Method for producing cutting tools

Abstract

Method for producing cutting tools provides a first hard material coating on a first region of a tool base body containing at least one cutting edge, using a plasma vacuum coating process. A second hard material coating is provided on a second region which is adjacent the first, also via plasma vacuum coating process. Hard material for the coatings is a carbide, oxide, oxicarbide, nitride, nitrocarbide, oxinitride or nitrooxicarbide of at least two of Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W, Al. The first coating has a content of at least two of the metal elements which is at most 2 at % different from the content of the two metal elements in the second coating if the tool is for higher adhesive strength than hardness. The first coating has a content of the two metal elements that is different from the content of the two metal elements of the second coating by more than 2 at % if the tool is for higher hardness than high adhesive strength.

Description

FIELD AND BACKGROUND OF THE INVENTION

[0002] Definition

[0003] In the present specification by hard material is understood a compound, namely a carbide, oxide, oxycarbide, but in particular a nitride, nitrocarbide, oxynitride or nitrooxycarbide, of at least two of the metallic elements listed in the following, in particular of Ti and Al. By metallic elements are understood Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W and Al.

[0004] If within the scope of the present application reference is made to a change of the composition of the hard material layer material in the active edge region, by that is understood a difference of at least 2 at % of a hard material layer metal component between a hard material layer in the active edge region and a hard material layer in the remaining regions of the tool.

[0005] Analogously, no change exists if the stated difference is less than 2 at %, in particular less than 1 at %.

[0006] By machining cross section f aP is understood the product “VorschubxSchnitttiefe” {Advance×cutting depth} according to DIN 6580, Section 11.1.1, “Bewegungen und Geometrie des Zerspanungsvorgang” [Motions and Geometry of the Machining Process] (DN 6580, October 1985).

[0007] German Patent DE 38 25 399 as well as European Patent EP 0 352 545 disclose coating tools by means of a vacuum process with a layer of hard material, and therein especially with a (Ti,Al)N hard material layer. The coating takes place such that in the active edge region, i.e. in the region of the cutting edges, the hard material layer material has a changed composition compared with that on the remaining tool regions: according to DE 38 25 399 as well as EP 0 352 545 at the active edge regions of drills a thinning out of the aluminum is realized which is distinguishable on the tools by the reddish or yellowish coloration of these regions. Thinning-out ratios of 5 at % or 2 percent by mass of the Al are declared.

SUMMARY OF THE INVENTION

[0008] The process discovered, namely to change the hard material layer composition in the active edge region, is fundamentally represented as a measure for attaining a significant improvement of the quality of the coating.

[0009] Building generally on tools in which the provided hard material layer in the active edge region has substantially, and within the scope of measurability, an unchanged material composition as well as on tools in which, in contrast to the first stated, the composition of the hard material layer in the active edge region is changed, each relative to the hard material layer composition on the remaining tool regions, it is the task of the present invention to propose a process for the protective coating of machining tools as well as a set of at least two tools, by means of which substantially improved specific working properties are attained. In particular, as a working property to be improved is understood the service life of the tool or the decrease of the tool wear.

[0010] According to the process of the invention, onto the basic tool body a hard material layer is applied in any case but, specific to the tool stress, the composition of the hard material layer in the active edge region is either left with minimum changes relative to the composition of the hard material layer in the remaining coating regions on the tool basic body or is intentionally changed. The former, i.e. constant composition, is realized if the primary requirements to be made of the tools relate to adhesive strength of the hard material layer and only secondarily to hardness of the hard material layer. The second, in contrast, is realized if the primary requirements to be made of the tools relate to hardness of the hard material layer and only secondarily to adhesive strength of the hard material layer.

[0011] According to the invention it was consequently found that the estimating, previously described effective specifications of changed or unchanged compositions of hard material layers in the active edge regions of machining tools are not permissible, that namely, as a function of the working purpose of the tools, one time a hard material coating of constant composition and another time a hard material coating of varying composition in the active edge region in practice, i.e. when applying the tool, only leads to critical improvements: If tools for given application conditions are coated with the wrong coating technologies one of the two mentioned, therewith often an impairment of its working properties, in particular tool life, is obtained.

