Incremental sheet forming

Last updated

Incremental sheet forming (or ISF, also known as Single Point Forming) is a sheet metal forming technique where a sheet is formed into the final workpiece by a series of small incremental deformations. However, studies have shown that it can be applied to polymer and composite sheets too. Generally, the sheet is formed by a round tipped tool, typically 5 to 20mm in diameter. The tool, which can be attached to a CNC machine, a robot arm or similar, indents into the sheet by about 1 mm and follows a contour for the desired part. It then indents further and draws the next contour for the part into the sheet and continues to do this until the full part is formed. ISF can be divided into variants depending on the number of contact points between tool, sheet and die (in case there is any). The term Single Point Incremental Forming (SPIF) is used when the opposite side of the sheet is supported by a faceplate and Two Point Incremental Forming (TPIF) when a full or partial die supports the sheet.

Contents

Types

Single-point incremental forming (SPIF) and double-sided incremental forming (DSIF) are the two variants of the IF process. In the DSIF process, two tools are used to form the sheet on either side, while the SPIF process only uses a tool on one side of the sheet. Thus, a component having features on either side of the sheet, e.g., an inverted cone can be effectively formed by the DSIF process. [1]

Advantages over conventional sheet metal forming

Because the process can be controlled entirely by CNC processes no die is required as is in traditional sheet metal forming. The elimination of the die in the manufacturing process reduces the cost per piece and decreases turnaround time for low production runs because the need to manufacture a die is eliminated. However, for high production runs the time and cost to produce a die is absorbed by the higher per piece speed and lower per piece cost. Several authors recognize that the formability of metal materials under the localized deformation imposed by incremental forming is better than in conventional deep drawing. [2] In contrast, there is a loss of accuracy with the ISF process. [3]

Implementation

The ISF process is generally implemented by clamping a sheet in the XY plane, which is free to move along the Z axis. The tool moves in the XY plane and is coordinated with movements in the Z axis to create the desired part. It is often convenient to retrofit a CNC milling machine to accommodate the process. Spherical, flat-bottomed, and parabolic tool profiles can be used to achieve differing surface finishes and forming limits. [4]

The machine employs a combination of stretch forming by drawing the sheet incrementally down over a die, with the CNC tool approach described above. This is said to produce a more even distribution of thickness of the material. The process is well suited to one-off manufacture though difficulties in simulating the process mean that toolpaths are complex and time-consuming to determine.

Ford Motor Company has recently released Ford Freeform Fabrication Technology, a two-point incremental sheet-forming technique being implemented in the rapid prototyping of automotive parts. Complex shapes such as the human face [5] and cranial implants [6] have been manufactured successfully using this manufacturing process. Advances in the technology are expected to increase adoption in the near future by other sheet metal-reliant manufacturers.

Applications

Incremental forming (IF) is a recent manufacturing process having a wide range of applications in the following areas. [7]

List of process parameters

The mechanics of the process is influenced by many parameters, including:

Current research

Research is underway at several universities. [14] [15] The most common implementation is to outfit a traditional milling machine with the spherical tool used in the ISF process. Key research areas include

Related Research Articles

<span class="mw-page-title-main">Computer-aided manufacturing</span> Use of software to control industrial processes

Computer-aided manufacturing (CAM) also known as computer-aided modeling or computer-aided machining is the use of software to control machine tools in the manufacturing of work pieces. This is not the only definition for CAM, but it is the most common. It may also refer to the use of a computer to assist in all operations of a manufacturing plant, including planning, management, transportation and storage. Its primary purpose is to create a faster production process and components and tooling with more precise dimensions and material consistency, which in some cases, uses only the required amount of raw material, while simultaneously reducing energy consumption. CAM is now a system used in schools and lower educational purposes. CAM is a subsequent computer-aided process after computer-aided design (CAD) and sometimes computer-aided engineering (CAE), as the model generated in CAD and verified in CAE can be input into CAM software, which then controls the machine tool. CAM is used in many schools alongside CAD to create objects.

<span class="mw-page-title-main">Machine tool</span> Machine for handling or machining metal or other rigid materials

A machine tool is a machine for handling or machining metal or other rigid materials, usually by cutting, boring, grinding, shearing, or other forms of deformations. Machine tools employ some sort of tool that does the cutting or shaping. All machine tools have some means of constraining the workpiece and provide a guided movement of the parts of the machine. Thus, the relative movement between the workpiece and the cutting tool is controlled or constrained by the machine to at least some extent, rather than being entirely "offhand" or "freehand". It is a power-driven metal cutting machine which assists in managing the needed relative motion between cutting tool and the job that changes the size and shape of the job material.

