DE2422462C3 - Process for the production of abrasive grain agglomerates - Google Patents

Description

The invention relates to the manufacture of abrasive grain agglomerates.

An abrasive grain agglomerate consists of several elementary grains of the abrasive material that are joined together are connected by means of another material, which serves as a binder Serve as a binder under other metals, alloys or glass, with metals and alloys forming a stronger bond secure and are therefore preferable to glass and binders.

Abrasive grain agglomerates are used to manufacture cutting tools for machining of hard materials, e.g. B. of grinding wheels.

From GB-PS 4 91 659 a process for the production of diamond grain agglomerates is known, after which a mixture of diamond powder and a metal powder is pressed and then sintered will. The metal powder consists especially of nickel, Copper, cobalt or their alloys, with copper usually being the main component The metal powder is taken in such a ratio that the filling of the voids between the diamond grains What is secured is the agglomerate cake obtained, which is a dense grinding wheel Crushed after cooling, creating diamond grain agglomerates develop.

The main disadvantage of this method is that the The resulting abrasive grain agglomerates are characterized by a compact equiaxed shape, which in turn has the consequence that the agglomerates do not bind firmly in the die of a tool, in particular an organic die, comes another serious disadvantage of this method is the insufficiently high strength of the grain agglomerates, which means that the abrasive grains, in particular the diamond grains, have an insufficiently firm connection is due to the metal. When using the grinding tools, this leads to faster destruction and Dissolution of the same up to the elementary grains.

From GB-PS 1247 764 a process for the production of diamond grain agglomerates is by Hot pressing of a mixture of diamond and nickel powder also known to adhere to this process the disadvantages described.

Finally, these disadvantages also apply to a manufacturing process known from GB-PS 12 47 764 of diamond grain agglomerates with the aid of a galvanic coating of elementary grains a diamond body with a metal layer, usually made of copper or nickel, the Grain agglomerates form when a sufficient amount of the metal is applied to the abrasive grain.

The object of the invention is to show how a pqröse in the production of abrasive grain agglomerates Structure in the agglomerate cake with predominant accumulation of the metal on the abutting surfaces of the Grains can be obtained so that in the subsequent crushing of the agglomerate cake Abrasive grain agglomerates with a branched surface can be obtained. This is ultimately intended to be a solid Integration of the abrasive grain agglomerates in the

■ ο Die of a tool manufactured with you be achieved.

The problem posed is achieved by using the powder sintering process when full, with a mixture of abrasive

is and metal powder with additions of titanium, zirconium, Chromium, vanadium and / or silicon are sintered with the liquid phase and the agglomerate cake obtained is crushed will.

As a result of the sintering in the filled state, there is a

porous structure of the agglomerate cake with predominant accumulation of the metal on the abutting surfaces of the Abrasive grains. The additions make the elementary grains wettable with metal and thereby the strength of the connection between the individual

Elemental grains improved together

In addition, the formation of pores on the surface of the abrasive grains during sintering fine film chemically bonded to this surface, which removes surface defects of the Contributes abrasive grains and thereby increases their strength by 1.5-2 times as well as the grains together firmly connects

It is appropriate to add the additives in an amount of 5 to 10 parts by weight to 100 parts by weight of the

Add metal powder.

The invention is described below with the aid of exemplary embodiments and with the aid of a drawing explained in more detail The drawing shows schematically on an enlarged scale a Schleifkurner agglomerate obtained according to the invention.

To produce the abrasive grain agglomerates, diamond powder, Cubic boron nitride powder, boron carbide powder, singly or as a mixture, are used

The degree of dispersion of the abrasive powder is not important for the invention and is used for the respective process management selected appropriately. Various metals and alloys can be used as binders, e.g. copper, tin, nickel, cobalt, iron as well as alloys made of copper and silver, made of copper and Tin etc. can be taken.

The use of the above metals and alloys for the production of abrasive grain agglomerates by sintering is common and the invention does not differ from the prior art either by the materials used, so that these will not be discussed further.

The abrasive powder and the metal powder are mixed in a ratio as is the case with the known method is common and suitable. This ratio of grinding powder to metal powder is in Range from 4: 1 to 1: 5 (by volume). A ratio that is in the range can be viewed as optimal 4: 1 to 1: 1.5.

