參考文獻 |
Abomohra, A.E.F., Sheikh, H.M.A., El-Naggar, A.H., Wang, Q., 2021. Microwave vacuum co-pyrolysis of waste plastic and seaweeds for enhanced crude bio-oil recovery: Experimental and feasibility study towards industrialization. Renewable and Sustainable Energy Reviews 149, 111335.
Aisien, E.T., Otuya, I.C., Aisien, F.A., 2021. Thermal and catalytic pyrolysis of waste polypropylene plastic using spent FCC catalyst. Environmental Technology & Innovation 22, 101455.
Al-Salem, S.M., 2019. Thermal pyrolysis of high density polyethylene (HDPE) in a novel fixed bed reactor system for the production of high value gasoline range hydrocarbons (HC). Process Safety and Environmental Protection 127, 171-179.
Artetxe, M., Lopez, G., Amutio, M., Elordi, G., Bilbao, J., Olazar, M., 2012. Light olefins from HDPE cracking in a two-step thermal and catalytic process. Chemical Engineering Journal 207-208, 27-34.
Cai, N., Li, X., Xia, S., Sun, L., Hu, J., Bartocci, P., Fantozzi, F., Williams, P.T., Yang, H., Chen, H., 2021. Pyrolysis-catalysis of different waste plastics over Fe/Al2O3 catalyst: High-value hydrogen, liquid fuels, carbon nanotubes and possible reaction mechanisms. Energy Conversion and Management 229.
Charusiri, W., Phowan, N., Vitidsant, T., 2022. Pyrolysis of lignocellulosic biomass with high-density polyethylene to produce chemicals and bio-oil with high liquid yields. Sustainable Chemistry and Pharmacy 25, 100567.
Chen, C., Zhao, J., Fan, D., Qi, Q., Zeng, T., Bi, Y., 2022. Microwave-assisted co-pyrolysis of chlorella vulgaris and polypropylene: Characteristic and product distribution analyses. Bioresource Technology 344, 126279.
Chen, R., Xu, M., 2020. Kinetic and volatile products study of micron-sized PMMA waste pyrolysis using thermogravimetry and Fourier transform infrared analysis. Waste Management 113, 51-61.
Choi, I.H., Lee, H.J., Rhim, G.B., Chun, D.H., Lee, K.H., Hwang, K.R., 2022. Catalytic hydrocracking of heavy wax from pyrolysis of plastic wastes using Pd/Hβ for naphtha-ranged hydrocarbon production. Journal of Analytical and Applied Pyrolysis 161, 105424.
Coats, A.W., Redfern, J.P., 1964. Kinetic Parameters from Thermogravimetric Data. Nature 201, 68-69.
Cui, Y., Li, Y., Wang, W., Wang, X., Lin, J., Mai, X., Song, G., Naik, N., Guo, Z., 2021. Flotation separation of acrylonitrile-butadienestyrene (ABS) and high impact polystyrene (HIPS) from waste electrical and electronic equipment (WEEE) by potassium permanganate surface modification. Separation and Purification Technology 269, 118767.
Dhahak, A., Grimmer, C., Neumann, A., Rüger, C., Sklorz, M., Streibel, T., Zimmermann, R., Mauviel, G., Burkle-Vitzthum, V., 2020. Real time monitoring of slow pyrolysis of polyethylene terephthalate (PET) by different mass spectrometric techniques. Waste Management 106, 226-239.
Ding, Y., Zhang, W., Zhang, X., Han, D., Liu, W., Jia, J., 2022. Pyrolysis and combustion behavior study of PMMA waste from micro-scale to bench-scale experiments. Fuel 319, 123717.
Du, A.K., Zhou, Q., van Kasteren, J.M.N., Wang, Y.Z., 2011. Fuel oil from ABS using a tandem PEG-enhanced denitrogenation–pyrolysis method: Thermal degradation of denitrogenated ABS. Journal of Analytical and Applied Pyrolysis 92, 267-272.
