Injection moulding of natural reinforced plastics

Similar documents
Biocomposites Properties and Applications

Bio-based lightweight packaging materials

A NEW GENERATION OF FLAME RETARDED POLYAMIDES BASED ON PHOSPHINATES

COMPARISON BETWEEN GLASS AND FLAX NON-CRIMP STITCHED FABRICS

Research Article. Chemical treatment on hemp/polymer composites

The Effect of Fiber Twist on the Mechanical Properties of Natural Fiber Reinforced Composites

NATURAL FIBERS PLASTIC COMPOSITES FOR AUTOMOTIVE APPLICATIONS

Composites and light weight metals - the best of two worlds

About OMICS Group Conferences

EOSINT P and FORMIGA P materials for plastic laser-sintering systems

Materials selection for natural fiber reinforced polymer composites using analytical hierarchy process

Market data on Industrial Hemp fibres, shivs and seeds

Status quo of stress simulation for hot and warm work piece temperatures in forging

The Fundamental Principles of Composite Material Stiffness Predictions. David Richardson

Weathering Performance of Plant-Fiber/ Thermoplastic Composites

Elastic Properties of Polymer Melts Filled with Nanoparticles

The Advantages of Flax Fibers in Composites June 2009, Frankfurt. Medical Industrial Automotive Filtration Apparel June 2009 Page 1

SD-0150 GENERAL PURPOSE ABS (Acrylonitrile Butadiene Styrene) (TA)

Worldwide tank building applications using PP-Sheets: The effect of Foaming on properties

Carbon Fiber Composites Low Cost Materials & Manufacturing Options

CHARACTERIZATION OF HIGH PRESSURE RTM PROCESSES FOR MANUFACTURING OF HIGH PERFORMANCE COMPOSITES

TWOBEARS. Technical Information biofila silk & linen. By: Benno Besler & Eva Besler from: 7. November 2014 Version: 2

EXTRUDER FEEDING SYSTEMS

Lecture 3: Biodegradable Polymers

COATINGS FOR INCREASING AND PRESERVING THE BENDING STRENGTH OF GLASS

Composite Design Fundamentals. David Richardson

TWIN-SCREW COROTATING EXTRUDER A FLEXIBLE SOLUTION FOR ADVANCED RECYCLING

Comparative Study of Physical And Elastic Properties of Jute And Glass Fiber Reinforced LDPE Composites

HW 10. = 3.3 GPa (483,000 psi)

Foam Injection Molding:

Plastics and Polymer Business. Properties enhancement for Plastics

How To Improve Mechanical Properties Of A Composite Material

Influence of material data on injection moulding simulation Application examples Ass.Prof. Dr. Thomas Lucyshyn

100 Year Service Life of Polypropylene And Polyethylene Gravity Sewer Pipes. Summary Technical Report

EUROLAB 25 years. The role of metrology and testing to characterize materials and products. EUROLAB 25th Anniversary Seminar

Composites in Automotive : Great hope for the car of the future and enormous challenges to face. Yannick AMOSSE March 31, 2015

T he production of high-quality injection. Useful Process Data from the Injection Molding Machine

Thermoplastic composites

PP MASTERTM S T I F F N E S S S N 1 2 R I N G THE NEW POLYPROPYLENE SEWER PIPE SYSTEM

Commingled CF/PEEK Hybrid Yarns for Use in Textile Reinforced High Performance Rotors

EXTERIOR LONG GLASS FIBER POLYPROPYLENE SYSTEM FOR AUTOMOTIVE APPLICATIONS. Abstract

AS B E S T O S C O N V E R S I O N P R O C E S S ( AC P )

DEUTSCHE NORM June Plastics Determination of flexural properties (ISO 178 : 2001) English version of DIN EN ISO 178

COMPOSITE MATERIALS. Asst. Prof. Dr. Ayşe KALEMTAŞ

Railway Sleepers from Mixed Plastic Waste- Railwaste Project Status Information as of Oct, 2010

Because sustainability matters

Nylon 612: Viable Alternative Tubing Constructions in Fuel Systems

EVALUATION OF MECHANICAL PROPERTIES OF BIODEGRADABLE PACKAGING MATERIALS

joining expertise at the service of the plastic converting industry

List of Supplements to the compliance and licence Agreement

Novel biobased thermoplastic foams

Ecological benefits of hemp and flax cultivation and products. 1. Background. 2. Effects on soil and crop rotations. 3.

Recycling of plastic composites as basis for a competitive advantage h - GenVind Consortium

Factsheet. UP Resins

If safety and environmental compatibility is precious to you EXOLIT FLAME RETARDANTS FOR THERMOPLASTICS

Engineering Plastics Technical Presentation

DIRECT FIBER FEEDING INJECTION MOLDING OF CARBON FIBER REINFORCED POLYCARBONATE COMPOSITES. Abstract. Introduction

Man-made natural fibers and their composites. Man-made? Natural? Man-made natural fibers!

