94 research outputs found
Modeling and Simulation of Temperature Generated on Workpiece and Chip Formation in Orthogonal Machining
Experimental investigation in machining operation for the temperature generated on workpiece, chip formation and cutting tool are difficult, time consuming and costly to carry out. Machining simulation using FEM software is an alternative. This paper presents a simulation study of temperature generated on workpiece and chip formation for
various combinations of tool geometries (rake angle and clearance angle). Ductile cast iron FCD500 grade was used as material workpiece, and uncoated carbide tools with code
number DNMA432 were used as cutting tool. Twelve designs of carbide cutting tools with various combination of rake angle (15, 20, and 30 deg) and clearance angle (5, 7, 8 and 9 deg) were designed. The nose radius of the cutting tool was kept constant at 0.4 mm. Machining parameters of cutting speed, feed rate and dept of cut (DOC) were kept
constant at 200 m/min, 0.35 mm/rev and 3 mm respectively. Using a commercial software package Deform-3D, twelve orthogonal machining simulations were carried out to analyze
the effect of tool geometries on temperature generated and chip formation. The results show that by increasing the rake angle, the machining performance is improved due to the
low temperature generated on the machined surface, as well as low cutting force, stress, and strain. On the other hand, increasing/decreasing the clearance angle, does not
significantly affected the cutting force, stress, and strain, consequently it does not affected the temperature generated. For the chip formation, the highest temperature occurred in the sliding region due to the work piece material adheres to the cutting tool and shear occurs within the chip, the frictional force is very high; consequently heat is generated from this sticking regio
Prediction of Turning Performance in Various Machining Parameter Using FEM
In recent years, the applications of finite element
method (FEM) in metal cutting operations have proved to
be effective in studying the cutting process and
manufacturing process. The simulation result is useful for
both researchers and tool makers to optimize the cutting
process by designing new tools. Simulation and modelling
were performed in two-dimensional and threedimensional
for designing the new component prior to fabricating. These are very useful for reducing time and cost consumption in designing automotive parts. The FEM simulation just only requires computational tool and FEM simulation package. The present work aims to predict of performance three-dimensional orthogonal of cutting operations using FEM software (Deform-3D). Some important information such as cutting force, stress, strain and generated temperature during machining process were studied and analysed. Orthogonal cutting simulations were conducted to study the effect of cutting speed, feed rate and depth of cut on the cutting force, the effective-stress, strain and generated temperature in turning process. FCD 500 (ductile cast iron) was used as the work material and cutting tool was DNMA 432
(uncoated carbide tool, SCEA = 0; BR = -5; SR = -5 and
radius angle 55o). The cutting parameters varied were
cutting speed (100 m/min, 150 m/min and 200 m/min), feed
rate (0.1, 0.25 and 0.4 mm/rev), and depth of cut (DOC)
(0.3, 0.6 and 0.9 mm). The performance was showed by the
simulation results that show by increasing the cutting
speed, it causes decreasing in cutting force, effective stress and strain, but the generated temperature during the chip formation process increases. High value of feed rate
resulted in bigger cutting force, stress, strain and
generated temperature. In addition, bigger cutting force
and high generated temperature occurred at high depth of
cut
Effect of Rake Angle on Stress, Strain and Temperature on the Edge of Carbide Cutting Tool in Orthogonal Cutting Using FEM Simulation
Demand for higher productivity and good quality for machining parts has encourage many researchers to study the effects of machining parameters using FEM simulation using either two or three dimensions version. These are due to advantages such as software package and computational times are required. Experimental work is very costly, time consuming and labor intensive. The present work aims to simulate a three-dimensional orthogonal cutting operations using FEM software (deform-3D) to study the effects of rake angle on the cutting force, effective stress, strain and temperature on the edge of carbide cutting tool. There were seven runs of simulations. All simulations were performed for various rake angles of -15 deg, -10 deg, -5 deg, 0 deg, +5 deg, +10 deg, and +15 deg. The cutting speed, feed rate and depth of cut (DOC) were kept constant at 100 m/min, 0.35 mm/rev and 0.3 mm respectively. The work piece used was ductile cast iron FCD500 grade and the cutting tool was DNMA432 series (tungsten, uncoated carbide tool, SCEA = 0; and radius angle 55 deg). The analysis of results show that, the increase in the rake angle from negative to positive angle, causing the decrease in cutting force, effective stress and total Von Misses strain. The minimum of the cutting force, effective stress and total Von Misses strain were obtained at rake angle of +15 deg. Increasing the rake caused higher temperature generated on the edge of carbide cutting tool and resulted in bigger contact area between the clearance face and the workpiece, consequently caused more friction and wear. The biggest deformation was occurred in the primary deformation zone, followed by the secondary deformation zone. The highest stress was also occurred in the primary deformation zone. But the highest temperature on the chip usually occurs in secondary deformation zone, especially in the sliding region, because the heat that was generated in the sticking region increased as the workpiece was adhered by the tool and later it was sheared in high frictional force.