Dyer, A.C., Nahil, M.A., Williams, P.T., 2021. Catalytic co-pyrolysis of biomass and waste plastics as a route to upgraded bio-oil. Journal of the Energy Institute 97, 27-36.
Engamba Esso, S.B., Xiong, Z., Chaiwat, W., Kamara, M.F., Longfei, X., Xu, J., Ebako, J., Jiang, L., Su, S., Hu, S., Wang, Y., Xiang, J., 2022. Review on synergistic effects during co-pyrolysis of biomass and plastic waste: Significance of operating conditions and interaction mechanism. Biomass and Bioenergy 159, 106415.
Eschenbacher, A., Varghese, R.J., Weng, J., Van Geem, K.M., 2021. Fast pyrolysis of polyurethanes and polyisocyanurate with and without flame retardant: Compounds of interest for chemical recycling. Journal of Analytical and Applied Pyrolysis 160, 105374.
Esposito, L., Cafiero, L., De Angelis, D., Tuffi, R., Vecchio Ciprioti, S., 2020. Valorization of the plastic residue from a WEEE treatment plant by pyrolysis. Waste Management 112, 1-10.
Fan, Y., Lu, D., Wang, J., Kawamoto, H., 2022. Thermochemical behaviors, kinetics and bio-oils investigation during co-pyrolysis of biomass components and polyethylene based on simplex-lattice mixture design. Energy 239, 122234.
Geyer, R., Jambeck Jenna, R., Law Kara, L., 2017. Production, use, and fate of all plastics ever made. Science Advances 3, e1700782.
Hong, D., Gao, P., Wang, C., 2022. A comprehensive understanding of the synergistic effect during co-pyrolysis of polyvinyl chloride (PVC) and coal. Energy 239, 122258.
Huo, E., Lei, H., Liu, C., Zhang, Y., Xin, L., Zhao, Y., Qian, M., Zhang, Q., Lin, X., Wang, C., Mateo, W., Villota, E.M., Ruan, R., 2020. Jet fuel and hydrogen produced from waste plastics catalytic pyrolysis with activated carbon and MgO. Sci Total Environ 727, 138411.
Inayat, A., Rocha-Meneses, L., Ghenai, C., Abdallah, M., Shanableh, A., Al-Ali, K., Alghfeli, A., Alsuwaidi, R., 2022. Co-pyrolysis for bio-oil production via fixed bed reactor using date seeds and plastic waste as biomass. Case Studies in Thermal Engineering 31, 101841.
Jiang, C., Wang, Y., Luong, T., Robinson, B., Liu, W., Hu, J., 2022. Low temperature upcycling of polyethylene to gasoline range chemicals: Hydrogen transfer and heat compensation to endothermic pyrolysis reaction over zeolites. Journal of Environmental Chemical Engineering 10, 107492.
Jin, X., Lee, J.H., Choi, J.W., 2022. Catalytic co-pyrolysis of woody biomass with waste plastics: Effects of HZSM-5 and pyrolysis temperature on producing high-value pyrolytic products and reducing wax formation. Energy 239, 121739.
Jung, S., Kim, J.H., Tsang, Y.F., Song, H., Kwon, E.E., 2022. Valorizing plastic toy wastes to flammable gases through CO2-mediated pyrolysis with a Co-based catalyst. Journal of Hazardous Materials 434, 128850.
Jung, S.H., Cho, M.H., Kang, B.S., Kim, J.S., 2010. Pyrolysis of a fraction of waste polypropylene and polyethylene for the recovery of BTX aromatics using a fluidized bed reactor. Fuel Processing Technology 91, 277-284.
Kaminsky, W., 2021. Chemical recycling of plastics by fluidized bed pyrolysis. Fuel Communications 8, 100023.
Kartik, S., Balsora, H.K., Sharma, M., Saptoro, A., Jain, R.K., Joshi, J.B., Sharma, A., 2022. Valorization of plastic wastes for production of fuels and value-added chemicals through pyrolysis – A review. Thermal Science and Engineering Progress 32, 101316.
