Investigation of co-pyrolysis blends of camel manure, date pits and plastic waste into value added products using Aspen Plus

The increasing demand for energy worldwide and growing environmental concerns is the impetus for greater integration of alternate sustainable technologies. In parallel, the efficient and safe management of plastic waste is needed since it is reported that only 9 % of plastic is recycled, while 76 % is landfilled. This study performs a copyrolysis of four main types of feedstocks, such as camel manure (CM), date pits (DP), low-density polyethylene (LDPE) and high-density polyethylene (HDPE). Additionally, different mixing scenarios of those feedstocks are also studied. For this purpose, a simulated equilibrium model for the pyrolysis process is developed using Aspen Plus (R), which also investigates the impact of waste types, blends, and temperature on pyrolysis product distribution. Pyrchar and pyrgas production are major products for camel manure and date pits and also for plastic wastes with higher production. In biomass feedstock, the highest production of pyrgas is 623.78 kg/hr for camel manure and 555.69 kg/hr for date pits at 600 degrees C. The maximum production of pyrchar is 485.43 kg/hr for LDPE and 618.46 kg/hr for plastic feedstock (HDPE). As for mixing scenarios, the production of pyrchar is maximum at a ratio of 0.2CM: 0.2DP: 0.3LDPE: 0.3HDPE (S6) and 0CM: 0DP: 0.5LDPE: 0.5HDPE (S7) and a temperature of 600 degrees C resulting in 448.15 kg/hr and 614.69 kg/hr respectively. The pyrgas production at mixing ratio of 0.25CM: 0.25DP: 0.25LDPE: 0.25HDPE (S5) and 0.5CM: 0.5DP: 0LDPE: 0HDPE (S8) is maximum with 405.21 kg/hr and 589.24 kg/hr respectively at a temperature of 600 degrees C. Pyroil production is highest at a temperature of 300 degrees C for all scenarios resulting in a maximum production of date pits of 309.92 kg/hr.

Automated summary

The increasing demand for energy worldwide and growing environmental concerns are driving the need for greater integration of sustainable technologies, including the efficient management of plastic waste. A study was conducted on the copyrolysis of camel manure, date pits, low-density polyethylene (LDPE), and high-density polyethylene (HDPE), as well as different mixing scenarios of these feedstocks. The study developed a simulated equilibrium model to investigate the impact of waste types, blends, and temperature on pyrolysis product distribution. The results showed that different feedstocks and mixing scenarios influenced the production of pyrchar, pyrgas, and pyroil at varying temperatures.