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Multiaxis machining

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A 5-axis water jet cutter and a part manufactured with it.

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.[1] Once computer numerically controlled machining was introduced it provided a faster, more efficient method for machining complex parts.

Typical CNC tools support translation in 3 axis; multiaxis machines also support rotation around one or multiple axis. 5-axis machines are commonly used in industry in which the workpiece is translated linearly along three axes (typically x, y, and z) and the tooling spindle is capable of rotation about an addition 2 axes.[2]

There are now many CAM (computer aided manufacturing) software systems available to support multiaxis machining including software that can automatically convert 3-axis toolpaths into 5-axis toolpaths.[3] Prior to the advancement of Computer Aided Manufacturing, transferring information from design to production often required extensive manual labor, generating errors and resulting in wasted time and material.

There are three main components to multiaxis machines:

  1. The machines physical capabilities i.e. torque, spindle speed, axis orientation/operation.
  2. The CNC drive system, the components that move the machine. This includes servo-motors, rapid traverse systems, ball screws, and how positioning is monitored.
  3. The CNC controller, this is how data is transferred/stored within machine, and input data is processed and executed.[4]

Multiaxis machines offer several improvements over other CNC tools, at the cost of increased complexity and price of the machine:

  • The amount of human labor is reduced, if the piece would otherwise have to be turned manually during the machining.
  • A better surface finish can be obtained by moving the tool tangentially about the surface (as opposed to moving the workpiece around the spindle).
  • More complex parts can be manufactured, particularly parts with curved holes.
  • Increased tool life due to the ability to achieve optimal angles between the tool and machining surface.
  • Higher quality parts. What once required multiple setups now can be executed in only a few if not one, reducing steps and decreasing the opportunity for error.

The number of axes for multiaxis machines varies from 4 to 9.[5] Each axis of movement is implemented either by moving the table (into which the workpiece is attached), or by moving the tool. The actual configuration of axes varies, therefore machines with the same number of axes can differ in the movements that can be performed.

Applications

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Multiaxis CNC machines are used in many industries including:

Multiaxis machining is also commonly used for rapid prototyping as it can create strong, high quality models out of metal, plastic, and wood while still being easily programmable.[10]

Comparison of different multiaxis machines[11][12][13][14]
Name # of rotary axes on head # of rotary axes on table Advantages over other multiaxis machines Diagram
CNC lathe 0 1 rotating X axis
  • Optimized for machining cylindrical objects
Pivot spindle head and rotary table 1 rotating X axis 1 rotating Y axis
  • Able to have a larger work area that increases the versatility of the machine and the kinds of parts it can mill
  • More stable than a Double Pivot Spindle Head
Double rotary table 0 1 rotating X axis

1 rotating Y axis

  • Best method for milling overhangs
  • Easiest way to convert a 3 axis machine to a 5 axis machine
  • Able to machine higher-volume objects
Double pivot spindle head 1 rotating Y axis

1 rotating Z axis

0
  • Stationary base allows for heavy parts to be milled
  • Ideal for milling non-round objects
Rotary table and table trunion 0 1 rotating Z axis

1 rotating axis 45° between X & Y axes

  • Similar to a Double Rotary Table, but the 45° axis allows it to be more compact
  • Most cost-effective for machining small parts

Computer-aided manufacturing (CAM) software

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CAM software automates the process of converting 3D models into tool paths, the route the multiaxis machine takes to mill a part (Fig. 1). This software takes into account the different parameters of the tool head (in the case of a CNC router, this would be the bit size), dimensions of the blank, and any constraints the machine may have. The tool paths for multiple passes can be generated to produce a higher level of detail on the parts. The first few passes remove large amounts of material, while the final, most important pass creates the surface finish.[15] In the case of the CNC lathe, the CAM software will optimize the tool path to have the central axis of the part align with the rotary of the lathe.[16] Once the tool paths have been generated, the CAM software will convert them into G-code, allowing the CNC machine to begin milling.[17]

CAM software is currently the limiting factor in the capabilities of a multiaxis machine with ongoing development. Recent breakthroughs in this space include:

  • Topology optimization, an algorithm that refines 3D models to be more efficient and cost-effective on CNC machines.[18]
  • Automated recognition of 3D model features, which can simplify tool path generation by identifying instructions for the machine to follow from the features of the 3D model.[19][20]