[0012] It could be shown, for example, that according to EP 0 352 545 with a thinning-out of the coating only in a few application fields of machining working better or at least equally good results can be achieved, compared to the application of corresponding tools with a lower or no, at least not measurable, difference in the concentration of the hard material layer. It should be pointed out in particular that the example mentioned in EP 0 352 545 with respect to service life of twist drills, based on the representative comparisons made according to the present invention, is erroneous in the case two completely identical, except for stated coating difference, and identically coated drills are present. By completely identical is therein understood the application of the same coating processes, in particular arc or sputtering processes, on identical tool bodies, and the adjustment of the realized or nonrealized concentration difference takes place exclusively by adjusting the voltage applied on the basic tool body during the coating with respect to ground or reference potential, referred to as bias voltage Ubias in the following, and/or of the reactive gas partial pressure preactiv in the vacuum coating receptacle with further process parameters remaining unchanged.

[0013] That the prior known thinning-out in the active edge region can effect critical disadvantages in the use of the tool, and that consequently it is necessary to assess very carefully according to the invention which process is applied at which time, can be seen, for example, by the fact that precisely the aluminum depletion of the hard material layer in the active edge region has negative effects on the wear through thermal stress of the hard material layer since through the aluminum thinning-out potentially now less aluminum reaches the surface of the hard material layer through diffusion and no continuous thermally insulating aluminum oxide layer can be formed there. The Al2O3 layer on the surface is simultaneously worn out during the working process and formed again through Al diffusion. But precisely this phenomenon can critically influence the durability of a provided hard material layer with aluminum component under specific conditions of application.

[0014] According to the invention as explained in the following examples, it could be shown that tools with a hard material layer, in particular a (Ti,Al)N layer, comprising at least only a low or no longer measurable composition change of the material of the hard material layer in the active edge region, in many application cases yield a substantially better service life, even with increased cutting efficiency, than other tools, otherwise identical, with a composition change of the hard material layer in the active edge region. Especially good results can be achieved, in the case given first, if in the active edge region the change of one of the metal components of the hard material layer is less than 2 at %, preferably it is maximally 1 at % or no longer measurable.

[0015] Following another feature of the invention, when using arc vaporization for depositing the hard material layer, an as much as possible unchanged hard material layer composition in the active edge region is attained thereby that for the ratio UBIAS—of the electric basic tool body voltage relative to reference potential, usually ground potential,—to the partial pressure of the reactive gas preactiv the following range is maintained:

1×10−3≦UBIAS/preactiv≦4×103,

[0016] with the unit of voltage being “volt” and the unit of pressure “mbar”.

[0017] Furthermore the invention produces drills, roughing milling cutters, peripheral milling cutters and hobbing machines with as much as possible unchanged composition of the hard material layer in the active edge region, however front-end milling cutters and ball-end milling cutters with changed composition of the hard material layer in the active edge region.

[0018] It was in particular found that the composition of the hard material layer in the active edge region of the tools should be realized as much as possible unchanged if these tools are intended for the working of relatively large voltage or cross sections and for low cutting rates; however, that tools should be prepared with a changed composition of the hard material layer in the active edge region if the latter are intended for relatively low voltage machining cross sections but relatively high cutting rates.

[0019] A further criterion for the selection according to the invention of the type of hard material coating in the active edge region of the tools results thereby that for the working of materials with a hardness of at most 45 Rockwell (HRS) and a tensile strength up to at most 1500 N/mm2, preferred for the working of heat-treatable steels, high-alloy and stainless steels as well as of nonferrous metals, to carry out the coating with hard material in the active edge region as much as possible without changing the composition. The same applies to tools whose active edges in application are simultaneously subjected to different cutting rates, such as in particular to drills on which a minimum cutting rate occurs at the tip of the drill and a high rate on the drill periphery.

