatures occurring in conjunction with the ceramic brake disc can assume very high values. In addition, for the materials of the sliding surface good physical compatibility, especially in terms of thermal expansions, with the rest of the wheel hub required to keep the thermal cycling in continuous operation low.

Only by the corrosion-protected construction, it is possible to enable a permanently slidable connection of the ceramic brake discs even at very low clearance. The smallest possible play is of great importance in order to allow the most complete possible engagement of the connecting elements of the wheel hub and brake discs. As a result, the harmful for the ceramic material mechanical stress peaks are effectively reduced.

The mechanical coupling of the brake disc and the hub via interlocking spline profiles. The result is a splined shaft. For the invention, a high mechanical strength, or strength and corrosion protection in the region of the splines, or the sliding surfaces formed in the splines are crucial. It is provided to provide the sliding surface on the side of the wheel hub with a corrosion-resistant solid material, while the opposite sliding surface of the ceramic brake disc can be used substantially unchanged. Especially due to the high hardness of the ceramic brake disc, it is important to provide a high-strength material for the splines of the wheel hub in mechanical contact therewith.

The further spaced from the profile areas of the wheel hub, however, may be constructed from less high quality or corrosion-resistant materials. This makes it advantageous to use a less expensive or a lightweight material for the hub.

The extent of the sliding surfaces also depends on how far the spline meshes with each other. It is for example possible to make the teeth of the brake disc so short that a contact with the bottom of the corresponding valley of the hub is not given. The reverse arrangement is conceivable. In contrast, the flanks of the spline teeth are typically designed as a sliding surface, since essentially the power transmission takes place during braking.

The invention and advantageous embodiments are explained in more detail below with reference to exemplary schematic illustration.

Showing:

1 a wheel hub ( 9 ) with wheel hub spline ( 10 ), a sliding sleeve applied to a splined tooth ( 14 ), a sliding sleeve applied to 2 spline teeth ( 14 ' ), and two disassembled brake discs ( 5 . 6 ) with corresponding brake disk splines ( 11 )

2 a wheel hub ( 9 ) with a wreath ( 15 ), which is a hub spline ( 10 ), and two disassembled brake discs ( 5 . 6 ) with corresponding brake disk splines ( 11 )

3 a caliper ( 8th ) from below with outer brake pads ( 1 . 2 ), Brake carrier ( 7 ) and hereon set inside brake pads ( 3 . 4 ) and

4 a caliper ( 8th ) from diagonally below with outer brake pads ( 1 . 2 ), Brake carrier ( 7 ) and a thereto set inside brake pad ( 12 ).

In a first embodiment, the exemplary in 1 is shown, is the sliding surface of the hub spline ( 10 ) by sliding sleeves ( 14 ), which are clamped on the teeth of the wheel hub spline ( 10 ) are attached. The sliding sleeves can be pushed laterally over the teeth of the spline profile for mounting and then fixed. Particularly preferably, they are designed so that a radial bias to the Brake Disc Spline Shaft Profile ( 11 ) is constructed and in addition to the axial and a radial mobility exists. This can be reduced by thermal expansion resulting thermal stresses in the radial direction. The sliding sleeves ( 14 ) can each span only one wedge tooth separately or several at the same time. In a variant, the sliding sleeves are connected to a contiguous, the entire wheel hub spanning wreath. The wreath has over the individual sliding sleeves in particular the advantage of easier installation. But the thermal shielding of the underlying wheel hub is usually more efficient than individual sliding sleeves. The sliding sleeves are further preferably designed so that an axial and radial mobility of the spline profile of the brake disc is ensured.

A further advantageous embodiment of the invention provides that at least the wheel hub spline ( 10 ) of the wheel hub is made of corrosion-resistant stainless steel, corrosion-resistant tempering steel or a nickel-based alloy. The area can, for example, as in 2 represented by a toothed annular ring ( 15 ) be formed on the wheel hub. The Ring of Wreath ( 15 ) is firmly connected to the wheel hub. The remainder of the wheel hub can be formed by less expensive materials, such as the usual iron casting alloys.

Even the simplest structural design of the wheel hub, in which the entire hub of the corrosion-resistant metals, corrosion-resistant stainless steel, corrosion-resistant heat-treated steel or a nickel-based alloy is formed (one-piece construction) may be advantageous, although comparatively expensive metal alloys are used. Cost savings arise over the simpler one-piece gegenübdr the multi-part manufacturing.