ICS: Strengthening retrofitting of reinforced concrete structures by gluing of fibre reinforced polymeric fabrics (FRP fabrics)

Biodegradable polymers and plastics. Andrej Kržan

Wire and Cable Product Guide

PROPERTIES OF SPRAYED CONCRETE WITH RECYCLED TYRE POLYMER FIBRES

Jetfine talcs for high performance polypropylene and engineering thermoplastics

Biomass-to an overview

The influence of annealing on dynamical mechanical properties of polyamide 6 / fiber glass composites

External Wrapping of Steel Riser Pipe. Case Study HJ3 CS200902

polymer additive General Overview

Biopolymers: overview of several properties and consequences on their applications

Broad Base. Best Solutions. SIGRAFIL Continuous Carbon Fiber Tow

Nano Crystalline Cellulose: A Canadian Adventure

The Potential of Flax Fibres as Reinforcement for Composite Materials

INVESTIGATIONS ON WOOD-PLASTIC COMPOSITE MACHINABILITY DURING DRILLING

The EJOT. Fastener. Predictable performance improvement for thermoplastics. EJOT The Quality Connection

Carbon Fibre in Mass Automotive Applications Challenges and Drivers for composites

Injection molding equipment

Investigating Methods of Prototyping with ABS

Composite Materials. Mary P. Shafer. Fabric Development, Inc. Quakertown, PA 18951

GESTCO final report. Work Package 2, Study area F: Storage in deep coal beds : Germany

Form-flexible Handling Technology (FormHand) for Automation in RTM preforming

CLASSIFICATION OF FIBRES

Understanding Plastics Engineering Calculations

METU DEPARTMENT OF METALLURGICAL AND MATERIALS ENGINEERING

Product Data. HexPly 8552 Epoxy matrix (180 C/356 F curing matrix)

The Original Carbon Fiber Reinforced Polymer System

Science and Technology of Polymers Prof. Basudam Adhikari Department of Materials Science Centre Indian Institute of Technology, Kharagpur

4.461: Building Technology 1 CONSTRUCTION AND MATERIALS FALL TERM 2004 SCHOOL OF ARCHITECTURE AND PLANNING: MIT

Compression RTM - A new process for manufacturing high volume continuous fiber reinforced composites

Notes on Polymer Rheology Outline

Standard Specification for Polyethylene Plastics Molding and Extrusion Materials 1

April Report Prepared By: Phil Brindley, Dr Ruth Goodridge, Mark East & Prof Richard Hague Loughborough University, Loughborough, UK

Transcription:

Injection moulding of natural reinforced plastics Dipl.-Ing. Dipl.-Wirtsch.-Ing Andreas Marek; Prof. Dr. Hartmut Widdecke Institut für Recycling; Robert-Koch-Platz 8a; 3844 Wolfsburg ABSTRACT Typical fibres used in reinforced plastics are glass- and carbon-firbres. Recently natural fibres have found more and more interest. In this study completely biodegradable reinforced plastics were obtained by injection moulding. KEYWORDS: natural fibres; reinforced plastics; injection moulding; biodegradable plastics 1 BIODEGRADABLE PLASTICS AS MATRIX SYSTEMS Biodegradable polymers (Schroeder 1998) which can be used as matrix systems for reinforced plastics are either starch (e.g. blends) and cellulose (e.g. cellulose acetate) or polyesters (e.g. polylactide). A detailed study of the different properties of these materials was recently carried out in our laboratories (Raschke, 2). An example is given in table 1. The cellulose derivate and the natural polyester show similar properties as polystyrene. To improve the mechanical properties different additives or natural fibres can be used. Table 1: Mechanical properties of different plastics polystyrene polylactide cellulose acetate density [g/cm³] 1,5 1,26 1,27 breaking t [N/mm²] tensile-e-modulus [N/mm²] impact [kj/m²] 6 59,25 34,5 32 3461 178 2 1,5 4 1

2 NATURAL FIBRES Natural fibres from plants can be divided into four groups: Bast fibre (flax, jute, hemp) Leaf fibre (sisal, palmfibre) Seed fibre (cotton, capoc) Fruit fibre (cocos, pineapple) All of them are biodegradable but also other advantages in comparison with glass or carbon fibre can be listed: Lower density (e.g. sisal: 1,2 g/cm3, glass: 2,5 g/cm3): This is important for the construction of low-weight components. Minor abrasion: That means less stress for the tools. Higher elasticity than glass fibres: The biocomposites do not splitt so heavyly, which may be important for applications in the interior of cars (Hanselka 1997). No support of hothouse effect: CO 2 -recycling However there may exist also some disadvantages. Fibre quality and availability could be a problem. Table 2: Mechanical properties of plant and glass fibres [Höck 1994, Gassan 1997, Hanselka 1998; Niederstad 1997] density [g/cm³] tensile [N/mm²] spec. tensile [kn/mm² x cm³/g] E-modulus [GPa] elongation [%] jute 1,4 187 457,13, 33 14 39 1,6 3,1 ramie 1,5 85 9,57,6-2,4 hemp 1,5 195-58,13,37 12 3 4 flax 1,4 1,5 254 39,17,28 12 26 1,3 2,8 sisal 1,2 57 835,42,7 16 37 2 3 glass 2,6 1748,67 72 2,1 The natural fibres show different mechanical properties (tab. 2). Especially interesting is the specific tensile demonstrating that natural fibres may be used alternatively in comparison to glass fibres. 2