[0020] Basic tool bodies are coated in the active edge region with changed composition of the hard material layer, which are intended for the machining working of materials with a hardness of more than 45 Rockwell (HRC) and with a tensile strength of more than 1500 N/mm2, in particular for operations involving the removal of hard metal by cutting tools, for example, instead of grinding or erosion processes.

[0021] It has in particular been found, that

[0022] indexable inserts for turning tools and for materials AISI 304SS or DIN 1.4306 to be worked,

[0023] indexable inserts for peripheral milling cutters for materials AISI 4140 or DIN 1.7225 to be worked,

[0024] indexable inserts SEE 42TN for milling cutters for material SKD 61 (HRC 45) to be worked,

[0025] hard metal roughing shank-type milling cutters for materials DIN 1.2344 to be worked in dry working, as well as

[0026] HSS drills for materials AISI D3 or DIN 1.2080 as well as GG 25 to be worked with emulsion lubrication

[0027] should be realized as much as possible with unchanged composition of the hard material layer in the active edge region; however

[0028] hard metal roughing shank-type milling cutters for materials DIN 1.2311 to be worked with emulsion lubrication

[0029] hard metal front-end milling cutters for materials AISI D2 or DIN 1.237 to be worked

[0030] hard metal ball-end milling cutters J97 for dry working of DIN 1.2343, 49.5 HRC, preferably with changed composition of the hard material layer in the active edge region.

[0031] Further, at least two tools are therein provided, one for a first specific application operation in which primarily high adhesion strength of the hard material layer is required, however, only secondarily high hardness of the hard material layer, and a second tool, during the application of which primarily high hardness of the hard material layer is required and only secondarily high adhesion strength of this layer.

[0032] In this tool set according to the invention, the first tool is coated in the active edge region with substantially uniform composition of the hard material layer, however the second one with varying composition of the hard material layer.

[0033] Whether or not a tool is provided with a hard material coating whose composition in the active edge region is changed, is often evident by the coating coloration of the tool in the active edge region, thus typically for (Ti,Al)N layers with Al depletion in the active edge region through its yellowish or reddish coloration in stated region.

[0034] Through the present specification and the claims, the relevant expert gains clear instructions, based on which criteria he is to investigate, which active edge hard material coating techniques lead to better tool application behavior. Even when in specification and claims specific tool types as well as their type of application and the materials to be worked are specified, this is not to be understood to be conclusive for the expert but rather he recognizes, based on the evaluation of the useful coating type for further tools for further application fields and materials, considered by analogy, which coating technique is to be applied, or he obtains the advice first of all to try which of the two coating techniques leads to better results.

BRIEF DESCRIPTION OF THE DRAWINGS

[0035] In the following the invention will be explained with reference to examples and, in connection therewith, to Figures. Therein depict:

[0036] FIG. 1 an Auger line scan diagram, recorded in the active edge region, by example of an indexable insert of type SNGA 120408, at right angles to the active edge. The titanium and aluminum distribution is recognizably uniform, corresponding to an unchanged composition of the hard material layer in the active edge region,

[0037] FIG. 2 an Auger line scan recorded on the same object as in FIG. 1, however, on which the titanium and aluminum distribution in the active edge region is of changed composition of the material of the hard material layer,

[0038] FIG. 3 simplified and schematically, a view onto an installation used for the described experiments.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0039] In the discussed examples, identical basic tool bodies were in each instance coated by means of arc vaporization. In examples 1 to 4 the coating conditions specified in the following by A and B were selected. The layer thickness, in particular in the active edge region, was approximately 3.5 μm.

[0040] The coatings realized under A show a uniform titanium or aluminum distribution according to the Auger line scan of FIG. 1. It was recorded starting on the edge of an indexable insert of Type SNGA 120408 coated according to A at right angles to the active edge or the polished machining face to a length of 0.5 mm, corresponding to approximately 60 measuring points per scan. The hardness of the layers realized under A was approximately 3000 HV0.05.