<span class="mw-page-title-main">Diamond turning</span> Method for making advanced optical elements

Diamond turning is turning using a cutting tool with a diamond tip. It is a process of mechanical machining of precision elements using lathes or derivative machine tools equipped with natural or synthetic diamond-tipped tool bits. The term single-point diamond turning (SPDT) is sometimes applied, although as with other lathe work, the "single-point" label is sometimes only nominal. The process of diamond turning is widely used to manufacture high-quality aspheric optical elements from crystals, metals, acrylic, and other materials. Plastic optics are frequently molded using diamond turned mold inserts. Optical elements produced by the means of diamond turning are used in optical assemblies in telescopes, video projectors, missile guidance systems, lasers, scientific research instruments, and numerous other systems and devices. Most SPDT today is done with computer numerical control (CNC) machine tools. Diamonds also serve in other machining processes, such as milling, grinding, and honing. Diamond turned surfaces have a high specular brightness and require no additional polishing or buffing, unlike other conventionally machined surfaces.

<span class="mw-page-title-main">Sheet metal</span> Metal formed into thin, flat pieces

Sheet metal is metal formed into thin, flat pieces, usually by an industrial process.

<span class="mw-page-title-main">Inconel</span> Austenitic nickel-chromium superalloys

Inconel is a nickel-chromium-based superalloy often utilized in extreme environments where components are subjected to high temperature, pressure or mechanical loads. Inconel alloys are oxidation- and corrosion-resistant. When heated, Inconel forms a thick, stable, passivating oxide layer protecting the surface from further attack. Inconel retains strength over a wide temperature range, attractive for high-temperature applications where aluminium and steel would succumb to creep as a result of thermally-induced crystal vacancies. Inconel's high-temperature strength is developed by solid solution strengthening or precipitation hardening, depending on the alloy.

<span class="mw-page-title-main">Turning</span> Machining process

Turning is a machining process in which a cutting tool, typically a non-rotary tool bit, describes a helix toolpath by moving more or less linearly while the workpiece rotates.

A cryogenic treatment is the process of treating workpieces to cryogenic temperatures in order to remove residual stresses and improve wear resistance in steels and other metal alloys, such as aluminum. In addition to seeking enhanced stress relief and stabilization, or wear resistance, cryogenic treatment is also sought for its ability to improve corrosion resistance by precipitating micro-fine eta carbides, which can be measured before and after in a part using a quantimet.

<span class="mw-page-title-main">Shear forming</span>

Shear forming, also referred as shear spinning, is similar to metal spinning. In shear spinning the area of the final piece is approximately equal to that of the flat sheet metal blank. The wall thickness is maintained by controlling the gap between the roller and the mandrel. In shear forming a reduction of the wall thickness occurs.

<span class="mw-page-title-main">STEP-NC</span> Machine tool control language

STEP-NC is a machine tool control language that extends the ISO 10303 STEP standards with the machining model in ISO 14649, adding geometric dimension and tolerance data for inspection, and the STEP PDM model for integration into the wider enterprise. The combined result has been standardized as ISO 10303-238.

In manufacturing, threading is the process of creating a screw thread. More screw threads are produced each year than any other machine element. There are many methods of generating threads, including subtractive methods ; deformative or transformative methods ; additive methods ; or combinations thereof.

<span class="mw-page-title-main">Ultrasonic consolidation</span>

Ultrasonic Consolidation (UC) or Ultrasonic Additive Manufacturing (UAM) is a low temperature additive manufacturing or 3D printing technique for metals.

<span class="mw-page-title-main">Multiaxis machining</span> Manufacturing processes using tools that can move in 4 or more directions

Multiaxis machining is a manufacturing process that involves tools that move in 4 or more directions and are used to manufacture parts out of metal or other materials by milling away excess material, by water jet cutting or by laser cutting. This type of machining was originally performed mechanically on large complex machines. These machines operated on 4, 5, 6, and even 12 axes which were controlled individually via levers that rested on cam plates. The cam plates offered the ability to control the tooling device, the table in which the part is secured, as well as rotating the tooling or part within the machine. Due to the machines size and complexity it took extensive amounts of time to set them up for production. Once computer numerically controlled machining was introduced it provided a faster, more efficient method for machining complex parts.

