Microwave pyrolysis using a well-mixed bed of activated carbon as both the microwave absorber and reaction bed was investigated for its potential to recover useful products from waste palm cooking oil – a cooking oil widely used in Asia. The carbon bed provided rapid heating (∼18 °C/min) and a localized reaction hot zone that thermally promoted extensive pyrolysis cracking of the waste oil at 450 °C, leading to increased production of a biofuel product in a process taking less than 25 min. It also created a reducing reaction environment that prevented the formation of undesirable oxidized compounds in the biofuel. The pyrolysis produced a biofuel product that is low in oxygen, free of sulphur, carboxylic acid and triglycerides, and which also contains light C$_{10}$-C$_{15}$ hydrocarbons and a high calorific value nearly comparable to diesel fuel, thus showing great potential to be used as fuel. This pyrolysis approach offers an attractive alternative to transesterification that avoids the use of solvents and catalysts, and the need to remove free fatty acids and glycerol from the hydrocarbon product. The pyrolysis apparatus operated with an electrical power input of 1.12 kW was capable of producing a biofuel with an energy content equivalent to about 3 kW, showing a positive energy ratio of 2.7 and ≥73% recovery of the energy input to the system. The results show that the pyrolysis approach has huge potential as a technically and energetically viable means for the recovery of biofuels from the waste oil.The authors acknowledge the financial support by the Ministry of Science, Technology and Innovation and the Ministry of Higher Education Malaysia for the conduct of the research under the E-Science fund (UMT/RMC/SF/13/52072(5), Vot 52072) and the FRGS grant (FRGS/1/2016/TK07/UMT/02/3, Vot 59434).This is the author accepted manuscript. The final version is available from Elsevier via https://doi.org/10.1016/j.energy.2016.09.07

Chase, HA

Cheng, CK

Chong, CT

Lam, SS

Omar, R

Wan Mahari, WA

English

Apollo (Cambridge)

Recovery of diesel-like fuel from waste palm oil by pyrolysis using a microwave heated bed of activated carbon

Microwave pyrolysis using a well-mixed bed of activated carbon as both the microwave absorber and reaction bed was investigated for its potential to recover useful products from waste palm cooking oil – a cooking oil widely used in Asia. The carbon bed provided rapid heating (∼18 °C/min) and a localized reaction hot zone that thermally promoted extensive pyrolysis cracking of the waste oil at 450 °C, leading to increased production of a biofuel product in a process taking less than 25 min. It also created a reducing reaction environment that prevented the formation of undesirable oxidized compounds in the biofuel. The pyrolysis produced a biofuel product that is low in oxygen, free of sulphur, carboxylic acid and triglycerides, and which also contains light C10-C15 hydrocarbons and a high calorific value nearly comparable to diesel fuel, thus showing great potential to be used as fuel. This pyrolysis approach offers an attractive alternative to transesterification that avoids the use of solvents and catalysts, and the need to remove free fatty acids and glycerol from the hydrocarbon product. The pyrolysis apparatus operated with an electrical power input of 1.12 kW was capable of producing a biofuel with an energy content equivalent to about 3 kW, showing a positive energy ratio of 2.7 and ≥73% recovery of the energy input to the system. The results show that the pyrolysis approach has huge potential as a technically and energetically viable means for the recovery of biofuels from the waste oil

Lam, Su Shiung

Wan Mahari, Wan Adibah

Cheng, Chin Kui

Omar, Rozita

Chong, Cheng Tung

Chase, Howard A.