[0041] The parameters described under B yield layers which in the active edge region have a strong depletion of the aluminum, namely from 50 at % (on the edge) to 40 at %, or an enrichment of titanium from 50 at % (on the edge) to 60 at %, according to FIG. 2. With more sharply pronounced edges, such as for example in the case of knife cutters, markedly greater differences in the material composition of the hard layer could be measured. The hardness of the layers deposited under B is approximately 3500 HV0.05. In the following tables, the two parameter sets A and B for the arc vaporization coating are summarized.

[0042] All experiments were carried out on an installation BAJ 1200 under production conditions.

[0043] In FIG. 3 the view onto an installation of the given type is shown schematically. In a cylindrical treatment chamber 1 a revolving table is supported rotatably with respect to the central axis A1 as shown with the rotational motion ω1. On the revolving table several substrate carrier arrangements 3 are supported each rotatable about axes A2, as is shown with the rotational motion ω2. On the substrate carrier arrangements 3 are supported in individual substrate carriers the substrates 5 grouped about the particular axis A2, which substrates are preferably themselves, and as shown with ω3 driven about their own axis, set into rotational motion.

[0044] Onto the wall of the chamber 1 are flanged one or several arc vaporizer sources 7. With respect to the specific and detailed structure of the installation used, reference is made for example to U.S. Pat. No. 5,709,784 by the same applicant.

[0045] In the experiments exclusively N2 gas was used, i.e. as the working gas as well as also the reactive gas. It is understood that additionally also an inert gas, in particular argon, can be used as the working gas. For the coating of type A the total pressure, i.e. the N2 pressure, was approximately 3×10−2 mbars, for the experiments B approximately 1×10−2 mbars.

[0046] Ti, Al was arc-vaporized from alloy targets.

[0047] In the following tables denote further:

[0048] pN2: partial pressure of reactive gas N2

[0049] ITi: arc current during titanium vaporization

[0050] ITlA1: arc current during TiAl alloy vaporization

[0051] Coating Parameters A:

			TiN Intermediate	(TiAl) N Hard
	Parameter		Layer	Material Layer
	pN2	[mbar]	8 × 10−3	3.2 × 10−2
	ITi	[A]	170	0
	ITiAl	[A]	0	200
	UBIAS	[V]	−200	−40

[0052] Coating Parameters B:

			TiN Intermediate	(TiAl) N Hard
	Parameter		Layer	Material Layer
	pN2	[mbar]	8 × 10−3	1 × 10−2
	ITi	[A]	170	0
	ITiAl	[A]	0	200
	UBIAS	[V]	−150	−150

[0053] In all cases a TiN intermediate layer was installed between basic tool body and hard material layer.

EXAMPLE 1

[0054]

Tool:                 Turning tools with indexable
                      insert K313/CNGP432
Material worked:      AISI 304SS ≅ DIN 1.4306
Cutting rate:         vc = 244 m/min
Advance per rotation: fU = 0.2 mm/r
Cutting depth:        ap = 1.524 mm
Lubricant:            emulsion

[0055]

Experiment No.	Layer	Working Cycles	Cycle Average
1	TiN	7.5	6.8
2		6.5
3		6.5
4	TiAlN “A”	21.0	18.3
5		17.0
6		17.0
7	TiAlN “B”	6.4	5.8
8		5.5
9		5.5

EXAMPLE 2

[0056]

Tool:                 Peripheral milling cutters with
                      indexable insert K903/SEHW43A6T
Material worked:      AISI 4140 ≅ DIN 1.7225
Cutting rate:         vc = 1152 m/min
Advance per rotation: ft = 0.25 mm/r
Cutting depth:        ap = 2.54 mm
Lubricant:            emulsion

[0057]

Experiment No.	Layer	Working Cycles	Cycle Average
10	TiN	15.0	14.8
11		13.0
12		15.5
13		15.5
14	TiAlN “A”	37.0	24.8
15		19.0
16		21.5
17		21.5
18	TiAlN “B”	13.0	12
19		11.0
20		12.0
21		12.0

EXAMPLE 3

[0058]

Tool:                 HSS drill, 6 mm
Material worked:      AISI D3 ≅ DIN 1.2080
Cutting rate:         vc = 35 m/min
Advance per rotation: fU = 0.12 mm/r
Engagement size:      ae = 3 mm
Drilling depth:       h = 15 mm, pocket hole
Lubricant:            5% emulsion

[0059]

		Average Number
Experiment No.	Layer	of Holes
28	TiN	45
29	TiCN	85
30	TiAlN “A”	190
31	TiAlN “B”	30

[0060] Examples 1, 2 and 3 show that for specific tools and conditions of use a composition of the hard material changed in the active edge region, in particular depletion of Al, leads to markedly poorer service lives than an unchanged composition of the hard material layer.

