EP1444421B1 - Method for the production of a valve seat - Google Patents

Abstract

This invention relates to a method for the production of a valve seat ( 5 ) for a cylinder head of an internal combustion engine. According to said method, an additional material is melted with the cylinder head by applying energy in the site in which the valve seat ( 5 ) is to be formed. An alloy or a mixture consisting of an aluminum-iron alloy and at least another component is used as additional material.

Description

The invention relates to a process for the preparation a valve seat for a cylinder head of an internal combustion engine according to the preamble of claims 1, 16, 23 and 29 more defined type. Furthermore, concerns the invention a valve seat assembly for a Cylinder head of an internal combustion engine.

DE 199 12 889 A1 describes a generic Method for producing a valve seat. there is an additional material, namely an alloy or a mixture of an aluminum-silicon alloy and Nickel, by a laser beam with the base material fused to the cylinder head.

From DE 35 17 077 C1 is a method for tanks the valve seat surface of a gas exchange valve known in which in a circumferential recess on the valve plate preferably of a nickel or cobalt base superalloy existing tank material introduced becomes.

A method of coating the surface of metallic Workpieces with a powder or wire shape present filler material is described in DE 199 12 894 A1.

Another such method is known from EP 00 92 683 B1 known. The base material of the cylinder head consists essentially of aluminum and as Additional material for the formation of the valve seat is either Iron or nickel or an alloy with a used as the main component of these two metals.

A disadvantage here is that iron and nickel are essential higher melting point than that of aluminum have existing cylinder head. This can cause that upon exposure to a laser beam the cylinder head may already have melted, though the filler first begins to melt. Furthermore It can happen that the previously liquid iron already is solidified while the aluminum is still as Melt is present. This leads to the formation of intermetallic Phases in the border region between iron and Aluminum material, which is a very brittle microstructure May have consequences. That's why it's difficult to get a homogeneous one Connection between the valve seat to be created and to reach the base material of the cylinder head, whereby here also the different surface tensions the materials play a big role.

A cylinder head made of an aluminum alloy describes EP 02 28 282 B1. The valve seats This cylinder head is made of a plated Copper alloy layer formed.

When using copper as the material for valve seats is, however, arises especially in diesel internal combustion engines the disadvantage that in the diesel fuel contained sulfur attacks the copper, causing Problems with exhaust gas development and corrosion arise. The use of copper for valve seats is therefore useful only for Otto internal combustion engines and therefore can not be done in an economic way be used.

DE 196 39 480 A1 discloses a process for internal coating of cylinder surfaces by means of powdery Additives alloyed by laser radiation will be described.

A method for surface treatment of light metal components, in particular of light metal pistons of Internal combustion engines, with a strength-increasing and / or wear-resistant filler material goes out of the DE 22 00 003 A1.

It is an object of the present invention, alternative Method for producing valve seats for the cylinder head to create an internal combustion engine.

According to the invention, this object is achieved in that as an additional material an alloy or a mixture of an aluminum-iron alloy and at least one another ingredient is used.

With appropriate design of the cylinder head acts it is in such an alloy to a to the base material of the cylinder head, which is often off an aluminum-silicon alloy consists of its own Alloy. This allows a very good metallurgical Connection without the formation of brittle intermetallic Phases at the interface between the coating or the additional material and the base material. This results in a low tendency to cracking. The iron content in the invention for the Additional alloy used advantageously increases the hardness of the same.

An alternative solution of the problem results from that as an additional material an alloy or a Mixture of aluminum and titanium is used.

Again, the above apply with respect to the Use of a species-specific alloy specified advantages for a low tendency to crack. The result is advantageously an intermetallic Titanium and aluminum phase, the advantages regarding hardness, wear resistance and temperature stability of this alloy.

Another alternative solution gives the task in that as an additional material an alloy or a mixture of an iron-carbon alloy and at least one other ingredient used becomes.

This composition is in principle based on proven Materials of valve seat rings mounted as separate parts, However, it can also by the inventive Melting process can be applied and has a high hardness and very good wear properties on.

Another alternative solution gives the task in that as an additional material an alloy or a mixture of a nickel-chromium alloy as well at least one further ingredient is used.

Such an alloy allows high temperature and wear resistance and has, if appropriate Selection of the other ingredient, very good tribological properties.

All of the solutions mentioned is common that the Connection of the valve seat with the cylinder head very durable and thus used extremely well in practice can be. Furthermore, carry the described Mixtures and alloys at a considerable Increase process reliability.

A valve seat assembly for a cylinder head of a Internal combustion engine is described in claim 46.

By the invention, the valve seats widening, annular areas that partially overlap, the areas exist between the actual ones Valve seats, the so-called valve webs, too from the higher quality material for the valve seats. This advantageously the susceptibility to cracking this valve webs and the associated area of the respective Combustion chamber of the cylinder head significantly reduced. This is a higher in this area thermal and mechanical stress on the cylinder head possible.

