Kati Mustonen scite author profile

The cost-efficient reutilization of byproduct materials is a significant global goal, contributing towards the sustainable use of resources. In this study, the effects of including primary sludge in composite materials on their physical performance are examined, in order to achieve more effective reuse. The studied materials were made from high-density polyethylene (HDPE), anhydride-grafted polyethylene (MAPE), lubricants, and either wood flour from spruce (Picea abies) or primary sludge from the side-stream of forest industry processes as a filler. The materials were compounded by agglomeration, followed by manufacturing with a conical twin-screw extruder. The physical properties of the materials were characterized by water absorption and thickness swelling tests; furthermore, impact strength was characterized after the stress of a cyclic freeze-thawing test. The elemental compositions of the materials were also analyzed by scanning electron microscopy coupled with energy-dispersive X-ray spectroscopy (SEM-EDS). Primary sludge, as a component in the structure of the composite material, resulted in a significant improvement of moisture behaviors in the water absorption and thickness swelling tests. The identified results demonstrate that primary sludge is a technically applicable material for utilization in composite materials.

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Nitrogen behaviour during thermal drying of mechanically dewatered biosludge from pulp and paper industry

Mustonen

Deviatkin

Havukainen

et al. 2017

Environmental Technology

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An ongoing call to implement a circular economy is underway in the European Union, and a specific attention has been placed on the forest industry, which seeks additional recycling routes for its side streams, including biosludge. Biosludge is often dried and incinerated, thus wasting the nitrogen contained therein. This paper describes a study in which the release of nitrogen during thermal drying, the impact of the drying temperatures of 130°C, 180°C, and 210°C on the mass of ammonia released, and the potential for recovery of nitrogen from biosludge were examined. The results indicate that 1310-1730 mg kgTS of nitrogen was released, which corresponded to 56-74% of the soluble nitrogen in biosolids or 4.0-5.3% of the total nitrogen. Of this released nitrogen, 83-85% was identified in condensate and absorbing water, thus indicating a high potential for recovering nitrogen from biosludge.

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Implications of Pulp and Paper Mill Primary Sludge Incineration versus Use in Composites Production: Decision-Making Based on Life Cycle Assessment

Mustonen¹,

Deviatkin²,

Horttanainen³

et al. 2020

J ENVIRON INFORM LET

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Kati Mustonen

The effect of primary sludge on the mechanical performance of high-density polyethylene composites

The Impact of Primary Sludge on the Physical Features of High-Density Polyethylene (HDPE) Composites

Nitrogen behaviour during thermal drying of mechanically dewatered biosludge from pulp and paper industry

Implications of Pulp and Paper Mill Primary Sludge Incineration versus Use in Composites Production: Decision-Making Based on Life Cycle Assessment

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