EXAMPLE 4a

[0061]

Tool:                 Hard metal roughing shank-type
                      milling cutter, ø = 10 mm, 25/64
Teeth number:         z = 4
Material worked:      DIN 1.2344, 55-56 HRC
Cutting rate:         vc = 50 m/min
Advance per rotation: ft = 0.02 mm/tooth
Engagement size:      ae = 2 mm
Cutting depth:        ap = 10 mm
Lubricant:            dry, compressed-air cooling

[0062]

Experiment		Wear Width in μm after x Operations
No.	Layer	x = 10	x = 20	x = 30	x = 35
22	TiAlN “A”	45	54	65	70
23	TiAlN “B”	50	69	80	88

[0063] This example shows especially hard conditions of use since hard material is worked dry. The tools coated with the parameters A and consequently tools with unchanged composition of the hard material layers in the active edge region show markedly lower wear mark widths than tools with changed composition of the hard material layer in the active edge region.

EXAMPLE 4b

[0064]

Tool:                 Hard Metal roughing shank-type milling cutter,
                      ø = 10 mm, 25/64
Teeth number:         z = 3
Machined material:    DIN 1.2311, 33 HRC, Rm = 1050 N/mm2
Cutting rate:         vc = 100 m/min
Advance per rotation: ft = 0.035 mm/tooth
Engagement size:      ae = 3 mm
Cutting depth:        ap = 16 mm
Lubricant:            5% emulsion

[0065]

Experiment		Average Length
No.	Layer	of Path
24	TiN	24
25	TiCN	27
26	TiAlN “A”	42
27	TiAlN “B”	78

[0066] This example makes evident that at high cutting rate and additional emulsion lubrication, further with relatively soft material to be worked, on average greater path lengths are achieved with the coating technique according to B.

[0067] Consequently, Examples 4a and 4b show that in similar operations but different conditions of use, identical tools coated differently in the active edge region are advantageous in each instance.

[0068] In the following Examples 5 to 9 further tools are specified with the particular applicable coating parameters analogous to A and B. Those tools with constant composition of the hard material layer in the active edge region are denoted by A0, analogous tools with changed composition of the hard material layer in the active edge region by B0. Apart from the specified coating parameters, identical basic tool bodies were coated with identical coating processes and compared with one another with respect to their service life.

EXAMPLE 5

[0069]

Tool:                      milling cutter with indexable
                           inserts SEE 42 TN (G9)
Teeth number:              z = 6
Layer thickness (TixAly)N: each 4.5 μm
Material worked:           SKD 61 (HRC45)
Cutting rate:              vc = 100 m/min
Advance per tooth:         fz = 0.1 mm/tooth
Cutting depth:             ap = 2 mm

[0070]

		Al
	Coating Conditions	decrease
				Arc	toward	Cutting
		Bias	N2	Current	edge	length
Samples	No.	[−V]	[10−2 mbars]	[A]	[at %]	[m]
A0	32	60	2.5	150	1	3.2
	33	60	3.2	150	1	3.0
	34	40	2.0	150	0	8.8
	35	40	4.0	150	0	3.9
	36	40	0.5	150	0	2.0
	37	30	2.0	150	0	4.2
B0	38	100	2.0	150	4	1.1
	39	150	3.0	150	7	1.1
	40	150	2.0	150	4	0.5

EXAMPLE 6

[0071]