See also

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References

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  1. ^ Apro, Karlo (2009). Secrets of 5-axis machining. Industrial Press. p. 3. ISBN 978-0-8311-3375-7. OCLC 1008856747.
  2. ^ "What Are The Main Applications For 5-Axis CNC Machining? - Kentin Engineering Australia". Kentin Engineering Australia. 2016-05-05. Retrieved 2018-11-17.
  3. ^ MCADCafé. Sescoi's WorkNC 5-Axis and Auto 5 - a competitive advantage at ALLIO.
  4. ^ Saxer, M; De Beer, N; Dimitrov, DM (3 December 2012). "High-speed 5-axis machining for tooling applications". The South African Journal of Industrial Engineering. 23 (3): 144–153. doi:10.7166/23-3-517. ProQuest 1269154092.
  5. ^ Apro, Karlo (2009). Secrets of 5-axis machining. Industrial Press. pp. 14–15. ISBN 978-0-8311-3375-7. OCLC 1008856747.
  6. ^ Perry, Clinton (September 2018). "5-axis CNC machines for aerospace". Aerospace Manufacturing And Design. Retrieved 4 April 2024.
  7. ^ "The Precision Use of 5-Axis CNC Machining in Automotive Industry". www.waykenrm.com. 30 October 2018. Retrieved 2020-11-15.
  8. ^ "Specialist CNC machining solutions". Furniture & Joinery Production. Retrieved 2020-11-15.
  9. ^ Duncan Thompson (December 2021). "On the ball with hip implants". The World's Most Flexible Tool Grinder - ANCA - CNC Machines. Retrieved 26 September 2023.
  10. ^ "Why People Like To Use 5 Axis CNC Machine In Rapid Prototyping?". www.ltc-proto.com. Retrieved 2020-11-16.
  11. ^ "What is CNC Lathe Machine and what its function?". Worthy Hardware. 2017-08-09. Retrieved 2020-10-22.
  12. ^ "Everything You Need To Know About 5-Axis CNC Machining". www.waykenrm.com. Retrieved 2020-10-25.
  13. ^ "Machine Configurations". What is 5-Axis CNC Machining & Programming. Retrieved 2020-11-15.
  14. ^ "Four Types Of Five-Axis Machining Centers". www.mmsonline.com. Retrieved 2020-11-15.
  15. ^ Chang, Kuang-Hua, 1960- (2013). Product manufacturing and cost estimating using CAD/CAE. Oxford, UK: Academic Press. ISBN 978-0-12-404600-9. OCLC 868597615.{{cite book}}: CS1 maint: multiple names: authors list (link) CS1 maint: numeric names: authors list (link)[page needed]
  16. ^ Kawaguchi, Yasuhiro; Nakamoto, Keiichi; Ishida, Toru; Takeuchi, Yoshimi (2009). "C8 Artistic Machining by Means of Multi-tasking Machine(Multi-axis control machining)". Proceedings of International Conference on Leading Edge Manufacturing in 21st Century: Lem21. 2009 (5): 145–148. doi:10.1299/jsmelem.2009.5.145.
  17. ^ Dejan (2020-05-06). "G-code Explained | List of Most Important G-code Commands". HowToMechatronics. Retrieved 2020-11-15.
  18. ^ Mirzendehdel, Amir M.; Behandish, Morad; Nelaturi, Saigopal (May 2020). "Topology optimization with accessibility constraint for multi-axis machining". Computer-Aided Design. 122: 102825. arXiv:2002.07627. doi:10.1016/j.cad.2020.102825. S2CID 211146708.
  19. ^ Manufacturing science and technology VI : Selected, peer reviewed papers from the 2015 6th International Conference on Manufacturing Science and Technology (ICMST 2015), June 1-2, 2015, Bandar Seri Begawan, Brunei. De Silva, Liyanage C.,, Debnath, Sujan,, Reddy, M. Mohan. [Zurich], Switzerland. 2 September 2015. ISBN 978-3-0357-0014-5. OCLC 921032943.{{cite book}}: CS1 maint: location missing publisher (link) CS1 maint: others (link)[page needed]
  20. ^ Ding Han. "Tool path planning and dynamics simulation in 5-axis CNC machining". RuiYi Model.