Universiti Putra Malaysia Institutional Repository

Recovery of diesel-like fuel from waste palm oil by pyrolysis using a microwave heated bed of activated carbon ABSTRACT Microwave pyrolysis using a well-mixed bed of activated carbon as both the microwave absorber and reaction bed was investigated for its potential to recover useful products from waste palm cooking oil – a cooking oil widely used in Asia. The carbon bed provided rapid heating (∼18 °C/min) and a localized reaction hot zone that thermally promoted extensive pyrolysis cracking of the waste oil at 450 °C, leading to increased production of a biofuel product in a process taking less than 25 min. It also created a reducing reaction environment that prevented the formation of undesirable oxidized compounds in the biofuel. The pyrolysis produced a biofuel product that is low in oxygen, free of sulphur, carboxylic acid and triglycerides, and which also contains light C10-C15 hydrocarbons and a high calorific value nearly comparable to diesel fuel, thus showing great potential to be used as fuel. This pyrolysis approach offers an attractive alternative to transesterification that avoids the use of solvents and catalysts, and the need to remove free fatty acids and glycerol from the hydrocarbon product. The pyrolysis apparatus operated with an electrical power input of 1.12 kW was capable of producing a biofuel with an energy content equivalent to about 3 kW, showing a positive energy ratio of 2.7 and ≥73% recovery of the energy input to the system. The results show that the pyrolysis approach has huge potential as a technically and energetically viable means for the recovery of biofuels from the waste oil. Keyword: Pyrolysis; Microwave pyrolysis; Waste cooking oil; Palm oil; Activated carbon   

Lam, S. S.

Wan Mahari, W. A.

Cheng, C. K.

Omar, R.

Chong, C. T.

Chase, H. A.

Universiti Teknologi Malaysia Institutional Repository

Su Shiung Lam

Wan Adibah Wan Mahari

Chin Kui Cheng

Rozita Omar

Cheng Tung Chong

Howard A. Chase

Crossref

Energy

Microwave pyrolysis using a well-mixed bed of activated carbon as both the microwave absorber and reaction bed was investigated for its potential to recover useful products from waste palm cooking oil - a cooking oil widely used in Asia. The carbon bed provided rapid heating (~18 C/min) and a localized reaction hot zone that thermally promoted extensive pyrolysis cracking of the waste oil at 450 C, leading to increased production of a biofuel product in a process taking less than 25 min. It also created areducing reaction environment that prevented the formation of undesirable oxidized compounds in the biofuel. The pyrolysis produced a biofuel product that is low in oxygen, free of sulphur, carboxylic acid

and triglycerides, and which also contains light C10-C15 hydrocarbons and a high calorific value nearly

comparable to diesel fuel, thus showing great potential to be used as fuel. This pyrolysis approach offers

an attractive alternative to transesterification that avoids the use of solvents and catalysts, and the need

to remove free fatty acids and glycerol from the hydrocarbon product. The pyrolysis apparatus operated

with an electrical power input of 1.12 kW was capable of producing a biofuel with an energy content equivalent to about 3 kW, showing a positive energy ratio of 2.7 and 73% recovery of the energy input to the system. The results show that the pyrolysis approach has huge potential as a technically and energetically viable means for the recovery of biofuels from the waste oil