The binding metal or alloy for it will depend on the nature of the abrasive material as illustrated by the examples below.

The additives, such as titanium, silicon, zirconium, chromium or vanadium, and their amount are also included in Selected depending on the nature of the abrasive material. For example, for To use diamond powder as an additive to titanium, FQr a mixture of diamond powder and powder of boron carbide should preferably be used as an additive zirconium. Further information on the choice of additives can also be found in the Examples.

The additives are practically introduced individually. Their use as a mixture is of no major importance positive effect The powdery) additives are usually in the powder of the binding metal before its Mixing with the abrasive powder introduced. It is also possible to add the additive after mixing the Introduce binder metal powder with the abrasive powder.

The mixture of powders prepared in this way or in another way is filled in a protective gas or sintered in vacuo at a temperature such that it melts the binder metal comes; ie, the sintering is carried out in the presence of the liquid phase of the binder metal is well known, the temperature of sintering depends on the nature of the Binder metal and abrasive material and is usually 800 to 1200 "C.

The melting temperature of the binding metal is maintained during sintering.

The agglomerate cake obtained has a porous Structure on. After cooling in vacuo, it is comminuted in the usual way in the air, whereby one Abrasive grain agglomerates according to the attached figure are obtained from elementary abrasive grains 1 exist and are interconnected by the metal 2. You have as from the picture can be seen, a highly branched surface, which can be attributed to the porous structure of the agglomerate cake is

The formation of pores in the powder mass to be sintered contributes, especially in the presence of the Additions of titanium, zirconium, chromium, silicon or vanadium to form fine films 3 on the surface the abrasive grains that are firmly attached to the surface of the Elementary abrasive grain 1 are connected.

Because of their strongly fissured surface, the abrasive grain agglomerates in the die become one The cutting tool is stronger than the known agglomerates of abrasive grains held, since these represent more compact bodies with less branched surface.

The effects described significantly increase the service life of the tool that is being used this abrasive grain agglomerate is produced.

example 1

Diamond powder with a grain size of 100 / 80μπι and powder one made of 72% silver was used for sintering and 28% copper alloy. The ratio of diamond powder to alloy powder was 3: 1. As an additive, titanium was used in an amount of 7% over the 100% of the alloy metal taken.

The sintering was introduced in the filled state at a temperature of 900 ^° C. in a vacuum. The abrasive grain agglomerates obtained after comminuting the agglomerate cake are characterized by a highly branched structure and a firm connection between the elementary grains.

The agglomerates were used to produce

Grinding wheels with an organic bond are used and these have been tested when machining hard alloys The tests were carried out at a speed of 25 m / selo, a S Longitudinal feed of 2 m / min a transverse feed of 0.02 mm / double pass carried out The specific The consumption of diamonds was 0.05 to 0.08 mg / g.

Example 2

For sintering, an abrasive mixture of 60% diamond powder and 40% boron carbide powder as well as Binder metal is the powder taken from an alloy of 80% copper and 20% tin. The ratio of Abrasive powder to alloy powder was 1.5: 1. As an additive, titanium powder was used in an amount of 10% taken in addition to the 100% of the metal powder.

The sintering was carried out in the filled state at a temperature of 1000 ° C. in a vacuum The abrasive grain agr. '^ Merates obtained were drawn are characterized by a branched structure and a solid connection between the elementary grains.

Grinding wheels with organic bonding, manufactured with these abrasive grain agglomerates, were used at 2s grinding of multi-cutting carbide tools checked; The machining of the hard metal and steel part of the tool was carried out at the same time the end. The peripheral speed of the disk was 20 to 30 m / sec, the longitudinal feed 2 m / min, the Cross feed 0.04 mm / double turn. The specific consumption of diamonds was during this processing about 03 mg / g.

Example 3

For sintering, cubic boron nitride powder with a grain size of 125/100 μm was used as an abrasive and the powder of an alloy of 80% copper and 20% tin is taken as the binding metal. The ratio of Abrasive powder to alloy powder was 1.2: 1.

As an additive, zirconium powder was used in an amount of 10% over 100% of the metal powder.

