Testing the Performance of Rival Warehousing Policies through Discrete Event Simulation
This research tested the performance of alternative
warehouse designs concerning the picking process. The chosen
performance measures were Travel Distance and Total Fulfilment
Time. An explanatory case study was built up around a model
implemented with SIMUL8. Hypotheses were set by selecting
outcomes from the literature survey matching popular empirical
findings. 17.4% reductions were found for Total Fulfilment Time and
Resource Utilisation. The latter was then used as a proxy for
operational efficiency. Literal replication of theoretical data-patterns
was considered as an internal validity sign. Assessing the estimated
changes benefits ahead of implementation was found to be a
contribution to practice.
[1] Gu J., Goetschalckx M., McGinnis L., (2010), “Research on warehouse
design and performance evaluation: a comprehensive review”, European
Journal of Operational Research, vol. 203, pp. 539–549.
[2] Rouwenhorst, B., Reuter, B., Stockrahm, V., van Houtum, G., Mantel,
R., Zijm, W., (2000), “Warehouse design and control: framework and
literature review”, European Journal of Operational Research, vol.
122(3), pp. 515-533.
[3] Van den Berg, J., (1999), “A literature survey on planning and control of
warehousing systems”, IIE Transactions, vol. 31(8), pp. 751-762.
[4] Frazelle, E. (2002), World-class warehousing and material handling,
New York, McGraw-Hill.
[5] Petersen, C., Aase, G., & Heiser, D., (2004), “Improving order-picking
performance through the implementation of class-based storage”,
International Journal of Physical Distribution & Logistics Management,
vol. 34(7/8), pp. 534.
[6] Chan, F. & Chan H., (2011), “Improving the productivity of order
picking of a manualpick and multi-level rack distribution warehouse
through the implementation of classbased storage”, Expert Systems with
Applications, vol. 38, pp. 2686-2700.
[7] Petersen, C. & Aase, G., (2004), “A comparison of picking, storage, and
routing policies in manual order picking”, Int. J. Production Economics,
vol. 92, pp. 11-19.
[8] Rushton A., Croucher, P. and Baker, P., (2010), The handbook of
logistics & distribution management, London, Kogan Page.
[9] De Koster, M. & Roodbergen, K., (2007), “Design and control of
warehouse order picking: a literature review”, European Journal of
Operational Research, vol. 182, pp. 481-501.
[10] Van den Berg, J., Zijm, W., (1999), “Models for warehouse
management: classification and exemples”, Int. J. Production
Economics, vol. 59, pp. 519 528.
[11] Establish Inc. / Herbert W. Davis & Co., (2005). Logistic Cost and
Service 2005, presented at Council of Supply Chain Managers
Conference 2005.
[12] ELA European Logistics Association / A T Kearney Management
Consultants, (2004).
[13] Goetschalckx, M, McGinnis, L., Bodner, D., Govindaraj, T., Sharp, G.,
Huang, K., (2002), “A systematic design procedure for small parts
warehousing systems using modular drawer and bin shelving systems”,
IMHRC proceedings.
[14] Baker P. & Canessa, M., (2009), “Warehouse design: a structured
approach”, European Journal of Operational Research, vol. 193, pp. 425-
436.
[15] Richards, G., (2011), Warehouse management: a complete guide to
improving efficiency and minimizing costs in the modern warehouse,
London, Kogan Page.
[16] De Koster, M. & Roodbergen, K., (2007), “Design and control of
warehouse order picking: a literature review”, European Journal of
Operational Research, vol. 182, pp. 481-501.
[17] Roodbergen, K., Vis, I., (2005), “A model for warehouse layout”, IIE
Transactions, vol. 38(10), pp. 799-811.
[18] Petersen, C., Siu, C., Heiser, D., (2005), “Improving order picking
performance utilizing slotting and golden zone storage”, International
Journal of Operations & Production Management, vol. 25(9/10), pp. 997.
[19] Saccomano, A., (1996), “How to pick picking technologie”, Traffic
World, 13 May, pp. 39-40.
[20] Jones, E. and Battieste, T., (2004), “Golden retrieva”, Industrial
Engineer, vol. 36(6), pp. 37-41.
[21] Roodbergen, K., De Koster, M., (2001), “Routing methods for
warehouses with multiple cross aisles”, International Journal of
Production Research, vol. 39(9), pp. 1865-1883.
[22] Robinson, S. (2004), Simulation: the practice of model development and
use, Chichester, John Wiley & Sons Ltd.
[23] Moreira, L. (2013), A Simulation Approach to Warehousing Policies:
The GrandVision Case, MSc Thesis, ISCTE – IUL, Portugal.
[24] Yin, R., (1994), Case study research: design and methods, 2nd ed., Sage
Publications, Inc., USA.
[25] Vilas-Boas da Silva, J.M., Kay, J.M. and Dinis, J.A. (1999), "Credibility
in explanatory multiple-case studies: a practical approach", VI
international annual conference of the EurOMA, Venice, Italy, 7th-8th
June 1999, pp. 129-136. [26] Eisenhardt, K. (1989), “Building theories from case study research”,
Academy of Management Review, vol. 14(4), pp. 532-550.
[1] Gu J., Goetschalckx M., McGinnis L., (2010), “Research on warehouse
design and performance evaluation: a comprehensive review”, European
Journal of Operational Research, vol. 203, pp. 539–549.
