DE10225461A1 - High temperature-proof sealing component involves taking section from spring with wire of high heat-proof refined steel with elasticity module at 300 degrees Celsius of over 90000 N-mm2 - Google Patents

Abstract

The high temperature-proof sealing component involves taking a section from a spring with wire of high heat-proof refined steel with an elasticity module at 300 degrees Celsius of over 90000 N/mm2>. The removed section is transformed into an arc shape, a sealing ring (1) or similar. The wire section removal can be by spark erosion or with smaller wire diameters by laser. In the area of the ring gap (3) there is a burr-free abutment. The refined steel used is a nickel-based alloy, the nickel content being preferably over 40 per cent by weight.

Description

The present invention relates to a sealing element and a method for its production.

Annular sealing elements metallic materials, e.g. Piston rings are known per se. They are usually in a ring shape Recess or groove added, which e.g. around an outer circumference a piston is arranged. The piston is in one Cylinder can be moved back and forth. The piston compresses fluids such as e.g. inflammatory Gases in the cylinder when ignited the fluid becomes the piston pushed away from the ignition point. The The piston ring is exposed to very high temperatures, e.g. it can get warmer than 300 ° C with a direct injection gasoline engine.

However, high temperature resistance also in other, also ring-shaped, Sealing systems required. For example, also with sealing rings for exhaust gas recirculation valves high temperatures at which e.g. known elastomer seals are not satisfactorily applicable.

The present invention lies hence the task of a high temperature resistant sealing element or to provide a method for its production, wherein the sealing element is manufactured in a simple and inexpensive manner with high precision can be.

This task is followed by a procedure Claim 1 and a sealing element according to claim 10 solved.

Characterized in that in the method for producing a high-temperature-resistant sealing element from a wire coil with wire from a high-temperature stainless steel with an elasticity module at 300 ° C of more than 90,000 Newtons per m ² . Sections are separated and formed in the form of an arc, a ring or the like, a very inexpensive manufacture of a sealing element is possible.

It should be emphasized that under "wire helix" each any form of wire winding is to be understood. This term is by no means spiral tortuous circular cylindrical shapes limited, they are also square or oval winding forms possible with the wire helix. Particularly advantageous it is (in the sense of a reduced forming effort and thus too an even faster and cheaper production) that the separated Section in its flat projection the shape of the later sealing element (e.g. with a spiral circular cylindrical winding on the wire coil only a "flat forming" is necessary to to get a sealing ring). But of course it is too possible, the separated section first again (in addition to the flat molding) before the final shape of the sealing element is obtained.

It has been found that the modulus of elasticity of the heat-resistant stainless steel is expressive as an essential feature of the high temperature resistance. For the applications desired here, a modulus of elasticity of over 90,000 Newtons per mm ² at a temperature of 300 ° C is a prerequisite for the seal to function properly at high temperatures.

Advantageous further training as well Uses of the present invention are specified in the further claims.

An advantageous development of the The procedure provides that as high-temperature stainless steel a stainless steel made of a nickel-based alloy is used. According to the invention as a nickel-based alloy understood in the present invention when nickel is the largest by weight on the alloy, preferably over 40% by weight of the total alloy.

A particularly advantageous development of the method provides that the nickel-based alloy is Nimonic 90 (2.4632), Inconel X 600, Inconel X 750 (2.4669), stainless steel ( 1 .4980), Duratherm 600 or the like is used. These are commercially available nickel-based alloys which have high-temperature strength according to the invention with good formability properties.

A particularly advantageous development sees before that Separation of the sections from the wire coil by spark erosion (Electroerosion) or laser happens. This is a burr-free separation possible, so that post-processing is no longer necessary. lasers is particularly suitable for the separation of small wire cross-sections, so that Detach quickly and in a clean way. However, are conceivable also mechanical separation processes, e.g. the water jet separation or usual cutting processes, such as saws Etc.

