Pipeline element with friction-reducing layer
阅读说明:本技术 带有减小摩擦的层的管路元件 (Pipeline element with friction-reducing layer ) 是由 D.鲍姆霍夫 M.亨克尔曼 O.D.泽尔特 A.格哈德 S.豪克 K-H.明克 K.申克 于 2019-01-29 设计创作,主要内容包括:本发明涉及一种管路元件(100),该管路元件带有内部元件(IE)、包围内部元件的外部元件(AE)、和呈滑动漆形式的滑动层(131,132),该滑动层在接触区域中布置在内部元件(IE)上和/或布置在外部元件(AE)上。(The invention relates to a line element (100) having an Inner Element (IE), an outer element (AE) surrounding the inner element, and a sliding layer (131,132) in the form of a sliding varnish, which is arranged on the Inner Element (IE) and/or on the outer element (AE) in the region of contact.)
1. A pipe element (100) for exhaust gas pipes and the like, said pipe element comprising:
-an internal element (IE, 120);
-an outer element (AE,110) surrounding and at least partially contacting the inner element;
-a sliding layer (131,132) comprising a temperature-resistant sliding lacquer, which is arranged on the Inner Element (IE) and/or on the outer element (AE) in the contact area.
2. A pipe element (100) according to claim 1, wherein the slip varnish (131,132) is liquid before or during processing, adheres at the surface of the inner or outer element and hardens there.
3. Pipe element (100) according to at least one of the preceding claims, characterized in that the sliding layer (131,132) comprises or consists of at least one of the following materials: PTFE, molybdenum disulfide (MoS)2) Chromium nitride (CrN), titanium dioxide (TiO)2) Graphite, zinc sulfide, (metallo) phosphate, aluminum, alumina, boron nitride, silane, silicon dioxide, tungsten disulfide (WS)2) Aramid fibers, glass beads, carbon fibers, glass spheres, polymer composites, polyamide resins (PAI resins), epoxy resins (PEEK), polyvinyl butyral resins, polyolefins; preferably, other organic and/or inorganic binders, solvents, and/or additives are combined.
4. Pipeline element (100) according to at least one of the preceding claims, wherein the thickness of the sliding layer (131,132) is less than 30% of the wall thickness of the Inner Element (IE) or the outer element (AE) in which the sliding layer is located.
5. The line element (100) according to at least one of the preceding claims, characterized in that a sliding layer (131) is arranged on the Inner Element (IE) and a sliding layer (132) is arranged on the outer element (AE).
6. The line element (100) according to at least one of the preceding claims, characterized in that the sliding layer (131,132) is applied onto a completely manufactured Inner Element (IE) and/or outer element (AE).
7. The line element (100) according to at least one of the preceding claims, characterized in that the Inner Element (IE) and/or the outer element (AE) have a non-circular cross section, preferably an elliptical or polygonal cross section, at least in an axial section of the line element.
8. Method for manufacturing a line element (100) according to at least one of the preceding claims, comprising the steps of:
-winding a strip of metal into a wound hose (120) of the Inner Element (IE);
-providing an external element (AE);
-coating the outside of the coiled hose (120) with a sliding layer (131) and/or the inside of the outer element (AE) with a sliding layer (132);
-arranging the Inner Element (IE) in the outer element (AE).
Technical Field
The invention relates to a line element with an inner element and an outer element which are arranged concentrically with respect to one another. Preferably, such a line element is installed in the exhaust gas line in a motor vehicle and flexibly connects rigid line units to one another.
Background
Vibrations are generated in the exhaust gas system of a motor vehicle, which are caused, for example, by an imbalance of the rotating elements in the engine, the turbocharger or in the auxiliary group, by a pulse-like pressure profile of the internal combustion engine or by a driving movement in combination with roadway irregularities and their feedback into the vehicle frame. In this connection, the line element (which is also referred to as decoupling element) has the task of decoupling such vibrations and movements in the exhaust system from the motor vehicle. Furthermore, the line element balances possible installation tolerances.
DE 202015104177U 1 discloses a line element of various embodiments, which comprises a tubular inner element and a tubular outer element, wherein at least one of the tubes is generally gas-tight. Furthermore, WO 2017/016728 a1 discloses a line element in which damping is achieved by the contact of an inner element and an outer element, wherein a friction layer acts in the contact region of the inner element and the outer element to reduce wear. The documents mentioned are fully incorporated by reference into this application.
Disclosure of Invention
In view of this, the task of the invention is: an alternative design of a line element with good operating properties in the case of a long service life is provided, which can be produced in a simple manner.
