ZA200501296B

ZA200501296B - Method of preparing iron-based components by compaction with elevated pressures

Info

Publication number: ZA200501296B
Application number: ZA200501296A
Authority: ZA
Inventors: Kejzelman Mikhail; Skoglund Paul; Vidarsson Hilmar
Original assignee: Ganos Ab H
Priority date: 2002-10-22
Filing date: 2003-10-22
Publication date: 2006-10-25
Also published as: KR20050059285A; RU2005115474A; WO2004037468A1; EP1554071B1; TW200417433A; KR101179725B1; PL208668B1; TWI415698B; RU2333075C2; BR0314079B1; JP2010189769A; JP4909514B2; CN1705533A; DE60335280D1; JP2006503983A; ES2357741T3; CN1705533B; KR20110114689A; CA2495697C; PL375094A1

Abstract

The present invention concerns a process for the preparation of high density green compacts comprising the steps of providing an iron-based powder essentially free from fine particles; optionally mixing said powder with graphite and other additives; uniaxially compacting the powder in a die at a compaction pressure of at least about 800 MPa and ejecting the green body. The invention also concerns the powder used in the method.

Description

Method of preparing iron-based components by compaction with elevated pressures.

FIELD OF THE INVENTION

The present invention relates to metal powder compositions useful within the powder metal- lurgical industry. More specifically the invention concerns a method for the preparation of components having high density by using these compositions.

There are several advantages by using powder metallurgical methods for producing structural parts compared with conventional matching processes of full dense steel. Thus, the energy consumption is much lower and the material utilisation is much higher. Another important factor in favour of the powder metallurgical route is that components with net shape or near net shape can be produced directly after the sintering process without costly shaping proc- esses such as turning, milling, boring or grinding. However, normally a full dense steel mate- rial has superior mechanical properties compared with PM components. This is mainly due to the occurrence of porosity in the PM components. Therefore, the strive has been to increase the density of PM components in order to reach values as close as possible to the density value of a full dense steel.

Among the methods used in order to reach higher density of PM components the powder forging process has the advantage that full dense components may be obtained. The process is however costly and is utilised mainly for mass production of heavier components, such as connection rods. Full dense materials can also be obtained by elevated pressures at high tem- peratures, such as in hot isostatic pressing, HIP, but also this method is costly.

By using warm compaction, a process where the compaction is performed at an elevated tem- perature, typically at 120 to 250 °C, the density can be increased with about 0,2 g/cm’, which results in a considerable improvement of the mechanical properties. A disadvantage is how- ever that the warm compaction method involves additional investment and processing. Other processes, such as double pressing, double sintering, sintering at elevated temperatures etc, may further increase the density. Also these methods will add further production costs hence reducing the overall cost effectiveness.

In order to expand the market for powder metallurgical components and utilise the advantages with the powder metallurgical technique there is thus a need for a simple, less expensive method of achieving high density compacts with improved static and dynamic mechanical strength.

SUMMARY OF THE INVENTION

It has now been found that high density components can be obtained by using high compac- tion pressures in combination with coarse powders. In view of the general knowledge, that conventionally used powders, i.e. powders including fine particles, cannot be compacted to high densities without problems with e.g. damaged or deteriorated surfaces of the compacts this finding is quite unexpected. Specifically, the method according to the present invention includes the steps of providing an iron-based powder essentially free from fine particles; op- tionally mixing said powder with graphite and other additives; uniaxially compacting the powder in a dic at high pressure and ejecting the green body, which may subsequently be sin- tered.

DETAILED DESCRIPTION OF THE INVENTION

The term “ high density” is intended to mean compacts having a density of about at least 7.3 g/cm’. Components having lower densities can of course also be produced but are believed to be of less interest.

The iron-based powder according to the present invention includes pure iron powder such as atomised iron powder, sponge iron powder, reduced iron powder; partially diffusion-alloyed steel powder; and completely alloyed steel powder. The partially diffusion-alloyed steel pow- der is preferably a steel powder alloyed partially with one or more of Cu, Ni, and Mo. The completely alloyed steel powder is preferably a steel powder alloyed with Mn, Cu, Ni, Cr,

Mo, V, Co, W, Nb, Ti, Al, P, S and B. Also stainless steel powders are of interest.

