DE202009001002U1 - Wire-shaped spray material - Google Patents

Abstract

Wire-shaped spray material (4),
in particular for arc wire spraying,
essentially comprising iron,
wherein the spray material (4) is formed at least with carbon as a micro-alloy such that martensite, bainite and perlite arise during the solidification of the spray material,
wherein in the microalloy solid lubricant constituents or alloy components are provided for the formation of solid lubricant constituents,
characterized,
that the following alloy constituents are included:
Carbon: 0.1% to 0.28% by weight,
Manganese: 1.4% to 2.1% by weight,
- Silicon: 0.05 wt .-% to 0.3 wt .-%.
each based on a total weight.

Description

The Invention relates to a wire-shaped spray material, in particular for arc wire spraying, comprising substantially Iron and a layer deposited on a substrate. The invention further relates to a method for coating a Substrate in which a wire-shaped spray material in melted an arc and as a layer on the substrate is deposited.

at The production of internal combustion engines is for reasons energy efficiency and emission reduction as much as possible low friction and high abrasion and wear resistance sought. For this purpose, engine components, such as cylinder bores or their walls provided with a tread layer or bushings are inserted into the cylinder bores, which are provided with a tread layer. The Applying such tread layers is usually done by thermal spraying, for example electric arc wire spraying. When arc wire spraying is between two wire-shaped Spray materials generated an arc by applying a voltage. The wire tips melt and are, for example, by means of an atomizing gas on the surface to be coated, For example, the cylinder wall conveys where it is attach.

From the DE 103 08 563 B3 a cylinder liner for internal combustion engines is known, comprising a base body with a wear protection coating on the tread, based on a hard iron alloy with carbon and oxygen, wherein the wear protection layer has martensitic phases and oxides and the wear protection layer in the arc-wire spraying process is applicable and the alloy of the coating has a carbon content of 0.05 to 3 wt .-%.

From the DE 20 2008 009 964 U1 is a wire-shaped spray material, in particular for arc wire spraying, comprising essentially iron, which is characterized in that the spray material is formed at least with carbon as a micro-alloy such that arise during solidification of the spray martensite, bainite and lower proportion of finely stripped perlite, wherein the microalloy solid lubricant constituents or alloy constituents are provided for the formation of solid lubricant constituents. In the spray material include 0.55 wt .-% to 0.65 wt .-% carbon, 0.7 wt .-% to 1.1 wt .-% manganese and 0.1 wt .-% to 0.4 wt .-% silicon included.

It It is an object of the invention to provide a cost effective improved wire-shaped spray material, in particular for arc wire spraying specify. When determining the wire-shaped spray material In addition to the coating properties, the spray behavior of the wire-shaped spray material and the machinability the sprayed layer influenced.

It Another object of the invention is a dense, tribological represent improved sprayed layer, which in particular by arc wire spraying on a substrate and apply work well.

The The object is achieved by a wire-shaped spray material with the features of Claim 1.

A coating of such a wire-shaped spray material has comparable properties as a coating of a spray material according to the DE 20 2008 009 964 U1 but the lower carbon content and the increased manganese content have a positive influence on the spray behavior of the spray material.

advantageous Further developments are the subject of the dependent claims.

An inventive wire-shaped spray material, in particular for arc wire spraying, essentially comprises iron. The spray material is formed at least with carbon as a micro-alloy such that at least pearlite, bainite and lower levels of martensite are formed upon solidification of the spray material, micro-alloying elements being additionally provided for forming wear-resistant phases and for improving the tribological properties. Microalloys are those alloys which are predominantly formed from a constituent to which only minor amounts of further constituents are added relative to a total mass. Fine-grained pearlite, consisting of hard Fe ₃ C and ferrite, is a tribologically positive effective phase. Bainite is a conversion phase of medium hardness and wear resistance. Martensite is a hard, wear-resistant structure. The formation of martensite can be targeted by the nature of the cooling of the spray material and by the choice of alloying components of the microalloy be influenced. A layer on a substrate, for example a cylinder surface, produced by means of an arc wire spraying using the spray material according to the invention comprises bainite, wear-resistant islands of martensite and finely striated pearlite.

tribologically effective phases serve to improve the running behavior in critical System states, so that z. B. when tearing off Lubricating films excessive wear of the Friction partner or their damage by adhesive Reactions are avoided. These states occur in particular in mixed friction areas on z. B. OT and UT areas in the Tribosystems Cylinder surfaces / piston rings.

in the Below is an embodiment of the invention based a drawing explained in more detail.

there shows:

1 a substrate having a sheet deposited by arc wire spraying.

In 1 is a substrate 1 with a layer deposited by wire arc spraying (LDS) 2 shown. In arc wire spraying, a coating head 3 two wire-shaped spray materials 4 fed. Between the wire-shaped spray materials 4 becomes an arc 5 ignited. This melts the wire-shaped spray material 4 and is targeted by means of a carrier gas to the substrate to be coated 1 Applied where it cools, it solidifies and the layer 2 forms.

The wire-shaped spray material 4 essentially comprises iron. The spray material is formed at least with carbon as a micro-alloy such that predominantly perlite and bainite are formed upon solidification of the spray material. Furthermore, alloy constituents are provided in the microalloy for the formation of wear-resistant phases (martensite) and for reducing the coefficient of friction.

