Waste tire textile fiber (WTTF), a secondary product from the processing of end-of-life tires, is predominantly disposed of through incineration or landfilling-both of which present significant environmental hazards. The incineration process emits large quantities of greenhouse gases (GHGs) as well as harmful substances such as dioxins and heavy metals, exacerbating air pollution and contributing to climate change. Conversely, landfilling WTTF results in long-term environmental degradation, as the synthetic fibers are non-biodegradable and can leach pollutants into the surrounding soil and water systems. These detrimental impacts emphasize the pressing need for environmentally sustainable disposal and reuse strategies. We found that 80% of WTTF was used for the production of thermal insulation mats. The other part, i.e., 20% of the raw material, used for the twining, stabilization, and improvement of the properties of the mats, consisted of recycled polyester fiber (RPES), bicomponent polyester fiber (BiPES), and hollow polyester fiber (HPES). The research shows that 80% of WTTF produces a stable filament for sustainable thermal insulating mat formation. The studies on sustainable thermal insulating mats show that the thermal conductivity of the product varies from 0.0412 W/(m center dot K) to 0.0338 W/(m center dot K). The tensile strength measured parallel to the direction of formation ranges from 5.60 kPa to 13.8 kPa, and, perpendicular to the direction of formation, it ranges from 7.0 kPa to 23 kPa. In addition, the fibers, as well as the finished product, were characterized by low water absorption values, which, depending on the composition, ranged from 1.5% to 4.3%. This research is practically significant because it demonstrates that WTTF can be used to produce insulating materials using non-woven technology. The obtained thermal conductivity values are comparable to those of conventional insulating materials, and the measured mechanical properties meet the requirements for insulating mats.

In recent years, there has been an increasing interest in soil additives used in environmental ecosystems. Currently, most soil amendments are produced from synthetic materials. Some synthetic amendments break down into microplastics, which persist in the environment and can be ingested by soil organisms, affecting soil health and biodiversity and the chemicals they contain can leach into groundwater. At the same time, the number and availability of biodegradable technologies are limited, and the aspects related to their biodegradation in soil are not sufficiently known. The study developed a sustainable water-saving and vegetationsupporting technology in the form of a biodegradable water-absorbing geocomposite (BioWAG). BioWAGs were produced using biodegradable materials derived from animal and plant waste, such as waste wool, jute, and linen. In a three-year field experiment, their physicochemical properties in the soil were analysed. These were characterized using a.o. Surface weight, scanning electron microscopy (SEM), and FTIR. The results indicate that the degree of biodegradation of materials used in BioWAG depended on the raw material and production technology. Needle-punched nonwovens underwent intensive biodegradation just 6 months after being buried in the soil, while stitched nonwovens retained their mechanical properties even for three growing seasons. In the case of seamed non-woven fabrics, a decrease in selected physical parameters was observed. The addition of wool-based soil additive, a decrease in surface mass was observed by 85% after 6 months, 88% after 18 months and 90% after 30 months. Regardless of the waste materials used, BioWAGs provided plants with continuous access to water and nutrients. The work indicates a sustainable method of managing textile waste and analyzes its properties in the soil, which enables the development of technologies based on natural fibers for applications such as geotextiles, mulches and controlled-release fertilizers. The technology was developed in line with the principles of a circular economy and can improve soil quality, mitigate the effects of climate change and reduce environmental pollution.

This study aimed to develop an energy-efficient process for treating highly saline textile wastewater (TWW) in a 10 m3/day pilot plant and evaluate forage sorghum irrigation with treated wastewater in terms of crop production and soil and irrigation device performance. The TWW treatment pilot plant, consisting of a coagulation/flocculation unit followed by a sand filter and an anion exchange resin column, produced treated effluent that complied with the permissible limits specified in the ISO 16075-2:2020 standard for Category C irrigation water. The corresponding average energy consumption was 1.77 kWh/m3. Reusing treated TWW for forage sorghum irrigation over a 13-week cycle yielded crop performances comparable with freshwater irrigation, with no negative impact on the irrigation system. Although soil profiles were similar between treated TWW and freshwater irrigation, both soils featured an increase in electrical conductivity, which may reversibly or irreversibly affect soil quality and damage salt-sensitive crops. These findings demonstrate the effective treatment and reuse of saline TWW for irrigating salt-tolerant crops, offering significant implications for industrial wastewater management and cropping patterns in arid and semi-arid regions. A 10-m3/day pilot plant was developed for the treatment of highly saline textile wastewater. The pilot plant demonstrated average removal efficiencies of 63% for COD, 97% for colour, 96% for TSS and 21% for EC. Treated effluent met ISO 16075-2:2020 standards for Category C irrigation water, with an average energy consumption of 1.77 kWh/m3. The use of treated wastewater showed sorghum crop production comparable with freshwater irrigation. The use of treated wastewater had no adverse effects on the irrigation system; however, it led to an increase in soil electrical conductivity.