As regards the particle shape it is preferred that the particles have an irregular form as is ob- tained by water atomisation. Also sponge iron powders having irregularly shaped particles may be of interest.

A critical feature of the invention is that the powder used have coarse particles i.e. the powder is essentially without fine particles. The term “essentially without fine particles” is intended to mean that less than about 5 % of the powder particles have a size below 45 um as measured by the method described in SS-EN 24 497. So far the most interesting results have been achieved with powders essentially consisting of particles above about 106 pm and particularly above about 212 um. The term “essentially consists” is intended to mean that at least 50 %, preferably at least 60 %, and most preferably at least 70 % of the particles have a particle size above 106 and 212 pum, respectively. The maximum particle size may be about 2 mm. The particle size distribution for iron-based powders used at PM manufacturing is normally dis- tributed with a gaussian distribution with a average particle diameter in the region of 30 to 100 pm and about 10-30 % less than 45 pm. Iron based powders essentially free from fine particles may be obtained by removing the finer fractions of the powder or by manufacturing a powder having the desired particle size distribution.

The influence of particle size distribution and the influence of particle shape on the compac- tion properties and properties of the compacted body have been subjected to intense studies.

Thus the US patent 5,594,186 reveals a method of producing PM components with a density higher than 95 % of theoretical density by utilising substantially linear, acicular metal parti- cles having a triangular cross section. Such particles are suitably produced by a machining or milling process.

Powders having coarse particles arc also used for the manufacture of soft magnetic compo- nents. Thus the US patent 6 309 748 discloses a ferromagnetic powder, the particles of which have a diameter size between 40 and 600 pm. In contrast to iron based powder particles ac- cording to the present invention, these powder particles are provided with a coating.

In the US patent 4,190,441 a powder composition for production of sintered soft magnetic components is disclosed. In this patent the iron powder includes particles with less than 5 % exceeding 417 pm, and less than about 20 % of the powder particles have a size less than 147 um. This patent teaches that, because of the very low content of particles less than 147 pm, the mechanical properties of components manufactured from this coarse, highly pure powder are very low. Furthermore the patent teaches that if higher strength is desired, it is not possi- ble to increase the content of particles having a size less than 147 pm without simultaneously deteriorating the soft magnetic properties. Therefore this powder is mixed with specific amounts of ferrophosphorus. Graphite which may be used in the compositions according to the present invention is not mentioned in this patent and besides the presence of graphite would deteriorate the magnetic properties.

Powder mixtures including coarse particles are also disclosed in the US patent 5225459 ( EP 554 009) which also concerns powder mixtures for the preparation of soft magnetic compo- nents. Nor do these powder mixtures include graphite.

Within the field of powder forging it is furthermore known that pre-alloyed iron-based pow- ders with coarse particles can be used. The US patent 3 901 661 discloses such powders. This patent discloses that a lubricant may be included and specifically that the amount of lubricant should be 1 % by weight (example 1). If the powders according to the present invention were mixed with such a high amount of lubricant it would however not be possible to achieve the high densities.

In order to obtain compacts having satisfactory mechanical sintered properties of the sintered part according to the present invention it is necessary to add certain amounts of graphite to the powder mixture to be compacted. Thus graphite in amounts between 0.1 — 1, preferably 0.2 —-1.0 and most preferably 0.2-0.8 % by weight of the total mixture to be compacted could be added before the compaction.

Other additives may be added to the iron-based powder before compaction, such as alloying elements comprising Mn, Cu, Ni, Cr, Mo, V, Co, W, Nb, Ti, Al, P, S, and B. These alloying elements may be added in amounts up to 10 % by weight. Further additives are machinability enhancing compounds, hard phase material and flow agents.

The iron-base powder may also be combined with a lubricant before itis transferred to the die (internal lubrication). The lubricant is added to minimize friction between the metal power particles and between the particles and the die during a compaction, or pressing, step.

