φ40×25蓋塞注塑模具設(shè)計(jì)
φ40×25蓋塞注塑模具設(shè)計(jì),φ40×,25蓋塞注塑模具設(shè)計(jì),40,25,注塑,模具設(shè)計(jì)
Optimization of Gate, Runner and Sprue in Two-Plate Family Plastic Injection Mould M.A. Amran * , M. Hadzley, S. Amri, R. Izamshah, A. Hassan, S. Samsi, and K. Shahir 1 Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia (UTeM), Locked Bag 1200, Hang Tuah Jaya, Ayer Keroh, Melaka, Malaysia *Email: mohdamranutem.edu.my Abstract. This paper describes the optimization size of gate, runner and sprue in two-plate family plastic injection mould. An Electronic Cash Register (ECR) plastic product was used in this study, which there are three components in electronic cast register plastic product consist of top casing, bottom casing and paper holder. The objectives of this paper are to find out the optimum size of gate, runner and sprue, to locate the optimum layout of cavities and to recognize the defect problems due to the wrong size of gate, runner and sprue. Three types of software were used in this study, which Unigraphics software as CAD tool was used to design 3D modeling, Rhinoceros software as post processing tool was used to design gate, runner and sprue and Moldex software as simulation tool was used to analyze the plastic flow. As result, some modifications were made on size of feeding system and location of cavity to eliminate the short- shot, over filling and welding line problems in two-plate family plastic injection mould. Keywords: Computer Modeling; Flow Simulation; Optimization PACS: 07.05Tp 1. INTRODUCTION The plastic injection generally has three phase processes comprising filling, packing and cooling phases. The introduction of simulation software has made a significant impact in the mould making industry with the increasing use of computers in design engineering, the amount of commercially available software on the market has also increased 1. The ECR plastic product uses same material and colour, however different size of part. Each part has it own mould but on this research, all the parts used family mould. The difficult stage to design family mould is to decide the mould layout, injection location, size of gate, runner, sprue and location of water holes 2, 6, 7. To investigate the flow behaviour the Moldex software as simulation software was used to analyze the plastic flow. 2. METHODOLOGY This study started from design 3D modeling of ECR product using Unigraphic software and then the files were transferred into Rhinoceros software for post processing. In Rhinoceros software the feeding system such as gates, runners, sprues, 309 waterholes and mould base were designed. Finally, Moldex software is used by importing file from Rhinoceros software. Plastic materials, processing conditions were decided before filling, packing, cooling and warpage analysis. If results do not satisfy, the modification will be done again as shown in Figure 1. End Interperet data A is surface area of cavity (mm 2 ) and n is material constant. From calculation surface area of top casing is 84,648 mm 2 , the width is 5.8 mm. Further calculation, bottom casing width is 5.9 mm and paper holder is 1.27 mm. 3.2 Circular Runner Diameter runner was calculated by taking the weight of part from volume multiply density and distance part from centre of mould as equation 2 4. D = W x L / 30 (2) Where, D is runner diameter, W is part weight and L is distance part to centre mould. Volume of top casing was taken from Rhinoceros software is 78,202 mm 3 and the weight is 0.08 kg so the diameter of runner is 6.5 mm. Further calculation, the diameter of bottom casing is 6.7 mm and paper holder is 1.5 mm. 3.3 Sprue The sprue size was decided by taking the thickness cavity plate mouldbase and given angle one degree from diameter 7 mm. Initial cold slug well is 7 mm and base cold slug well is 10 mm. Figure 3 shows the location of top casing, bottom casing and paper holder together with feeding system. FIGURE 3. Layout of two-plate mould. 311 4. FILLING ANALYSIS OF TWO PLATE MOULD Result from filling analysis shows that the total filling period is 1.041 seconds. At the stage, 100% there were two results where the top casing was short shot and the plastic cannot flow to the impression of paper holder as shown in Figure 4. FIGURE 4. Filling process The top casing was redesigned because of the meeting area of flow front situated at side body, as result a welding line was developed on that area as shown in Figure 5. Welding line is the result of a flow front, which easily breaks up into two separate parts. When the two fronts meet, they try to welding back together again so as result form a single front line which it can be easily broken down 5. FIGURE 5. Welding line at top casing 4.1 Modification on Two-Plate Mould Modification was done on gate of bottom casing by decreasing 25% from 5.9 mm to 4.3 mm and runner from 6.7 mm to 5 mm due to over filling. Location of paper holder was moved from 50 mm from center of mould to 25 mm and increase runner size by 25%. A set of groove was added on surface of top casing to ensure the plastic flow toward corner of top casing as shown in Figure 6. FIGURE 6. Modification of Two-Plate mould. 312 4.2 Filling process after Modification Result from filling analysis after modification shows the melt of plastic of three components were balance on each other. The total filling melt front time is 7.804x10 -1 seconds. The welding line has been eliminated on the centre side body of top casing and as result melt plastic flows towards on the corner as shown in Figure 7. FIGURE 7. Filling process after modification 5. DISCUSSION The size of runner of paper holder was increased and shifted to eliminate the unfilling. Gate and runner of bottom casing were decreased due to the over filling. Top casing was redesigned by adding a set of groove on the top surface of top casing to eliminate the welding line. As the result the welding line on centre side body of top casing was eliminated. From results it was found that the size of gate and runner in two-plate mould for paper holder increased by 25% due to the short shot problem and gate and runner for bottom casing reduced by 25% due to the over filling. 6. CONCLUSION This study was success on analyzing the flow of plastic materials in two-plate mould. The modifications was done on layout of cavities and feeding system as result improved the quality of the product. Furthermore, the defects of plastic product on short shot, over filling and welding line were eliminated before the actual mould is fabricated. REFERENCES 1. S.S.S. Imehezri., S.M. Sapuan, S. Sulaiman, Journal Material and Design, volume 26, pp. 157 166, 2005. 2. L.T. Manzione, Applications of Computer Aided Engineering in Injection Molding, Hanser, New York, 1987. 3. R.G.W. Pye, Injection Moulding Design, Longman Scientific & Technical, New York, 1989. 4. G. Monges & P. Mohren, How to Make Injection Molds, Hanser Publishers, New York, 1993. 5. M.B. Douglas, Plastics Injection Moulding- Manufacturing Process Fundamentals. Society of Manufacturing Engineer, Michigan, 1996. 6. C.T. Wong, S. Sulaiman , N. Ismail, A.M.S. Hamouda, Procedings of Second World Engineering Congress, Sarawak, Malaysia,. pp. 193-198, 2002. 7. M. Khairol, Master Thesis, Universiti Putra Malaysia, 2001. 313 Copyright of AIP Conference Proceedings is the property of American Institute of Physics and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holders express written permission. 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