3 COMPOSITES The development of biocomposites started in the 8s. Duromeric and thermoplastic material are used (e.g. Keller 1999), but in case of the injection moulding process of biocomposites only very few studies are available. Therefore the influence of natural fibre on the properties on biodegradable plastics was investigated. Sisal fibre was used because of low density and a high specific tensile. Also it is commercially available and easy to handle. For the matrix material cellulose acetat was chosen. The composites were generated in two different ways. First in cooperation with the MIT Mischtechnik GmbH, Detmold the matrix and the fibre were mixed into a heating-cooling system to get agglomerate, which was hackled in a granulator. At the end the granulate was used for injection moulding. Samples of the new composite were characterised. In another process both materials were mixed in a twinscrewextruder folloed by a granulation process. Then the injection moulding process was repeated to determine the properties. Figure 1: Mechanical properties of sisal reinforced cellulose acetate (mixer) 3 25 2 [%] 15 1 5 tensile tensile E- modulus flexural flexural E- Modulus % fibres 1 % fibres 2 % fibres Figure 1 shows the mechanical properties of the reinforced plastic which was produced in the heating-cooling mixer. The impact, the tensile and flexural E-modulus was improved by the use of fibres. In a second project we used a twinscrewextruder and a gravimetric dosage unit. We investigated biocompostits with 1 up to 4 % of fibres. Figure 2 shows the mechanical properties of these composits. 3

Figure 2: Mechanical properties of sisal reinforced cellulose acetate (extruder) 3 25 2 [%] 15 1 5 tensile tensile E- modulus flexural flexural E- Modulus % fibre 1 % fibres 2 % fibres Similar results were obtained using this process. Only the tensile of the extruder material is higher than the tensile of the mixer material, although the fibres became shorter during the extrusion process. This effect could be minimized with another screw configuration. These results are confirmed in by investigation of sisal reinforced polypropylene. Figure 3 shows the tensile-e-modulus of reinforced polypropylene. The tensile-e-modulus increased with increasing fibre content. 4

Figure 3: Tensile-E-modulus of sisal reinforced polypropylene tensile-e-modulus [MPa] 5 4 3 2 1 1 2 3 4 35 3 25 2 15 1 5 tensile-e-modulus [%] fibre [%] Tensile-E-Modulus [MPa] Tensile-E-Modulus [%] 4 SUMMARY The results show the potential of reinforced plastic for an injection moulding application. The continuous production by extrusion is an interesting alternative for the synthesis of biocomposites. The use of the mixer could be suggested for small charges. Natural fibres in comparison to classic fibres show similar mechanical properties. Fibres can also be used to minimize the cocts of biodegradble plastics. LIST OF REFERENCES Schroeter, J.: Biologisch abbaubare Werkstoffe. Kunststoffe 88 (1998) 7, S.1-14 Raschke, M.; Marek, A.; Otten, A.; Widdecke H.: Kunststoffe aus nachwachsenden Rohstoffen Ein Vergleich; Tagungsband Narossa 2 6. Int. Fachkongress für nachwachsende Rohstoffe; 5.-6. Juni 2 Hanselka, H. Naturfassern verstärken die Werkstoffe kommender Produktgenerationen, Industrieanzeiger 1/2,1997, S28ff Höck, P. Verstärkung von Polypropylen durch Flachsfasern auf Gleichdralldoppelschneckenextrudern, Dissertation an der RWTH Aachen, 1994 Gassan, J. Naturfaserverstärkte Kunststoffe Korrelation zwischen Struktur und Eigenschaften der Fasern und deren Composites, Dissertation an der GH Kassel, 1997 5

Hanselka, H. Faserverbundwerkstoffe aus nachwachsenden Rohstoffen für den ökologischen Leichtbau, Materialwissenschaft und Werkstofftechnik 29, Willey-VCH Verlag, 1998, S.3-311 Niederstad, G., Hanselka, H., u.a. Ökonomischer und ökologischer Leichtbau mit faserverstärkten Polymeren,, 2. Aufl., Expert Verlag, 1997, S. 21-225 Keller, A. et al.: Bastfaserverstärkte, biologisch abbaubare Polyester- Einfluss der Faserverfeinerung durch Dampfaufschluss: 2nd International Wood and Natural Fibre Composites Symposium, Kassel 1999 The authors are thankful to the Ministry for Science and Culture of Lower Saxony (MWK) / Arbeitsgruppe Innovative Projekte (AGIP) for financial support 6

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information