Examples of suitable lubricants are e.g. stearates, waxes, fatty acids and derivatives thereof, oligomers, polymers and other organic substances with lubricating effect. The lubricants are preferably added in the form of particles but may also be bonded and/or coated to the parti- cles. According to the present invention the amount of lubricant added to the iron-based pow- der may vary between 0.05 and 0.6 %, preferably between 0.1-0.5 % by weight of the mix- ture.

The method according to the invention may also be performed with the use of external lubri- cation (die wall lubrication) where the walls of the die are provided with a lubricant before the compaction is performed. A combination of external and internal lubrication may also be used.

The term “at high compaction pressure” is intended to mean at pressures of about at least 800

MPa. More interesting results are obtained with higher pressures such as pressures above 900, preferably above 1000, more preferably above 1100 MPa.

Conventional compaction at high pressures, i.e. pressures above about 800 MPa with conven- tionally used powders including finer particles, in admixture with low amounts of lubricants (less than 0.6 % by weight) are generally considercd unsuitable due to the high forces re- quired in order to eject the compacts from the die, the accompanying high wear of the die and the fact that the surfaces of the components tend to be less shiny or deteriorated. By using the powders according to the present invention it has unexpectedly been found that the ejection force is reduced at high pressures, about 1000 MPa, and that components having acceptable or even perfect surfaces may be obtained also when die wall lubrication is not used.

The compaction may be performed with standard equipment, which means that the new method may be performed without expensive investments. The compaction is performed uni- axially in a single step at ambient or elevated temperature. Alternatively the compaction may be performed with the aid of a percussion machine (Model HYP 35-4 from Hydropulsor) as described in patent publication WO 02/38315.

The sintering may be performed at temperatures normally used within the PM field, e.g. at standard temperature between 1080 and 1160C°C or at higher temperatures above 1160°C and in conventionally used atmospheres.

Other treatments of the green or sintered component may as well be applied, such as machin- ing, case hardening, surface densification or other methods used in PM technology.

In brief the advantages obtained by using the method according to the present invention are that high density green compacts can be cost effectively produced. The new method also permits production of higher components which are difficult to produce by using the conven- tional technique. Additionally standard compaction equipment can be used for producing high density compacts having acceptable or even perfect surface finish.

Examples of products which suitably can be manufactured by the new method are connecting rods, gears and other structural parts subjected to high loads. By using stainless steel powders flanges are of special interest.

The invention is further illustrated by the following examples.

Example 1

Two different iron-based powder compositions according to the present invention were com- pared with a standard iron-based powder composition. All three compositions were produced with Astaloy Mo available from Hogands AB, Sweden. 0.2 % by weight of graphite and 0.4 % by weight of a lubricant (Kenolube™) were added to the compositions. In one of the iron- based powder compositions according to the invention, particles of the Astaloy Mo with a diameter less than 45 pm were removed and in the other composition according to the inven- tion particles of Astaloy Mo less than 212 pm were removed. The compaction was performed at ambient temperature and in standard equipment. As can be seen from figure 1-1 a clear density increase at all compaction pressures is obtained with the powder having a particle size above 212pum.

Figure 1-2 shows that in order to obtain components without deteriorated surfaces the most important factor is the reduction or elimination of the smallest particles, i.e. particles below 45 pm. Furthermore from this figure it can be seen that the force needed for ejection of the compacts produced by the iron based powder composition without particles less than 212pm was considerably reduced compared with the ejection force needed for compacts produced from the standard iron-based powder composition having about 20 % of the particles less than 45pm. The ejection force needed for compacts produced from the iron-based powder composition according to the invention without particles less than 45um is also reduced in comparison with the standard powder.

A noticeable phenomenon is that the ejection force for compacts produced according to the present invention decreases with the increasing ejection pressure whereas the opposite is valid for the standard composition.

It was also observed that the compacts obtained when the standard powder was compacted at a pressure above 700 MPa had deteriorated surfaces and were accordingly not acceptable.

The compacts, which were obtained when the powder essentially without particles less than 45 pm was compacted at a pressure above 700 MPa, had a less shiny surface which at least under certain circumstances is acceptable.