Today the metal forming industry is making increasing use of simulation to evaluate the performing of dies, processes and blanks prior to building try-out tooling. Finite element analysis (FEA) is the most common method of simulating sheet metal forming operations to determine whether a proposed design will produce parts free of defects such as fracture or wrinkling.

<span class="mw-page-title-main">CNC plunge milling</span>

CNC plunge milling, also called z-axis milling, is a CNC milling process. In this process, the feed is provided linearly along the tool axis while doing CNC processing.

<span class="mw-page-title-main">Freeform surface machining</span> Machining techniques for complex surfaces

In manufacturing, freeform surface machining refers to the machining of complex surfaces that are not uniformly planar. The industries which most often manufactures free-form surfaces are basically aerospace, automotive, die mold industries, biomedical and power sector for turbine blades manufacturing. Generally 3- or 5-axis CNC milling machines are used for this purpose. The manufacturing process of freeform surfaces is not an easy job, as the tool path generation in present CAM technology is generally based on geometric computation so tool path are not optimum. The geometry can also be not described explicitly so errors and discontinuities occurrence in the solid structure cannot be avoided. Free-form surfaces are machined with the help of different tool path generation method like adaptive iso-planar tool path generation, constant scallop tool path generation, adaptive iso-parametric method, iso-curvature, isophote and by other methods. The different methods are chosen based on the parameters which is needed to be optimized.

A machine tool monitoring system is a flow of information and system processing in which the information selection, obtaining data, processing of information and decision making on the refined information are integrated. The aim of tool condition monitoring is to detect early the disturbances in the machining process and wear of machine tool components.

Virtual machining is the practice of using computers to simulate and model the use of machine tools for part manufacturing. Such activity replicates the behavior and errors of a real environment in virtual reality systems. This can provide useful ways to manufacture products without physical testing on the shop floor. As a result, time and cost of part production can be decreased.

Digital manufacturing is an integrated approach to manufacturing that is centered around a computer system. The transition to digital manufacturing has become more popular with the rise in the quantity and quality of computer systems in manufacturing plants. As more automated tools have become used in manufacturing plants it has become necessary to model, simulate, and analyze all of the machines, tooling, and input materials in order to optimize the manufacturing process. Overall, digital manufacturing can be seen sharing the same goals as computer-integrated manufacturing (CIM), flexible manufacturing, lean manufacturing, and design for manufacturability (DFM). The main difference is that digital manufacturing was evolved for use in the computerized world.

Design for additive manufacturing is design for manufacturability as applied to additive manufacturing (AM). It is a general type of design methods or tools whereby functional performance and/or other key product life-cycle considerations such as manufacturability, reliability, and cost can be optimized subjected to the capabilities of additive manufacturing technologies.

<span class="mw-page-title-main">Yoram Koren</span> Israeli-American engineering academic

Yoram Koren is an Israeli-American academic. He is the James J. Duderstadt Distinguished University Professor Emeritus of Manufacturing and the Paul G. Goebel Professor Emeritus of Engineering at the University of Michigan, Ann Arbor. Since 2014 he is a distinguished visiting professor at the Technion – Israel Institute of Technology.