Advantageous embodiments and further developments of Invention will become apparent from the dependent claims and from the below with reference to the drawing in principle illustrated embodiments.

Fig. 1

ein in einem Zylinderkopf einer Brennkraftmaschine angeordnetes Ventil mit einem Ventilsitz;

Fig. 2

eine alternative Ausführungsform des Ventilsitzes in einer vergrößerten Darstellung;

Fig. 3

eine weitere alternative Ausführungsform des Ventilsitzes in einer vergrößerten Darstellung;

Fig. 4

eine weitere alternative Ausführungsform des Ventilsitzes in einer vergrößerten Darstellung;

Fig. 5

eine weitere alternative Ausführungsform des Ventilsitzes in einer vergrößerten Darstellung;

Fig. 6

eine weitere alternative Ausführungsform des Ventilsitzes in einer vergrößerten Darstellung;

Fig. 7

das erfindungsgemäße Verfahren als einstufiger Prozeß; und

Fig. 8

das erfindungsgemäße Verfahren als zweistufiger Prozeß.

It shows:

Fig. 1

a valve disposed in a cylinder head of an internal combustion engine with a valve seat;

Fig. 2

an alternative embodiment of the valve seat in an enlarged view;

Fig. 3

a further alternative embodiment of the valve seat in an enlarged view;

Fig. 4

a further alternative embodiment of the valve seat in an enlarged view;

Fig. 5

a further alternative embodiment of the valve seat in an enlarged view;

Fig. 6

a further alternative embodiment of the valve seat in an enlarged view;

Fig. 7

the inventive method as a single-stage process; and

Fig. 8

the inventive method as a two-stage process.

In Fig. 1, a part of a cylinder head 1 is a in their entirety not shown internal combustion engine shown. In known manner, the cylinder head 1 an inlet channel 2, which in the present Case, of course, also as outlet channel could be trained. The inlet channel 2 is through a gas exchange valve 3, in the following the simplicity half referred to as valve 3, closed or opened, so that a fuel / air mixture from the Inlet 2 into a combustion chamber 4 of the cylinder head 1 can occur.

The cylinder head 1 is provided with a valve seat 5, at which the valve 3 in its closed Condition is applied and so the inlet channel 2 of the Combustion chamber 4 separates.

FIGS. 2 to 6 show various embodiments the valve seat 5, wherein the method for producing the respective valve seat 5 at a later date with reference to the Figures 7 and 8 will be described.

The in a circumferential groove 6 of the cylinder head. 1 accommodated valve seat 5 of FIG. 2 has a Thickness of about d = 1 - 6 mm, is at that vertex, which is completely inside the cylinder head 1, provided with a radius r and the Angle α, the connecting surface of the valve seat. 5 with the cylinder head 1 with respect to the longitudinal axis of the Valve 3, is approximately α = 0 ° - 45 °. By the structure described, in particular by the said Thickness d, this results in a sufficient wear reserve for a possible post-processing, for example, in case of a required repair.

In Fig. 3 is another embodiment of the valve seat 5, which are similar to those according to FIG Fig. 2 is. In contrast to Fig. 2, however the angle α with respect to the longitudinal axis of the valve 3rd negative, i. the valve seat 5 has an undercut with an angle of approximately α = 2 - 15 ° opposite the groove 6 in the cylinder head 1, the one Keying of the coating or the valve seat 5 forms against falling out of the groove 6.

The thickness d of the valve seat 5 according to FIG. 4 is about d = 0.5 - 5 mm and the angle α in this case straight running connecting surface of the valve seat 5 with the cylinder head 1 with respect to the longitudinal axis of the Valve 3 is approximately α = 45 °, of course small deviations are possible.

In all embodiments according to FIGS. 2, 3 and 4 are opposite geometric space savings conventional seat ring geometries possible.

Another embodiment of the valve seat 5 show Figures 5 and 6, wherein here the valve seat 5 a much wider range than the ones described above Embodiments occupies. In other words, the valve seats 5 are around an annular area 5a extended. The individual areas 5a overlap partially so that the areas between the actual Valve seats 5, namely the so-called Valve bars, also from the higher quality material for the valve seats 5 exist. This leads to a considerable Reduction of the susceptibility to cracking of the valve webs and the associated area of the respective combustion chamber 4 of the cylinder head 1, so that in this area a higher thermal and mechanical load the cylinder head 1 is possible. The thickness d of the valve seat 5 is d = 1 - 10 mm.

