Paper to the Polymer Processing Society European Meeting, Strasbourg, 29th-31st August, paper 5-3.
S F Bush
Introduction
To view the introduction, please click on the link: ModellingLace
Modelling Fibre Lace Structures in Shaped Flow Fields
Relationship of Impact Strength, Tensile Strength and the Fiber-Matrix Interface in varieties of Polypropylene Long-Glass Fiber Injection Moldings
Paper (6-2-8) to the 10th International Annual Meeting of the Polymer Processing Society, Akron, USA, 5th-8th April 1994.
S F Bush with D R Blackburn, O K Ademosu, F B Yilmaz and P F Zhang
Introduction
Earlier papers(1, 2, 3, 4) have described the factors affecting fiber-matrix cntacting, the organization of long fibers into coherent lace-like or mat-like structures, and the dependence of tensile strength on these two classes of variable. Equations for the mean number of touches1 in the fiber structure and tensile strength2 have been proposed which allow for the main variables present in moldings and extrusions, including differing matrix properties. Fiber management technology developed under the generic acronym SAFIRE4 (Self Assembling Fiber Reinforcement) has recently been applied commercially to practical moldings such as hard hats and pallets, in both of which examples impact strength is a key property.
Accordingly, a wide series of experiments has been carried out using the Izod method to determine the variation of impact strength as a function of the fiber length, fiber concentration, the fiber-matrix interface, fiber reinforcement structure and matrix properties. Both commercially available long-fiber granules and laboratory-compounded types have been used with different mold configurations and molding conditions for a variety of polypropylene and polyethylene matrices.
References
[1] S F Bush, Control of Fiber Structures in Melt Extrusion, 36 Ann Mtg Can Soc Chem Eng, Sarnia, Canada (1986) paper 32d.
[2] S F Bush, O K Ademosu, D R Blackburn, F B Yilmaz, Factors Affecting the Strength of Long-Fibre Reinforced Injection Moldings, Poly Proc Soc Eur Mtg, Prague (1992) paper 6-06.
[3] D R Blackburn and O K Ademosu, Factors Affecting Fiber-Matrix Contacting in Fiber-filled Granules, Poly Proc Soc, 9th Ann Mtg, Manchester 1993, Paper 6-14.
[4] S F Bush, Self Assembling Fibre Reinforcement (SAFIRE) processes, “Textile-reinforced Composites for Engineering”, Bolton Institute, Bolton, England, 12-14 January, 1994.
Impact strengths of injection moulded polypropylene long-glass-fibre composites
Paper (5) to the Institute of Materials 6th International Conference on Fibre Reinforced Composites, Newcastle, England, 29-31 March 1994.
Published in Plastics, Rubber and Composites Processing and Applications, Vol 24, No 3 (1995).
S F Bush with F B Yilmaz and P F Zhang
Abstract
A wide series of experiments has been undertaken to measure impact strength as a function of fibre length and concentration, the fibre/matrix interface, and induced fibre-mat structure and matrix properties. Both commercially-available long-fibre polypropylene granules and in-house polypropylene and polyethylene glass-fibre compounds have been used where the interface conditions are known and can be varied. For the fibre-mat structures achieved, notched impact strengths rise with fibre lengths and with fibre concentration, giving in all cases an improvement on the virgin polypropylenes – for some conditions a five-fold improvement at 25% w/w concentration.
Comparison of Long-fibre Granule Compositions in Polypropylene Injection Moulding
Paper to the Polymer Processing Society 9th Annual Meeting, UMIST, 5th-8th April 1993, 02-35.
F B Yilmaz with S F Bush
Introduction
There are a number of different techniques for the production of long glass-fibre reinforced polypropylene (LGFRPP) granules for injection moulding. Dispersion and wetting of glass-fibre in the granule will be different according to the type of polypropylene grade and the compounding methods. Most of the materials used in this study were produced by the melt coating method and contain two bundles of filaments. The granules which are used in this study are given in Table 1.
| Granule Code | Wetting of fibre | Fibre content by weight | Fibre diameter (mm) | Initial Fibre length (mm) |
|---|---|---|---|---|
| FIBERFIL/G60/20/E* | Good | 20 | 17×10-3 | 12 |
| FIBERFIL/G60/10 | Poor | 10 | 10×10-3 | 6.35 |
| SAFIRE/NCA | Average | 17 | 17×10-3 | 8 |
| SAFIRE/CA* | Good | 17 | 17×10-3 | 8 |
| CELSTRAN/PPG40* | Good | 40 | 17×10-3 | 9 |
| SAFIRE/55S* | Good | 25 | 17×10-3 | 10 |
* They have coupling agent.
Injection moulding is a two-step operation which involves first the plasticization of solid materials in a screw extrusion unit, followed by the high pressure pumping of molten material into a mould cavity. Most fibre breakage occurs in the screw extrusion unit with injection moulding of fully dispersed LGFRPP granules[1]. There is in fact an advantage in using melt coated granules. When glass-fibre bundles are travelling in the screw unit, they protect each other against severe fibre breakage. On the other hand to disperse the fibre bundles a separator is necessary. In tis study a proprietary dispersion device was used between the mould and the screw unit.
References
[1] R S Bailey and H Kraft, Int. Polymer Process. 22, p94-101 (1987)
[2] S F Bush, O K Ademosu, D R Blackburn, F B Yilmaz, “Factors Affecting the Strength of Long-fibre Reinforced Injection Moldings”, Polymer Processing Society 1992 European Meeting, Prague, 21-24 September, paper 06-06.