Study on Thickness Thinning Ratio of the Forming Parts in Single Point Incremental Forming Process

An excessive thickness-reducing ratio of the deformation zone in single point incremental forming of the metal sheet process has an important influence on the forming limit. Prediction of the deformation zone thickness is an important approach to control the thinning ratio. Taking the 1060 aluminum as the research object, the principle of thickness deformation in the single point incremental forming process was analyzed; the finite element model was established using ABAQUS. A formula with high accuracy to predict the deformation zone thickness was fitted with the simulation results, and the influences of process parameters, such as tool diameter, step down, feeding speed, sheet thickness, and forming angle, on thinning ratio were analyzed. The accuracy of the finite element simulation was verified by experiment. A method to control the thinning rate by changing the forming trajectory was proposed. The results showed that the obtained value by using the fitted formula is closer to the experimental results than that obtained by the sine theorem. The thinning rate of the deformation zone increases with the increase of tool diameter, forming angle, and sheet thickness and decreases with the increase of step down, while the feeding speed had no significant effect on the thinning ratio. The most important factor of the thinning ratio is the forming angle, and the thinning ratio can be effectively reduced by using the forming trajectory with a uniformly distributed pressing point.

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Experimental Investigation of Single Point Incremental Forming of Aluminum Sheet in Groove Test

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.867.177 ◽

2017 ◽

Vol 867 ◽

pp. 177-183 ◽

Cited By ~ 1

Author(s):

Vikrant Sharma ◽

Ashish Gohil ◽

Bharat Modi

Keyword(s):

Experimental Investigation ◽

Incremental Forming ◽

Single Point ◽

Fractional Factorial ◽

Single Point Incremental Forming ◽

Forming Process ◽

Backing Plate ◽

Groove Test ◽

Factorial Design Of Experiments ◽

Tool Diameter

Incremental sheet forming is one of the latest processes in sheet metal forming industry which has drawn attention of various researchers. It has shown improved formability compared to stamping process. Single Point Incremental Forming (SPIF) process requires only hemispherical tool and no die is required hence, it is a die-less forming process. In this paper experimental investigation on SPIF for Aluminium sheet has been presented. A groove test on Vertical Machining Centre has been performed. Factors (Step depth, Blank holder clamping area, Backing plate radius, Program strategy, Feed rate and Tool diameter) affecting the process are identified and experiments are carried out using fractional factorial design of experiments. Effect of the factors on fractured depth, forming time and surface finish have been analyzed using Minitab 17 software.

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Study of the Effect of Process Parameters on Surface Profile Accuracy in Single-Point Incremental Sheet Forming of AA1050-H14 Aluminum Alloy

Advances in Materials Science and Engineering ◽

10.1155/2020/7265941 ◽

2020 ◽

Vol 2020 ◽

pp. 1-14

Author(s):

Abdulmajeed Dabwan ◽

Adham E. Ragab ◽

Mohamed A. Saleh ◽

Saqib Anwar ◽

Atef M. Ghaleb ◽

...

Keyword(s):

Surface Quality ◽

Process Parameters ◽

Incremental Forming ◽

Single Point ◽

Surface Profile ◽

Sheet Thickness ◽

Numerical Control ◽

Single Point Incremental Forming ◽

Tool Diameter ◽

Profile Accuracy

Single-point incremental forming is an innovative flexible and inexpensive technique to form sheet products when prototypes or small batches are required. The process allows complex geometries to be produced using a computer numerical control machine, eliminating the need for a special die. This study reports on the effects of four important single-point incremental forming process parameters on produced surface profile accuracies. The profile accuracy was estimated by measuring the side angle errors and surface roughness and also waviness and circularity of the product inner surface. Full factorial design of experiments was used to plan the study, and the analysis of variance was used to analyze and interpret the results. The results indicate that the tool diameter (d), step depth (s), and sheet thickness (t) have significant effects on the produced profile accuracy, while the feed rate (f) is not significant. As a general rule, thin sheets with greater tool diameters yielded the best surface quality. The results also show that controlling all surface quality features is complex because of the contradicting effects of, and interactions between, a number of the process parameters.

