DE1065624B - - Google Patents

Description

GERMAN

The invention relates to hard metals consisting essentially of tungsten carbide, an additive of a secondary carbide, such as the carbide of titanium, zirconium, tantalum or niobium, and a metallic one There are binders, which are iron, cobalt, nickel or alloys of these metals acts.

In particular, the invention relates to cemented carbides of this type which are used for cutting tools are intended and are used for processing steel and steel alloys.

The cemented carbides currently used to make cutting tools stand out by the fine grain size of the portion formed by the tungsten carbide crystals and by the use of a metallic binder. With the hard metals on the market have the carbide crystals predominantly have a size of 0.5 to 10 μ and often 3 to 8 μ. The proportion of as a binder serving metal amounts to about 12% for these multi-carbides available on the market of weight. For high wear resistance, we recommend hard metals with a particularly low content and for high toughness and notched impact strength, cemented carbides with a higher content of binder metal. However, it is currently not recommended to reduce the proportion of binder to below 5%, The tools then easily break, crack, or chip. In an effort to reduce the brittleness of the cemented carbide To avoid this, one has already resorted to changing the grain size of the carbide somewhat. Also contain hard metals of this type, which are used for cutting tools for machining Steel, usually a secondary carbide, is intended to be higher than the multi-carbide hard metal A to give resistance to scouring, which arise from the fact that the cutting to machining material welds to the tool and attacks it. Secondary carbides come as such those of titanium, zirconium, tantalum or niobium in question.

The multiple carbides, which have proven themselves as commercially available hard metals of this type, stand out are characterized by the fact that they contain a high proportion of tungsten carbide and that all or at least the most secondary carbides, e.g. B. titanium carbide, in the form of a solid solution. The cheap ones Results of these cemented carbides have just been attributed to the fact that the carbides in the sintered Product as a solid solution. The importance of this has therefore been emphasized in earlier papers it is to strive for the highest possible degree of one, regardless of the composition solid solution is created. Also is in the literature so far

Applicant:

General Electric Company,
Schenectady, NY (V. St. A.)

Representative:

Dipl.-Ing. M. Licht, Munich 2, Sendlinger Str. 55,
and Dr. R. Schmidt, Oppenau (Renchtal), patent attorneys

Claimed priority:
V. St. v. America May 13, 1954

George William Lucas, St. Clair Shores, Mich.,

and Carl Stanley Wiedman, Oakland, Mich. (V. St. A.) have been named as inventors

and in previous patents it has been consistently held that cemented carbides with a Secondary carbide, e.g. B. titanium carbide, in addition to tungsten carbide and with a serving as a binder Metal can only achieve its best performance when the tungsten carbide is for the most part is dissolved in the secondary carbide. .

Up to now, a grain size of 1 to 10 μ was considered the best value for common multi-carbide hard metals. With the current state of the art, grain sizes of around 25 μ would be a rare exception regard. For most of the cemented carbides currently being manufactured, the crystal size amounts to to about 3 μ.

According to the invention, bonded multiple carbide hard metals are now proposed for the first time, which characterized by higher toughness and wear resistance than they are according to the currently valid views are to be expected. The invention is based on new knowledge that the previous conceptions on the Aeffect and importance of the crystal size and the solid solution refute.

To the size difference between the tungsten carbide crystals in the subject invention and in To show the well-known hard metals, some cut-out pictures are given. Show it

Figures 1 and 2 are microphotographs at 1500 and 200 times linear magnifications, respectively, for illustrative purposes the crystal structure of a multi-carbide hard metal according to the invention and

90 »628/349

Figures 3 and 4 are photomicrographs at 1500 and 200 times linear magnifications of the crystal structure known multi-carbide hard metals, the tungsten carbides of which have the usual grain size.

In all the figures the large angular crystals are tungsten carbide.

