SE511089C2 - Cutting tool insert for turning steel - Google Patents

Abstract

A cutting tool insert comprises: (a) a cemented carbide body of WC, 6-15 (9-12) weight % Co and 0.2-1.8 weight % cubic carbides of Ti, Ta and/or Nb, and a highly W-alloyed hinder phase with a CW ratio of 0.78-0.93 (0.8-0.91); and (b) a coating comprising an innermost TiCxNyO2 1.5~mm thick with equiaxed grains 0.5~mm, a 2-5~mm thick TiCxNyO2 layer with columnar grains with an average diameter 5~mm, and an outer layer of smooth fine-grained (0.5-2 ~mm) k-Al2O3 0.5-6 ~mm thick. The manufacture of the insert is also claimed and comprises forming the innermost layer of TiCxNyO2 by known CVD methods (x+y+2=1, z0.5) to a thickness of 0.1-1.5~mm, forming the 2nd TiCxNyO2 layer by MTCVD using acetonitrile as the C and N source at 850-900 deg.C (x+y+z=1, 2 = preferably 0, x>0.3 and y>0.3, and forming a TiN layer 1~mm on the k-Al2O3 layer.

Description

10 15 20 30 35 511 089 4 021. The Al 2 O 3 layer has a thickness of 0.5-2 μm. Another one layer (0 1-1 μm thick) of TiN precipitates. This outermost layer of TiN, has a surface finish RmaX <0.4 μm over a length of 10 μm. The even coating surface can be obtained by a light wet blasting of the coating with fine-grained (400-150 mesh) alumina powder or by brushing the edges with brushes based on SiC as described in Swedish patent application 9402543-4. TiN layer removed along the cutting edge.

Example_1 A. A cemented carbide insert of type CNMG120408-MM with assembly 1.16 wt% Ta, 0.28 wt% Nb and ba- lance WC, with a binder phase highly alloyed with W corresponding to a CW 10.5% by weight of Co, ratio of 0.87, was coated with an innermost 0.5 μm of axial axis TiCN layer with a high nitrogen content, corresponding to an estimated tat C / N ratio of 0.05, followed by a 4.3 μm thick layer of column year TiCN precipitated using MT-CVD technology. IN the following steps during the same coating process precipitated a 1.1 pm layer of Al2O3 consisting of pure K-phase according to the process written in EP-A-523 021. A thin, 0.5 μm, TiN layer was precipitated, during the same cycle, on top of the Al2O3 layer. The coated insert brushed with a SiC-containing nylon brush after coating, whereby the outer TiN layer was removed on the edge.

B. A CNMG120408-MM core metal insert having a composition 1.8% by weight of TiC, 3.0% by weight of TaC, 0.4% by weight of % NbC, balance WC and a CW ratio of 0.88. The hard metal had a surface zone, about 25 μm thick, depleted of cubic carbide 7_5% by weight of Co, there. The insert was coated with an innermost 0.5 μm of axial TiCN layer with a high nitrogen content, corresponding to an estimated C / N ratio of 0.05, followed by a 7.2 μm thick layer of column TiCN precipitated using MT-CVD technology. In the following step during the same coating process, a 1.2 μm precipitated layer of Al2O3 consisting of pure K-phase according to the procedure described in EP-A-523 021. A thin, TiN layer was precipitated below the same cycle on top of the Al2O3 layer. The coated notch was brushed 0.5 pm, with a SiC ~ containing nylon brush after coating, wherein the outer TiN layer was removed on the edge. lC 15 20 25 30 511 089 the concentration of 10-11% by weight of Co, is the preferred grain size 1.5-2 pm, preferably around 1.7 pm. The CW ratio should be 0.80-0.91. of eta phase (M5C), without any harmful effect. Of the CW value The cemented carbide may contain small amounts, <1% by volume, It follows that no free graphite is permitted in the cemented carbide substrate according to the present embodiment.

The coating includes a first (innermost) layer of TiCxNyOz with x + y + z = 1, and z <0.5, with equal-axis grains with size <0.5 pm and a total thickness a layer of TiCxNy with x + y = 1, x> 0.3 and y> O.3, with a thickness of 2-5 pm, with columnar grains and with an average diameter of O.l ~ 2 pm. The thickness of the TiCxNyOz layer depends on the type of application, 2-5 pm in extremely edge-line toughness-demanding workpiece material such as Ti-stabilized stainless steel. - a layer of a smooth, fine-grained (grain size about 0.5- 2 pm) Al2O3 consisting essentially of K-phase. The layer may contain pour small amounts, 1-3% by volume, of the 6- or u-phases determined with XRD measurement. The Al2O3 layer has a thickness of 0.5-2 μm.