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An Upper-Bound Prediction of Tangential Force in Single Point Incremental Forming

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.504-506.833 ◽

2012 ◽

Vol 504-506 ◽

pp. 833-838

Author(s):

Mohammad Javad Mirnia ◽

Bijan Mollaei Dariani

Keyword(s):

Upper Bound ◽

Deformation Zone ◽

Incremental Forming ◽

Single Point ◽

Tangential Force ◽

Single Point Incremental Forming ◽

Effective Parameters ◽

Bound Solution ◽

Upper Bound Solution ◽

Tool Diameter

In the present work, the upper-bound approach is used to study the deformation zone of single point incremental forming of truncated cones. The velocity field and the dissipated power of the process are achieved using an assumed deformation zone and streamlines defined by Bezier curves. The tangential force acting on the tool is attained by optimizing the presented upper-bound solution. Then, influences of the effective parameters including vertical pitch, initial thickness, tool diameter, and wall angle on the tangential force are investigated. In order to validate the presented upper-bound solution, predicted tangential forces are compared with experimental data available in literature. The comparison shows an appropriate agreement between them.

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Experimental Investigation and Optimal Prediction of Maximum Forming Angle and Surface Roughness of an Al/SUS Bimetal Sheet in an Incremental Forming Process Using Machine Learning

Materials ◽

10.3390/ma12244150 ◽

2019 ◽

Vol 12 (24) ◽

pp. 4150

Author(s):

Raneen Abd Ali ◽

Wenliang Chen ◽

M.S.H. Al-Furjan ◽

Xia Jin ◽

Ziyu Wang

Keyword(s):

Machine Learning ◽

Surface Roughness ◽

Incremental Forming ◽

Single Point ◽

Continuous Variable ◽

Gradient Boosting ◽

Forming Process ◽

Step Size ◽

Forming Angle ◽

Tool Diameter

Bimetal sheets have superior properties as they combine different materials with different characteristics. Producing bimetal parts using a single-point incremental forming process (SPIF) has increased recently with the development of industrial requirements. Such types of sheets have multiple functions that are not applicable in the case of monolithic sheets. In this study, the correlation between the operating variables, the maximum forming angle, and the surface roughness is established based on the ensemble learning using gradient boosting regression tree (GBRT). In order to obtain the dataset for the machine learning, a series of experiments with continuous variable angle pyramid shape were carried out based on D-Optimal design. This design is created based on numerical variables (i.e., tool diameter, step size, and feed rate) and categorical variable (i.e., layer arrangement). The grid search cross-validation (CV) method was used to determine the optimum GBRT parameters prior to model training. After the parameter tuning and model selection, the model with a better generalization performance is obtained. The reliability of the predictive models is confirmed by the testing samples. Furthermore, the microstructure of the aluminum/stainless steel (Al/SUS) bimetal sheet is analyzed under different levels of operating parameters and layer arrangements. The microstructure results reveal that severe cracks are attained in the case of a small tool diameter while a clear refinement is observed when a high tool diameter value with small step down is used for both Al and SUS layers.

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RESEARCH ON THE FORMING ANGLE OF A1050-H14 ALUMINUM MATERIAL PROCESSED BY USING SINGLE POINT INCREMENTAL FORMING TECHNOLOGY (SPIF)

Science and Technology Development Journal ◽

10.32508/stdj.v12i16.2357 ◽

2009 ◽

Vol 12 (16) ◽

pp. 72-79

Author(s):

Nam Thanh Nguyen ◽

Tuan Dinh Phan ◽

Cuong Van Vo ◽

Dien Khanh Le ◽

Binh Thien Nguyen ◽

...

Keyword(s):

Incremental Forming ◽

Single Point ◽

Metal Sheet ◽

Single Point Incremental Forming ◽

Regression Equations ◽

Cnc Milling ◽

Cnc Milling Machine ◽

Forming Technology ◽

Forming Angle ◽

Tool Diameter

Single Point Incremental Forming - SPIF is the recent manufacturing process of metal sheet forming by drafting a non-cutting edge sphere-tip tool on a clamped metal sheet. The formability of metal sheet in SPIF is considered by the forming angle (ψ)- the maximum draft angle so that the material is not torn. The experimental research on A1050-H14 aluminum sheet on Bridge Port VMC500-16 CNC milling machine in C1 workshop of the HCMUT in order to find out the regression equations to predict the maximum forming angle in the relation with four most important technology parameters in SPIF: size of the step down z, forming feed vxy, spindle speed n, forming tool diameter d.