In Fig. 7 and Fig. 8 are two different methods for the production of the valve seat 5 shown. On the base material of the cylinder head 1, for example a light metal alloy, e.g. an aluminum-silicon alloy, becomes an additional material 7 applied in the form of a powder. On the ingredients the additional material 7 will be at a later date discussed in more detail. Alternative to an aluminum-silicon alloy as the base material of the cylinder head 1 are of course other light metal alloys and optionally also cast iron or other alloys conceivable.

For applying the additional material 7 is in the area of the valve seat 5 to be formed, a nozzle 8 is arranged, which the additional material 7 in the direction of the cylinder head 1 outputs. When the additional material 7 on hits the cylinder head 1, so it is in the embodiment according to Fig. 7 process simultaneously from a laser beam 9 together with the outer layer of the base material of the cylinder head 1 melted to to produce a melt 10 on the cylinder head 1. Instead of the laser beam 9 is as an energy source as well the use of an electron beam, not shown possible to get out of the additional material 7 by Incorporation of energy to produce the melt 10.

In order to achieve a progressive process, the nozzle 8 and the laser beam 9 constantly in one Continued circular motion. When the laser or Electron beam 9 in the feed direction according to the arrow A has removed from the melt 10, this solidifies a layer 11 which forms the valve seat 5.

Fig. 8 shows an alternative method of manufacture the valve seat 5, wherein the additional material 7, for example in the form of a paste, a wire, a sintered body or a powder preform applied to the cylinder head 1 or in the groove. 6 introduced and then with the laser beam 9 or also with an electron beam to the melt 10th is melted. Here, too, arises again the melt 10 after removal of the laser beam 9 in Arrow direction A, the layer 11, the valve seat. 5 forms. This process is called a two-step process designated.

If the additional material 7 by absorbing energy even before hitting the surface of the cylinder head 1 heated or partially or completely is melted, so can the primary Energy source, ie the laser beam 9 or the electron beam, introduced energy can be reduced. Thereby, the base material of the cylinder head 1 only slightly melted, causing the occurrence brittle phases and cracking in the interface between the cylinder head 1 and the valve seat 5 is reduced becomes. In this way, you can also otherwise less suitable materials than filler material 7 use. This procedure is especially for the described above, two-stage process well suited.

In a manner not shown, in the region of the valve seat 5 may be provided a magnetic field, which the additional material 7 or from the additional material. 7 resulting melt 10 contoured and / or mixed, resulting in a more homogeneous distribution of the substances within the melt 10 leads. Furthermore, you can possibly in the melt 10 located in this way Outgas pores.

Both in the method of FIG. 7 and in the Process according to FIG. 8 can be used for the additional material 7 various mixtures and alloys used which are listed below:

As additional material 7, an alloy or a mixture of an aluminum-iron alloy as well be used at least one other ingredient. Here, the aluminum-iron alloy 6 - 13 % By weight of iron and 87-94% by weight of aluminum.

As a further alloying ingredient, the additional material 7 1 - 3% by weight vanadium and / or 1 - 3% by weight Silicon included.

Furthermore, it is conceivable that the additional material. 7 30-55% by weight of nickel and then optionally 3 - Contains 15% by weight of copper.

Alternatively, the additional material 7 5 - 20% by weight of nickel and then optionally 35-45 Weight% copper included.

By the use of nickel and copper arise Nickel-aluminum or copper-aluminum phases, which increase the hardness of the valve seat 5.

Another component of the additional material 7 can 0.2-1% magnesium by weight and 0.2-2% by weight Boron, titanium and / or scandium. This causes a finer formation of intermetallic phases and an improved homogeneity of the structure.

Optionally, it is also conceivable that the additional material Contains 7 hard material components, which from a compound of a metal with carbon, Oxygen or nitrogen exist. Such hard materials increase the wear resistance of the valve seat 5 considerably.

Optionally, the hard material components can homogeneously over the volume of the valve seat 5 be distributed or it is possible that the hard material components inhomogeneous over the volume of the valve seat 5 are distributed, wherein the content of the hard material components from the cylinder head 1 increase toward the surface of the valve seat 5. The latter alternative, ie a so-called Gradient layer, leads to an increasing Concentration of hard constituents to the surface of the valve seat 5, whereby the hardness and thus the wear characteristics of the valve seat. 5 increase. At the same time, however, this is the susceptibility to cracking in the connection zone, ie at the connection surface the valve seat 5 with the cylinder head 1, reduced.

That for the hard material components regarding the advantages The same applies to the components of nickel and copper, on the one hand homogeneous over the volume the valve seat 5 or on the other hand inhomogeneous over the volume of the valve seat 5 can be distributed, wherein the content of the components of nickel and copper from the cylinder head 1 to the surface of the valve seat 5 increase.

Alternatively to the version with an aluminum-iron alloy or a mixture of these metals can also be an alloy or a filler 7 Mixture of aluminum and titanium are used. In In this case, the additional material 7, for example 30-40% by weight of aluminum and 60-70% by weight Titanium included. Alternatively, it may also be provided be that the additional material 7 13 - 17% by weight Aluminum and 83-87% by weight of titanium.