Kassargy, C., Awad, S., Burnens, G., Kahine, K., Tazerout, M., 2018. Gasoline and diesel-like fuel production by continuous catalytic pyrolysis of waste polyethylene and polypropylene mixtures over USY zeolite. Fuel 224, 764-773.
Kathalingam, A., Vikraman, D., Karuppasamy, K., Kim, H.S., 2022. Water mediated electrochemical conversion of PMMA and other organic residues into graphene and carbon materials. Ceramics International.
Kumagai, S., Nakatani, J., Saito, Y., Fukushima, Y., Yoshioka, T., 2020a. Latest Trends and Challenges in Feedstock Recycling of Polyolefinic Plastics. Journal of the Japan Petroleum Institute 63, 345-364.
Kumagai, S., Yamasaki, R., Kameda, T., Saito, Y., Watanabe, A., Watanabe, C., Teramae, N., Yoshioka, T., 2020b. Catalytic Pyrolysis of Poly(ethylene terephthalate) in the Presence of Metal Oxides for Aromatic Hydrocarbon Recovery Using Tandem μ-Reactor-GC/MS. Energy & Fuels 34, 2492-2500.
Kurniawati, D., Putra, N., Abdullah, N., Ibnu Hakim, I., Nurrokhmat, A., 2021. An experimental analysis of diesel fuel produced from HDPE (high-density polyethylene) waste using thermal and catalytic pyrolysis with passive heat pipe cooling system. Thermal Science and Engineering Progress 23, 100917.
Li, D., Lei, S., Wang, P., Zhong, L., Ma, W., Chen, G., 2021. Study on the pyrolysis behaviors of mixed waste plastics. Renewable Energy 173, 662-674.
Liu, X., Burra, K.R.G., Wang, Z., Li, J., Che, D., Gupta, A.K., 2021. Towards enhanced understanding of synergistic effects in co-pyrolysis of pinewood and polycarbonate. Applied Energy 289, 116662.
Liu, Y., Fu, W., Liu, T., Zhang, Y., Li, B., 2022. Microwave pyrolysis of polyethylene terephthalate (PET) plastic bottle sheets for energy recovery. Journal of Analytical and Applied Pyrolysis 161, 105414.
Lopez-Urionabarrenechea, A., de Marco, I., Caballero, B.M., Laresgoiti, M.F., Adrados, A., 2015. Upgrading of chlorinated oils coming from pyrolysis of plastic waste. Fuel Processing Technology 137, 229-239.
Luo, W., Fan, Z., Wan, J., Hu, Q., Dong, H., Zhang, X., Zhou, Z., 2021. Study on the reusability of kaolin as catalysts for catalytic pyrolysis of low-density polyethylene. Fuel 302.
Luo, W., Hu, Q., Fan, Z.y., Wan, J., He, Q., Huang, S.x., Zhou, N., Song, M., Zhang, J.c., Zhou, Z., 2020. The effect of different particle sizes and HCl-modified kaolin on catalytic pyrolysis characteristics of reworked polypropylene plastics. Energy 213.
Maniscalco, M., La Paglia, F., Iannotta, P., Caputo, G., Scargiali, F., Grisafi, F., Brucato, A., 2021. Slow pyrolysis of an LDPE/PP mixture: Kinetics and process performance. Journal of the Energy Institute 96, 234-241.
Marino, A., Aloise, A., Hernando, H., Fermoso, J., Cozza, D., Giglio, E., Migliori, M., Pizarro, P., Giordano, G., Serrano, D.P., 2021. ZSM-5 zeolites performance assessment in catalytic pyrolysis of PVC-containing real WEEE plastic wastes. Catalysis Today.
Mensah, I., Ahiekpor, J.C., Herold, N., Bensah, E.C., Pfriem, A., Antwi, E., Amponsem, B., 2022. Biomass and plastic co-pyrolysis for syngas production: Characterisation of Celtis mildbraedii sawdust as a potential feedstock. Scientific African 16, e01208.