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Application of Response Surface Analysis and Genetic Algorithm for the Optimization of Single Point Incremental Forming Process

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.554-557.1265 ◽

2013 ◽

Vol 554-557 ◽

pp. 1265-1272 ◽

Cited By ~ 17

Author(s):

Riadh Bahloul ◽

Henia Arfa ◽

Hedi Belhadj Salah

Keyword(s):

Response Surface ◽

Incremental Forming ◽

Single Point ◽

Single Point Incremental Forming ◽

Forming Process ◽

Step Size ◽

Unknown Parameters ◽

Forming Parameters ◽

Tool Diameter ◽

Incremental Step

Single point incremental forming (SPIF) is a modern method of forming sheet metal, where parts can be formed without the use of dedicated dies. The ability of SPIF to form a part is based on various forming parameters. Previous work was not accomplished with the help of design of experiments (DOE), thus reducing the number of parameters varied at any time. This paper presents a Box-Behnken experimental design, which develops the numerical plan, formalizes the forming parameters critical in SPIF and analyse data. The most critical factors affecting SPIF were found to be wall inclination angle, incremental step size, material thickness and tool size. The main effects of these parameters on the quality of the formed parts were studied in detail. Actually this work aims to “optimize the thinning rate and the maximum force by considering the tool diameter and the vertical pitch as unknown parameters for two different wall angles and thicknesses”. To this purpose, an optimization procedure based on the use of response surface methodology (RSM) and genetic algorithms (GA) have been proposed for application to find the optimum solutions. Finally, it demonstrated that the developed methods can solve high non-linear problems successfully. Associated plots are shown to be very efficient for a quick localization of the region of the search space containing the global optimum values of the SPIF parameters.

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Experimental Study the Effect of Tool Geometry on Dimensional Accuracy in Single Point Incremental Forming (SPIF) Process

Al-Nahrain Journal for Engineering Sciences ◽

10.29194/njes21010108 ◽

2018 ◽

Vol 21 (1) ◽

pp. 108 ◽

Cited By ~ 2

Author(s):

Aqeel Sabree Bedan ◽

Halah Ali Habeeb

Keyword(s):

Incremental Forming ◽

Single Point ◽

Dimensional Accuracy ◽

Numerical Control ◽

Tool Geometry ◽

Single Point Incremental Forming ◽

Forming Process ◽

Wall Angle ◽

Product Profile ◽

Tool Diameter

Incremental forming is a flexible sheet metal forming process which performed by utilizes simple tools to locally deform a sheet of metal along a predefined tool path without using of dies. One limitations of single point incremental forming (SPIF) process is the error occur between the CAD design and the product profile. This work presents the single point incremental forming process for produced pyramid geometry and studied the effect of tool geometry, tool diameter, wall angle, and spindle speed on the dimensional accuracy. Three geometries of forming tools were used in experimental work: ball end tool, hemispherical tool, and flat with round corner tool. The sheet material used was pure Aluminum (Al 1050) with thickness of (0.9 mm). The experimental tests in this work were done on the computer numerical control (CNC) vertical milling machine. The products dimensions were measured by utilized the dimensional sensor measuring instrument. The extracted results from the single point incremental forming process indicated the best acceptance between the CAD profile and product profile was found with the ball end tool and diameter of (10 mm), wall angle (50°) and the rotational speed of the tool was (800 rpm).

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An Investigation Study of Tool Geometry in Single Point Incremental Forming (SPIF) and their effect on Residual Stresses Using ANOVA Model

Al-Khwarizmi Engineering Journal ◽

10.22153/kej.2018.11.001 ◽

2019 ◽

Vol 14 (2) ◽

pp. 1-13

Author(s):

Aqeel S Sabree Bedan ◽

Halah Ali H Habeeb

Keyword(s):