A hardened martensitic steel is particularly suitable as a corrosion-protected steel for the material of at least the sliding surface of the wheel hub splined shaft profile, or the splined portion of the wheel hub. For the connection to the ceramic brake disc, a high hardness of the steel in the contact surfaces of steel and ceramic is required. By sliding the ceramic on the steel surface, in particular during the application of force during braking, the hardness of the surface is of particular importance. Preferred martensitic steels have as alloying elements in wt .-% 12-18% Cr and 0.1% to 1% C. Preferred steels are, for example, X4CrNi18-12, X8CrNiS18-9, X2CrNi19-11, X2CrNi18-9, X2CrNiN18-10, X6CrNiTi18-10, X6CrNiNb18-10, X10CrNi18-8, X5CrNiMo17-12-2, X2CrNiMo17-12-2, X6CrNiMoTi17- 12-2 or X1CrNiMoTi18-13-2. This steel is also well suited for a one-piece construction of the wheel hub.

Another suitable type of steel of a corrosion-resistant stainless steel are typical austenitic stainless steels, in particular V2A steel.

The suitable nickel-based alloys are a series of alloys consisting of nickel and other metals such as Cu, Cr, Fe, Mo, and having both good heat and corrosion resistance.

A further embodiment of the invention provides for the wheel hub before a light metal composite. It has a central region of light metal alloy, for example Al or Mg alloy and armored splines, or a ring collar ( 15 ) made of the corrosion-resistant metal alloys. The annular ring comprises at least the entire splined shaft profile of the hub. Due to the corrosion-resistant metal alloys, the light metal is mechanically armored and additionally protected against high-temperature corrosion.

A further embodiment of the wheel hub sees in the central region below the sliding surface or below the wheel hub spline ( 10 ) a cast steel alloy. More preferably, the cast steel alloy is formed from an austempered ductile iron or ADI. The casting technology production of the complex wheel hub geometry offers significant procedural simplifications.

Optionally, the corrosion-resistant metal alloys are provided with separate lubricious coatings, in particular TiN, TiC and / or BN.

With regard to the brake linings different fastening and construction concepts can be realized. In this case, however, the high brake disk temperature and wear stress due to the ceramic brake disk must be taken into account in particular.

In a first embodiment are between the both brake discs ( 5 . 6 ) two internal brake pads ( 3 . 4 ) on an axially displaceable brake carrier ( 7 ) of the fixed caliper ( 8th ) in each case opposite. As a result, an improved interaction during braking is achieved. The responsible for the axial mobility devices, for example. Holding pins for the brake pads are preferably also made of corrosion-inhibited steel or stainless steel, as the sliding surfaces of the hub.

In a further embodiment, the exemplary in 3 is shown, between the two brake discs ( 5 . 6 ) two internal brake pads ( 3 . 4 ) on a brake carrier ( 7 ) of the fixed caliper ( 8th ) in each case axially immovably mounted opposite each other. The brake carrier ( 7 ) is formed for example as a support plate which is fixedly mounted in the saddle. The two brake pads are fixed on the carrier plate. An axial mobility is not provided. This embodiment is characterized by high reliability and simple construction. To reduce the variety of variants within the brake, the same brake pads can be used for all 4 positions. An advantage of the fixed fixation of the brake carrier is that no temperature-stable axial sliding devices must be provided.

Another embodiment, according to 4 sees between the two brake discs ( 5 . 6 ) a single inside and two brake discs associated brake pad ( 12 ) on an axially fixed or displaceable brake carrier ( 7 ) in front. In this embodiment, the inner brake pad ( 12 ) typically thicker than the outside. Preferably, the brake pad ( 12 ) introduced by a clamping or plug connection from below into the brake carrier.

The only internal and both brake discs associated brake pad ( 12 ) may also be mounted axially non-displaceable.

Compared with the ceramic brake discs, the lining materials commonly used for cast iron brake discs have relatively high wear rates. Therefore, in a preferred embodiment, at least the inner brake pad is constructed from a very low-wear pad material. In a preferred embodiment, a ceramic material, in particular made of C / SiC, C / C-SiC or oxidation-protected C / C material is used for this purpose. This increases the service life of the hard-to-reach inner brake pads and extends the service cycle. A preferred combination of brake linings provides for the outer an organically bound covering material and for the inner linings a ceramic material, in particular a CMC or SiC material before, which has a relation to the brake disc material reduced strength.

In a further embodiment, the inner brake pad is made larger than the corresponding outer pads.

This also increases the service cycle. The braking surface of the inner lining is here preferably at least 1.2 times the area of the respective opposite brake pad.

A further advantageous development provides that the inner brake pad has at least twice the thickness of one of the outer linings. Preferably, the thickness is 2.5 to 3 times the thickness of an outer brake pad. Particularly preferably, the entire thickness of the inner brake pads ( 3 . 4 . 12 ) at least twice the thickness of the outer brake pads ( 1 . 2 ).

The two brake discs are fiber-reinforced ceramic materials. Materials selected from carbon fiber reinforced silicon carbide, C / SiC or C / C-SiC are preferably selected, as can be produced in particular by the liquid infiltration of C / C preforms with silicon.

