Hybrid Spindle - An approach for a milling machine tool spindle with extended working range for HSC and HPC

Research output: Contribution to journalConference articleResearchpeer review

Authors

  • B. Denkena
  • B. Bergmann
  • M. Mücke
  • J. Königsberg
  • B. Ponick

Research Organisations

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Details

Original languageEnglish
Pages (from-to)159-165
Number of pages7
JournalProcedia Manufacturing
Volume24
Early online date6 Jul 2018
Publication statusPublished - 2018
Event4th International Conference on System-Integrated Intelligence: Intelligent, Flexible and Connected Systems in Products and Production, 2018 - Hannover, Germany
Duration: 19 Jun 201820 Jun 2018

Abstract

Commercial motor-driven spindles for milling machine tools are generally developed for specific machining operations, such as HPC (High Performance Cutting) or HSC (High Speed Cutting). HPC and HSC require significantly different working ranges regarding spindle speed and torque. E.g. in HPC operations, high torque at low spindle speeds is needed. The two working ranges are covered only limited by a conventional spindle so far. However, a spindle system that can switch the working range allows cost-effective manufacturing of a wider range of materials within the same machine tool. The spindle bearings and the power electronics supply are challenges, when switching between both working ranges. HPC operation requires high bearing stiffness in order to transmit high forces occurring during the cutting process. However, the associated high bearing preload leads to high frictional losses at high speeds for HSC operations. Furthermore, the wide operating range generates contrary requirements for the motor winding. To increase the spindle speeds with a winding being assembled for high torques, the current has to be increased. For this purpose, expensive and non-standardized motor inverters are required. This paper introduces a concept to overcome these challenges. Firstly, an approach to adjust the bearing preload is presented, using a compact, electrically controlled bearing preload element, which is suitable for industrial applications. Next, an approach for a reconfigurable winding design of the spindle motor is shown. This allows electrical switching between the working ranges using conventional motor inverters. Finally, an analysis of the conditions of use of the hybrid spindles is presented.

Keywords

    Hybride spindle, Machine tool, Milling

ASJC Scopus subject areas

Cite this

Hybrid Spindle - An approach for a milling machine tool spindle with extended working range for HSC and HPC. / Denkena, B.; Bergmann, B.; Mücke, M. et al.
In: Procedia Manufacturing, Vol. 24, 2018, p. 159-165.

Research output: Contribution to journalConference articleResearchpeer review

Denkena, B, Bergmann, B, Mücke, M, Königsberg, J & Ponick, B 2018, 'Hybrid Spindle - An approach for a milling machine tool spindle with extended working range for HSC and HPC', Procedia Manufacturing, vol. 24, pp. 159-165. https://doi.org/10.1016/j.promfg.2018.06.045, https://doi.org/10.15488/3810
Denkena, B., Bergmann, B., Mücke, M., Königsberg, J., & Ponick, B. (2018). Hybrid Spindle - An approach for a milling machine tool spindle with extended working range for HSC and HPC. Procedia Manufacturing, 24, 159-165. https://doi.org/10.1016/j.promfg.2018.06.045, https://doi.org/10.15488/3810
Denkena B, Bergmann B, Mücke M, Königsberg J, Ponick B. Hybrid Spindle - An approach for a milling machine tool spindle with extended working range for HSC and HPC. Procedia Manufacturing. 2018;24:159-165. Epub 2018 Jul 6. doi: 10.1016/j.promfg.2018.06.045, 10.15488/3810
Denkena, B. ; Bergmann, B. ; Mücke, M. et al. / Hybrid Spindle - An approach for a milling machine tool spindle with extended working range for HSC and HPC. In: Procedia Manufacturing. 2018 ; Vol. 24. pp. 159-165.
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title = "Hybrid Spindle - An approach for a milling machine tool spindle with extended working range for HSC and HPC",
abstract = "Commercial motor-driven spindles for milling machine tools are generally developed for specific machining operations, such as HPC (High Performance Cutting) or HSC (High Speed Cutting). HPC and HSC require significantly different working ranges regarding spindle speed and torque. E.g. in HPC operations, high torque at low spindle speeds is needed. The two working ranges are covered only limited by a conventional spindle so far. However, a spindle system that can switch the working range allows cost-effective manufacturing of a wider range of materials within the same machine tool. The spindle bearings and the power electronics supply are challenges, when switching between both working ranges. HPC operation requires high bearing stiffness in order to transmit high forces occurring during the cutting process. However, the associated high bearing preload leads to high frictional losses at high speeds for HSC operations. Furthermore, the wide operating range generates contrary requirements for the motor winding. To increase the spindle speeds with a winding being assembled for high torques, the current has to be increased. For this purpose, expensive and non-standardized motor inverters are required. This paper introduces a concept to overcome these challenges. Firstly, an approach to adjust the bearing preload is presented, using a compact, electrically controlled bearing preload element, which is suitable for industrial applications. Next, an approach for a reconfigurable winding design of the spindle motor is shown. This allows electrical switching between the working ranges using conventional motor inverters. Finally, an analysis of the conditions of use of the hybrid spindles is presented.",
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AU - Denkena, B.

AU - Bergmann, B.

AU - Mücke, M.

AU - Königsberg, J.

AU - Ponick, B.

N1 - Funding information: The authors thanks for funding the project H“ ybride Spindel”. The project has been funded by the AiF within the programme for sponsorship by Industrial Joint Research (IGF) of the German Federal Ministry of Economic Affairs and Energy based on an enactment of the German Parliament.

PY - 2018

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N2 - Commercial motor-driven spindles for milling machine tools are generally developed for specific machining operations, such as HPC (High Performance Cutting) or HSC (High Speed Cutting). HPC and HSC require significantly different working ranges regarding spindle speed and torque. E.g. in HPC operations, high torque at low spindle speeds is needed. The two working ranges are covered only limited by a conventional spindle so far. However, a spindle system that can switch the working range allows cost-effective manufacturing of a wider range of materials within the same machine tool. The spindle bearings and the power electronics supply are challenges, when switching between both working ranges. HPC operation requires high bearing stiffness in order to transmit high forces occurring during the cutting process. However, the associated high bearing preload leads to high frictional losses at high speeds for HSC operations. Furthermore, the wide operating range generates contrary requirements for the motor winding. To increase the spindle speeds with a winding being assembled for high torques, the current has to be increased. For this purpose, expensive and non-standardized motor inverters are required. This paper introduces a concept to overcome these challenges. Firstly, an approach to adjust the bearing preload is presented, using a compact, electrically controlled bearing preload element, which is suitable for industrial applications. Next, an approach for a reconfigurable winding design of the spindle motor is shown. This allows electrical switching between the working ranges using conventional motor inverters. Finally, an analysis of the conditions of use of the hybrid spindles is presented.

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Y2 - 19 June 2018 through 20 June 2018

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