According to the invention, this object is achieved by a line element according to claim 1 and a method according to claim 9. Advantageous developments are contained in the dependent claims.
The line element according to the invention for exhaust gas lines and the like comprises the following components:
-a hose-like inner element.
A hose-like outer element which surrounds the inner element and (during operation) at least partially contacts the inner element.
A sliding layer, which is arranged on the inner element, or on the outer element, or on both the inner element and the outer element in the contact region of the inner element and the outer element, and which contains or consists of a temperature-resistant sliding varnish.
Preferably, the inner and/or outer elements are in contact with one another in a punctiform, linear, partial surface or overall manner. In this case, the contact is present in particular during the use of the line element, i.e. for example during vibration decoupling between the engine block and the exhaust system. However, the contact is usually permanent, that is to say even during the stationary phase of the line element.
The sliding layer serves to reduce frictional and vibrational wear and is characterized in that it has a lower coefficient of sliding friction than the material of the inner or outer element in which it is located, relative to the material of the opposite element. The sliding layer applied on the outside of the inner element therefore has a lower sliding friction coefficient with respect to the material of the outer element than the inner element. With respect to stainless steel as the friction pair, the sliding friction coefficient of the sliding layer is preferably less than about 0.1, less than 0.08, less than 0.06, or less than 0.02. Here, as is usual, the coefficient of sliding friction μ is defined as the ratio of the sliding friction force FR to the normal force FN by which the friction pair is pressed against each other.
Further optional technical features of the sliding layer are: the sliding layer is stable in the high temperature range between 400 ℃ and 800 ℃, but is also resistant in the low temperature range, preferably between 0 ℃ and-50 ℃. Furthermore, the sliding layer is advantageously at Pabs=0 bar and Pabs=PatmUnder vacuum or negative pressure and/or at a pressure up to PabsOver pressure range of =200 bar is stable. Furthermore, the sliding layer is preferably relatively flammable and is resistant to more easily ionized beams. In contrast to sliding agents or lubricants in liquid or paste form, no creep processes occur in the sliding layer, and the application site and its environment preferably have no dirt due to dust particles. The friction-reducing properties are advantageously combined with an extremely high load capacity of 0.1N/mm to 750N/mm.
According to the invention, the sliding layer comprises a temperature-resistant sliding lacquer. This type of temperature resistance depends on the intended use of the line element. In conjunction with the exhaust gas line, the sliding layer should preferably withstand temperatures of more than 400 ℃, more than 600 ℃ or particularly preferably more than 800 ℃. Furthermore, a "slip coat" is understood to mean a material which is liquid before or during processing, adheres to the surface of the inner or outer element and hardens there (for example by chemical crosslinking) (aush ä rten, sometimes referred to as curing). The hardening can be carried out at room temperature or preferably at a temperature between 30 and 150 degrees celsius or between 150 and 500 degrees celsius. After hardening, the sliding paint should adhere to the bottom with sufficient wear resistance and have the desired friction-reducing surface.
The sliding layer (sliding paint) can in particular comprise or consist of at least one of the following materials: solid lubricant, matrix material, solvent, binder and additive. These materials are exemplified, but not exhaustive in their list:
PTFE; molybdenum disulfide (MoS)2) Chromium nitride (CrN), titanium dioxide (TiO)2) Graphite, zinc sulphide, (metallo) phosphates, aluminium oxide, boron nitride (Bornitid), Silane (Silane), silicon dioxide, tungsten disulphide (WS)2) Aramid fibers, glass beads, carbon fibers, glass spheres, polymer composites, polyamide resins (PAI resins), epoxy resins (PEEK), polyvinyl butyral resins, polyolefins. Particularly preferred additives (solid lubricants) are boron nitride and molybdenum disulfide.
Additives for improving the sliding layer with respect to hydrophobic and/or dirt-repellent properties, corrosion resistance, UV resistance, and also the hardening duration and hardening temperature, the total hardness, elasticity or resistance to oils, greases, solvents, for example butyl glycol acetate (butyl glycollate), ethylene glycol acetate (ethyl glycollate).
The solvent used here depends on the respective type of application and has no influence on the properties of the subsequently hardened coating.
The particle size of the solid lubricant can be measured by means of scattered light methods in a manner known to the person skilled in the art.
The fiber length used has an average fiber length of less than 1000 microns, preferably less than 600 microns. The average fiber thickness is less than 550 microns, preferably less than 50 microns.