Since the brake according to the invention is equipped with two brake discs, the thermal load of the individual discs relative to comparable brakes with only one brake disc decreases significantly. This makes it possible to use simple brake disc designs and to realize significant cost savings over brakes with simple ceramic brake disc.

In contrast to the usual complicated to produce in single disc systems ventilated ceramic brake discs ceramic discs are preferably used without internal channels or recesses for cooling. In addition to a significant cost reduction through simplified production, such non-ventilated brake discs also have comparatively lower thicknesses. The leaner construction also saves expensive raw materials.

To improve the braking effect, the brake disc can be perforated. Here, through holes are provided perpendicular to the disk surface. Such perforations are procedurally simple and resource-friendly to produce.

In a preferred embodiment of the brake disc massive discs are used, which are free of internal ventilation, perforation or otherwise such recesses.

In a further preferred embodiment of the invention, the brake disc is constructed of a monohydric material. This is to be understood that the entire brake disc has substantially the same material composition. This means in particular that the material composition of the brake disc has no gradient parallel to the surface normal and that the brake disc has no separate friction layer. The concept of the double brake disc makes it possible to dispense with a separate oxidation protection layer or a special friction layer on the brake disc surface.

Claims (14)

Disc brake with two brake discs of carbon fiber reinforced SiC, C / SiC or C / C-SiC sliding axially over a brake disc spline ( 11 ) on the inner edge of the brake discs and a corresponding hub spline ( 10 ) are connected to the wheel hub at the outer edge of the wheel hub, and with a fixed caliper with a plurality of brake pads, of which two outer brake pads ( 1 . 2 ) are each associated with a friction ring on a respective brake disk and mounted so as to be axially movable via brake pistons and at least one inner brake pad arranged between the brake disks, characterized in that at least the sliding surface of the wheel hub spline profile ( 10 ) is made of corrosion-resistant stainless steel, corrosion-resistant quenched steel or a nickel-based alloy, and that the sliding surface of the wheel hub spline ( 10 ) by sliding sleeves ( 14 ) which is clamped to the teeth of the hub spline ( 10 ) and a radial bias to the brake disk spline ( 11 ), wherein the sliding sleeves are connected to a continuous, the entire wheel hub spanning wreath. Disc brake according to claim 1, characterized in that at least the wheel hub spline ( 10 ) consists of corrosion-resistant stainless steel, corrosion-resistant heat-treated steel or a nickel-based alloy. Disc brake according to claim 1, characterized in that the entire wheel hub consists of a hardened martensitic steel. Disc brake according to claim 1, characterized in that the wheel hub consists of a metal composite component, wherein the central region (below the sliding surface or below the wheel hub spline 10 ) consists of an Al or Mg alloy or a cast steel alloy. Disc brake according to claim 3, characterized in that the cast steel alloy is formed from an austempered ductile iron or ADI. Disc brake according to one of the preceding claims, characterized in that between the two brake discs ( 5 . 6 ) two internal brake pads ( 3 . 4 ) on a brake carrier ( 7 ) of the fixed caliper ( 8th ) are each mounted axially immovable opposite each other. Disc brake according to one of claims 1 to 5, characterized in that between the two brake discs ( 5 . 6 ) two internal brake pads ( 3 . 4 ) on an axially displaceable brake carrier ( 7 ) of the fixed caliper ( 8th ) are mounted opposite each other. Disc brake according to one of claims 1 to 5, characterized in that between the two brake discs ( 5 . 6 ) an inner and two brake discs associated brake pad ( 12 ) on an axially fixed or displaceable brake carrier ( 7 ) is attached. Disc brake according to one of claims 1 to 5, characterized in that the brake discs has no internal channels or recesses for cooling. Disc brake according to one of the preceding claims, characterized in that the material composition of the brake disc is substantially unchanged parallel to the surface normal. Disc brake according to one of the preceding claims, characterized in that the outer brake linings ( 1 . 2 ) of organically bound coverings and the inner brake pad (s) ( 3 . 4 . 12 ) consist of a ceramic material. Disc brake according to claim 10, characterized in that the inner brake pads ( 3 . 4 . 12 ) consist of a C / SiC, C / C-SiC or oxidation-protected C / C material. Disc brake according to one of the preceding claims, characterized in that the braking surface of the inner brake pad ( 3 . 4 . 12 ) At least 1.2 times the braking surface of the corresponding outer brake pad ( 1 . 2 ) having. Disc brake according to one of the preceding claims, characterized in that the entire thickness of the inner brake pads ( 3 . 4 . 12 ) at least twice the thickness of the outer brake pads ( 1 . 2 ) is.

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