References

  1. Nagargoje, Aniket; Kankar, Pavan; Jain, Prashant; Tandon, Puneet (9 February 2021). "Performance Evaluation of the Data Clustering Techniques and Cluster Validity Indices for Efficient Toolpath Development for Incremental Sheet Forming". Journal of Computing and Information Science in Engineering. 21 (3): 031001. doi:10.1115/1.4048914. S2CID   228968844.
  2. Strano, Matteo (31 December 2004). "Technological Representation of Forming Limits for Negative Incremental Forming of Thin Aluminum Sheets". Journal of Manufacturing Processes. 7 (2): 122–129. doi:10.1016/S1526-6125(05)70089-X.
  3. "Dieless NC forming". Retrieved on 2008-11-05.
  4. Examining Tool Shapes in Single Point Incremental Forming (Cawley et al, 2013)
  5. Behera, Amar Kumar; Lauwers, Bert; Duflou, Joost R. (2014-05-01). "Tool path generation framework for accurate manufacture of complex 3D sheet metal parts using single point incremental forming". Computers in Industry. 65 (4): 563–584. doi:10.1016/j.compind.2014.01.002.
  6. Duflou, Joost R.; Behera, Amar Kumar; Vanhove, Hans; Bertol, Liciane S. (2013-01-01). "Manufacture of Accurate Titanium Cranio-Facial Implants with High Forming Angle Using Single Point Incremental Forming". Key Engineering Materials. 549: 223–230. doi:10.4028/www.scientific.net/kem.549.223. ISSN   1662-9795. S2CID   136559821.
  7. Nagargoje, Aniket; Kankar, Pavan; Jain, Prashant; Tandon, Puneet (9 February 2021). "Performance Evaluation of the Data Clustering Techniques and Cluster Validity Indices for Efficient Toolpath Development for Incremental Sheet Forming". Journal of Computing and Information Science in Engineering. 21 (3): 031001. doi:10.1115/1.4048914. S2CID   228968844.
  8. Hamilton, K.; Jeswiet, J. (2010). "Single point incremental forming at high feed rates and rotational speeds: Surface and structural consequences". Cirp Annals. 59: 311–314. doi:10.1016/j.cirp.2010.03.016.
  9. Golabi, Sa’id; Khazaali, Hossain (August 2014). "Determining frustum depth of 304 stainless steel plates with various diameters and thicknesses by incremental forming". Journal of Mechanical Science and Technology. 28 (8): 3273–3278. doi:10.1007/s12206-014-0738-6. ISSN   1738-494X. S2CID   110179841.
  10. Davarpanah, Mohammad Ali; Mirkouei, Amin; Yu, Xiaoyan; Malhotra, Rajiv; Pilla, Srikanth (August 2015). "Effects of incremental depth and tool rotation on failure modes and microstructural properties in Single Point Incremental Forming of polymers". Journal of Materials Processing Technology. 222: 287–300. doi:10.1016/j.jmatprotec.2015.03.014.
  11. Lu, B.; Fang, Y.; Xu, D.K.; Chen, J.; Ou, H.; Moser, N.H.; Cao, J. (October 2014). "Mechanism investigation of friction-related effects in single point incremental forming using a developed oblique roller-ball tool". International Journal of Machine Tools and Manufacture. 85: 14–29. doi: 10.1016/j.ijmachtools.2014.04.007 .
  12. Carrino, L.; Giuliano, G.; Strano, M. (2006), "The Effect of the Punch Radius in Dieless Incremental Forming", Intelligent Production Machines and Systems, Elsevier, pp. 204–209, doi:10.1016/b978-008045157-2/50040-7, ISBN   9780080451572
  13. Fan, Guoqiang; Gao, L.; Hussain, G.; Wu, Zhaoli (December 2008). "Electric hot incremental forming: A novel technique". International Journal of Machine Tools and Manufacture. 48 (15): 1688–1692. doi:10.1016/j.ijmachtools.2008.07.010.
  14. " Archived 2017-01-29 at the Wayback Machine " Retrieved 2008-11-05.
  15. J Jeswiet: "Asymmetric Single Point Incremental Forming of Sheet Metal", CIRP Annals - Manufacturing Technology, 2005
  16. Behera, Amar Kumar; Lu, Bin; Ou, Hengan (2016-03-01). "Characterization of shape and dimensional accuracy of incrementally formed titanium sheet parts with intermediate curvatures between two feature types". The International Journal of Advanced Manufacturing Technology. 83 (5–8): 1099–1111. doi: 10.1007/s00170-015-7649-2 . ISSN   0268-3768.
  17. Behera, Amar Kumar; Verbert, Johan; Lauwers, Bert; Duflou, Joost R. (2013-03-01). "Tool path compensation strategies for single point incremental sheet forming using multivariate adaptive regression splines". Computer-Aided Design. 45 (3): 575–590. doi:10.1016/j.cad.2012.10.045.
  18. Walczyk, Daniel F.; Hosford, Jean F.; Papazian, John M. (2003). "Using Reconfigurable Tooling and Surface Heating for Incremental Forming of Composite Aircraft Parts". Journal of Manufacturing Science and Engineering. 125 (2): 333. doi:10.1115/1.1561456.
  19. Behera, Amar Kumar; Ou, Hengan (2016-12-01). "Effect of stress relieving heat treatment on surface topography and dimensional accuracy of incrementally formed grade 1 titanium sheet parts" (PDF). The International Journal of Advanced Manufacturing Technology. 87 (9–12): 3233–3248. doi:10.1007/s00170-016-8610-8. ISSN   0268-3768. S2CID   54579233.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.