Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction
Polymer injection moulds are generally manufactured with tool steels which give reliable functioning of moulds with long service life. Manufacturing of injection moulds in steel is a lengthy process due to the strength and hardness. If the injection mould is required quickly for a short prototype or...
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2014
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my.utp.eprints.316942022-03-29T03:30:42Z Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction Altaf, K. Rani, A.M.A. Polymer injection moulds are generally manufactured with tool steels which give reliable functioning of moulds with long service life. Manufacturing of injection moulds in steel is a lengthy process due to the strength and hardness. If the injection mould is required quickly for a short prototype or production run, one of the good choices is to use Aluminum filled epoxy material, which can give a mould in a very short time using Rapid Tooling (RT) techniques, as compared to a machined tool. Aluminum-filled epoxy tools work best for relatively simple shapes. The benefits of fabricating injection moulds with epoxy resins includes time saving, ability to set at room temperature and ease of machining. But a major drawback of epoxy material is that the cooling time for epoxy injection moulds are still relatively long due to the poor thermal conductivity of epoxy. This paper reports investigation of an innovative idea for enhancing the thermal conductivity for epoxy moulds. The basic concept behind the idea was to embed high thermal conductive metal insert within the mould between the cavity and the cooling channel. This technique will increase the effective thermal conductivity of the epoxy mould, leading to reduction in cooling time for the injection moulded polymer part. By substituting part of the epoxy with low-cost aluminum, a cost advantage is also to be derived, besides increased mould strength. Experimental analysis done in the current study also verified that mould with embedded metal insert has considerable shorter cooling time. © Copyright 2014 by Research Publishing Services. Pro-AM 2014 Conference or Workshop Item NonPeerReviewed https://www.scopus.com/inward/record.uri?eid=2-s2.0-85027399397&doi=10.3850%2f978-981-09-0446-3_008&partnerID=40&md5=ffc03fac9503c4aa3f6d329ee7c120fa Altaf, K. and Rani, A.M.A. (2014) Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction. In: UNSPECIFIED. http://eprints.utp.edu.my/31694/ |
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Polymer injection moulds are generally manufactured with tool steels which give reliable functioning of moulds with long service life. Manufacturing of injection moulds in steel is a lengthy process due to the strength and hardness. If the injection mould is required quickly for a short prototype or production run, one of the good choices is to use Aluminum filled epoxy material, which can give a mould in a very short time using Rapid Tooling (RT) techniques, as compared to a machined tool. Aluminum-filled epoxy tools work best for relatively simple shapes. The benefits of fabricating injection moulds with epoxy resins includes time saving, ability to set at room temperature and ease of machining. But a major drawback of epoxy material is that the cooling time for epoxy injection moulds are still relatively long due to the poor thermal conductivity of epoxy. This paper reports investigation of an innovative idea for enhancing the thermal conductivity for epoxy moulds. The basic concept behind the idea was to embed high thermal conductive metal insert within the mould between the cavity and the cooling channel. This technique will increase the effective thermal conductivity of the epoxy mould, leading to reduction in cooling time for the injection moulded polymer part. By substituting part of the epoxy with low-cost aluminum, a cost advantage is also to be derived, besides increased mould strength. Experimental analysis done in the current study also verified that mould with embedded metal insert has considerable shorter cooling time. © Copyright 2014 by Research Publishing Services. |
| format |
Conference or Workshop Item |
| author |
Altaf, K. Rani, A.M.A. |
| spellingShingle |
Altaf, K. Rani, A.M.A. Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction |
| author_facet |
Altaf, K. Rani, A.M.A. |
| author_sort |
Altaf, K. |
| title |
Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction |
| title_short |
Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction |
| title_full |
Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction |
| title_fullStr |
Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction |
| title_full_unstemmed |
Thermal conductivity augmentation of epoxy injection moulds for cooling time reduction |
| title_sort |
thermal conductivity augmentation of epoxy injection moulds for cooling time reduction |
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Pro-AM |
| publishDate |
2014 |
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https://www.scopus.com/inward/record.uri?eid=2-s2.0-85027399397&doi=10.3850%2f978-981-09-0446-3_008&partnerID=40&md5=ffc03fac9503c4aa3f6d329ee7c120fa http://eprints.utp.edu.my/31694/ |
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13.214268 |