. The invention is based on the knowledge that the wear resistance and the toughness of a increased multi-carbide cemented carbide by making the tungsten carbide crystals dimensioned extraordinarily large. Multi-carbide hard metals, the tungsten carbide crystals of which are up to to 250 μ and for the most part are dimensioned to 25 to 150 μ, for example, have proven to be the usual Hard metals have proven to be far superior. This size range by far exceeds that previously proposed or used, ten times as much.

The term "macrocrystallic tungsten carbide" used below means tungsten carbide crystals, the size of which amounts to 25 to 250 μ.

The invention is also based on the completely new knowledge that macrocrystalline tungsten carbides be used for the purpose of counteracting or delaying the formation of solid carbide solutions. This also contradicts the previous view of the advantages of fixed solutions. It has it has been shown that if one counteracts the formation of solid carbide solutions, then the Share of secondary carbides, e.g. B. increase the proportion of titanium carbide and thereby part of the Can replace tungsten carbide. This can be done without noticeably reducing the toughness, provided that the Grain size of the tungsten carbide is chosen as large as specified, and provided that the formation is more solid Carbide solutions counteracts. In fact, there is a further improvement in toughness through use a coarse-grained tungsten carbide because it makes the binder effective between all of them Grains is distributed. The overall result is a product with increased notched impact strength.

Another advantage of using macrocrystallic tungsten carbide is the reduction in the proportion of binding metal compared with most commercially available multiple carbides. For bonded multi-carbide hard metals, currently used for cutting tools are on the market, the proportion of the metal used as a binder is 5 to 12 percent by weight, while in the hard metal according to the invention this proportion is only 1.5 to 10 percent by weight. The main advantage achieved by this reduction in binder is that the cemented carbide has a correspondingly higher content of hard carbides, which leads to the desired properties of the cutting tool and do the actual cutting work.

The coarse-grained tungsten carbide mixtures which are used according to the invention can be used can be produced with the process currently in use, which is used for the production of the common multi-carbides used if this procedure is modified somewhat. An important change to the The method consists in carrying out the grinding process in the ball mill in two steps. By doing. The first step is only the secondary carbides and the one used as a binding agent Grind metal, whereby at most a part of the tungsten carbide can be admixed. At the second time The entire proportion of the tungsten carbide is used for a relatively short period of time with wed. This prevents the coarser crystals from being ground too finely.

The proportion of tungsten carbide in the manufacture of the multiple carbide hard metals according to the invention can fluctuate. In general, a proportion of 60 to 90 percent by weight has proven useful.

As secondary carbides for the production of the hard metal according to the invention, the carbides come from

ίο titanium, zirconium, tantalum or niobium in question. you The proportion can also fluctuate within wide limits and can be, for example, 5 to 30 percent by weight of the carbide. The grain size of the secondary carbides is, as usual, in the range of 0.5 to 10 μ.

Cobalt, nickel or iron are suitable as binders for the hard metal according to the invention. The proportion can vary between about 1.5 and 10% of the weight of the hard metal. Preferably

this is how you use cobalt. But you can also take place use its nickel or iron or an alloy of these metals with cobalt. In particular, is suitable also nickel alone as a binder. A nickel-cobalt alloy can also be used. Finally one can replace half of the nickel or the cobalt with iron. If you use mixtures of these metals, it is best that the total weights of these metals are approximately those mentioned above Percentage range.

Although tungsten carbide crystals can be used for the production of hard metals according to the invention Size up to 250 μ can be used; but the tungsten carbide content of the sintered hard metal is best At least half the size of a grain, measured according to the weight or volume of the cemented carbide from 25 to 150 μ. Individual crystals can of course be smaller or larger.

In order to further understand the invention and its feasibility, may the following examples of serve the composition that comes into question for cutting tools. In these examples the crystal size of the tungsten carbide was 25 to 250 μ, predominantly 25 to 150 μ. The amount is shown in both weight and volume percentages.