This Al2O3 layer is followed by an additional layer (0.1-1 μm) thick) of TiN with a surface finish Rmax pm. TiN layer is removed along the cutting edge.

According to the method of the invention, a WC-Co-base is manufactured. cemented carbide substrate with a high W-alloy binder phase with a CW ~ ratio as above and a content of cubic carbides as above and a WC grain size as above, a first (innermost) layer of TiCxNyOz with x + y + z = 1, and z <0.5, with a thickness of <1.5 pm, and with equilateral grains with size <0.5 pm using known CVD methods. a layer of TiCXNy x + y = 1, x> 0.3 and y> 0.3, with a thickness of 2-5 pm, with columnar grains and with an average diameter of 0.1-2 μm, using preferably MTCVD technology (with use of acetonitrile as a source of carbon and nitrogen to form layer in the temperature range 700-900 OC). The exact however, the conditions depend to some extent on the of the equipment used. - a smooth, fine-grained Al2O3 layer substantially permanent of k-Al 2 O 3 precipitated under conditions described in e.g. EP-A-523 10 15 20 25 511 D89 Wear mechanism in this test is chipping of the Gene. The inserts with the gradient substrates (B, E and F) look good ef- three interventions but suddenly failed after about four.

Notch (according to the invention) 15 Number of procedures (comparison) (outer variety) (outer variety) (outer variety) * n m tj 0 ul P »BßVJVJUI (outer variety) Example_2 Cuts A and B as above were selected for a turning test, longitudinal and planing in machinability-enhanced AISI304L stainless steel.

Cutting speed was 250 m / min, feed 0.3 mm / revolution and cutting speed depth 2 mm. Cutting time 1 minute / cycle.

The wear mechanism was plastic deformation.

Cut Number of cycles B (comparison) 7 A (according to the invention) 4 Example_3 G. Inserts in geometry TNMGl60408-MM with composition and laying according to A above.

H. Inserts in geometry TNMGl60408-MM with composition and laying according to B above.

I. Cuts in geometry TNMG16Ö408 with composition and laying according to C above.

The inserts G, H and I were tested in longitudinal, dry, turning of a duplex stainless steel shaft.

Feed rate 0.3 mm / rev, speed 140 m / min and cutting depth 2 mm.

Total cutting time per component was 12 minutes.

Cuts-G and I got plastic deformation while cut H got any radiation wear.

LT) lO 15 20 STAY 35 511 089 C. A competing cemented carbide insert of type CNMG120408 from a leading core metal producer was selected for comparison in one turning test. The cemented carbide had a composition of 9.0% by weight of Co, 0.2 wt% TiC, 1.7 wt% TaC, 0.2 wt% NbC, balance WC and a CW ratio of 0.90. The insert had a coating lasting of 1.0 μm TiC, 0.8 μm TiN, 1.0 μm TiC and, ultimately, 0.8 μm TiN.

Examination under a light optical microscope showed no edge treatment after coating.

D. A competing cemented carbide insert of type CNMG120408 from an external leading cemented carbide producer was chosen for comparison in a turning test. The cemented carbide had a composition of 5.9 3.1 wt% TiC, 5.6 wt% TaC, 0.1 wt% NbC, lance WC and a CW ratio of 0.95. The carbide had one surface zone, about 30 pm thick, which was enriched at Co. The insert had weight% Co, ba- a coating consisting of 5.3 μm TiC, 3.6 μm TiCN, ultimately, 2.0 pm TiN. Examination under a light optical microscope showed no edge treatment after coating.

E. A competing cemented carbide insert of type CNMGl20408 from an external leading cemented carbide producer was chosen for comparison in a turning test. The cemented carbide had a composition of 8.9 weight% Co, balance WC and a CW ratio of 0.84. The insert has they a coating consisting of 1.9 μm TiC, 1.2 μm TiN, 1.5 μm Al2O3 laminated with 3 0.1 μm thick layer of TiN and, ultimately, 0.8 pm TiN. Examination under a light optical microscope showed no edge treatment after coating.

