MUHAMMED MAMOUN
GRENTHE INGMAR
US3440035A | 1969-04-22 |
1. | Method for preparing a powder containing W and Co and/or Ni from APT and a soluble salt of Co(Ni) by chemical reactions in a water solution at temperatures from room temperature to the boiling point of the solu¬ tion, whereafter the formed powder is filtered off, dried and reduced to a metallic powder, c h a r a c t e r i s e d in that the solution pH is kept at a constant level during the chemical reactions. |
2. | Method according to claim 1 c h a r a c t e r i s e d in that the solution pH is kept at a constant level adding an amount of ammoniiim hydroxide continuously during the reaction, so that the pH is maintained within 8+.0.5. |
3. | Method according to claim 1 c h a r a c t e r i s e d in that the solution pH is kept at a constant level by using a Co (Ni) salt with an anion with a pHbuffering capacity. |
4. | Method according to claim 3 c h a r a c t e r i s e d in that said Co salt is cobalt acetate. |
5. | Method according to any of the preceding claims c h a r a c t e r i s e d in that said metallic powder is further carburized to form a powder containing WC and Co and/or Ni. |
The present invention relates to a method of preparing fine grain WC-Co (Ni)- powders for cemented carbides.
WC-Co-cemented carbides are made by powder metallur¬ gical methods milling a powder mixture containing pow¬ ders forming the hard constituents and binders phase, pressing and sintering. The milling operation is an in¬ tensive wet milling in mills of different sizes and with the aid of milling bodies which are usually made of ce¬ mented carbide. The milling time is of the order of se¬ veral hours up to days. Milling is believed to be neces- sary in order to obtain a uniform distribution of the binder phase in the milled mixture. It is further be¬ lieved that the intensive milling creates a reactivity of the mixture which further promotes the formation of a dense structure. During the long milling time the milling bodies are worn and contaminate the milled mixture which has to be compensated for. The milling bodies can also break dur¬ ing milling and remain in the structure of the sintered bodies. Furthermore, even after an extended milling a non-homogeneous rather than an ideal homogeneous mixture may be obtained. In order to ensure an even distribution of the binder phase in the sintered structure sintering has to be performed at higher temperature than the theo¬ retical. An alternative way is to start from an intimate mix¬ ture of Co and W, which subsequently is carburized. The patent US 3,440,035 (Iwase et al. ) discloses such a method of preparing cemented carbide powder characte¬ rised in that a solution or suspension of ammonium para- tungstate in water is mixed with a nitric or hydrochlo-
ric aqueous solution of e.g. cobalt. The mixture is neu¬ tralised with ammonium hydroxide and reacted at tempera¬ tures from 20 to 80 °C. The pH shall after the reaction be within the range 4.5-8. The resultant fine composite precipitate containing tungsten and cobalt is filtered, dried by heating and then subjected to reduction and carburization to obtain a WC-Co composite powder in which the WC grain size is generally submicron.
The solution pH is identified in the patent US 3,440,035 as a critical parameter for the control of the precipitation yields and, therefore also, control of the powder composition. The examples, however, indicate large variations in the solution pH leading to varia¬ tions in the reaction yield and in the product composi- tion. Precise control of compositions is essential for the application of the method. The reactions should therefore be stoichiometric (99-100 % yield) and/or have reproducible yields. Variations, as in US 3,440,035, make accurate control of the powder composition diffi- cult.
The method according to the present invention is characterised by thorough control of the powder composi¬ tion and the reaction yields by maintaining the solution pH at a constant level through the whole process. In the method of the present invention powder of am¬ monium paratungstate (APT) with the chemical formula (NH4) ιo H 2 w 12°42 • X'H.2θ(x=4-ll) , is suspended in a water solution of a soluble cobalt (II) salt. The APT particle size should be about 0.1-100 μm, preferably 1-10 μ . The weight/weight ratio APT-powder/suspension shall be 5-60 %, preferably 20-50 %, most preferably about 20-30 %. The cobalt salt can be cobalt chloride, cobalt nitrate, cobalt acetate or any soluble salt of cobalt. The con¬ centration of cobalt in the solution is chosen to give the desired composition of the final material, taking
the yield of the chemical reaction into account. The so¬ lution pH is controlled, either by continuous addition of ammonium hydroxide(NH4OH) solution during the pro¬ cess, or by the use of a metal salt containing an anion with a pH buffering capacity, e.g. cobalt acetate. The suspension is stirred intensively at temperatures from room temperature to the boiling point of the solution. As the reaction proceeds the colour of the suspended powder changes from white to pink. The time to complete the reaction depends on the reaction temperature, con¬ centration of ammonium hydroxide, cobalt amount, APT grain size, APT-powder/water ratio etc. A more exact de¬ termination of the degree of transformation can be made by conventional powder X-ray diffraction analysis. The powder is filtered off after the reaction is completed, dried and reduced in hydrogen atmosphere to a fine homogeneous metallic powder containing intimately mixed Co and W. This mixture may subsequently be carbur- ized at a relatively low temperature of 1100 °C either by mixing with carbon or in a carbon containing gas to a WC-Co-powder with a typically submicron grain size. The powder can be mixed with pressing agent, compacted and sintered to dense cemented carbide. The initial amounts of APT and cobalt salt are chosen such as to give the desired composition of the WC-Co powder. It has been found that Co-contents of 1-25 %, preferably 3-15 %, easily can be obtained but compositions outside that range are also possible.
