DE10118029C1 - Process for the thermo-chemical pre-treatment of metallic workpieces, especially case hardening steel is carried out in an atmosphere containing hydrogen and hydrogen-containing gases to which oxygen and air are added - Google Patents

Abstract

Process for the thermo-chemical pre-treatment of metallic workpieces is carried out in an atmosphere containing hydrogen and hydrogen-containing gases to which oxygen and air are added at a temperature of at least 800 deg C and at a pressure of 0.04-0.2 MPa. Preferred Features: The pre-treatment is carried out in a mixture of hydrogen or hydrogen-containing gases and 1-50 vol.% oxygen, or in a mixture of natural gas and air having a volume ratio of 2.2-1.8: 1. The pre-treatment is carried out at a temperature of at least 800 deg C for 1-60 minutes, preferably 8-12 minutes.

Description

The invention relates to a method for thermochemical pretreatment of metallic workpieces, in particular case-hardening steels, for one subsequent thermochemical treatment from the carburizing group, Nitriding, nitro carburizing, boronizing, pretreatment of the plant pieces in an atmosphere containing hydrogen or water gases containing at temperatures of at least 800 ° C.

The well-known thermochemical carburizing and / or embroidery of Steels at high temperatures in gas atmospheres with components from the group carbon and nitrogen represents an economical and environmentally friendly process for case hardening of workpieces.

It is also only possible with such methods to partially remove components, if necessary. H., only to be treated accordingly in certain surface areas. In particular for so-called complicated workpieces, i. H. such with a complicated geometry, only such processes are possible, if necessary, but not necessarily, with the support of a plasma discharge.  

A common feature of the mentioned methods is a dependency of the treatment result of the surface condition of the workpieces, wherein disruptive effects, especially in bores and even more so in snakes Do not drill blind holes with unfavorable ratios of lengths Diameters and for workpieces with different wall thicknesses occur.

It is known that the diffusion processes through the surfaces are strong depend on the delivery condition of the workpieces. Possible mismatch cleaning agents such as detergent residues, preservatives, cutting oils etc. can significantly influence the treatment result. homogeneous and reproducible diffusion processes and hardness profiles are thereby practically not possible. The causes are uneven and incomplete Cleaning, residues from production or other surfaces changes, for example through forming processes with structure changes and / or machining as well as oxide layers. Inhomogeneous diffusion processes can occur in the following Harden to create mechanical residual stresses lead that the strength, especially the fatigue strength of the Adversely affect workpieces.

From EP 0 545 069 B1 it is known that when carburizing, tempering, annealing, carbonitriding and nitrocarburizing, due to the use of oxygen-containing process gases, there is an intercrystalline edge oxidation of the workpieces, which reduces the fatigue strength and reduces the service life Consequence. To solve this problem, a two-stage process for thermochromic treatment of the surfaces of workpieces made of steels and refractory metals is proposed, in which step case hardening is carried out by gas or gas mixtures and in a second process step for thermochemical removal of the edge oxidation at least one gas the group N ₂ , H ₂ or NH ₃ let into a process chamber and a pressure greater than 0.1 MPa and a temperature between 100 ° C and 1000 ° C is set. Pressures of 1 and 2 MPa and a temperature of 580 ° C are given as examples.

The primary concern is the removal of the oxide passive layer ten that later diffusion of non-metals such as N, C and B when nitriding, nitro carburizing and boronizing. The aim is So as far as possible a reduction and removal of the edge oxides avoiding any addition of oxygen or an oxygen containing connection. However, it has been shown that not all Consequences of different pretreatments of the workpieces for success rich after-treatments can be eliminated. With complicated shaped workpieces, the undercuts that are difficult to access, Have internal holes and blind holes or pipes, ball cages or This document deals with nozzle bodies with inner surfaces to be hardened Not.

From DE 41 15 135 C1 it is known to use steel workpieces difficult to access areas such as hollow bodies with holes Carburize nozzle bodies and / or embroider that one Workpieces temperatures above 450 ° C, pressures above 0.2 MPa to 10 MPa and reactive gases exposed to ammonia, nitrogen, and / or carbon compounds such as methane, carbon dioxide and carbon contain monoxide. Air additions are also given. For the nitrie temperatures of 500 ° C, for carburizing temperatures between 870 and 1000 ° C. With the removal of influences this document does not deal with pretreatments of the workpieces.