Tool:                      HSS drill, ø 6 mm
Layer thickness (TixAly)N: each 5 μm
Intermediate TiN layer:    each 0.5 μm
Material worked            DIN 1.2080 (AISI D3)
(with emulsion):
Cutting rate:              vc = 40 m/min
Advance:                   f = 0.10 mm/r
Drilling depth:            15 mm (pocket hole)

[0072]

		Al
	Coating Conditions	decrease
				Arc	toward
		Bias	N2	Current	edge	Number
Samples	No.	[−V]	[10−2 mbars]	[A]	[at %]	boreholes
A0	41	40	3.0	200	0	198
	42	40	3.0	200	0	231
B0	43	150	1.0	200	7	45
	44	150	1.0	200	7	38

EXAMPLE 7

[0073]

Tool:                      HSS roughing milling cutter, ø 12 mm
Number of teeth:           z = 4
Layer thickness (TixAly)N: each 4.5 μm
Intermediate TiN layer:    each 0.3 μm
Material worked dry:       DIN 1.2344 (AISI H13)
Cutting rate:              vc = 120 m/min
Advance per tooth:         fz = 0.6 mm/tooth
Cutting depth:             ap = 20 mm
Engagement size:           ae = 5 mm

[0074]

		Al
	Coating Conditions	decrease
				Arc	toward	Cutting
		Bias	N2	Current	edge	length
Samples	No.	[−V]	[10−2 mbars]	[A]	[at %]	[m]
A0	45	40	2.5	200	0	41
B0	46	150	1.0	200	7	12

EXAMPLE 8

[0075]

Tool:                      Hard metal drill, ø 11.8 mm
Layer thickness (TixAly)N: each 5 μm
Intermediate TiN layer:    each 0.5 μm
Material worked            GG 25 (gray cast iron)
(with emulsion):
Cutting rate:              vc = 110 m/min
Advance:                   f = 0.4 mm/r
Drilling depth:            35 mm (pocket hole)

[0076]

		Al
	Coating Conditions	decrease
				Arc	toward
		Bias	N2	Current	edge	Number
Samples	No.	[−V]	[10−2 mbars]	[A]	[at %]	boreholes
A0	47	40	3.0	200	0	2840
B0	48	150	1.1	200	7	1270

EXAMPLE 9

[0077]

Tool:                      Hard metal indexable
                           insert, external turning
Layer thickness (TixAly)N: each 5 μm
Intermediate TiN layer:    each 0.2 μm
Material worked            DIN 1.4306 (X2CrNi 1911)
(with lubrication):
Cutting rate:              vc = 240 m/min
Advance per rotation:      f = 0.6 mm
Cutting depth:             ap = 1.5 mm

[0078]

		Al
	Coating Conditions	decrease
				Arc	toward	Cutting
		Bias	N2	Current	edge	length
Samples	No.	[−V]	[10−2 mbars]	[A]	[at %]	[m]
A0	49	40	3.0	200	0	4.732
B0	50	150	1.0	200	7	2.015

[0079] The Examples 5 to 9 show the superiority of tools with unchanged hard material layer composition in the active edge region in different spectific applications.

EXAMPLE 10

[0080]

Tool:                      Hard metal front-end milling
                           cutter, ø 10 mm
Tooth number:              z = 6
Layer thickness (TixAly)N: each 3.5 μm
Material worked dry        AISI (DIN 1.2379), 60 HRC
Cutting rate:              vc = 20 m/min
Advance per tooth:         fz = 0.035 mm/tooth
Cutting depth:             ap = 15 mm
Engagement size:           ae = 1 mm

[0081]

		Al
	Coating Conditions	decrease
				Arc	toward	Cutting
		Bias	N2	Current	edge	length
Samples	No.	[−V]	[10−2 mbars]	[A]	[at %]	[m]
A0	51	40	3.0	200	0	4
	52	40	2.0	200	0	2
	53	20	2.0	200	0	3
	54	70	3.0	200	1.5	12
B0	55	200	3.0	200	9	21
	56	150	2.0	200	7	29
	57	100	1.0	200	4	17
	58	100	2.0	200	4	22

EXAMPLE 11

[0082]