The sintering was in the full state at a temperature of 1050 ⁰ C and a pressure of not

more than 2 · ^10-5 Η column mm min carried out during 25

The abrasive grain agglomerates obtained from pie were characterized by their branched structure and high strength the end. They were used for making grinding wheels

jo used with organic binding Testing the Grinding wheels happened when machining steel specimens with a carbon content of 0.7 to 035 be? 30 m / sec peripheral speed of the disc, a longitudinal feed of 1 m / min and a transverse feed of 0.02 mm / double pass. The was specific consumption of cubic boron nitride 0.2 to 0.26 mg / g.

Example! 4th

to to sintering was μπι a mixture of abrasive powders of 70% cubic boron nitride with a grain size of 125/100 and μπι 30% electric Konnd with a grain size of 100/80 and taken as the binder metal, the powder of an alloy of 95% copper and 5% nickel. The ratio between abrasive powder and metal powder was 1: 1. As an additive, chromium powder was taken in an amount of 6% to 100% of the metal powder.

The sintering was carried out in the filled state at a temperature of 1200 ° C in a vacuum for 30 minutes carried out.

The abrasive grain agglomerates had - as in the previous examples - a branched structure and a solid connection of the elementary bodies among themselves. They were used in the manufacture of grinding wheels with an organic bond.

The grinding wheels were used in machining specimens made of high carbon steel containing Tested carbon from 0.7 to 0.95%. The peripheral speed of the disc was 20 to 30 m / sec, the longitudinal feed 2 m / min and the cross feed 03 mm / double pass. The specific consumption Diamonds in processing the specimens was about 0.4 mg / g.

Example 5

Schieifmiiieipuiver was used for sintering Mixture of 75% diamond powder with a grain size of 160/125 μπι and 25% boron carbide powder with a Grain size of 100/80 μm and copper powder was used as the binding metal. The relationship between the Abrasive and metal powder was 1: 1. As an additive, silicon powder was used in an amount of 10% of the Metal powder taken in addition.

The sintering was carried out in the filled state at a temperature of 1000 ^° C. vacuum for 40 minutes. The grains obtained were distinguished by a branched surface and a firm connection to one another.

The abrasive grain agglomerates were used to manufacture grinding wheels with an organic bond used. These were used together with the machining of specimens made of hard metal alloy Steel tested with a carbon content of 0.4 to 0.5%. The peripheral speed was the Discs 25 m / sec, the longitudinal feed 1 m / min and the cross feed 0.02 mm / double pass. The specific one The consumption of diamonds in this processing of the specimens was about 0.3 mg / g.

Example 6 A mixture of abrasive powder was used for sintering

, o ver from 60% diamond powder with a grain size of 100/80 μιη and 40% silicon carbide powder with a Grain size 63/50, and as a binding metal the powder of an alloy of 90% copper and 10% nickel taken. The ratio of the abrasive powder

_.5 to metal powder was 1: 1.2. As an additive, vanadium powder was used in an amount of 8% of the weight of the metal powder.

The sintering was carried out in the filled state at a temperature of i2öö ⁼ C in a vacuum vuii

, .ο 1 -τ- 2 ■ 10- ⁵ mm Hg column carried out for 30 min. The abrasive grain agglomerates obtained were distinguished by a branched surface and high strength and were used for the production of abrasive wheels with an organic bond.

j ₅ The grinding wheels were tested during machining on specimens made of hard metal with a carbon content of 0.7 to 0.95%. The circumferential speed of the disks was 30 m / sec, the longitudinal feed 1 m / min and the transverse feed

0.04 mm / double thread. The specific consumption ar diamonds was 0.6 mg / g.

The abrasive grain agglomerates obtained according to this example can also be used independently as an abrasive medium can be used.

1 sheet of drawings

Claims (2)

Claims 1, Application of the filling state sintering process to the extraction of Abrasive grain agglomerates from one with liquid Phase sintered and crushed mixture of abrasive and metal powder with additions of Titanium, zirconium, chromium, vanadium and / or Silicon. 2. Use according to claim 1 to a mixture of 5 to 10 parts by weight of additives to 100 Parts by weight of metal powder.