Nisar, J., Ali, G., Shah, A., Farooqi, Z.H., Iqbal, M., Khan, S., Sherazi, S.T.H., Sirajuddin, 2021. Production of fuel oil and combustible gases from pyrolysis of polystyrene waste: Kinetics and thermodynamics interpretation. Environmental Technology & Innovation 24, 101996.
Oberoi, I.S., Rajkumar, P., Das, S., 2021. Disposal and recycling of plastics. Materials Today: Proceedings 46, 7875-7880.
Odejobi, O.J., Oladunni, A.A., Sonibare, J.A., Abegunrin, I.O., 2020. Oil yield optimization from co-pyrolysis of low-density polyethylene (LDPE), polystyrene (PS) and polyethylene terephthalate (PET) using simplex lattice mixture design. Fuel Communications 2-5, 100006.
Park, K.B., Choi, M.J., Chae, D.Y., Jung, J., Kim, J.S., 2022. Separate two-step and continuous two-stage pyrolysis of a waste plastic mixture to produce a chlorine-depleted oil. Energy 244, 122583.
Park, K.B., Jeong, Y.S., Kim, J.S., 2019. Activator-assisted pyrolysis of polypropylene. Applied Energy 253.
Peng, C., Feng, W., Zhang, Y., Guo, S., Yang, Z., Liu, X., Wang, T., Zhai, Y., 2021. Low temperature co-pyrolysis of food waste with PVC-derived char: Products distributions, char properties and mechanism of bio-oil upgrading. Energy 219, 119670.
Peng, Y., Wang, Y., Ke, L., Dai, L., Wu, Q., Cobb, K., Zeng, Y., Zou, R., Liu, Y., Ruan, R., 2022. A review on catalytic pyrolysis of plastic wastes to high-value products. Energy Conversion and Management 254, 115243.
Platnieks, O., Barkane, A., Ijudina, N., Gaidukova, G., Thakur, V.K., Gaidukovs, S., 2020. Sustainable tetra pak recycled cellulose / Poly(Butylene succinate) based woody-like composites for a circular economy. Journal of Cleaner Production 270, 122321.
Prabu, S., Chiang, K.Y., 2021. Ni based nanoparticle catalysts for catalytic coffee residues gasification and using spent catalyst deposited carbon for energy storage applications.
Pyo, S., Kim, Y.M., Park, Y., Lee, S.B., Yoo, K.S., Ali Khan, M., Jeon, B.H., Jun Choi, Y., Hoon Rhee, G., Park, Y.K., 2021. Catalytic pyrolysis of polypropylene over Ga loaded HZSM-5. Journal of Industrial and Engineering Chemistry 103, 136-141.
Rathnayake, D., Ehidiamhen, P.O., Egene, C.E., Stevens, C.V., Meers, E., Mašek, O., Ronsse, F., 2021. Investigation of biomass and agricultural plastic co-pyrolysis: Effect on biochar yield and properties. Journal of Analytical and Applied Pyrolysis 155, 105029.
Rehan, M., Miandad, R., Barakat, M.A., Ismail, I.M.I., Almeelbi, T., Gardy, J., Hassanpour, A., Khan, M.Z., Demirbas, A., Nizami, A.S., 2017. Effect of zeolite catalysts on pyrolysis liquid oil. International Biodeterioration & Biodegradation 119, 162-175.
Samal, B., Vanapalli, K.R., Dubey, B.K., Bhattacharya, J., Chandra, S., Medha, I., 2021. Char from the co-pyrolysis of Eucalyptus wood and low-density polyethylene for use as high-quality fuel: Influence of process parameters. Science of The Total Environment 794, 148723.
Singh, R.K., Ruj, B., Sadhukhan, A.K., Gupta, P., 2019. Thermal degradation of waste plastics under non-sweeping atmosphere: Part 1: Effect of temperature, product optimization, and degradation mechanism. Journal of Environmental Management 239, 395-406.
Singh, S., Tagade, A., Verma, A., Sharma, A., Tekade, S.P., Sawarkar, A.N., 2022. Insights into kinetic and thermodynamic analyses of co-pyrolysis of wheat straw and plastic waste via thermogravimetric analysis. Bioresource Technology 356, 127332.