The method according to the invention is preferred on wires with a diameter between 1 and 10 mm, preferably 1.2 mm applicable up to 3 mm. Round wire cross-sections are special here easily available. However, any other cross sections, e.g. Rectangular cross sections, at the output wire possible. The cross-sectional area these other cross-sectional shapes correspond in their preferred Cross-sectional area of round wires between 1 and 10 mm in diameter.

A particularly advantageous development provides that an impact of the later sealing element is already taken into account in the separation. So can be done, for example, by targeted cutting (e.g. by spark erosion or lasers) so that, for example, a straight joint, an oblique joint or an overlap joint is created in the event of a sealing ring that is formed later. The separation methods that are particularly preferred here (also spark erosion or lasers) allow shocks with a quality within the tolerance ranges that are later ready for installation.

Another advantageous training of the manufacturing method according to the invention stipulates that the severed section after severing from the wire coil flat is formed. For wire coils on which the wire has an incline is a flat molding (e.g. to preserve a flat, simply slotted ring) is required. For this finds a heat treatment after separation of the severed section instead of being flat-formed Section. This heat treatment is that Material about a time between 1 and 8 hours at a temperature between 600 and 1200 ° C is held at NIMONIC 90 750 ° C for 4 hours with a later one Air cooling. A heat treatment is also used to create the desired spring properties necessary. This consists of a one-step or multi-step process with temperatures per level between 500 ° C and 1200 ° C, which are between 2 and 24 Held for hours per level; after each stage is a cooling phase, e.g. by flash cooling in oil or through air cooling possible. But it is also possible that the heat treatment for the treatment of spring properties simultaneously with the warming (to shape the section flat) or in a later step).

After severing the section, preferably also after the heat treatment the sealing element is subjected to further manufacturing steps, e.g. area-by-area flattening (with a round cross-section of the output wire). Possible are also other surface treatment processes, e.g. a lapping from touch surfaces to a cylinder in order to minimize friction an ideal round shape, preferably light gap tightness> = 90%).

A particularly advantageous development of the sealing ring according to the invention provides that at the end of the manufacturing process it has a modulus of elasticity between 150,000 N / mm ² and 250,000 N / mm ² at room temperature (= 20 ° C.).

A central advantage of the sealing element according to the invention is the temperature resistance, which a permanent load in the application range up to 800 ° C enables.

As a use for sealing elements according to the invention comes e.g. the use as a piston ring for explosion engines. A particularly advantageous application results as a sealing ring for rotary flaps. Here, the outer circumference of the preferably circular rotary flap with a circumferential groove or provided a circumferential web in which a sealing ring is fixed becomes. Depending on the position of the rotary flap, a pipe, e.g. an exhaust pipe, open or closed. This is particularly evident as an advantage of the present Invention that at small diameters (the diameter of the sealing ring can go down to 40 mm outer circumference, preferably down to an outer circumference of 25 mm) economical can be produced, and a temperature stability up to 800 ° C having.

Advantageous further developments of present invention are specified in the remaining claims.

The present invention will now explained using several figures. Show it:

• 1 a wire coil according to the invention,
• 2a to 2c several views or sections of a sealing ring according to the invention, and
• 3 several types of impact in a sealing element according to the invention.

1 shows as a starting component for the production of high temperature resistant sealing elements a wire coil 2 , This has an outer diameter D, which is in the range between 25 mm and 200 mm. The wire helix has the shape of a spirally wound circular cylindrical winding. The winding consists of a high-temperature stainless steel with a modulus of elasticity at 300 ° C of over 90000 N / mm ² . This is, for example, a nickel-based alloy, for example made of a material that is commercially available under the brand name "Nimonic 90 " (2.4632) is available. Of course, all of the other alloys specified above can also be used. The wire has a circular cross section and a diameter of d = 1.5 mm. Depending on the cross-sectional shape of the later sealing element, other cross-sections can also be selected.

Regarding possible other forms of wire helix other diameter or cross-sectional areas of the wire is on the Reference introduction referenced.

