SU1522077A1 - Method of determining friction coefficient of material in plastic deformation - Google Patents

Abstract

The invention relates to the processing of materials by pressure and can be used to determine the contact friction coefficient for various types of pressure treatment, drawing, rolling, extrusion, and the like. The purpose of the invention is to increase the information content by determining the coefficient of friction with various deformation modes. A device for carrying out the method comprises a container 1 with a chamber 5 in which a deforming tool 2 and a sample 3 are installed. A cable 10 with a winding device 9 is attached to the end of sample 3. When moving sample 3 under the action of forces, deformation occurs before and after tool 2. Record current forces and calculate the coefficient of friction. The speed of movement of the sample 3 is controlled by the pressure of the fluid in the chamber 5 and the tension of the cable 10. 1 sludge.

Description

P1 (Pr1

informativeness by determining the coefficient of friction under various deformation modes. A device for carrying out the method comprises a container 1 with a chamber 5 in which a deforming tool 2 and a sample 3 are installed. A cable 10 with a winding cable is attached to the end of sample 3.

device 9. When moving sample 3 under the action of forces, before and after tool 2, deformation occurs. Record current forces and calculate the coefficient of friction. The speed of movement of the sample 3 is controlled by the pressure of the fluid in the chamber 5 and the tension of the cable 10. 1 sludge.

The invention relates to the processing of materials by pressure and can be used to determine the contact friction coefficient for various types of pressure treatment: drawing, rolling, extrusion, and the like.

The purpose of the invention is to increase the information content by determining the coefficient of friction with different deformation modes.

The drawing shows a device for plastic deformation of a material.

The device comprises a high-pressure container 1 with a hole in which a deforming tool is installed: d4ent 2, and a test axisymmetric sample 3 of the material under study. The container 1 is placed on the frame 4. The working chamber 5 of the container 1 is designed to be filled with a liquid working medium and connected to a pressure gauge 6 and a high pressure pump (not shown). At the base of the frame 4 there is an electric motor 7, a worm gearbox 8 with a winding device 9 for a cable 10 connected through a dynamometer 11 and a clamp 12c for the axially symmetric material sample 3 under study.

The method is carried out as follows.

The working chamber 5 of the container 1 serves the working fluid and moves the sample 3 of the material due to the efforts before and after the tool, which are recorded by the pressure gauge 6 and din by the meter 11, as a result, the sample 3 is deformed, which is recorded, and the trend factor is determined from the ratio

but

and sin e6

 2SVln |

CP, P,) - ™

2 S in ai,.

coso;

6 - yield strength of the sample material;

K is the sample radius before deformation; g - deforming radius

over the instrument, ol is the angle of inclination of the cone forming the deforming surface of the instrument; PJ and Pj are specific forces up to and

after the tool. The speed of movement of the sample 3 is controlled by the pressure of the fluid in the chamber 5 and the tension of the cable 10 by changing the speed of movement of the cable 10

winding device 9, i.

Example, simulate extrusion

with drawing at a different ratio of efforts. A sample is made of molybdenite brand M4, a pressure is created in the chamber at 11400 kgf / cm and recorded with a manometer of the type

CB-26p, set the tension of the cable 120 kG and register it with a dynamometer DPU-05-2, Move the sample through a steel matrix of 3 mm with a tilt angle of the cone forming the deforming surface of the tool Yu with a degree of deformation of 75%. a mixture of ethylene glycol and glycerin is used as a liquid.

in the ratio of 1: 1, get the coefficient of friction jU. 0.13, Change test conditions. Make a sample of pure technical copper with i yield strength of 7 kgf / mm, create

the fluid pressure in the chamber is 90.5 kG / cm; the fluid pressure in the chamber is 90.5 kG / cm; the tension force of the cable is 150 kG; the sample is moved through the steel matrix orifice

9 mm with a tilt angle of a cone forming 7.5, with a degree of deformation of 19%. Graphite and soap are used for the sample lubrication in a ratio of 60 and 40%. A coefficient of friction / 0.18 is obtained.

Claims (1)

Invention Formula The method of determining the coefficient of friction of the material during its plastic deformation, which consists in that an axially symmetrical sample of material is forced through the tool hole by applying forces along the sample axis simultaneously before and after the tool, these forces are determined and taking into account their coefficient of friction, so that, in order to increase the information content by determining the coefficient of friction with different deformation modes, the force applied after the tool is directed in the same direction, h This force applied to the tool, the flushing is carried out at several speeds corresponding to different deformation modes, keep these speeds stable by adjusting the amount of force, and the force measurement is carried out for each stable speed value.