Citation
Furuichi S., . and Mat Daham M. D., . and Sato J., . (2003) Development of solar dryer for drying oil palm fronds before processing into animal feed. [Proceedings Paper]
Abstract
A prototype 30 tons capacity solar dryer was developed in MARDI for drying OPF prior to being processed into animal feed. The parameters inside the dryer are monitored by a computer which is programmed to record solar energy temperature and humidity inside and outside the solar house at 15 minutes interval for 24 hours a day. The computer is also set to control the temperature and humidity of the dryer through a supplementary diesel heater and ventilating fan respectively. Maximum temperature of 50 C and minimum relative humidity of 11 could be obtained inside the solar house during the best weather conditions. A number of drying tests were conducted using the solar dryer and subsequently modified with addition of blow-down ventilating fans and improved agitators. Initial drying tests showed that the drying time to achieve 13 moisture content was about 7 days. Drying tests conducted when blow-down ventilating fans and improved stirrers were installed showed that OPF could be dried from 65 to 13 moisture content within 3 days. This shows that drying efficiency could be improved further by stirring the OPF material during drying using automated mechanical stirrers and using blow-down fans during the daytime. Solar energy has a good potential to be used as a cheap source of energy for drying OPF before they are processed into animal feed.
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Abstract
A prototype 30 tons capacity solar dryer was developed in MARDI for drying OPF prior to being processed into animal feed. The parameters inside the dryer are monitored by a computer which is programmed to record solar energy temperature and humidity inside and outside the solar house at 15 minutes interval for 24 hours a day. The computer is also set to control the temperature and humidity of the dryer through a supplementary diesel heater and ventilating fan respectively. Maximum temperature of 50 C and minimum relative humidity of 11 could be obtained inside the solar house during the best weather conditions. A number of drying tests were conducted using the solar dryer and subsequently modified with addition of blow-down ventilating fans and improved agitators. Initial drying tests showed that the drying time to achieve 13 moisture content was about 7 days. Drying tests conducted when blow-down ventilating fans and improved stirrers were installed showed that OPF could be dried from 65 to 13 moisture content within 3 days. This shows that drying efficiency could be improved further by stirring the OPF material during drying using automated mechanical stirrers and using blow-down fans during the daytime. Solar energy has a good potential to be used as a cheap source of energy for drying OPF before they are processed into animal feed.
Additional Metadata
Item Type: | Proceedings Paper |
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Additional Information: | Available at Perpustakaan Sultan Abdul Samad Universiti Putra Malaysia 43400 UPM Serdang Selangor Malaysia. mal SF94.6 I61 2003 Call Number |
AGROVOC Term: | Elaeis guineensis |
AGROVOC Term: | Oil palm |
AGROVOC Term: | Feed production |
AGROVOC Term: | Drying |
AGROVOC Term: | Solar drying |
AGROVOC Term: | Dryers |
AGROVOC Term: | Artificial drying |
AGROVOC Term: | Temperature |
AGROVOC Term: | Moisture content |
AGROVOC Term: | Animal feeding stuffs |
Geographical Term: | MALAYSIA |
Depositing User: | Ms. Suzila Mohamad Kasim |
Last Modified: | 24 Apr 2025 05:16 |
URI: | http://webagris.upm.edu.my/id/eprint/13533 |
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