SU844246A1 - Method of working metal-based alloy articles - Google Patents

Description

one

The invention relates to metal working, in particular, to methods for treating hard alloy products, and can be used in the manufacture of carbide cutting tools.

There is a method of magnetic-abrasive processing of products from metals and their alloys, in which the workpiece and the powder with magnetic and abrasive properties are placed in the working area, a complex mechanical movement is reported to the product, and a magnetic field is created in the working area. The magnetic field keeps the powder grains in the working area and presses them against the surface to be machined, which, in combination with the mechanical movement of the part, leads to cutting forces 1.

However, this method cannot be applied to the treatment of products from hard alloys due to their high hardness and poor workability.

There is also known a method of processing products from metals and their alloys, including pre-annealing and magnetoabrasive processing 2.

This method improves the processing performance of metal products, but it also does not provide

sufficiently high performance in the processing of products from hard alloys.

The aim of the invention is to increase the efficiency in the processing of products from hard alloys.

This goal is achieved by the fact that the preliminary annealing of products from hard alloys is carried out in an oxidizing environment.

When annealing is carried out in an oxidizing environment, reactions occur, leading to the formation of oxide elements that are part of the material of the product. With a properly selected heat treatment mode, the reactions take place only in the surface layer, which is relatively easily removed as a result of magnetic abrasive processing. The proposed processing method can be used for parts made of hard alloys of the tungsten group We-Co (BK6, BK8, BK15, BK20). Titanium-tungsten group We-TiC-Co (T15K10, T 15 K 6) and titanium group TiC-Ni (TH-20; TH-30).

Example. Consider the processing of products from alloy TN-20. Heat treatment of parts was carried out in gas and muffle furnaces in the temperature range from 500 to 900 ° C. Annealing environment was used during the annealing.

Note. 1. Brand hard alloy TN-20

2. Heat treatment of samples 1–13 is carried out in air, and sample 14 in vacuum at 10 mm Hg. Art.

3.When processing samples 12, 13, the material is peeled off, cracks form on the surface of the samples.

4. Magnetoabrasive processing mode: B-1, IT; HM 3 m / s; An injection. 0.5 m / s; t 2 min.

At THOM, it was found that in the muffle furnace the process of oxidizing carbide samples occurs more intensively, since in a gas furnace a significant amount of oxygen in the air is spent on maintaining the burning gas.

Research has shown that the noticeable oxidation of hard alloys begins with

600 ° C. Carrying out annealing at temperatures above 900 ° C leads to peeling of the material and the formation of cracks on the surface of the samples. In this case, the annealing time is selected within 15-20 minutes.

The table shows the value of specific removal of material from the surface of the workpiece (processing performance), depending on the processing modes.

As can be seen from the table, the optimal mode is annealing at 900 ° C for 60 minutes, at which the maximum specific removal of material is achieved (3, 41)

without peeling it and the formation of surface defects, exceeding by two orders of time the specific removal of the material when it is processed by a known method. Thus, the application of the described method allows for a significant increase in the processing efficiency of hard alloys compared to the known one.

Claims (2)

1. Baron Yu. M. Technological abrasive machining in a magnetic field. L., “Mechanical Engineering, 1975, p. 5-6. 2. Khomich N. S., Kozhuro L. M. Machinability of materials by magnetic abrasive polishing. Magnetic abrasive polishing parts. Abstracts of the Republican Scientific and Technical Conference, Minsk, 1976, p. 57-61.