eprintid: 1581 rev_number: 2 eprint_status: archive userid: 1 dir: disk0/00/00/15/81 datestamp: 2023-11-09 15:49:45 lastmod: 2023-11-09 15:49:45 status_changed: 2023-11-09 15:40:55 type: conference_item metadata_visibility: show creators_name: Altaf, K. creators_name: Rani, A.M.A. creators_name: Raghavan, V.R. title: Fabrication of circular and Profiled Conformal Cooling Channels in aluminum filled epoxy injection mould tools ispublished: pub keywords: 3D printers; Aluminium plates; Aluminum-filled epoxy; Cavity wall; Channel pattern; Circular channels; Circular cross-sections; Conformal cooling channels; Conventional manufacturing; Coolant flow; Cooling channels; Cross sectional area; Cross-sectional shape; Curing cycle; Epoxy injection; Fabrication technique; Face surfaces; Injection mould; Injection moulding; Moulded parts; Profiled channels; Rapid tooling, Aluminum; Cooling; Curing; Fabrication; Rapid prototyping; Sustainable development; Temperature control, Molds note: cited By 9; Conference of 3rd National Postgraduate Conference - Energy and Sustainability: Exploring the Innovative Minds, NPC 2011 ; Conference Date: 19 September 2011 Through 20 September 2011; Conference Code:88531 abstract: The purpose of this paper is to present a technique of fabricating Profiled Conformal Cooling Channels (PCCC) in an Aluminum filled epoxy mould using Rapid Prototyping (RP) and Rapid Tooling (RT) techniques. The cooling channels in injection mould tools have a circular cross section. In a PCCC, the cross sectional shape is so designed that the flat face surface of the channel facing the cavity follows the profile of the cavity. These types of channels can be manufactured through RP techniques. A part to be moulded was designed and modeled. Two moulds were then designed with the part cavity, one having a circular channel and the second with a profiled channel, both having the same cross sectional area for coolant flow. The channel patterns were designed with supports according to their position regarding height and distance from the cavity as designed earlier. Both channels have the same distance from the cavity wall. RP patterns were produced for both channels and part using the Thermojet 3D printer. The cooling channel and the moulded part were then assembled as designed in the moulds. Moulding frames were fabricated with aluminium plates and the pattern was placed in the frames. Epoxy was poured on the pattern and then cured. The moulded part and the channel patterns embedded inside epoxy were melted out during the final curing cycle, leaving behind the circular-and profiled-cooling channels in the moulds. The RT fabrication technique adopted in the current work was to make the profiled channels which cannot be fabricated through conventional manufacturing methods. © 2011 IEEE. date: 2011 official_url: https://www.scopus.com/inward/record.uri?eid=2-s2.0-84857098503&doi=10.1109%2fNatPC.2011.6136406&partnerID=40&md5=bb430e4ae7150738183c917dcaada15a id_number: 10.1109/NatPC.2011.6136406 full_text_status: none publication: 2011 National Postgraduate Conference - Energy and Sustainability: Exploring the Innovative Minds, NPC 2011 place_of_pub: Perak refereed: TRUE isbn: 9781457718847 citation: Altaf, K. and Rani, A.M.A. and Raghavan, V.R. (2011) Fabrication of circular and Profiled Conformal Cooling Channels in aluminum filled epoxy injection mould tools. In: UNSPECIFIED.