Machining Simulation of AISI 1045 and Carbide Tool Using FEM
In recent years, the applications of finite element method (FEM) in metal cutting operations have proved to be effective in studying the cutting process and chip
formation. In particular, the simulation results can be used for both researchers and machine tool makers to optimize the cutting process and designing new tools. Many researches were done on two-dimensional simulation of cutting process because the three-dimensional versions of FEM software required more computational time. The present work aims to simulate three-dimensional orthogonal cutting operations using FEM software of Deform-3D. Orthogonal
cutting finite element model simulations were conducted to study the effect of cutting speed on effective-stress, strain and temperature in turning process. AISI 1045 was used as work material and cutting tool was TNMA 332 (uncoated carbide tool, SCEA = 0; BR = -5; SR = -5 and radius angle 60o). The emphasis on the designed geometries are limited to the changes in the cutting speed between
100 m/min and 450 m/min. The machining parameters of feed rate and depth of cut were kept constant at 0.35 mm/rev and 0.3 mm respectively. The simulation results show that by increasing the cutting speed causes a decrease in cutting force and effective-strain. On the other hand, increasing in
cutting speed will increase effective -strain and temperature of the chip formed
Application of FEM in Investigating Machining Performance
The two biggest problems that often experienced in machining cast iron are poor machinability and high hardness. Up to now, many researchers have investigated machining performance and how to find optimum condition in machining ductile cast iron. This study aims to investigate the machining performance of ductile cast iron and carbide cutting tool using FEM. Performances were evaluated by changing the cutting tool geometries on the machining responses of cutting force, stress, strain, and generated temperature on the workpiece. Deform-3D commercial
finite element software was used in this study. Ductile cast iron FCD 500 grade was used as the work piece material and carbide insert DNMA432 type with WC (Tungsten) was used for the cutting tool. The effects of rake and clearance angles were investigated by designing various tool
geometries. Various combination of carbide insert geometries were designed using Solid Work to produce +15, +20 and +30 deg for rake angle and 5, 7, 8 and 9 deg for clearance angle. Machining condition for the simulations were remained constant at cutting speed of 200 m/min, feed rate of 0.35 mm/rev, and depth of cut of 0.3 mm. The results of effective-stress, strain and generated temperature on both chip and material surface were analysed. The results show that by increasing the rake angle (α), it will improves the machining performance by reducing the cutting force, stress, strain and generated temperature on surface of workpiece. But, by increasing the clearance angle (γ), it will not affect much to the cutting force, stress, strain and generated temperature on chip
Kesan suhu pensinteran terhadap sifat mekanik dan mikrostruktur alumina-zirkonia yang difabrikasi dengan kaedah pengacuan suntikan seramik
Kesan suhu pensinteran terhadap sifat mekanik dan mikrostruktur bahan komposit alumina-zirkonia telah dikaji. Jasad hijau alumina-zirkonia difabrikasi dengan menggunakan kaedah pengacuan suntikan seramik menggunakan sistem bahan pengikat pelbagai komponen. Jasad perang yang terhasil selepas proses penyahikatan disinter pada suhu 1400, 1450, 1500, 1550, 1600 dan 1650°C selama 2 jam. Selanjutnya nilai ketumpatan, kekerasan dan keliatan patah bagi jasad tersinter diukur. Mikrostruktur jasad tersinter ditentukan dengan menggunakan mikroskop imbasan elektron (SEM). Kajian menunjukkan nilai ketumpatan, kekerasan dan keliatan patah bagi jasad tersinter meningkat sejajar dengan peningkatan suhu pensinteran. Hasil uji kaji juga mendapati pada suhu pensinteran 1650°C sifat mekanik bahan mencapai keadaan maksimum. Penumpatan jasad tersinter 98% menghampiri ketumpatan teori dengan nilai kekerasan 16.9 GPa dan keliatan patah mencecah 3.95 MPa.m1/2. Keputusan tersebut dapat dikaitkan dengan mikrostruktur bahan yang padat didorong oleh tumbesaran ira yang lengkap
Effect of Rake Angle on Stress, Strain and Temperature on the Edge of Carbide Cutting Tool in Orthogonal Cutting Using FEM Simulation
Demand for higher productivity and good quality for machining parts has encourage many researchers to study the effects of machining parameters using FEM simulation using either two or three dimensions version. These are due to advantages such as software package and computational times are required. Experimental work is very costly, time consuming and labor intensive. The present work aims to simulate a three-dimensional orthogonal cutting operations using FEM software (deform-3D) to study the effects of rake angle on the cutting force, effective stress, strain and temperature on the edge of carbide cutting tool. There were seven runs of simulations. All simulations were performed for various rake angles of -15 deg, -10 deg, -5 deg, 0 deg, +5 deg, +10 deg, and +15 deg. The cutting speed, feed rate and depth of cut (DOC) were kept constant at 100 m/min, 0.35 mm/rev and 0.3 mm respectively. The work piece used was ductile cast iron FCD500 grade and the cutting tool was DNMA432 series (tungsten, uncoated