This research presents a study of the design and construction of a fertilizer rotary dryer in a pig farm which used waste heat at 400 degree Celsius from an electrical generator. The designed rotary dryer consisted of two pipes with lengths of 10 meters. These pipes consisted of a drying and a cooling pipe, each with a diameter of 0.5 meter. The power was supplied by two 5 horse power motors, and 2 horse power blowers were used to suck in hot and cool air for drying. The fertilizer, with an initial moisture content of 55-60 %db, was examined. Three parameters were varied to study the optimal condition of drying. These were rotary speed, degree of tilt angle and air flow rate. The rotary speed was varied at 10, 15 and 20 RPM, the degree of tilt angle was set at 1, 3 and 5 degrees, and the air flow rate was varied at 60, 120 and 180 cubic meters per hour. From the experiment, the result revealed that the condition of 1 degree of tilt angle, 10 rpm of rotary speed and an air flow rate of 180 cubic meters per hours were the optimal conditions for drying the fertilizer. The moisture in the fertilizer was reduced from 57.84 %db to 12.45 %db. The drying rate was 56.93 kg/h, and the thermal efficiency was 79.24 %. The energy consumption was 328.64 kWh/ ton. The capacity of the designed rotary dryer was 3 tons/day which is three times more than the amount of the traditional drying method. If the cost of the rotary dryer is 450,000 Baht, the payback period will be 3.73 months.
This research compared rotary dryer efficiency using waste heat from an electrical generator and liquefied petroleum gas (LPG) as a heat source. A fertilizer drying experiment was conducted using residues from bio-gas production with a 3-ton/day capacity fertilizer dryer. Flow drying and drying efficiency was tested concurrently and measured together with water evaporation, energy consumption, and an economic analysis of data was conducted. Two heat sources were applied at the rates of 10, 15, and 20 rpm, drying cylinder with inclination angles of 1°, 3°, and 5°, and hot gas flow rates of 60, 120, and 180 m3/h. The tests showed that dryer inclination of 1°, heat flow rate of 180 m3/h, and dryer rotation speed at 10 rpm were the most optimal drying conditions. When waste heat from the electrical generator was applied, thermal efficiency was 79.19%, while the fertilizer's moisture content could be reduced from 57.84% dry weight standard to 12.45%, with an evaporation rate of 56.93 kg/h. The energy consumption was 23.78 kW h/1 ton of fertilizer. LPG drying yielded a heat efficiency of 72.69%, while moisture content went from 56.16% to 12.77%. Water evaporation from the fertilizer was 54.24 kg/h, and heat consumption was 986.33 kW h per 1 ton of fertilizer. Analysis revealed that fertilizer drying by waste heat from an electrical generator yields better efficiency and saves more energy than using LPG as the heat source. The cost of drying is also approximately 3.14 times lower.
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