DE102008036796A1 - Method for increasing friction between frictionally connected components, involves arranging resistant material body between frictionally cooperative surfaces of components - Google Patents

Abstract

The method involves arranging resistant material bodies (20) between the frictionally cooperative surfaces of components (10',12'). The resistant material bodies are inserted in the surfaces of the components. The resistant material bodies are embedded in a non-metallic matrix. A volatile, drying or hardened matrix is used. The resistant material bodies consist of diamond, silicon carbide, silicon nitride, tungsten carbide, boron nitride or other ceramics. An independent claim is included for an arrangement of two frictionally connected components which are connected by respective frictionally cooperative surfaces.

Description

The The invention relates to a method for increasing the friction between frictionally connected components according to the preamble of claim 1, and an arrangement of two frictionally connected Components according to the preamble of claim 7.

It is known to frictionally engage the joints connected components friction-increasing coatings applied. By such coatings, the torque transfer capability increased such frictional connections become. For example, a method by which chemical treatment steps a nickel matrix on the friction surfaces the components to produce, in which hard material particles, for example Diamond or silicon carbide are introduced. When connecting the Both friction surfaces are these hard particles in the metallic body of the components pressed, causing the coefficient of friction of the connection is significantly increased.

The DE 23 64 275 A1 further discloses means for preventing relative movement between inter-engaged frictional cooperating components, wherein metal nitrides are produced on a previously roughened surface by nitrogen diffusion. When clamping the components against each other via this surface, this nitride layer is broken, whereby hard nitride particles are introduced between the friction surfaces of the components, which press in the further clamping of the components in the component surfaces.

The require known from the prior art methods usually a plurality of chemical treatment steps as well an elaborate surface treatment. These are expensive, energetically complex and often for environmental reasons not desirable.

Of the The present invention is therefore based on the object, a method to increase the friction between frictionally engaged To provide connected components, which with as possible takes little steps, and both cost effective and is also environmentally friendly. Furthermore, it is the task of an arrangement to provide with two frictionally connected components which is inexpensive to produce and is stable.

These Tasks are performed by a method having the features of the claim 1, and solved an arrangement with the features of claim 7.

at The method is between frictionally cooperating Surfaces of two frictionally connected components hard bodies which can be pressed into these surfaces arranged according to the invention, that the hard bodies in a non-metallic matrix are embedded.

By the abandonment of an embedding in an additional metallic Matrix can thus advantageously several chemical treatment steps be saved, which according to the state of Technology for example for the production of a nickel matrix or necessary for nitriding a steel surface would. The method according to the invention is suitable in particular for use in components, in which does not require repeated loosening and joining is. A homogeneous distribution of the hard body is therefore only required for the first time joining. By use a nonmetallic matrix can continue to a previous one elaborate surface treatment, such as chemical Endgraten or cleaning the surfaces are omitted.

Prefers In such a process, a volatile, drying or curing matrix used. In case of a volatile or drying matrix, the matrix substance serves only the first time homogeneous arrangement of the hard material body. After the first Joining the two frictionally connected components evaporates or volatilizes the matrix material, so that between the friction surfaces only the hard material body stay behind and the coefficient of friction of the frictional Increase connection.

at the use of liquid non-metallic matrices can the orientation of the hard body in a preferred orientation and / or a preferred distribution by the application of an electrical or magnetic field can be further optimized. Depending on the nature The hard material particles can do this directly by the influence of Fields happen, namely when magnetic or charged Particles are used which move themselves along the field lines can align. When using non-magnetic Hard material body may have such alignment by addition of additives, which themselves in magnetic or electrical Align the field and thus indirectly the alignment influence the hard body, be achieved.

It is also advantageous to use a matrix of a liquid medium, wherein the medium is solidified during assembly of the components, in particular frozen. In the simplest case, the use of water is possible in which the respective hard material bodies are suspended. During the joining process, this liquid matrix is frozen to frictionally position the same enable components in all positions.

