Biodegradable packaging materials based on low density polyethylene, starch and monoglycerides

Studies aimed at determining the features of printing on biocomposite polymer materials were carried out. It has been found that the untreated composite films have a low adhesion strength at the composite film-paint interface, the surface tension did not exceed 28 mN/m, and the contact wetting angle was greater than 80 degrees. When the surface is activated by the "corona" discharge method, the adhesion properties appear to a greater extent, and with an increase in the processing stress of the "corona" discharge, the adhesion strength also increases. Thus, in a 25 kV surface treatment, the surface tension for the test composites was estimated to be above 40 mN/m and the contact wetting angle was less than 45 degrees. For BHA based on LDPE and TPC of various bases (corn, pea, rice), adhesion strength was evaluated in the range from 2.9 to 3.5 N/cm2, for PCM based on LDPE and ORD - 29 N/cm2. The result of this work is an increase in surface tension due to the appearance of polar groups on the surface of composite films, in particular oxygen-containing C-O and C = O, as confirmed by Fourier IR spectroscopy. Although the adhesion strength at the film-paint interface is increased when the surface of the composite films is activated, it has been observed that for LDPE-based BHC and thermoplastic starch, the adhesion properties are not constant and decrease over time. After two weeks, adhesion strength was evaluated, on average, 1.4 N/cm2. Most likely, BHCs do not transition to the electret state when the surface is activated by "corona" discharge, and external factors such as temperature and humidity act, as a result of which the number of polar groups on the surface decreases. On the contrary, a slight decrease in adhesion strength from 29 to 27 N/cm2 was observed for PCM based on LDPE and OPD, which is due to the chemical nature of the starting components.

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Biocomposite materials based on polyethylene and amphiphilic polymer-iron metal complex

Vasilyev

2023

Fine Chem. Technol.

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Objectives. To obtain and study the properties including degradability of polymer composite materials (PCM) based on low-density polyethylene (LDPE) obtained by introducing an environmentally friendly additive comprising an oxo-decomposing additive (ODA) based on an amphiphilic polymer-iron metal complex, which accelerates the process of polymer degradation.Methods. PCMs based on LDPE and ODA were produced by processing in laboratory extruders in the form of strands, granules, and films. Thermodynamic properties were determined by differential scanning calorimetry in the temperature range 20-130 °C. In order to assess the performance characteristics (physical and mechanical properties) of the PCM, tensile strength and elongation at break were determined. The biodegradability of PCM was evaluated by Sturm's method, with the biodegradation index being determined by the amount of CO2 gas released as a result of microorganism activity, as well as composting by placing the PCMs for six months in biohumus. Changes in physical and mechanical properties and water absorption of the films during storage were evaluated. The photochemical degradability of the PCM was determined by exposing it to ultraviolet radiation for 100 h (equivalent to approximately one year of exposure of the films under natural conditions). The appearance of the composite samples following removal from the biohumus was determined using an optical microscope with ×50 magnification in transmitted and reflected light.Results. Following biodegradation by composting, the physical and mechanical properties of PCMs decrease by an average of 40.6%. This is related to the structural changes that occur in composites during storage in biohumus, i.e., the formation of a looser structure due to the development of large clusters of microorganisms that affect the formation of microcracks. It leads to the stage of fragmentation of the polyethylene matrix and indicates the progress of biological degradation of composites. In this case, the water absorption of the composite samples was 63% after 96 h of exposure. The biodegradability index determined by the Sturm method after 28 days of bubbling had changed by 82%, indicating an intensive biodegradation process. Exposure to ultraviolet radiation for 96 h resulted in the complete destruction of the PCMs, which turned into small “flakes.” This method is the most effective for the degradation of LDPE- and ODA-based PCMs.Conclusions. According to the results of the study of ODA-containing PCMs based on an amphiphilic polymer-iron metal complex, the tested filler-modifier can be recommended for the production of PCMs offering an accelerated degradation period.

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Biodegradable packaging materials based on low density polyethylene, starch and monoglycerides

Cited by 3 publications

References 19 publications

A Review on Biodegradable Composite Films Containing Organic Material as a Natural Filler

A Review on Biodegradable Composite Films Containing Organic Material as a Natural Filler

Investigation of surface properties of biocomposite materials modified by corona plasma treatment

Biocomposite materials based on polyethylene and amphiphilic polymer-iron metal complex

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