The solution pH has a large effect on the time need- ed for the conversion of the white coloured APT to the cobalt tungstate powder, as well as on the homogeneity of the formed powder. To obtain homogeneous products within short reaction time, the solution pH should be constantly maintained in a fairly narrow range, pH=8± 0.5, during the whole process. This is achieved by con-
tinuous addition of ammonium hydroxide during the pro¬ cess . Comparative examples 1 and 2 have been included to demonstrate the effect of adding the whole amount of am¬ monium hydroxide from the start. In comparative example 1, the concentration of ammonium hydroxide is initially 0.6 mole/kg solution, with a pH over the recommended range in the beginning of the reaction. The obtained product is inhomogeneous in composition. In comparative example 2 the initial concentration of ammonium hydroxide is lower, 0.06 mole/kg solution. The effect is a final pH under the recommended range, resulting in a long process time.
In an alternative embodiment the solution pH is con¬ trolled by the use of a metal salt containing an anion with pH buffering capacity, e.g. cobalt acetate. No fur¬ ther adjustment of the pH is necessary. The solution pH will be lower, pH=5.5±0.5, than recommended above and longer process times will therefore be required.
The yield of the chemical reaction between APT and the cobalt salt is typically 90-100 % with respect to tungsten and cobalt. Several parameters such as the so¬ lution pH and the W/Co ratio will affect the reaction yield.
The method according to the invention has been de- scribed with reference to APT and a cobalt salt but can also be applied to APT, a cobalt salt and/or a nickel salt. The solvent can be water or water mixed with other solvents e.g. ethanol .
The homogeneous fine Co+W-metal powder can also be used in other applications like materials for catalysis or in materials for alloys of high density.
Example 1 (Comparative)
790 g cobalt chloride solution (1.69 mole Co/kg so- lution) , 1600 g APT and 3800 g water were charged in a
6000 ml round bottom glass reactor under stirring. 190 g concentrated (25% NH3) ammonium hydroxide solution was added from a dropping funnel during 10 min. The suspen¬ sion was heated up to 80 °C. The warming up time was 40 min and the reaction time after that 2 h. The powder was filtered off and dried at 80 °C for 1 day. 4240 g solution, containing 8.5 mmole W/kg and 1.1 mmole Co/kg, was collected. The pH was 8.4. Powder samples were taken for elemental analysis. The powder was inhomogeneous with a molar ratio W/Co varying from 2.4-4.3 in large dark grains to 6.7-7.7 in small pink grains.
Example 2 (Comparative)
760 g cobalt chloride solution (1.75 mole Co/kg so- lution) , 1600 g APT, 3930 g water and 19 g concentrated ammonium hydroxide solution (25 % NH 3 ) , diluted with water to 112 g, were charged in a round bottom glass re¬ actor. The suspension was stirred and heated to 84 °C. The powder was filtered off after 8 h, washed with 500 ml ethanol (99.5%) and dried at 80 °C for 2 days. The dry weight was 1755 g. 3900 g solution, containing 1 mmole W/kg and 3 mmole Co/kg, was collected. The pH was about 6.5. The powder was homogeneous in composition containing 65 % W and 4.5 % Co.
Example 3
790 g cobalt chloride solution (1.68 mole Co/kg so¬ lution) , 1600 g APT and 3800 g water were charged in a round bottom glass reactor. The suspension was stirred and heated up to 80 °C. The time for warming up to 80 °C was about 50 min and the reaction time after that 3 h. 190 g concentrated ammonium hydroxide solution (25 % NH 3 ) was added continuously with a peristaltic pump to maintain the solution pH around 8, starting when the temperature reached 80 °C and ending after 3 h. The pow-
der was separated by filtration and dried at 80 °C for 2 days. The powder was homogeneous in composition contain¬ ing 63 % W and 4.3 % Co.
Example 4
300 g cobalt acetate solution (0.27 mole Co/kg solu¬ tion) and 100 g APT were charged into a round bottomed glass reactor. The suspension was stirred and heated un¬ til boiling. The powder was filtered off after 7 h and dried at 60 °C. The dry weight was 106 g. 245 g solu¬ tion, containing 4.8 mmole W/kg and 9.2 mmole Co/kg, was collected. The pH was 5.3. The homogeneous powder con¬ taining 64.3 % W and 4.4 % Co was reduced and carburized to a WC-Co powder.
Example 5
80 g cobalt nitrate solution (1.7 mole Co/kg solu¬ tion) , 160 g APT, 320 g water and 80 g ethanol were charged in a round bottom glass reactor. The suspension was stirred and heated up to 70 °C. The time for warming up to 65 °C was about 45 min and the reaction time after that 3 h. 20 g concentrated ammonium hydroxide solution (25 % NH 3 ) was added continuously with a peristaltic pump to maintain the solution pH around 8, starting when the temperature reached 65 °C and ending after 3 h. The powder was separated by filtration and dried at 80 °C for 2 days. The powder was homogeneous in composition containing 60 % W and 4.5 % Co.