Should The components are mounted while a liquid or gel-like matrix applied to at least one friction surface is, so a free orientation of the components can be ensured by that an edge region of the frictionally cooperating Surfaces of the components limited by an assembly tool so as to prevent leakage of the matrix. Of the same effect can be achieved by using components at which the edge regions of the frictionally cooperating Areas an increase, a bridge or the like exhibit.

The The invention further relates to an arrangement of two frictionally engaged connected components which via respective frictional interacting surfaces are connected, wherein between the surfaces of hard material body are arranged. In inventive embodiment of the arrangement These hard bodies include diamond, silicon carbide, silicon nitride, Tungsten carbide, boron nitride or similar ceramics, in particular consisting of one or more of said components. By the special hardness of the materials mentioned can already be one Initially described friction increase between the frictionally engaged interacting surfaces even with particularly high quality Materials of the components are achieved. In particular, this is the case an increase in friction also for components made of nitriding steels, To achieve tempering steels and the like.

In Another embodiment of the invention is provided that this Hard material body to form a Mikroformschlusses pressed into the two surfaces of the two components are. This is advantageously a microforming directly between the achieved without the mediation of the interaction by a metallic matrix, in particular a nickel matrix, necessary is.

In Another embodiment of such an arrangement is provided that at least one of the surfaces in an edge region a Elevation, a bridge or the like. This is the application of the hard body in a liquid Matrix allows by means of an initially described method.

in the Following is the invention and its embodiments will be explained in more detail with reference to the drawing.

in this connection demonstrate:

1 a schematic sectional view of a friction-increasing compound of two frictionally connected components, which was produced by a method according to the prior art, and

2A and B two steps of the assembly of two frictionally connected components, wherein an inventive method is used to increase the friction between the components.

1 shows a frictional connection of two components 10 and 12 where the friction between the friction surfaces 14 and 16 was increased using a conventional method. This was done on the friction surface 14 of the first component 10 chemically a nickel matrix 18 deposited, in which during the deposition sharp-edged hard body 20 , which are not all for the sake of clarity, have been embedded. When clamping the first component 10 with the second component 12 penetrate the hard body in the friction surface 16 of the second component 12 a, resulting in a microforming between the second component 12 and the one with the first component 10 connected nickel matrix 18 results. As a result, the coefficient of friction of the frictional connection between the components 10 and 12 clearly increased.

The application of the non-galvanically deposited nickel layer 18 however, it is a highly complex process. The surface 14 of the first component 10 must be elaborately pretreated before nickel plating. Among other things, after a mechanical pretreatment of the friction surface 14 These are freed from hydrophobic substances by thermal fats and then pickled sour or alkaline. As a rule, this is followed by another electrolytic degreasing step with subsequent pickling of the surface 14 on before the nickel matrix 18 can be applied. Such a method is not only technically complex, it also attract large amounts of waste products, which must be disposed of consuming to comply with environmental standards. Another disadvantage of the prior art method is also evident in 1 to recognize. The hard bodies 20 penetrate into the nickel matrix due to their embedment 18 only in the main body of the second component 12 one. Opposite the component 10 They are exclusively through the nickel matrix 18 Because of this, the maximum shear capacity is essentially due to the adhesion of the nickel matrix 18 on the surface 14 of the first component 10 is determined.

These problems do not occur in a method according to the invention, as in the 2A and B can be seen with reference to an embodiment. 2A shows a first component 10 ' before making the actual frictional connection. The friction surface 14 of the component 10 ' is to the edge with a jetty 22 limited. By doing from this jetty 22 surrounded area 24 becomes first a non-metallic matrix 26 with hard bodies 20 brought in. The matrix 26 is preferably kept liquid or gel, wherein the web 22 an outflow of the matrix 26 prevented. In the hard bodies 20 may be diamond particles, but also high performance ceramics such as silicon nitride, silicon carbide, tungsten carbide or the like. In the simplest embodiment of the invention is in matrix 26 around water, which involves a joining in all positions of the component 10 ' to allow, after application to the surface 14 can be frozen. In the frozen state of the matrix 26 can now, as in 2 B illustrated a second component 12 ' with the component 10 ' be tense. By heating or appropriate pressurization, the water of the matrix liquefies 26 again and gets out of the gap between the components 10 ' and 12 ' squeezed out or can evaporate or sublime. As a result, the hard body 20 both in the surface 14 of the component 10 ' as well as in the surface 16 of the component 12 ' pressed. The frictional force between the two surfaces 14 and 16 is therefore greatly increased by a microformure, which is mediated by the hard material body. Unlike in 1 As shown in the prior art embodiment of the microforming actually arises between the components 10 ' and 12 ' without mediating a metallic matrix, which on one of the surfaces 14 or 16 is applied. The maximum shear stress between the surfaces 14 and 16 is therefore in the 2 B shown much higher, since they are not affected by the adhesive force of a metallic matrix on one of the surfaces 14 or 16 is limited.