The following alloy components are provided: Carbon from 0.1% to 0.28% by weight + Silicon from 0.05% to 0.3% by weight + Manganese 1.4% by weight to 2.1% by weight + - Nitrogen 120 ppm. up to 170 ppm. + Copper from 0.05% to 0.25% by weight + Titanium maximum 0.001% by weight + - Phosphorus not more than 0.02% by weight + Sulfur maximum 0.02% by weight + - Vanadium not more than 0,001% by weight - - Aluminum maximum 0.02 wt .-% - Boron maximum 0.0004% by weight -

The Quantities are in percent by weight each based on a total weight, if no other information is given.

• – Kohlenstoff 0,23 Gew.-%
• – Silizium 0,29 Gew.-%
• – Mangan 1,8 Gew.-%
• – Kupfer 0,2 Gew.-%
• – Stickstoff 150 ppm.

It is preferred for the wire-shaped spray material 4 used a microalloy with the following constituents:

• Carbon 0.23% by weight
• Silicon 0.29 wt.%
• Manganese 1.8% by weight
• Copper 0.2% by weight
• - Nitrogen 150 ppm.

Of the The main component of microalloying is iron.

The arc wire spraying with a wire-shaped spray material formed from this microalloy 4 leads to a particularly homogeneous layer 2 with low porosity and low roughness.

The opposite to the DE 20 2008 009 964 U1 lower carbon content, the increased manganese content and the silicon content of the microalloy result in an improved spray behavior, which is characterized by the fact that the arc wire spraying produces regular, small, viscous droplets. On Due to their viscosity, these decompose only slightly in flight and when they bounce to finer particles and thus tend less to oxidation. A lower surface oxidation promotes the adhesion of the particles to the substrate (layer adhesion) and the adhesion of the particles to one another (layer cohesion).

In addition, the increased manganese content leads to a predominantly pearlitic / bainitic microstructure during the solidification of the sprayed layer 2 ,

The addition of copper improves the corrosion protection of the layer 2 ,

When the layer solidifies 2 produces fine-grained pearlite and bainite. Bainite is a tough intermediate structure of carbonaceous steels. Perlite is a mixed structure of soft ferritic and hard carbide phases. The layer 2 has a soft, ductile matrix of pearlite and bainite with hard, wear-resistant martensite islands.

The addition of nitrogen promotes the formation of wear-resistant nitrides upon solidification of the layer 2 , The nitrides are wear-resistant and tribologically effective in terms of friction coefficient reduction.

The wire-shaped spray material 4 is preferably hot rolled and / or hot drawn and then slowly and controlled cooled in an oven and / or annealed to obtain a ductile structure, so that the wire-shaped spray material 4 remains flexible.

The alloy components of the wire are sized so that the burning of certain elements, eg. B. carbon is taken into account. The alloy composition of the layer 2 is changed according to the burnup. The wire composition is tailored to the target properties of the sprayed layer

Preferably, a surface of the wire-shaped spray material 4 coppered to prevent corrosion of the spray wire.

Of the Wire is low-alloyed, with the choice being specific to cost-effective Alloy elements is aligned.

The The resulting sprayed coating shows good workability and excellent tribological properties and a very good wear resistance.

1

substratum

2

layer

3

coating head

4

wire-shaped Spraying material

5

Electric arc

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 10308563 B3 [0003]
• - DE 202008009964 U1 [0004, 0008, 0022]

Claims (6)

Wire-shaped spray material ( 4 ), in particular for arc wire spraying, comprising essentially iron, wherein the spray material ( 4 ) is formed at least with carbon as a microalloy such that martensite, bainite and perlite are formed upon solidification of the spray material, wherein in the microalloy solid lubricant constituents or alloy constituents are provided for the formation of solid lubricant constituents, characterized in that the following alloying constituents are present: carbon: 0, 1% by weight to 0.28% by weight, manganese: 1.4% by weight to 2.1% by weight, silicon: 0.05% by weight to 0.3% by weight %. each based on a total weight. Wire-shaped spray material ( 4 ) according to claim 1, characterized in that nitrogen is additionally contained in the spray material in proportions of 100 to 200 ppm, preferably from 120 to 170 ppm. Wire-shaped spray material ( 4 ) according to claim 1 or 2, characterized in that in addition copper in the spray material is contained with a proportion of 0.05 wt .-% to 0.25 wt .-% based on a total weight. Wire-shaped spray material ( 4 ) according to one of claims 1 to 3, characterized in that additional alloying constituents are contained: titanium: 0.0001% by weight to 0.001% by weight and / or phosphorus: 0.001% by weight to 0.02 Wt .-% and / or - sulfur: 0.001 wt .-% to 0.02 wt .-% and / or - vanadium: 0.0001 wt .-% to 0.001 wt .-% and / or - Alminium: 0.001 wt .-% to 0.02 wt .-% and / or - boron: 0.0001 wt .-% to 0.0004 wt .-% and / or in each case based on a total weight. Wire-shaped spray material ( 4 ) according to one of the preceding claims, characterized in that a copper plating of a surface of the spray material ( 4 ) is provided. Thermally sprayed iron-based layer, in particular Arc wire sprayed, characterized in that the sprayed layer a fine pearlitic, bainitic martinsitic structure in which finely divided nitrides are present.