From DE 24 17 179 C3 it is known to use in high-alloy steels a chromium content of at least 2% at temperatures up to 1037 ° C in an oxidizing atmosphere for 30 minutes to 4 hours, too for 6 to 30 hours, first an oxide layer on the steel surface generate surface and then carburize the oxidized steel. This is explained by the fact that in the gaps or pores by the Verhin change in direct access to carbon dioxide due to a dense, better carburization takes place throughout the outer oxide layer. According to the task, the problems caused by the formation of a passive oxide layer at low temperature  so that it becomes possible to keep the steels for a considerable time to be stored before they are carburized. The one at high tempera oxide layer produced should not stand in the way of carburization, but allow carbon to be uniform in the steel surface diffused. It is also stated that carbon steel the high-temperature oxidation loses carbon, which subsequently The carburizing phase must be fed again. It is also indicated ben that the blank hardened by quenching bear must be processed to remove the oxide layer again. Not specified is the simultaneous presence of hydrogen or hydrogen containing gases.

From the abstract of JP 060 57 400 A it is also known under Avoiding prior degreasing the uniformity of the Nitriding of steel parts to increase by having the steel parts on Air is heated to temperatures of at least 200 ° C to reach the steel share to form an oxide layer. Then either the residual air removed and supplied with a nitrogenous gas, or the Steel parts are said to be in an inert gas atmosphere at temperatures of be heated to at least 200 ° C, and then again Air is supplied to create the oxide layer, and again a nitriding treatment is then to be carried out in a known manner become. The simultaneous presence of water is not specified gases or hydrogen-containing gases.

The invention is therefore based on the object of a method of The type described at the beginning for pretreating workpieces specify by the for a subsequent homogeneous and reproducible bare gas diffusion disturbing or harmful impurities, influences removed from mechanical and / or chemical manufacturing processes are, and in particular for workpieces made of steel with difficult to access areas such as hollow bodies with holes Nozzle bodies and sleeves. In particular, such workpieces should also be activated for the subsequent thermochemical treatment.  

The solution to the problem is the one specified at the beginning Method according to the invention in that a gas from the atmosphere oxygen and air are added to the group and that the pretreatment at a pressure between 0.04 and 0.2 MPa.

The object is achieved in full by the invention, in particular it was surprisingly found that the presence of oxygen leads to more positive results, namely:

• 1. Treatment of complicated workpiece geometries,
• 2. of narrow and long bores, especially of deep blind holes,
• 3. with better activation for the subsequent processes,
• 4. with more homogeneous mass transfer in the subsequent process,
• 5. with greater reproducibility and process reliability,
• 6. with better cleaning effect,
• 7. with reduction of surface oxides,
• 8. with simultaneous combustion of organic residues,
• 9. with a "healing effect" by reduction too strongly activated workpieces in the sense of a weak passivation due to slight oxidation,
• 10. with the reduction of internal stresses and structural Influences caused by previous Manufacturing measures (machining, forming) were caused
• 11. with more even hardness gradients from the surface inside the workpieces (see the diagrams),
• 12. with a stabilization of the surface properties against subsequent air influences.

This leads to the simultaneous presence of reducing hydrogen or hydrogen-containing gases and oxidizing gases such as oxygen or air that is fed separately to the furnace chamber is by no means blocked an explosion, as this is prevented by the furnace temperature. The  Mastery of such gas mixtures with oxygen and hydrogen is known from other processes.

In the course of further refinements of the method according to the invention, it is particularly advantageous if - either individually or in combination:

• - pretreatment in a mixture of hydrogen or water gases and 1 to 50% by volume oxygen carried out becomes,
• - pretreatment in a mixture of natural gas and air with a Volume ratio of (3 to 1): 1 is carried out,
• - pretreatment in a mixture of natural gas and air with a Volume ratio of (2.2 to 1.8): 1 is carried out,
• - The duration of the pretreatment at temperatures of at least 800 ° C is between 1 and 60 minutes, especially if the Pretreatment time is between 8 and 12 minutes.

It is particularly advantageous to apply the method to the preparation action of complex workpieces with inner surfaces from the group Undercuts, holes and blind holes.

An embodiment of the subject matter of the invention and its mode of operation are explained in more detail below with reference to FIGS. 1 to 3.

Show it:

Fig. 1 is an axial section through a sleeve-shaped workpiece,

Fig. 2 is a graph of the hardness profiles of the workpiece surface in the depth of the workpiece at various points without pretreatment according to the invention and

Fig. 3 is a graph of the hardness profiles of the workpiece surface to the depth of the workpiece at various points of measurement according to the invention pre-treatment.