Sections are then separated from the wire helix. These are further shaped in the further process to form an arc or a flat ring. It is particularly advantageous that the diameter of a later sealing ring to limit the diameter of the here in order to limit the uniform effort 1 shown wire coil 2 is voted.

The separation of the sections from the wire helix (which can have any shape, even the shape of a straight wire) can be done with smaller methods such as spark erosion Wire diameters happen by laser. This will in the area of the gap 3 (please refer 2 ) a burr-free impact is achieved.

The following is a closer look at the in 2a to 2c seal ring shown. However, this shape is in no way intended to limit the invention; there are any other sealing elements (different cross sections of the wire and different geometric shapes in plan view than that in FIG 2 B shown circle, eg ovals etc.) possible.

2a shows a plan view of a sealing element in the form of a sealing ring 1 , This shows a straight joint 3 on (see also 3 . a )). The in 2a The ring shown was obtained by removing a section from the wire helix 1 the section was subjected to heat treatment to flatten this section. It was then subjected to a further heat treatment to produce the desired spring properties of the sealing ring 1 (see the introduction to the description above for details).

2 B shows that the former circular wire was flattened by a grinding process, the top and bottom. On the left and right side that was in 2c Retain cross-sectional image with arc-shaped sections shown enlarged again as details X.

Depending on the tightness requirement for the joint, different embodiments of the joint are possible. This shows 3 various possibilities. The possibility according to a) is in 2a realized. According to b), a straight joint with a groove for a retaining pin, according to c) an oblique joint and after d) an overlap joint can also be provided. It is particularly advantageous here that these forms of bumps can already be implemented without burrs during the separation process from the wire helix.

In its final form (ie after the heat treatment processes and further processing steps), the present ring has a modulus of elasticity between 150,000 N / mm ² and 250,000 N / mm ² at 20 ° C. This sealing ring is particularly possible as a gas-tight seal for, for example, rotary flaps in exhaust gas recirculation valves, which can be exposed to temperature loads of up to 800 ° C. in the long term. It is particularly noteworthy here that light-gap-tight rings, even of small diameters, can be produced inexpensively with high precision using the method according to the invention.

Claims (13)

Method for producing a high-temperature-resistant sealing element, whereby a wire coil ( 2 ) with wire made of a heat-resistant stainless steel, whose modulus of elasticity at 300 ° C is more than 90000 N / mm ² , sections separated and in the form of an arch, a ring ( 1 ) or the like. A method according to claim 1, characterized in that the highly heat-resistant Stainless steel is a nickel-based alloy, with nickel the largest proportion by weight on the alloy, preferably over 40% by weight. A method according to claim 2, characterized in that the nickel-based alloy Nimonic 90 (2.4632), Inconel X 600, Inconel X 750 (2.4669), stainless steel ( 1 .4980), Duratherm 600 or the like. Method according to one of the preceding claims, characterized characterized that the Separation by spark erosion or laser happens. Method according to one of the preceding claims, characterized characterized in that the Output wire on the wire coil a diameter (d) between 1 and 10 mm. Method according to one of the preceding claims, characterized in that the separation takes place in such a way that the sealing element which arises forms a straight joint ( 2 B ), has an oblique joint or an overlap joint. Method according to one of the preceding claims, characterized in that after the section has been severed in a separate method step, a flat sealing ring ( 1 ) is formed. A method according to claim 6, characterized in that according to the Detach the section and form a flat ring on it Ring is partially flattened and / or ground. Method according to one of the preceding claims, characterized characterized that after separating a heat treatment of the separated section takes place for the flat shaping of the section and / or to generate desired ones Spring properties. Sealing element, manufactured by a method according to claims 1 to 9. Sealing element, consisting of a heat-resistant stainless steel, the elasticity modulus at 300 ° C is more than 90000 N / mm ² . Sealing element according to claim 11, characterized in that it has a modulus of elasticity between at room temperature between 150,000 N / mm ² and 250,000 N / mm ² . Use of a sealing element according to one of claims 9 to 12, characterized in that this is used as a piston ring or as a sealing ring for rotary flaps.