Residual Stresses ◽

Rotational Speed ◽

Incremental Forming ◽

Single Point ◽

Numerical Control ◽

Tool Geometry ◽

Single Point Incremental Forming ◽

Forming Process ◽

Wall Angle ◽

Tool Diameter

Incremental forming is a flexible sheet metal forming process which is performed by utilizing simple tools to locally deform a sheet of metal along a predefined tool path without using of dies. This work presents the single point incremental forming process for producing pyramid geometry and studies the effect of tool geometry, tool diameter, and spindle speed on the residual stresses. The residual stresses were measured by ORIONRKS 6000 test measuring instrument. This instrument was used with four angles of (0º,15º,30º, and 45º) and the average value of residual stresses was determined, the value of the residual stress in the original blanks was (10.626 MPa). The X-ray diffraction technology was used to measure the residual stresses. The sheet material used was Aluminum alloy (AL1050) with thickness of (0.9 mm). The experimental tests in this work were done on the computer numerical control (CNC) vertical milling machine. The extracted results from the single point incremental forming process were analyzed using analysis of variance (ANOVA) to predict the effect of forming parameters on the residual stresses. The optimum value of the residual stresses (55.024 MPa) was found when using the flat end with round corner tool and radius of (3 mm), wall angle of (55°) and a rotational speed of the tool of (800 rpm). The minimum value of the residual stresses (24.389MPa) was found when using hemispherical tool with diameter of (12 mm), wall angle of (45°) and a rotational speed of the tool of (800 rpm).

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Formability Analyses on Single Point Incremental Sheet Forming Process on Aluminum 1050

Materials Science Forum ◽

10.4028/www.scientific.net/msf.969.703 ◽

2019 ◽

Vol 969 ◽

pp. 703-708

Author(s):

Dawit Desalegn ◽

P. Janaki Ramulu ◽

Dagmawi Hailu ◽

S. Senthil Kumaran ◽

P. Velmurugan ◽

...

Keyword(s):

Sheet Metal ◽

Sheet Metal Forming ◽

Metal Forming ◽

Incremental Forming ◽

Single Point ◽

Sheet Thickness ◽

Forming Process ◽

Aluminum 1050 ◽

Tool Diameter ◽

Truncated Pyramid

In recent years, there is a lot of demand on metal forming processes in which sheet metal forming process has lots of applications in the automotive and aerospace industries. In sheet metal forming operations, incremental forming is an emerging technology in which, single point incremental forming (SPIF) process is die-less in incremental forming process and providing a competitive alternative to economical and effective in fabricating low volume products. The objective of this work is to analyze the forming analysis on truncated pyramid product by avoiding cracking and maintaining the optimum forming conditions. The formability is analyzed by using ABAQUS software and simulation, different process parameters were varied such as sheet thickness, tool diameter, step depth, spindle rotational speed on aluminum AA1050 alloy. From the simulation results, stress stain and stain distribution were evaluated on the deformed sheet. The product produced is truncated pyramid dimension having square base of side and fillet at corner.

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Parametric Effects of Single Point Incremental Forming on Hardness of AA1100 Aluminium Alloy Sheets

Materials ◽

10.3390/ma14237263 ◽

2021 ◽

Vol 14 (23) ◽

pp. 7263

Author(s):

Sherwan Mohammed Najm ◽

Imre Paniti ◽

Tomasz Trzepieciński ◽

Sami Ali Nama ◽

Zsolt János Viharos ◽

...

Keyword(s):

Aluminium Alloy ◽

Incremental Forming ◽

Sheet Material ◽

Single Point ◽

Alloy Sheet ◽

Single Point Incremental Forming ◽

Regression Equations ◽

Effective Parameters ◽

Forming Process ◽

Tool Diameter

When using a unique tool with different controlled path strategies in the absence of a punch and die, the local plastic deformation of a sheet is called Single Point Incremental Forming (SPIF). The lack of available knowledge regarding SPIF parameters and their effects on components has made the industry reluctant to embrace this technology. To make SPIF a significant industrial application and to convince the industry to use this technology, it is important to study mechanical properties and effective parameters prior to and after the forming process. Moreover, in order to produce a SPIF component with sufficient quality without defects, optimal process parameters should be selected. In this context, this paper offers insight into the effects of the forming tool diameter, coolant type, tool speed, and feed rates on the hardness of AA1100 aluminium alloy sheet material. Based on the research parameters, different regression equations were generated to calculate hardness. As opposed to the experimental approach, regression equations enable researchers to estimate hardness values relatively quickly and in a practicable way. The Relative Importance (RI) of SPIF parameters for expected hardness, determined with the partitioning weight method of an Artificial Neural Network (ANN), is also presented in the study. The analysis of the test results showed that hardness noticeably increased when tool speed increased. An increase in feed rate also led to an increase in hardness. In addition, the effects of various greases and coolant oil were studied using the same feed rates; when coolant oil was used, hardness increased, and when grease was applied, hardness decreased.

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