Example 2

Example 1 was repeated but as lubricant 0.5 % of EBS (ethylene bisstearamide) was used and the compaction was performed with the aid of a percussion machine (Model HYP 354 from Hydropulsor, Sweden)

From figure 2-1 and 2-2, respectively, it can be noticed that higher green densities and lower ejection forces were obtained with the powder composition according to the invention com- pared with the powder composition with the standard powder. It can also be noticed that com- ponents produced from the standard powder had deteriorated surfaces at all compaction pres- sures.

Claims

1. Process for the preparation of high density green compacts comprising the following steps: -providing an iron or iron-based powder wherein less than about 5% of the iron-based powder particles have a size below 45 um; -optionally mixing said powder with graphite and other additives; -uniaxially compacting the powder in a die at a compaction pressure of at least about 800 MPa and -ejecting the green body from the die.

2. Process according to claim 1, wherein the compaction is performed in a single step.

3. Process according to claim 1 or 2, wherein at least 50% of the iron-based powder consists of particles having a particle size above about 106 um.

4. Process according to any one of claims 1-3, wherein at least 60% of the iron-based powder consists of particles having a particle size above about 106 pm.

5. Process according to any one of claims 1-4, wherein at least 70% of the iron-based powder consists of particles having a particle size above about 106 um.

6. Process according to any one of claims 1-5, wherein at least 50% of the iron-based powder consists of particles having a particle size above about 212 um.

7. Process according to any one of claims 1-6, wherein at least 60% of the iron-based powder consists of particles having a particle size above about 212 pm.

8. Process according to any one of claims 1-7, wherein at least 70% of the iron-based powder consists of particles having a particle size above about 212 um.

9. Process according to any one of claims 6-8, wherein the maximum particle size is about 2 mm. 8 Amended sheet 19/01/2006

10. Process according to any of claims 2-9, wherein the graphite is present in an amount of

0.1-1.0%.

11. Process according to any of claims 1-10, wherein the iron-based powder is combined with a lubricant in an amount between 0.05 and 0.6% by weight before compaction.

12. Process according to any of claims 1-10, wherein the compaction is performed in a lubricated die.

13. Process according to any of claims 11-12, wherein the compaction is performed by using a combination of internal and external lubrication.

14. Process according to any of claims 1-13, wherein the additives are selected from the group consisting of alloying elements, machinability enhancing agents, hard phase materials and flow agents.

15. Process according to any of claims 1-14, wherein the alloying elements are selected from the group consisting of Mn, Cu, Ni, Cr, Mo, V, Co, W, Nb, Ti, Al, P, S and B.

16. Process according to any of claims 1-15, wherein the compaction is performed at a pressure of at least 900 MPa.

17. Process according to any of claims 1-16, wherein the compaction is performed at a pressure of at least 1000 MPa.

18. Process according to any of claims 1-17, wherein the compaction is performed at a pressure of above 1100 MPa.

19. Process according to any of claims 1-18, wherein the compaction is performed at ambient temperature.

20. Process according to any of claims 1-18, wherein the compaction is performed at elevated temperature 9 Amended sheet 19/01/2006

21. Process according to any of claims 1-20 for preparing sintered products, said process further including a single sintering step at a temperature above 1100°C.

22. Powder composition comprising an iron or iron-based powder wherein less than about 5% of the powder particles have a size below 45 pm; and 0.1-1.0% by weight of graphite.

23. Powder composition according to claim 22 further including 0.05-0.6% by weight of a lubricant.

24. Powder composition according to claim 22 or 23, wherein at least 50% of the iron-based powder particles have a particle size above about 106 um.

25. Powder composition according to any one of claims 22-24, wherein at least 60% of the iron-based particles have a particle size above about 106 pm.

26. Powder composition according to any one of claims 22-25, wherein at least 70% of the iron-based particles have a particle size above about 106 pm.

27. Powder composition according to any one of claims 24-26, wherein at least 50% of the iron-based powder particles have a particle size above about 212 pm.

28. Powder composition according to any one of claims 22-27 further including additives selected from the group consisting of alloying elements, machinability enhancing agents, hard phase materials and flow agents

29. Powder composition according to any one of claims 22-28, further including alloying elements selected from the group consisting of Mn, Cu, Ni, Cr, Mo, V, Co, W, Nb, Tj, Al P, S and B. Amended sheet 19/01/2006