Analysis and Optimization of Wire Drawing Process

DOI : 10.17577/IJERTV3IS090364

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Analysis and Optimization of Wire Drawing Process

Kesavulu. P1

P G Student, Thermal engineering Siddharth Institute of Engineering & Technology

Puttur 517583, Ap , India

G. Ravindrareddy2

Associate professor, Mech. Engg. Dept Siddharth Institute of Engineering & Technology Puttur 517583, Ap , India

AbstractThe finite element method is a numerical analysis tool for analyzing complex problems. We have taken the problem of understanding wire drawing process from Avitzurs theory Wire Drawing through Conical Dies of small cone angles. This theory was used to obtain the drawing load. Wire is drawn through dies with Land and With Land & Fillet. We find that the provision of die land and fillet at entry made the flow smooth and die safe i.e., operate low stresses and low heat generation due to friction and contact pressure. Hence least wire drawing defects and die life increased. Loads were applying to the finite element model treating the problem to be axisymmetric. The problem to be solving by using ANSYS a popular FEA software package.

KeywordsFEA, ANSYS, wire drawing, ,With Land and With Land & Fillet dies.

INTRODUCTION TO WIRE DRAWING

Wire is one of the most important products required by man. Endless lengths of wire are used in the form of conductors in communication and power transmission. Enormous quantities of wire are used for fencing, cables for bridges and hoists. The products require correct dimension, surface finish and mechanical properties. Sizes vary from fraction of an inch to thousands of an inch. Wires are produced by the process of wire drawing.

Fig(1) : Wire drawing through die

I N T R O D U C T I O N TO ANSYS

ANSYS° is general purpose finite element analysis software developed. Supported and marketed by ANSYS°. Inc., formerly Swanson Analysis Systems, Inc., founded in 1970 by Dr. John . ANSYS simulation solutions are used by several Fortune 500 companies to produce a wide

range of products including aircraft and automobile engines, spacecraft, computer chips, buildings, office furniture and medical devices.

PROBLEM DEFINITION

A Wire drawing die of length 8mm is required to reduce a wire from 10mm to 8mm dia. outer dia of the die being 18 mm. Die materials Tungsten carbide, Wire material AISI. 4340 steel

Fig(2) : Plain die

TABLE I MATERIAL PROPERTIES

Properties

Die Material (Tungsten carbide)

Wire Material (AISI No 4340)

Density,

15630 Kg/m3

7850Kg/m3

Young's Modulus

5.5 × 105 Mpa

2.1 × 105

Mpa

Thermal Conductivity, K

84.02 W/mK

44.5W/mK

Specific Heat. Cp

292 J/KgK

460 J/KgK

Passion's Ratio,

0.22

0.3

LOAD CALCULATION

B= µ / tan = 0.1 / tan 7.125 =0.8

Where µ = coefficient of friction (taken 0.1 – cold drawing) Tan = 1 / 8

Draw stress xa =xo [(1+B) {1-(Da/Db)2B}/B]

=744[(1+0.8){1-(4/5)2*0.8}/0.8]

= 502.16 Mpa

xa = Draw stress

xo = Yield strength of wire (744 Mpa)µ Da = Exit diameter of die

Db = Entrance diameter of die

% of Reduction = {1-(Da / Db)} ×100

= {1-(8/10)}×100

ANSYS SOLUTION, RESULTS AND DISCUSSIONS

Fig (5): Von Misses Stress:

= 20%

WIRE DRAWING THROUGH PLAIN DIE

The maximum stress induced at the exit of the die. In wire stress is very large than that is necessary to cause uniform yielding.

  1. Modelling

  2. ANSYS Meshed Models

Fig (6): Nodal temperature by Generation Due To Friction

Maximum heat generated over the contact length between wire and die due to friction and contact pressure. Peak temperature (312.36k) generated at entrance and exit of the die.