F. A competitive cemented carbide insert of type CNMG120408 from an external leading core metal producer was selected for comparison in a turning test. The core metal had a composition of 5.4 2.7 wt% TiC, 3.5 wt% TaC, 2.3 wt% NbC, lance WC and a CW ratio of 0.94. The carbide had one surface zone, about 40 pm thick, which was enriched in Co. The insert had wt% CO, ba- a coating consisting of 5.3 μm TiC, 3.6 μm TiCN, ultimately, 2.0 pm TiN. Examination under a light optical microscope showed no edge treatment after coating.

Inserts from A, B, C, D, E and F were compared in planing one close, diameter 180, with two, opposite, flat sides (thickness 120 mm) in 4LR60 material. Feed rate 0.25 mm / rev, speed 180 m / min and cutting depth 2.0 mm. 10 15 20 8 -5 Skar1J1ocQ§9 was selected for a turning test. Longitudinal and pl- casting valve component in AISI316L stainless steel. Notch- speed was 110 m / min, feed 0.25 / 0.3 mm / rev and cutting depth 1.25 mm. The cutting time was 2.8 minutes / component. Eight eggs test des per cutting type.

The wear was chipping of the edge for insert J and uneven phase wear for inserts K.

Cut Average number of components '6.s 4.4 J (according to the invention) K (outer variety) Examples Cuts according to A, B, C and D were selected for a turning test. Internal turning of AISI304 valve substrate in stainless steel. Skärhas- speed was 130 m / min and feed 0.4 mm / rev. The stability was poor dependence on the drill rod.

The wear was chipping of the edge for inserts D and B with dan cuts A and C got plastic deformation.

Cut _ Number of components A (according to the invention) (outer variety) NU1 \ 1 \ O D C (outer variety) B (comparison) EX fi mnel_1 Cuts A and C as above were selected for a turning test, coarse working of a square bar in AISI316Ti stainless steel. Bear- pickling was interrupted depending on component shape.

Cutting speed was 142 m / min) feed 0.2 mm / revolution, cutting depth 4 mm and cutting time 0.13 minutes / component.

The wear was chipping of the edge.

Cut Number of components A (according to the invention) 25 C (outer variety) 15 lO 15 20 25 30 11 089 Two edges of insert G were worn out to produce a component while an edge of insert H terminated one component and four edges was needed to finish a component using insert I.

Cut Number of edges / component H (comparative) 1 G (according to the invention) 2 I (outer variety) 4 Example_A Inserts A and E as above were selected for a turning test, main actually planing, in a rotor housing made of cast AISI316 stainless steel. Processing was interrupted due to component sign.

Cutting speed was 180 m / min, feed 0.2 mm / revolution and cutting depth O-2 mm (irregular shape of casting). Cutting time 10.5 min- ter / component.

Wear mechanism was a combination of egg chipping and plastic deformation.

Cut Number of components A (according to the invention) 2 E (outer variety) 1 Example_5 J. Inserts in geometry CNMG160612-MR with composition and laying according to B above.

K. A competing cemented carbide insert of type CNMGl606l2 from an external leading cemented carbide producer was chosen for comparison in a turning test. The cemented carbide had a composition of 6.3 % Co, 2.7 wt% TiC, 3.4 wt% TaC, 2.1 wt% NbC, balance WC and a CW ratio of 0.89. The cemented carbide had a surface zone, about 20 pm thick, depleted of cubic carbides. The insert had a coating consisting of 0.1 μm TiN, 6.0 μm column near TiCN, 1.5 μm multilayer, 1.4 μm Al 2 O 3 and outer, 0.6 μm TiN. During- search in a light optical microscope showed no edge treatment after coating.

Claims (1)

10 15 511 089 A cutting insert specially for turning stainless steel comprising a cemented carbide body and a coating Krax is characterized in that the cemented carbide body consists of WC, 10 -11% by weight of Co and 0.5-1.7% by weight of cubic carbides of Ta and Nb and a high W-alloy binder phase with a CW ratio of 0.80-0.91 and that the coating consists of - a first (innermost) layer of TiCxNyOz with x + y + z = 1 and z <0.5 and a thickness of the size - a layer of TiCxNY with x + y = 1 and x> 0.3 and y> 0.3 a thickness of 2-5 pm with columnar grains with an average diameter of o.1-2 pm - a layer of smooth, fine-grained (0.5-2 pm) K-Al2O3 with a thickness of 0.5-2 pm - an outermost layer of 0.1-1 pm TiN with a surface finish Rmax cutting edge.