Typically, the sliding layer is used only for the purpose of designing the surface of the inner element and/or the outer element to be friction-reducing, while the sliding layer does not bear the structure of the line element. Accordingly, the sliding layer preferably has a relatively small thickness, which is dimensioned, for example, according to: no wear-out of the sliding layer occurs during the service life of the line element (Durchrieb). For example, the thickness of the sliding layer can be less than 50% of the thickness of the inner or outer element (depending on the orientation in which the sliding layer is located), preferably less than 20%, less than 10%, or less than 5%. The thickness of the sliding layer is typically less than 150 μm, preferably less than 50 μm, or less than 10 μm in absolute value.
As already mentioned, it is possible to provide the sliding layer not only at the inner face of the outer element but also at the outer face of the inner element, so that the sliding layer rubs on the sliding layer in the contact region between the inner element and the outer element. This enables a particularly large reduction in friction. The sliding layer on the inner element and on the outer element can consist of the same material (for example the same sliding varnish) or of different materials.
Advantageously, the sliding layer is applied to the inner or outer element only after the inner or outer element has been finished or manufactured and in particular brought to its final shape.
According to a further development of the invention, the inner and/or outer element can have a non-circular cross section at least in an axial section of the line element. In particular, the inner element and/or the outer element can have an elliptical or polygonal, multi-radius cross section, wherein the corners are typically chamfered. Furthermore, non-circular inner/outer elements are often combined with circular outer/inner elements. By virtue of the non-circularity, a point contact, a line contact or a surface contact can be established in a simple manner.
The outer element and/or in particular the inner element is preferably a coiled hose, in particular a metal coiled hose. Such winding hoses are known in various embodiments (single-layer, multilayer, buckle-shaped (agrafff ribbon), with inner (Innenschuppe) and/or outer (outer) scales, etc.). A typical embodiment is described, for example, in DE 202015104177U 1.
Furthermore, the inner element and/or in particular the outer element of the line element can be designed as a corrugated bellows, a coil bellows or a diaphragm bellows. Corrugated bellows are typically made from one tube by an internal high-pressure modification in conjunction with a compression operation, while the wound bellows and the diaphragm bellows are welded, rotationally symmetrical or helically corrugated elements in the profile region, which elements either have a pronounced wave perpendicular to the axis of rotation or have a helical wave. The coiled bellows structure can preferably be hooked into or snapped into or welded together in a form-fitting manner. Such elements are described, for example, in DE 102008001297B 1 or DE 102011053131 a 1.
Furthermore, the outer element and/or the inner element can comprise or consist of at least one of the following materials: stainless steel, zinc, aluminum alloys, copper, titanium, tantalum, nickel based alloys, brass, and/or bronze.
The invention further relates to a method for producing a line element according to one of the above-described embodiments. Here, the method comprises the steps of:
a) the metal strip is wound into a wound hose which forms the internal element.
b) An external element, such as a diaphragm bellows, is provided.
c) The outer side of the (at least) wound hose mentioned is coated with a sliding layer and/or the inner side of the (at least) outer element mentioned is coated with a sliding layer, wherein the coating is applied over the entire surface or/and partially over the surface.
d) The inner element is coaxially arranged within the outer element.
The coating of step c) can be carried out at any point in time before, after or during the other steps a), b), d).
When the sliding layer is applied to the finished inner or outer element, it is advantageously not loaded by its production process (strip reforming, winding, etc.) and therefore there is no damage in the finished line element. Furthermore, by means of the method, the sliding layer can be limited to functionally relevant contact areas, which limits the material consumption to the required extent.
Drawings
The invention is explained in detail below by way of example with the aid of the figures. In the drawings:
fig. 1 shows a longitudinal section through a coiled hose with a sliding layer in the contact region;
FIG. 2 shows a sectional view of a wall section of a piping element with a coiled hose according to FIG. 1 as an inner element and a diaphragm bellows with a sliding layer as an outer element;
fig. 3 shows a sectional view of the line element according to fig. 2 on a smaller scale.
Detailed Description
Fig. 1 shows a longitudinal section of the coiled part of a metal coiled
The wrap-around
The application of the sliding layer can be carried out before the shaping and/or winding of the strip, in full or in part, and on one or both sides. Preferably, the sliding
The sliding
The thickness of the sliding
Fig. 2 shows a sectional view of the wall of a
As shown in the figure, the outer element AE can likewise carry a sliding
In an alternative embodiment, it is also possible to provide only the sliding
Fig. 3 shows a sectional view of the
However, an embodiment is particularly preferred in which the inner element IE has a non-circular cross-section, in particular an elliptical cross-section. Further details of this embodiment are known from DE 102015102258 a1 or WO 2017/016728 a 1.
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