Fig (7): Total Thermal and Mechanical Strain

Maximum total thermal and mechanical strain was observed at exit of the die. That is strain occurs very low and negligible.

Fig (8): Contact Friction Stress

Maximum contact friction stresses was observed at exit and entry portion of the die. Minimum contact friction stresses observed between exit and entry portion of the die. Therefore peak contact friction stresses (139.998 Mpa) was observed at entry portion of the die.

Fig (9): Contact Pressure:

Peak contact pressure (1399.98 Mpa) was observed at entrance of the die. Maximum contact pressure was observed at exit and entry portion of the die. Minimum contact pressure observed between exit and entry portion of the die

Peak contact pressure was observed at entrance of the die. It has reached maximum value at entrance and exite of the die. Therefore die defects likely occur.

It is there felt to create fillet at entrance portion of the die and land at exit portion of the die.

Contact Friction Stress:

Fig (10): Contact Friction Stress after creating die land and fillet

contact friction stresses was found to gradually increase from entry unlike what has happened without filter maximum contact friction stresses was observed at exit portion of the die. Minimum contact friction stresses observed between exit and entry portion of the die. Peak contact friction stresses was observed at exit portion of the die.

Therefore maximum contact friction stresses was decreased by creating fillet at entrance and land at exit portion of the die.

Fig (11): Contact pressure after creating die land and fillet

Contact pressure was found to gradually increase from entry unlike what has happened without filter .Peak contact pressure (880.606 Mpa) was observed at exit of the die. Maximum contact pressure was observed at exit and entry portion of the die. Minimum contact pressure observed between exit and entry portion of the die

Therefore maximum contact pressure was decreased (up to

500 Mpa) by creating fillet at entrance and land at exit portion of the die.

CONCLUSIONS

Theory of wire drawing was sufficiently studied. Performing the analysis of both wire drawing process and enabled us to understand what is the drawing load required to carry out the drawing process fruitfully ie., with no wire defects and safe die.. Both these ideas led to further improvements i.e., incorporation of die land and filleting at the entry. The use of the powerful tool ANSYS Analysis has helped to observe the stresses in the wire suitable for yielding.

REFERENCES

  1. B AVITZUR, Analysis Of Wire Drawing And Extrusion Through Conical Dies Of Small Cone Angle, ASME Journal Of Engineering For Industry, 1963, Vol. 85, Pp. 8996

  2. BETZELEL AVITZUR Analysis Of Wire Drawing And Extrusion Through Conical Dies Of Large Cone Angle

  3. N.CRISTESUC,Univercity Of Bucharest Drawing Through Conical Dies An Analysis Compared With Experimental

  4. .M.L.DEVENPECK&O.RICH MOND Strip Drawing Experiments With A Sigmoidal Die Profile

  5. DESAI/ABEL.,Introduction To FEM , CBS Publishers

  6. R.CHANDRUPATLA & D.BELEGUNDU, Introduction To Finite Elemen Analysis In Engineering., Pearson Education

  7. P.SESHU, A Text Book Of Finite Element Analysis . Prentice Hall Of India

  8. BOWDWN&TABOR The Friction And Lubrication Of Solids, Oxford Book Publishing House,1980,

  9. RASHEED AHMED BUTT Design Of Composite Dies For Wire Drawing, UMI ,A Bell & Howell Information Company

  10. BETZALEL AVITZUR. Metal Forming Process And Analysis

    MC Graw Hill Book Company 1968

  11. K.K. Tang, Z.X. Li , J. Wang Numerical Simulation Of Damage Evolution In Multi-Pass Wire Drawing Process And Its Applications

  12. R.M. SHEMENSKI, JOHN WALTERS AND MICHAEL FOSTER Finite Element Analysis Of Die Geometry

  13. ANDRZEJ MILENIN AND DOROTA J. BYRSKA-WÓJCIK, The Multi-Scale Model Of Mg Alloy Wire Drawing Process

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