Weight
percent Volume
percent example 1
Tungsten carbide 74.3
21 4 50.0
45.0 Titanium carbide 4.3
64.3
18.3 5.0
45.0
40.0 Cobalt .. 13.3
4.1 10.0
5.0 Example 2
Tungsten carbide 65.4
27.6
3.5
3.5
63.0 40.0
52.5
3.75
3.75
43.8 Titanium carbide 18.0
12.9
6.1 39.0
9.7
7.5 Tantalum carbide cobalt Example 3
Tungsten carbide. ... Titanium carbide .... cobalt nickel Example 4
Tungsten carbide Titanium carbide Tantalum carbide cobalt

Example 5
Tungsten carbide
Titanium carbide
Tantalum carbide.
cobalt

Example 6
Tungsten carbide
Titanium carbide
Tantalum carbide ..
cobalt

Example 7
Tungsten carbide
Titanium carbide
Tantalum carbide.
cobalt

Weight percent

61.5

17.6

12.7

8.2

68.1

14.0

10.1

7.8

59.1

18.8

13.7

8.4

Volume percentage

42.5

38.0

9.5

10.0

50.0

32.0

8.0

10.0

40.0 40.0 10.0 10.0

To test the suitability of these hard metals, cutting tools were made from them and compared to tools made from commercially available hard metals. It is the »Carboloy« multi-carbides with the grade designation 78, which are on the American market, 78 B, 78 C and 370 manufactured and marketed by the General Electric Company and all contain the usual finely ground tungsten carbide. For the purpose of an expedited Testing with these tools was a steel rod with a diameter of 25 cm turned off, with a cutting speed of 73 m / min, with a chip width of 3.175 mm and a feed of 0.56 mm per revolution was used. The service life was measured of the tool, i.e. the time from the beginning of the 'turning process to the moment in which the Tool became unusable. The wear was also determined in mm. The following resulted:

material

hardness

Specific
weight

lifespan

wear

Carboloy variety 78 C
Carboloy variety 78 B
Carboloy variety 78.
Carboloy variety 370

Example 2

Example 4

Example 7

91.0 91.0 92.0 91.0

90.9 90.9 90.4

13.45
12.60
11.80
12.65

10.80
10.80
10.54

35 sec.

45 sec.

4 min. 30 sec.
2 min. 15 sec.

10 min. +)

13 min.

13 min. 20 sec.

0.99
1.40
0.43
0.40

0.08
0.51
0.53

+) In this case, the attempt was aborted before the tool became unusable.

One recognizes the rapid progress without further ado, to which the invention leads. Because the tools from the hard metals according to the invention had a much longer lifespan than the usual tools.

Cemented carbides were then produced, although they also had the composition of the above examples but contained tungsten carbides of the usual grain size. These hard metals then became tools were also made and these were then tested in the usual manner. They interrupted the specified conditions because they have high hardness and high wear resistance, but inadequate Had toughness.

The hard metals according to the invention are also suitable for purposes other than cutting tools, although they are particularly suitable for turning tools, milling cutters, drills, reamers, planing tools, etc.

Claims (3)

Claims: 40 45 50 55 1. Sintered cemented carbide, which consists of tungsten carbide crystals in the amount of about 60 to 90 percent by weight, from one or more other carbides in the total amount of about 5 to 32.5 percent by weight and of a binder metal in the amount of about 1.5 to 10 percent by weight consists, characterized in that about half the weight or volume proportion of the tungsten carbide crystals has a size of at least 25 μ, preferably 25 to 150 μ. 2. Sintered hard metal according to claim 1, characterized in that the tungsten carbide crystals have a size of up to 250 μ. 3. A method for producing the cemented carbide according to claim 1 or 2, in which the components be ground in a ball mill before sintering, characterized in that the grinding process takes place in the ball mill in two operations, the first of which is the secondary carbide and the binding metal and, if desired, at most part of the tungsten carbide are ground, while in the second step the remaining tungsten carbide is added to the ground material of the first is added so that a different grain size of the various ingredients results. 1 sheet of drawings ■■ 909 628/349 9.