CZ2013542A3 - Coated pressing or forming tools - Google Patents

Abstract

Coating press or forming tools of steel, at least working surfaces of which have a protective nanocomposite titanium, boron and carbon (TiBC) layer in combination with titanium diboride (TiB 2) and titanium nitride (TiN). To ensure good adhesion of both (TiBC) and z (TiB.sub.2.n) intermediate layers to the steel substrate, a lower titanium nitride layer (TiN) is first applied followed by a medium protective intermediate layer composed of titanium, boron and carbon ( TiBC), wherein a titanium diboride top protective layer (TiB.sub.2) is applied to the intermediate protective interlayer (TiBC) containing boron nitrides and titanium nitrides, and the protective nanocomposite multilayer is terminated with a titanium nitride (TiN) topsheet . The protective nanocomposite multilayer has a thickness of 2 to 4 microns. The thickness of the first titanium nitride (TiN) backsheet applied to the steel substrate does not exceed 0.5 µm. In a preferred embodiment of this embodiment, the intermediate protective layer composed of titanium, boron and carbon (TiBC) regularly alternates with the upper titanium diboride protective layer (TiB 2) so that several of these intermediate layers are arranged one above the other. The protective nanocomposite multi-layer is always topped with a titanium nitride (TiN) top layer.

Description

Coated punching or forming tools

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to steel punching or forming tools whose surface is coated to increase durability as well as their quality.

BACKGROUND OF THE INVENTION

At present, there is a great interest in increasing the life of various types of tools, such as stamping tools. Various forming or pressing tools are used to produce various machine parts or finished products. This process is very demanding on the pressing or forming tool itself, and therefore more expensive grades of steel with higher performance properties are used as the basic materials for these tools. The production of the tool itself is also often very expensive, and therefore manufacturers have been looking for other technologies to extend the life of the dies in recent years in order to save production costs.

The pressing or forming process is carried out cold or hot, in several stages according to the technological process. Throughout the technological process, the pressing tools used are subject to a high mechanical stress. Increase in tool life can be achieved by thin film deposition created by plasma methods. In this case, it is mainly an increase in hardness and a reduction in the coefficient of friction.

At present, there is a great deal of published information on the coating of stamping or forming tools with thin hard layers to improve their performance. Various types of nitride, oxide or carbide coatings are made, for example based on tungsten carbide, which are characterized by good hardness, which guarantees high wear resistance of the tools.

Tool surface wear coatings are widely used in industry in many areas ₍ such as stamping or molding. Wear on these tools not only reduces tool life but also can lead to deterioration in molding quality. Worn tools are reconditioned or discarded depending on the state of wear, and various technological processes have been used to increase the life of the dies, and in recent years, the most widespread is the formation of thin films using the CVD method, which stands for Chemical Vapor Deposition. known method called PACVD (Plasma Assisted Chemical Vapor Deposition) or PVD (Physical Vapor Deposition) These methods impose specific requirements on the properties of thin films produced by plasma In all these cases, coatings should be characterized by a high hardness and a smooth surface with a low coefficient of friction.

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SUMMARY OF THE INVENTION

One possible way to solve the above problems with hardened steel punching or forming tools is to use thin protective multilayers based on titanium, boron and carbon, i.e. TiBG in combination with titanium diboride T1B2. To ensure good adhesion of the two T1BC / TiB2 layers to the steel substrate, a titanium nitride backing layer ΊΪΝ is first applied. In this case, most of the undesirable residual stresses of the multilayers so constructed are eliminated due to local deformation of the softer first TiN backing material. The protective multilayer formed upstream of the steel substrate TiN, TiBC and T1B2 is again topped with a top layer of titanium nitride TiN. Thus, between the first TiN backsheet and the TiN backsheet, there is an intermediate titanium, boron and TiBC based intermediate intermediate layer on which the top titanium diboride T1B2 intermediate intermediate layer is applied.

According to the proposed solution, it is advantageous that the TiBC and T1B2 protective interlayers are alternately deposited in the next stage of the tool treatment in order to increase the hardness and reduce the internal stresses in the multilayer thus formed. Thus, the intermediate protective interlayer consisting of titanium, boron and carbon is composed of several superimposed layers, and also the subsequent upper protective interlayer of titanium diboride is composed of several superimposed layers, the intermediate protective interlayers of titanium, boron and carbon alternating regularly with the upper protective titanium diboride interlayers. The protective nanocomposite multilayer is always topped with an upper layer made of titanium nitride. Based on the tool life studies carried out, it was found that to achieve the desired goal, a system of protective interlayers of TBC / T1B2 of more than twenty had to be created.

The system of individual coatings thus formed ensures a strong and durable connection between the protective multilayer and the steel surface of the tool. The protective multilayer has a thickness of 2 to 4 µm, while the thickness of the first TiN backing layer does not exceed 0.5 µm. The protective multilayer consists of the first TiN bottom layer, medium _? TiBC protective interlayer, T1B2 top protective interlayer, and final NfF top layer. Medium protective interlayer, resp. medium protective interlayers composed of titanium, boron and carbon / and a top protective interlayer, respectively. the upper protective interlayers of titanium diboride / have a hardness of about 45 GPa. The thickness of the final TiN top layer was 0.5 µm.