Tool:                      Hard metal front-end milling
                           cutter, ø 10 mm
Tooth number:              z = 6
Layer thickness (TixAly)N: each 3.5 μm
Intermediate TiN layer:    each 0.1 μm
Material worked            DIN 1.2379 (AISI D2), 60 HRC
Cutting rate:              vc = 20 m/min
Advance per tooth:         fz = 0.03 mm/tooth
Cutting depth:             ap = 15 mm
Engagement size:           ae = 1 mm

[0083]

		Al
	Coating Conditions	decrease
				Arc	toward	Cutting
		Bias	N2	Current	edge	length
Samples	No.	[−V]	[10−2 mbars]	[A]	[at %]	[m]
A0	55	40	3.5	200	0	22
B0	56	150	1.0	200	7	31

EXAMPLE 12

[0084]

Tool:                      Hard metal ball-end milling
                           cutter J97 (Jabro), R4
                           (ø 8 × 65 mm)
Layer thickness (TixAly)N: each 3.5 μm
Intermediate TiN layer:    each 0.1 μm
Material worked dry:       DIN 1.2343, 49.5 HRC
Cutting rate:              vc = 240 m/min
Cutting depth:             ap = 0.5 mm

[0085]

		Al
	Coating Conditions	decrease
				Arc	toward	Cutting
		Bias	N2	Current	edge	length
Samples	No.	[−V]	[10−2 mbars]	[A]	[at %]	[m]
A0	57	40	3.0	200	0	111
B0	58	150	1.0	200	7	168

[0086] Examples 10 to 12 show that under certain application conditions and with specific tools the service lives are increased if the composition of the hard metal layer is changed in the active edge region.

Claims

19. A method for producing cutting tools comprising the steps of: providing on a first region of a tool body that contains at least one first cutting edge, a first hard material coating by means of a plasma vacuum coating process; providing on a second region of said tool body that is adjacent said first region, a second hard material coating by means of said plasma vacuum coating process; selecting as hard material for said first and second hard material coatings, a material selected from the group consisting of: carbide, oxide, oxicarbide, nitride, nitrocarbide, oxinitride and nitrooxicarbide, of at least two of the metal elements Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W and Al; selecting said first hard material coating to have a content at least two of said metal elements which is at most 2at % different from a content of said at least two metal elements in said second hard material coating if the tool being produced must fulfill a requirement of high adhesive strength of the first hard material coating to a higher degree than a requirement of hardness of said first hard material coating; and selecting said first hard material coating to have the content of said at least two metal elements to be different from the content of said two metal elements of said second hard material coating by more than 2 at % if the tool being produced must fulfill a requirement of high hardness of said first hard material coating to a higher degree than a requirement of high adhesive strength of said first hard material coating.

20. The method of claim 19, further comprising the step of depositing at least as a part of said hard material coatings a (Ti,Al)N coating on said tool body.

21. The method of claim 20, further comprising the step of providing an intermediate layer between said tool body and said hard material coatings.

22. The method of claim 19, further comprising the step of depositing said hard material coatings by means of arc evaporation.

23. The method of claim 19, further comprising the step of realizing said first hard material coating to have a content of said at least two metal elements that is different from said content of said metal elements in said second hard material coating by at most 2at % by establishing a ratio of a bias voltage applied to said tool body during said coating process with respect to an electric reference potential for a plasma discharge of said plasma vacuum coating process with respect to partial pressure of a reactive gas in a process atmosphere of said plasma vacuum coating process to be:

24. The method of claim 23 including selecting ground potential as said electric reference potential.

25. The method of claim 19, including selecting said first hard material coating to have a content of said at least two metal elements at most 2 at % different from said content of said metal elements in said second hard material coating for tool bodies of drills, roughing milling cutters, peripheral milling cutters, tools for hobbing machines or turning tools.

26. The method of claim 19, further comprising the step of applying said fist hard material coating to have a content of said at least two metal elements to be different from said content of said at least two metal elements of said second hard material coating by more than 2 at % for tool bodies of front-end milling cutters or of ball-end milling cutters.

