Interchangeable core and cavity plates for two-plate family injection mould

M. A. M. Ali; N. Idayu; Z. Abdullah; M. H. A. Bakar; S. Sivarao; M. S. A. Aziz; A. Abdullah

doi:10.15282/jmes.11.3.2017.4.0255

Authors

M. A. M. Ali Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka (UTeM), 76100 Durian Tunggal, Melaka, Malaysia
N. Idayu Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka (UTeM), 76100 Durian Tunggal, Melaka, Malaysia
Z. Abdullah Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka (UTeM), 76100 Durian Tunggal, Melaka, Malaysia
M. H. A. Bakar Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka (UTeM), 76100 Durian Tunggal, Melaka, Malaysia
S. Sivarao Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka (UTeM), 76100 Durian Tunggal, Melaka, Malaysia
M. S. A. Aziz Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka (UTeM), 76100 Durian Tunggal, Melaka, Malaysia
A. Abdullah Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka (UTeM), 76100 Durian Tunggal, Melaka, Malaysia

DOI:

https://doi.org/10.15282/jmes.11.3.2017.4.0255

Keywords:

Family mould; plastic product; interchangeable mould; mould design.

Abstract

This study modified a two-plate family plastic injection mould to become interchangeable by changing the core and cavity plates using an existing mould base. The plastic parts produced in the modified two-plate family plastic injection mould included tensile, hardness, impact and flexural test specimens. The cavities of the plastic parts were machined at the parting surface of core plate. Meanwhile, the feeding systems including runner and gate system were machined at the cavity plate to ensure molten plastic can be injected in the cavity area. Various factors have been considered during the designing and fabricating process. This is to ensure the process of assembly between mould plate and standard mould parts can be done perfectly. The plastic parts in the family mould were successfully injected after mould was completed assembled and mould trial was performed. The plastic parts which had been ejected from the family injection mould are purposely produced for future research to study the mechanical properties of plastic materials.

References

Rech J, Calvez CL, Dessoly MA. A new approach for the characterization of machinability—application to steels for plastic injection molds. Journal of Materials Processing Technology. 2004;152:66-70.

Ajay KG. The complete technology book on plastic extrusion, moulding and moulds design: Asia Pacific Business Press Inc. Delhi. 2006.

Najiha MS, Rahman MM, Kadirgama K, Noor MM, Ramasamy D. Multi-objective optimization of minimum quantity lubrication in end milling of aluminum alloy AA6061T6. International Journal of Automotive and Mechanical Engineering. 2015;12:3003-17.

Rahman M, Wong YS, Zareena AR. Machinability of titanium alloys. International Journal Series C: Mechanical Systems, Machine Elements and Manufacturing. 2003;46:107-15.

Ali MA, Samsul M, Hussein NIS, Rizal M, Izamshah R, Hadzley M, et al. The effect of EDM die-sinking parameters on material removal rate of beryllium copper using full factorial method. Middle-East Journal of Scientific Research. 2013;16:44-50.

Mohanty S, Routara BC. A review on machining of metal matrix composites using nanoparticle mixed dielectric in electro-discharge machining. International Journal of Automotive and Mechanical Engineering. 2016;13:3518-39.

Izamshah R, Husna N, Hadzley M, Amran M, Shahir M, Amri M. Effects of cutter geometrical features on machining polyetheretherketones (PEEK) engineering plastic. Journal of Mechanical Engineering and Sciences. 2014;6:863-72.

Bakar MHA, Abdullah RIR, Ali MAM, Kasim MS, Sulaiman MA, Ahmad SSN, et al. Surface integrity of LM6 aluminum metal matrix composite when machined with high speed steel and uncoated carbide cutting tools. Journal of Mechanical Engineering and Sciences. 2014;6:854-62.

Kuzman K, Nardin B. Determination of manufacturing technologies in mould manufacturing. Journal of Materials Processing Technology. 2004;157:573-7.

Razak NH, Rahman MM, Kadirgama K. Investigation of machined surface in end-milling operation of Hastelloy C-2000 using coated-carbide insert. Advanced Science Letters. 2012;13:300-5.

Razak NH, Rahman MM, Kadirgama K. Cutting force and chip formation in end milling operation when machining nickel-based superalloy, Hastelloy C-2000. Journal of Mechanical Engineering and Sciences. 2017;11:2539-51.

Rao RV. Advanced modeling and optimization of manufacturing processes: international research and development: Springer-Verlag, London; 2010.

Amran MAM, Idayu N, Faizal KM, Sanusi M, Izamshah R, Shahir M. Part weight verification between simulation and experiment of plastic part in injection moulding process. IOP Conference Series: Materials Science and Engineering2016.

Ali MAM, Sani SSM. Warpage Analysis Verification Between Simulation And Experimental Of Dumbbell Plastic Part In The Injection Moulding Process. Science International (Lahore). 2014;26:1575-79.

Vishnuvarthanan M, Rajesh PR, Ilangovan S. Optimization of injection molding cycle time using moldflow analysis [J]. Middle-East Journal of Scientific Research. 2013;13:944-6.

Amran M, Salmah S, Sanusi M, Yuhazri M, Mohamad N, Azam MA, et al. Surface Roughness Optimization in Drilling Process Using Response Surface Method (RSM). Jurnal Teknologi. 2014;66:29-35.

Gheorghe O, Florin T, Vlad G, Gabriel D. Optimization of Micro Injection Molding of Polymeric Medical Devices Using Software Tools. Procedia Engineering. 2014;69:340-6.

Min BH. A study on quality monitoring of injection-molded parts. Journal of Materials Processing Technology. 2003;136:1-6.

Amran MA, Hadzley M, Amri S, Izamshah R, Hassan A, Samsi S, et al. Optimization of Gate, Runner and Sprue in Two‐Plate Family Plastic Injection Mould. AIP Conference Proceedings: AIP; 2010. p. 309-13.

King D, Tansey T. Alternative materials for rapid prototyping. Journal of Materials Processing Technology. 2002;121:313-7.

Rodriguez J, Crouch C, Guenther B, VanEeuwen L, DeMenter J. In: Latin American and Caribbean Conference for Engineering and Technology (LACCEI’2014) July 22 - 24. Guayaquil, Ecuador; 2014.

Mohd A, Noorfa I, Rosidah J, Mohd H, Yuhazri Y, Abdul R, et al. Comparison between star and linear runner layout of family plastic injection mold. ARPN Journal of Engineering and Applied Sciences. 2015;10:6263-68.

Characterization and failure analysis of plastics: ASM International, The Materials Information Society, USA; 2003.

Kaushish JP. Manufacturing Processes. New Delhi: PHI learning Private Limited; 2010.

Dey S, Chakraborty S. A study on the machinability of some metal alloys using grey TOPSIS method. Decision Science Letters. 2016;5:31-44.

Mohd AA, Siti S, Zulkeflee, Pay JL, Mohd RM, Raja I, et al. Effect of different coolant medium on warpage deflection using moldflow insight analysis. 2015. p. 42-6.

Akshay H, Naiju CD, Mukund NJ, Izabela N. Redesign of an in-market food processor for manufacturing cost reduction using