In Fig. 1, a sleeve-shaped workpiece 1 is shown having an axis AA, and outer cylindrical surfaces 2 and 3, between which an annular surface 4 is located. The workpiece 1 has a concentric stepped bore 5 with three cylindrical inner surfaces 5 a, 5 b and 5 c, between which annular surfaces 5 d and 5 e are arranged. The outer surface 3 delimits an extension 3 a with an annular end face 3 b.

The cylinder surfaces 5 b and 5 c, the annular surface 5 e and the end surface 3 b are to be post-treated in one of the following processes in gaseous atmospheres at high temperatures in order to increase the hardness against wear. These areas are highlighted by thick lines. The pre- and post-treatment of the inner surface 5 c, which forms a narrow channel, is particularly problematic. The following treatment methods are possible: vacuum carburizing, gas carburizing protection, salt bath nitriding, gas or plasma nitriding and carbonitriding.

The remaining surfaces, that is to say the cylindrical outer surfaces 2 and 3 and the inner surface 5 a, should not be treated because, for example, threads are to be subsequently produced on the outer surface 3 and / or in the inner surface 5 a. These surfaces and also the circular ring surfaces 4 and 6 and the outer surface 2 can be covered for this purpose by moldings, which is not the subject of this invention.

In FIGS. 2 and 3, the depth of penetration of post-treatments are given by carburizing in mm on the abscissa and on the ordinate the Vickers hardness in [HV0.5]. From the comparison of these figures it follows that the subsequent hardness values in the bores (surfaces 5 b and 5 c) due to carburizing, quenching and tempering, particularly on the surfaces, are subject to considerable scatter ( Fig. 2) and that in a pretreatment not according to the invention in a pretreatment according to the invention, these hardness values are within narrow limits and that the hardness values at the individual measuring points are almost identical and are within predetermined ranges ( FIG. 3).

example

. In the case of workpieces made of a nickel-containing hardening steel of Figure 1, the diameter / length ratio was of the bore 5, based on the narrowest portion (surface 5 c), about 1: 40, wherein for a subsequent carburizing a case depth of 0.4 ± 0.2 mm had to be observed. The workpieces came from a production with a mechanical and chemical treatment, e.g. B. by electrochemical deburring, and were accordingly contaminated on their surfaces by dirt particles, organic substances and oxides.

The workpieces were pretreated in a protective gas flow, as z. B. is used for brazing, placed on a conveyor belt and heated to a temperature of more than 800 ° C if necessary up to 1000 ° C. The belt speed was adjusted so that the residence time at this temperature was about 10 minutes. The furnace atmosphere consisted of a mixture of natural gas and air in a ratio of 2: 1 at atmospheric pressure. The workpieces were then cooled to room temperature in this atmosphere on an outlet section. Surprisingly, measurements showed that even contact with air did not lead to uncontrolled surface changes. The workpieces were then carburized in a vacuum, then quenched and tempered. The measurement results are shown in FIG. 3.

LIST OF REFERENCE NUMBERS

1

workpiece

2

outer surface

3

outer surface

3

a process

3

b face

4

Annular surface

5

stepped bore

5

a inner surface

5

b inner surface

5

c inner surface

5

d circular surface

5

e circular surface

6

Annular surface
AA axis

Claims (7)

1. Process for the thermochemical pretreatment of metallic workpieces ( 1 ), in particular case-hardening steels, for a subsequent carbochemical treatment from the group carburizing, nitriding, nitro-carburizing, boronizing, the pretreatment of the workpieces ( 1 ) in an atmosphere containing hydrogen or hydrogen-containing gases at temperatures of at least 800 ° C, characterized in that a gas from the group of oxygen and air is added to the atmosphere and that the pretreatment is carried out at a pressure between 0.04 and 0.2 MPa. 2. The method according to claim 1, characterized in that the Pretreatment in a mixture of hydrogen or water gases and 1 to 50% by volume oxygen is carried out. 3. The method according to claim 1, characterized in that the Pretreatment in a mixture of natural gas and air with a Volume ratio of (3 to 1): 1 is carried out. 4. The method according to claim 3, characterized in that the Pretreatment in a mixture of natural gas and air with a Volume ratio of (2.2 to 1.8): 1 is carried out. 5. The method according to claim 1, characterized in that the duration pretreatment at temperatures of at least 800 ° C is between 1 and 60 minutes.   6. The method according to claim 5, characterized in that the duration the pretreatment is between 8 and 12 minutes. 7. Application of the method according to at least one of claims 1 to 6 to the pretreatment of complicated workpieces ( 1 ) with inner surfaces ( 5 a, 5 b, 5 c) from the group of undercuts, bores and blind bores.