27. The method of claim 19, further comprising the step of applying said first hard material coating with a content of said at least two metal elements to be different by at most 2 at % with respect to said content of said at least two metal elements of said second hard material coating for tool bodies of tools for cutting with a larger cross-sectional area of the cut at a lower cutting rate and applying said first hard material coating with a content of said at least two metal elements to be different by more than 2 at % with respect to the content of said at least two metal elements in said second hard material coating for tool bodies for tools for cutting with smaller cross-sectional area of the cut at a larger cutting rate.

28. The method of claim 19, further comprising the step of applying said first hard material coating to have a content of said at least two metal elements to be different from said content of said at least two metal elements in said second hard material coating by at most 2 at % for tool bodies of tools for cutting workpiece material having a hardness of up to at most 45 Rockwell and a tensile strength of up to at most 1500 Nmm−2.

29. The method of claim 28, wherein said tool bodies are tool bodies of tools for working quenched steels, highly alloyed steels, stainless steels or non-ferrous metals.

30. The method of claim 19, further comprising the step of applying said first hard material coating to have a content of said at least two metal elements to be different from said content of said at least two metal elements in said second hard material coating by at most 2 at % for tool bodies for tools, the cutting edge thereof being loaded simultaneously with different cutting speeds relative to a worked workpiece.

31. The method of claim 30, wherein the tool to be produced is a drill where minimum cutting speed occurs at a tip of the drill and significantly higher cutting speed occurs at a circumference of the drill.

32. The method of claim 19, further comprising the step of applying said first hard material coating to have a content of said at least two metal elements to be different from said content of said at least two metal elements in said second hard material coating by more than 2 at % for tool bodies of tools for cutting workpiece materials having a hardness of more than 45 Rockwell and a tensile strength of more than 1500 Nmm−2.

33. The method of claim 32, wherein the tool body is a too l body for a tool for hard chipping.

34. The method of claim 19, further comprising the step of applying said first hard material coating to have a content of said at least to metal elements to be different from said content of said at least two metal elements in said second hard material coating by at most 2 at % for tool bodies for the following tools: indexable inserts for turning tools and for working material AISI 304 SS or DIN 1.4306; indexable inserts for peripheral milling cutters for working material AISI 4140 or DIN 1.7226; indexable inserts SEE42TN for milling cutters for working material SKD 61 (HRC 45); hard metal roughing shank-type milling cutters for working material DIN 1.2344 to be worked in dry working; HSS drills for working material AISI D3 or DIN 1.2080 as well as GG25 to be worked with emulsion lubrication.

35. The method of claim 19, further comprising the step of applying said first hard material coating to have a content of said at least two metal elements to be different from said content of said at least two metal elements in said second hard material coating by more than 2 at % for tool bodies of the following tools: hard metal roughing shank-type milling cutters for working materials DIN 1.2311 to be worked with emulsion lubrication; hard metal ball-end milling cutters for working material AISI D2 or DIN 1.2379; hard metal ball-end milling cutters J97 (Jabro) for dry working of DIN 1.2343, 49.5 HRC materials.

36. The method of claim 19, wherein said first and second hard material coatings comprise at least one (Ti,Al)N layer.

37. The method of claim 19, thereby selecting said first hard material coating to have a content of said at least two metal element which is at most 1 at % different from the content of said at least two metal elements in said second hard material coating, if said tool being produced must fulfill the requirement of high adhesive strength of the first hard material coating to a higher degree than the requirement of hardness of said first hard material coating.

38. The method of claim 36, wherein a content of Al in the material composition of said first hard material coating varies by less than 1 at % with respect to the content of said Al in said second hard material coating, if the tool being produced must fulfill the requirement of high adhesive strength of the first hard material coating to a higher degree than the requirement of hardness of said first hard material coating, and further selecting the content of aluminum in the material composition of said first hard material coating to be from the content of said Al of said second hard material coating by more than 2 at %, if said tool being produced must fulfill the requirement of high hardness of said first hard material coating to a higher degree than the requirement of high adhesive strength of said first hard material coating on said base body.