The additional material 7 can in this case at least contain another component, namely 0.5 - 5 Weight% or 17-50% by weight of niobium, resulting in reduction the embrittlement tendency very well suited is. It is also possible that the additional material 7 0.5 - 5% by weight chromium, vanadium, manganese, molybdenum and / or tantalum.

A third possibility for the formation of the additional material 7 may be that for the same an alloy or a mixture of an iron-carbon alloy and at least one other ingredient is used.

As a further component can in this embodiment of the process 0.5 to 4% by weight nickel and / or 0.5-4% by weight of chromium and / or 0.5-4% by weight Manganese and / or 5 - 15% by weight molybdenum and / or Contains cobalt. By the use of nickel and / or chromium can form carbides that reduce the hardness of the valve seat 5 increase. Furthermore, in this Be provided context that the additional material 7 contains 10 to 25% by weight of copper. Cobalt, copper and molybdenum improve lubricating properties, Copper's thermal conductivity.

A fourth way to carry out the process is that as additional material 7 an alloy or a mixture of a nickel-chromium alloy and used at least one other ingredient is then, in which case the nickel-chromium alloy 10-30 Containing% by weight of chromium and 70-90% by weight of nickel can.

For this embodiment, as a further alloying ingredient 3 - 5% by weight of silicon used become. Other possible alloying components exist in 3 - 5% by weight of boron and in 3 - 5% by weight Iron.

Optionally, in the additional material 7 10 - 40 Be contained by weight% molybdenum. Furthermore, it is it is possible that the additional material 7 5 - 10% by weight Contains copper and / or cobalt. It is also possible that the additional material 7 5 - 12% by weight aluminum and 0.1-2% by weight of carbon and / or yttrium contains.

Claims (15)

1. Method of producing a valve seat for a cylinder head of an internal combustion engine, whereby an additional material is melted onto the cylinder head at the point at which the valve seat is to be formed by applying energy,
   characterised in that
   an alloy or a mixture of aluminium and titanium is used as the additional material (7), which additional material (7) contains 30 - 40 % by weight of aluminium and 60 - 70 % by weight of titanium.
2. Method of producing a valve seat for a cylinder head of an internal combustion engine, whereby an additional material is melted onto the cylinder head at the point at which the valve seat is to be formed by applying energy,
   characterised in that
   an alloy or a mixture of aluminium and titanium is used as the additional material (7), which additional material (7) contains 13 - 17 % by weight of aluminium and 83 - 87 % by weight of titanium.
3. Method as claimed in claim 1 or 2,
   characterised in that
   the additional material (7) contains at least one other component.
4. Method as claimed in claim 3,
   characterised in that
   0.5 - 5 % by weight of niobium is used as the other component.
5. Method as claimed in claim 3,
   characterised in that
   17 - 50 % by weight of niobium is used as the other component.
6. Method as claimed in one of claims 3 to 5,
   characterised in that
   the additional material (7) contains 0.5 - 5 % by weight of chromium, vanadium, manganese, molybdenum and/or tantalum.
7. Method as claimed in one of claims 1 to 6,
   characterised in that
   the additional material (7) is melted onto the cylinder head (1) by means of a laser beam (9).
8. Method as claimed in one of claims 1 to 7,
   characterised in that
   the additional material (7) is melted onto the cylinder head (1) by means of an electron beam.
9. Method as claimed in one of claims 1 to 8,
   characterised in that
   a magnetic field is generated in the area of the valve seat (5) which contours and/or mixes the additional material (7) or the melt (10) produced from the additional material (7).
10. Method as claimed in one of claims 1 to 9,
    characterised in that
    the additional material (7) is applied to the cylinder head (1) at the same time as the energy is applied.
11. Method as claimed in one of claims 1 to 10,
    characterised in that
    the additional material (7) is applied to the cylinder head (1) in powdered form.
12. Method as claimed in one of claims 1 to 11,
    characterised in that
    the additional material (7) is applied to the cylinder head (1) by means of a nozzle (8).
13. Method as claimed in one of claims 1 to 12,
    characterised in that
    the additional material (7) is applied to the cylinder head (1) and then melted onto the cylinder head (1) by applying energy.
14. Method as claimed in claim 13,
    characterised in that
    the additional material (7) is applied to the cylinder head (1) in powdered form.
15. Valve seat arrangement for a cylinder head of an internal combustion engine, comprising several valve seats (5) produced using the method as claimed in one of claims 1 to 14 from the additional material (7), each of which valve seats (5) is made wider by an annular region (5a) also made from the additional material (7) so that the individual annular regions (5a) at least partially overlap.

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