Overview of the figure in the drawing

The construction of a protective nanocomposite multilayer applied to the surface of a steel stamping tool is shown schematically and illustratively in the attached figure. First, a first lower titanium nitride layer is formed in the direction away from the steel substrate, followed by a medium protective intermediate layer composed of titanium, boron and carbons. the top protective intermediate layer of titanium diboride is applied and the protective multilayer is then topped with an upper layer of titanium nitride.

DETAILED DESCRIPTION OF THE INVENTION

According to the figure, a protective nanocomposite multilayer composed of several layers formed sequentially away from the steel substrate is deposited on the die surface. The first backsheet consists of titanium nitride TiN, on which a middle protective intermediate layer of TiBC, composed of titanium, boron and carbon, is deposited, containing boron nitrides and titanium nitrides / followed by a top protective titanium diboride intermediate layer T1B2. In a preferred embodiment of the present invention, the intermediate protective intermediate layer TiBC and the upper protective intermediate layer T1B2 are arranged alternately with each other and this interconnection of the two intermediate layers is repeated several times, for example at least twenty times. The protective multilayer constructed in this way is finally terminated with an upper layer again made of titanium nitride TiN. This top layer of titanium nitride has a thickness of 0.5 µm. The thickness of the first TiN backing applied to the steel substrate does not exceed 0.5 µm.

The thickness of the entire protective nanocomposite multilayer is in the range of 2 to 4 µm and is always terminated with an upper layer of titanium nitride.

The protective nanocomposite multilayer is applied gradually and its creation uses PA CVD (plasma assisted chemical vapor deposition) technology. In the chamber of the device, gases are decomposed by means of plasma at a temperature of ~ 500 ° C: titanium tetrachloride (T1Cl4 - source Ti), boron trichloride (BCI3 - source B), methane (CH4 - source C) and nitrogen. Improvement of the adhesion of the intermediate TiBC intermediate layer and subsequently of the T1B2 top intermediate layer to the metal substrate is achieved by using the first TiN nitride backing layer which is first applied to the steel substrate and whose thickness does not exceed 0.5 µm. In the next phase, the protective interlayers TiBC and T1B2 are deposited alternately in the number of more than 20 repetitions to achieve the required hardness and reduce internal stresses. Finally, a top layer of TiN is applied, terminating the protective multilayer.

The device for application of individual layers of protective nanocomposite multilayers uses the pulse technology DC-PECVD, where the main source of plasma is DC pulse discharge (DC pulses). The use of this deposition system makes it possible to realize the formation of a protective nanocomposite multilayer without having to interrupt the process and open the reaction chamber. The wide range of plasma generator parameters, the ability to control temperature and pressure in combination with a precise gas metering system allow full control during the single layer formation process, giving the possibility to influence the chemical composition and properties of deposited layers deposited on the steel substrate surface of the die.

By realizing the deposition of TIN / TIB / TIB2 / TIN thin films on the press tool surface according to the invention, it has been shown that the friction coefficient for the friction pair consisting of steel and hardened steel sample provided with a top protective nanocomposite multilayer does not exceed 0.6 (on polished sample). It has been shown that the coating formed from the T1BC / TiB2 protective interlayers is characterized by a hardness of 45 GPa, Young's modulus of elasticity (GPa). The tools provided with these layers and interlayers have been successfully tested in industrial applications where they significantly increased the service life and performance of dies.

Claims (6)

Coated punching or forming tools of steel, characterized in that at least their working surfaces are provided with a protective nanocomposite multilayer composed of several layers formed successively downstream of the hardened steel substrate by the first titanium nitride (TiN) backing ₍ on which a middle protective intermediate layer made of titanium, boron and carbon (TiBC), also containing boron nitrides and titanium nitrides, the upper protective intermediate layer (TiBC) being coated with a top protective intermediate layer of titanium diboride (TiB2) and a protective nanocomposite multilayer topped with a top layer of titanium nitride (TiN). Coated steel punching or forming tools according to Claim 1, characterized in that the first titanium nitride (TiN) backing layer has a thickness not exceeding 0.5 µm. Coated steel punching or forming tools according to claim 1, characterized in that the terminating top layer of titanium nitride (TiN) has a thickness of 0.5 µm. Coated steel punching or forming tool according to claim 1, characterized in that the intermediate protective interlayer composed of titanium, boron and carbon (TiBC) is composed of several layers placed one above the other ₍ between which the individual top protective interlayers of diboride are regularly placed) titanium (T1B2), the protective nanocomposite multilayer is always topped with a top layer of titanium nitride (TiN), which is located on the last top protective intermediate layer of titanium diboride (TiB ₂ ). Coated steel punching or forming tools according to claim 1, characterized in that the protective nanocomposite multilayer has a thickness of 2 to 4 µm. Coated steel punching or forming tools according to claim 1, characterized in that the intermediate protective intermediate layer composed of titanium, boron and carbon (TiBC), the upper protective intermediate layer of titanium diboride (T1B2) and the finishing layer of titanium nitride (TiN) have hardness around 42 GPa.