carbide tool, SCEA = 0; and radius angle 55 deg). The analysis of results show that, the increase in the rake angle from negative to positive angle, causing the decrease in cutting force, effective stress and total Von Misses strain. The minimum of the cutting force, effective stress and total Von Misses strain were obtained at rake angle of +15 deg. Increasing the rake caused higher temperature generated on the edge of carbide cutting tool and resulted in bigger contact area between the clearance face and the workpiece, consequently caused more friction and wear. The biggest deformation was occurred in the primary deformation zone, followed by the secondary deformation zone. The highest stress was also occurred in the primary deformation zone. But the highest temperature on the chip usually occurs in secondary deformation zone, especially in the sliding region, because the heat that was generated in the sticking region increased as the workpiece was adhered by the tool and later it was sheared in high frictional force
TRIZ approach for machining process innovation in cryogenic environment
This paper presents the utilisation of TRIZ approach in machining process of AISI 4340 in cryogenic environment which lead to product improvement in turning process. The machining study is carried out in two stages; FEM simulation for finding the optimum condition and machining experiment to visualise the product improvement that involved plastic deformation. The simulation result revealed that at moderate to high cutting speed, high feed rate and high depth of cut will result in high temperature that enable for the change in phase of AISI 4340 from retained austenite to fully martensite. A sample from machining experiment at optimum cutting condition found that the microstructure changes beneath the machined until at the depth of ∼7 μm with high hardness to 8,500 N/mm2 Martens hardness at the machined surface. This hardness is equivalent to the hardness obtained in conventional case hardening process that is required after the machining of AISI 4340 in their application as automotive engine parts in order to enhance these parts in their service lives. This study reveals that the TRIZ approach helps to systematically analyse the various outcomes in this study started with process limitation, problem identification, axiomatic and Su-field analysis
Diallel analysis for seed yield and related traits in an energy crop jatropha curcas
Six parents (P1, P2, P3, P4, P5 and P6) half diallel population of Jatropha curcas were evaluated to determine the combining ability, genetic components of variance and heterosis for yield contributing traits. Diallel analysis showed that both additive and dominance gene action was responsible for the genetic regulation of all the traits under study. The cross combination P1 × P3 showed the highest positive specific combining ability for seed yield per plant. Combining ability results were also in close agreement with the findings of estimate of genetic components of variance. The seeds per fruit (89%) and 100-seed weight (93%) showed maximum narrow sense heritability. Seed yield per plant showed high mid parent (254.13%) and better parent (202.36%) heterosis in the cross combinations of P2 × P5 and P1 × P3, respectively. The parents of P1, P2, P3 and P5 were found to be superior for seed yield components when used in cross. Considering seed production for each plant, the hybrids P1 × P2, P1 × P3, P2 × P5 and P4 × P6 could be selected for the development of hybrid varieties
Comparison effect of delamination factor (Fd) on unidirectional and woven kenaf fibre reinforced plastic composite materials during milling process [Pembandingan kesan faktor pelekangan (Fd) ke atas bahan komposit plastik bertetulang ekaarah dan bertenun semasa proses pemesinan kisar]
Serabut kenaf merupakan salah satu serabut berasaskan tumbuhan di dalam kumpulan serabut asli yang semakin luas
penggunaannya. Serabut kenaf dicampurkan dengan bahan plastik (epoksi) bagi menghasilkan suatu bahan baharu
dengan sifat mekanikal yang baik dengan kos pembuatan yang rendah. Bahan kerja ini terbahagi kepada dua jenis iaitu
serabut kenaf ekaarah dan serabut kenaf tenunan. Uji kaji ini akan menumpukan kepada pembandingan kesan faktor
pelekangan Fd yang terhasil semasa proses pemesinan kisar ke atas bahan komposit tersebut dengan penentuan set
parameter mesin yang paling optimum bagi mengurangkan kesan Fd. Uji kaji dijalankan berdasarkan analisis kaedah
gerak balas permukaan (RSM) dengan pendekatan reka bentuk Box-Behnken bagi mendapatkan hasil faktor bersandar
terhadap sambutan. Faktor yang terlibat adalah kelajuan pemotongan, kadar suapan dan kedalaman pemotongan. Proses
pengisaran secara lelurus (lurah) dilakukan bagi melihat kesan Fd yang terhasil dengan menggunakan perkakasan mata
alat jenis Keluli Berkelajuan Tinggi (HSS) tidak bersalut hujung rata berdiameter 10 mm. Imej daripada mikroskop
menunjukkan bahan komposit serabut kenaf ekaarah menghasilkan faktor pelekangan yang tinggi berbanding kesan
ke atas bahan komposit serabut kenaf bertenun. Bagi set parameter optimum pula, bahan kerja serabut kenaf ekaarah
ialah kelajuan pemotongan, kadar suapan dan kedalaman pemotongan yang rendah. Manakala bagi bahan kerja serabut
kenaf bertenun, set parameter optimum adalah kelajuan pemotongan yang rendah dengan kadar suapan dan kedalaman
pemotongan yang tinggi
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