Su, Shiung Lam

Wan Adibah, Wan Mahari

Rozita, Omar

Cheng, Tung Chong

UMP Institutional Repository

Energy 115 (2016) 791e799Contents lists available at ScienceDirecte fud ofdibahjournRecovery of diesel-likmicrowave heated beSu Shiung Lam a, e, *, Wan ACheng Tung Chong d, Howard A.a Eastern Corridor Renewable Energy Group (ECRE), Schb Faculty of Chemical and Natural Resources Engineerinc Department of Chemical and Environmental Engineerid Faculty of Mechanical Engineering, Universiti TeknologtechnologWaste cooking oilPalm oilActivated carbon1. IntroductionCooking oil can be derived from variosuch as seeds from plants (e.g. sunﬂower oisoybean oil, peanut oil), and fruits (e.g. palmcooking oil is used, it becomes an undesirabe properly disposed of. The production obeen increasing each year throughout thUnited States generated approximately 10cooking oil each year [1], whereas China genmillion tons/year of waste cooking oil [2]. D* Corresponding author. Eastern Corridor RenewabTerengganu, Malaysia.E-mail addresses: lam@umt.edu.my (S.S. Lam), adctchong@mail.fkm.utm.my (C.T. Chong), hac1000@camhttp://dx.doi.org/10.1016/j.energy.2016.09.0760360-5442/© 2016 Elsevier Ltd. All rights reserved.el from waste palm oil by pyrolysis using aactivated carbonWan Mahari a, Chin Kui Cheng b, Rozita Omar c,Chase eool of Ocean Engineering, University Malaysia Terengganu, 21030 Kuala Terengganu, Malaysiag, University Malaysia Pahang, Lebuhraya Tun Razak, 26300 Gambang, Pahang, Malaysiang, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysiai Malaysia, 81310 Skudai, Johor, MalaysiaEnergyal homepage: www.elsevier .com/locate/energyy, University of Cambridge, New Museums Site, Pembroke Street, Cambridge CB2 3RA, Unitede Department of Chemical Engineering and BioKingdoma wtedAsmalf aenucech athustraa r t i c l e i n f oArticle history:Received 13 March 2016Received in revised form20 July 2016Accepted 11 September 2016Keywords:PyrolysisMicrowave pyrolysisa b s t r a c tMicrowave pyrolysis usingreaction bed was investigacooking oil widely used inreaction hot zone that therto increased production oreducing reaction environmbiofuel. The pyrolysis prodand triglycerides, and whicomparable to diesel fuel,an attractive alternative toto remove free fatty acids andwith an electrical power inpuequivalent to about 3 kW, shoto the system. The results shenergetically viable means forus biological resourcesl, sesame oil), nuts (e.g.oil, olive oil). Once theble waste that needs tof waste cooking oil hase world. For example,million tons of wasteerated approximately 5ue to the large amountle Energy Group (ECRE), Schoolibah.mahari@gmail.com (W.A. Wa.ac.uk (H.A. Chase).ell-mixed bed of activated carbon as both the microwave absorber andfor its potential to recover useful products fromwaste palm cooking oil e aia. The carbon bed provided rapid heating (~18 C/min) and a localizedly promoted extensive pyrolysis cracking of the waste oil at 450 C, leadingbiofuel product in a process taking less than 25 min. It also created at that prevented the formation of undesirable oxidized compounds in thed a biofuel product that is low in oxygen, free of sulphur, carboxylic acidlso contains light C10-C15 hydrocarbons and a high caloriﬁc value nearlyshowing great potential to be used as fuel. This pyrolysis approach offersnsesteriﬁcation that avoids the use of solvents and catalysts, and the needglycerol from the hydrocarbon product. The pyrolysis apparatus operatedt of 1.12 kW was capable of producing a biofuel with an energy contentwing a positive energy ratio of 2.7 and 73% recovery of the energy inputow that the pyrolysis approach has huge potential as a technically andthe recovery of biofuels from the waste oil.© 2016 Elsevier Ltd. All rights reserved.of waste cooking oil generated annually, the disposal of wastecooking oil has become a challenge and concern to the modernsociety.Recently, pyrolysis techniques have been reported to showincreased efﬁciency in transforming biomass and waste materialsinto potential fuel products [3e8]. Pyrolysis is a thermal degra-dation process that can be used to treat waste materials in anoxygen-free atmosphere to produce liquid oil, gases and char. Ithas been reported that the liquid oil and gases can be utilized as achemical feedstock or they can be upgraded to obtain light hy-drocarbons for use as a fuel, and the char produced can also beof Ocean Engineering, University Malaysia Terengganu, 21030 Kuala Terengganu,n Mahari), chinkui@ump.edu.my (C.K. Cheng), rozitaom@upm.edu.my (R. Omar),

Recovery of Diesel-Like Fuel from Waste Palm Oil by Pyrolysis using a Microwave Heated Bed of Activated Carbon

https://www.repository.cam.ac.uk/bitstream/handle/1810/261029/Lam-et_al-2016-Energy-AM.pdf?sequence=1&isAllowed=y

Recovery of diesel-like fuel from waste palm oil by pyrolysis using a microwave heated bed of activated carbon

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