Driven by increasing environmental

Driven by increasing environmental awareness, natural filler has been emerging as a desirable reinforcement for composites [1–4]. This increased interest is the combination of several advantages of these fillers, such as: low cost, low density, non-toxicity, high specific properties, no abrasiveness during processing and recycling possibility. The use of natural fillers as reinforcement in composite materials allows to exploit a local resource in less industrialized countries and to develop materials and technologies taking into account the impacts of the environment [5,6]. The polymer composites and natural fillers are a low cost materials with minimal impact on the environment and a good mechanical properties which are obtained when a good adhesion at the interface polymer-fillers is yield and fillers are well dispersed into the matrix [7–9]. The effectiveness of composites material depends largely on their ability to transfer stress from the polymer matrix (continuous phase) to fillers (dispersed phase). It is well-known however that the hydrophilic characteristic of natural fillers creates difficulties in achieving a proper homogenization with the polymer chains [10]; as a result, a poor adhesion between fillers and polymer matrix. The processing of natural fillers and some additives used in the composite improve the filler–matrix compatibility, that includes grafting compatibilizer groups, addition of a coupling agent or cleaning the filler’s surface [11]. Chemical coupling techniques provide chemical bridge between the cellulosic fillers and the thermoplastic polymer, the use of maleic anhydride modified polypropylene (MAPP) as a coupling agent reduces the surface tension between fillers and matrix [12].
Various natural fillers such as Jute [3], Banana [5], Alfa [6], Graphene [13], Argan Nut-shell [14], have been tested as reinforcement in polymer composites. The mechanical properties of composites reinforced by particles depend strongly on the dispersion /distribution state, interfacial adhesion, morphology and particle loading [15]. Particle size has an obvious effect on the mechanical properties [14,16] Almonds are a very important crop throughout the world’s temperate regions [17]. Almond Shell accounts about
35–75% of the total fruit weight [18] consequently; around 0.8–1.7 million tons of Almond Shell is left annually [19]. Almond Shell is the ligno-cellulosic material forming the thick endocarp or husk
of the almond tree fruit that upon processing the fruit to obtain the edible seeds. Almond Shells are separated from the edible seeds and since they have no important industrial usages are normally incinerated or dumped [17]. Burning agricultural residues causes environmental problems such as air pollution, soil erosion and decreases soil biological activity [20]. The Almond Shell particle as new fillers reinforcement in thermoplastic matrix, was compound using a twin screw extruder in a polypropylene grafted with 8 wt.% of styrene–(ethylene–butene)–styrene three block copolymer grafted with maleic anhydride (SEBS-g-MA) as a compatibilizer, the maleic anhydride grafted SEBS is used with polypropylene as coupling agent due to its compatible structure with olefinic block [21], and with hydrophilic part of particules. The various concentration of particles (from 5 to 30 wt.%) have been tested, the properties of this composite were compared to the composite without compatibilizer. The effects of coupling agent and particles loading on the thermal, tensile and rheological properties of composites are investigated. The basis for the selection of the polypropylene
matrix: (i) the low cost compared to other resins (resins amorphous PS, PMMA) (ii) the PP matrix as polyolefin polymer is used in many industrial applications, (iii) contrary to the studies in the literature that have used thermosetting matrix (epoxy), (iv) the relatively low processing temperature (200–220 _C) avoids the degradation of Almond Shell compounds, especially the cellulose. In addition, the experimental techniques and characterization approach used in this study are the originality of this work. The particles have been used without any extraction methods like that
needed for the cellulose and chitosan.