[2] Rouwenhorst, B., Reuter, B., Stockrahm, V., van Houtum, G., Mantel,
R., Zijm, W., (2000), “Warehouse design and control: framework and
literature review”, European Journal of Operational Research, vol.
122(3), pp. 515-533.
[3] Van den Berg, J., (1999), “A literature survey on planning and control of
warehousing systems”, IIE Transactions, vol. 31(8), pp. 751-762.
[4] Frazelle, E. (2002), World-class warehousing and material handling,
New York, McGraw-Hill.
[5] Petersen, C., Aase, G., & Heiser, D., (2004), “Improving order-picking
performance through the implementation of class-based storage”,
International Journal of Physical Distribution & Logistics Management,
vol. 34(7/8), pp. 534.
[6] Chan, F. & Chan H., (2011), “Improving the productivity of order
picking of a manualpick and multi-level rack distribution warehouse
through the implementation of classbased storage”, Expert Systems with
Applications, vol. 38, pp. 2686-2700.
[7] Petersen, C. & Aase, G., (2004), “A comparison of picking, storage, and
routing policies in manual order picking”, Int. J. Production Economics,
vol. 92, pp. 11-19.
[8] Rushton A., Croucher, P. and Baker, P., (2010), The handbook of
logistics & distribution management, London, Kogan Page.
[9] De Koster, M. & Roodbergen, K., (2007), “Design and control of
warehouse order picking: a literature review”, European Journal of
Operational Research, vol. 182, pp. 481-501.
[10] Van den Berg, J., Zijm, W., (1999), “Models for warehouse
management: classification and exemples”, Int. J. Production
Economics, vol. 59, pp. 519 528.
[11] Establish Inc. / Herbert W. Davis & Co., (2005). Logistic Cost and
Service 2005, presented at Council of Supply Chain Managers
Conference 2005.
[12] ELA European Logistics Association / A T Kearney Management
Consultants, (2004).
[13] Goetschalckx, M, McGinnis, L., Bodner, D., Govindaraj, T., Sharp, G.,
Huang, K., (2002), “A systematic design procedure for small parts
warehousing systems using modular drawer and bin shelving systems”,
IMHRC proceedings.
[14] Baker P. & Canessa, M., (2009), “Warehouse design: a structured
approach”, European Journal of Operational Research, vol. 193, pp. 425-
436.
[15] Richards, G., (2011), Warehouse management: a complete guide to
improving efficiency and minimizing costs in the modern warehouse,
London, Kogan Page.
[16] De Koster, M. & Roodbergen, K., (2007), “Design and control of
warehouse order picking: a literature review”, European Journal of
Operational Research, vol. 182, pp. 481-501.
[17] Roodbergen, K., Vis, I., (2005), “A model for warehouse layout”, IIE
Transactions, vol. 38(10), pp. 799-811.
[18] Petersen, C., Siu, C., Heiser, D., (2005), “Improving order picking
performance utilizing slotting and golden zone storage”, International
Journal of Operations & Production Management, vol. 25(9/10), pp. 997.
[19] Saccomano, A., (1996), “How to pick picking technologie”, Traffic
World, 13 May, pp. 39-40.
[20] Jones, E. and Battieste, T., (2004), “Golden retrieva”, Industrial
Engineer, vol. 36(6), pp. 37-41.
[21] Roodbergen, K., De Koster, M., (2001), “Routing methods for
warehouses with multiple cross aisles”, International Journal of
Production Research, vol. 39(9), pp. 1865-1883.
[22] Robinson, S. (2004), Simulation: the practice of model development and
use, Chichester, John Wiley & Sons Ltd.
[23] Moreira, L. (2013), A Simulation Approach to Warehousing Policies:
The GrandVision Case, MSc Thesis, ISCTE – IUL, Portugal.
[24] Yin, R., (1994), Case study research: design and methods, 2nd ed., Sage
Publications, Inc., USA.
[25] Vilas-Boas da Silva, J.M., Kay, J.M. and Dinis, J.A. (1999), "Credibility
in explanatory multiple-case studies: a practical approach", VI
international annual conference of the EurOMA, Venice, Italy, 7th-8th
June 1999, pp. 129-136. [26] Eisenhardt, K. (1989), “Building theories from case study research”,
Academy of Management Review, vol. 14(4), pp. 532-550.
@article{"International Journal of Business, Human and Social Sciences:71351", author = "João Vilas-Boas and Abdul Suleman and Luis Moreira", title = "Testing the Performance of Rival Warehousing Policies through Discrete Event Simulation", abstract = "This research tested the performance of alternative
warehouse designs concerning the picking process. The chosen
performance measures were Travel Distance and Total Fulfilment
Time. An explanatory case study was built up around a model
implemented with SIMUL8. Hypotheses were set by selecting
outcomes from the literature survey matching popular empirical
findings. 17.4% reductions were found for Total Fulfilment Time and
Resource Utilisation. The latter was then used as a proxy for
operational efficiency. Literal replication of theoretical data-patterns
was considered as an internal validity sign. Assessing the estimated
changes benefits ahead of implementation was found to be a
contribution to practice.", keywords = "Warehouse discrete-event simulation, Storage policy
selection and assessment, Performance evaluation of order picking.", volume = "9", number = "11", pages = "3820-6", }