Is the positional orientation of the component 10 ' opposite the component 12 ' not important in the assembly, so can the freezing of the matrix 26 be waived. It is then also possible, for example, to use partially or completely organic solvents, which are even easier from the gap between the components 10 ' and 12 ' can evaporate. Alternatively, curing matrices can be used. Due to the contact pressure when joining the components 10 ' and 12 ' Excess matrix material is pressed through the gap between the components, and only the remaining between the components share can harden after the hard material already in the surfaces 14 and 16 have cut. This advantageously still an additional material connection between the surfaces is achieved.

For a uniform distribution or preferential orientation of the hard material body 20 in the matrix 26 To achieve, it is also possible to align them directly or indirectly by applying an electric or magnetic field. In the case of charged or ferromagnetic hard bodies 20 Such an orientation can be carried out immediately. The hard material bodies 20 itself then align themselves after creation of the appropriate field at the field lines. In the case of uncharged and non-ferromagnetic hard bodies 20 Such alignment can be achieved by incorporating appropriate charged or ferromagnetic additives into the matrix 26 be introduced. An example of such additives would be, inter alia, charged long-chain polymers which align in an external field under extension along the field lines and thus adjacent hard bodies 20 also arrange along these preferred directions. By such an optimized alignment of the hard body 20 In this case, particularly homogeneous surface pressures can be achieved, which reduces the wear of the components 10 ' and 12 ' further reduced.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 2364275 A1 [0003]

Claims (9)

Method for increasing the friction between frictionally connected components ( 10 ' . 12 ' ), in which between frictionally interacting surfaces ( 14 . 16 ) of the components ( 10 ' . 12 ' ) in these areas ( 14 . 16 ) insertable hard material body ( 20 ), characterized in that the hard material bodies ( 20 ) in a non-metallic matrix ( 26 ) are embedded. A method according to claim 1, characterized in that a volatile, drying or curing matrix ( 26 ) is used. Method according to claim 1 or 2, characterized in that a liquid matrix ( 26 ) is used, wherein the hard body ( 20 ) be aligned directly or indirectly with the aid of added additives by a magnetic or electric field in a preferred orientation and / or a preferred distribution. Method according to claim 1 or 2, characterized in that a liquid matrix ( 26 ), which during assembly of the components ( 10 ' . 12 ' ) is frozen. Method according to one of claims 1 to 4, characterized in that during assembly of the components ( 10 ' . 12 ' ) an edge region of the frictionally cooperating surfaces ( 14 . 16 ) is limited by an assembly tool. Method according to one of claims 1 to 4, characterized in that components ( 10 ' . 12 ' ), in which edge regions ( 22 ) of frictionally cooperating surfaces ( 14 . 16 ) have an elevation, a bridge or the like. Arrangement of two frictionally connected components ( 10 ' . 12 ' ), which via respective frictionally interacting surfaces ( 14 . 16 ), whereby between the surfaces ( 14 . 16 ) Hard material body ( 20 ), characterized in that the hard material bodies comprise at least one of the components diamond, silicon carbide, silicon nitride, tungsten carbide, boron nitride or the like ceramics. Arrangement according to claim 7, characterized in that the hard material body ( 20 ) to form a microformure in both surfaces ( 14 . 16 ) are pressed. Arrangement according to claim 7 or 8, characterized in that at least one of the surfaces ( 14 . 16 ) in a peripheral area ( 22 ) has an elevation, a web or the like.