Sivagami, K., Divyapriya, G., Selvaraj, R., Madhiyazhagan, P., Sriram, N., Nambi, I., 2021. Catalytic pyrolysis of polyolefin and multilayer packaging based waste plastics: A pilot scale study. Process Safety and Environmental Protection 149, 497-506.
Sogancioglu, M., Yucel, A., Yel, E., Ahmetli, G., 2017. Production of Epoxy Composite from the Pyrolysis Char of Washed PET Wastes. Energy Procedia 118, 216-220.
Straka, P., Bičáková, O., Šupová, M., 2022. Slow pyrolysis of waste polyethylene terephthalate yielding paraldehyde, ethylene glycol, benzoic acid and clean fuel. Polymer Degradation and Stability 198.
Sun, C., Li, C., Tan, H., Zhang, Y., 2019. Synergistic effects of wood fiber and polylactic acid during co-pyrolysis using TG-FTIR-MS and Py-GC/MS. Energy Conversion and Management 202, 112212.
Sun, J., Luo, J., Lin, J., Ma, R., Sun, S., Fang, L., Li, H., 2022. Study of co-pyrolysis endpoint and product conversion of plastic and biomass using microwave thermogravimetric technology. Energy 247, 123547.
Sun, K., Wang, W., Themelis, N.J., Thanos Bourtsalas, A.C., Huang, Q., 2021a. Catalytic co-pyrolysis of polycarbonate and polyethylene/polypropylene mixtures: Promotion of oil deoxygenation and aromatic hydrocarbon formation. Fuel 285, 119143.
Sun, T., Lei, T., Li, Z., Zhang, Z., Yang, S., Xin, X., Zhang, M., He, X., Zhang, Q., Zhang, L., 2021b. Catalytic co-pyrolysis of corn stalk and polypropylene over Zn-Al modified MCM-41 catalysts for aromatic hydrocarbon-rich oil production. Industrial Crops and Products 171, 113843.
Supriyanto, Ylitervo, P., Richards, T., 2021. Gaseous products from primary reactions of fast plastic pyrolysis. Journal of Analytical and Applied Pyrolysis 158, 105248.
Suzuki, G., Uchida, N., Tuyen, L.H., Tanaka, K., Matsukami, H., Kunisue, T., Takahashi, S., Viet, P.H., Kuramochi, H., Osako, M., 2022. Mechanical recycling of plastic waste as a point source of microplastic pollution. Environmental Pollution 303, 119114.
Tian, X., Zeng, Z., Liu, Z., Dai, L., Xu, J., Yang, X., Yue, L., Liu, Y., Ruan, R., Wang, Y., 2022. Conversion of low-density polyethylene into monocyclic aromatic hydrocarbons by catalytic pyrolysis: Comparison of HZSM-5, Hβ, HY and MCM-41. Journal of Cleaner Production 358, 131989.
Usachev, S.V., Lomakin, S.M., Koverzanova, E.V., Shilkina, N.G., Levina, I.I., Prut, E.V., Rogovina, S.Z., Berlin, A.A., 2022. Thermal degradation of various types of polylactides research. The effect of reduced graphite oxide on the composition of the PLA4042D pyrolysis products. Thermochimica Acta 712, 179227.
Van Nguyen, Q., Choi, Y.S., Choi, S.K., Jeong, Y.W., Han, S.Y., 2021. Co-pyrolysis of coffee-grounds and waste polystyrene foam: Synergistic effect and product characteristics analysis. Fuel 292, 120375.
Verma, A., Sharma, S., Pramanik, H., 2021. Pyrolysis of waste expanded polystyrene and reduction of styrene via in-situ multiphase pyrolysis of product oil for the production of fuel range hydrocarbons. Waste Management 120, 330-339.
Wang, C., Jiang, Z., Song, Q., Liao, M., Weng, J., Gao, R., Zhao, M., Chen, Y., Chen, G., 2021. Investigation on hydrogen-rich syngas production from catalytic co-pyrolysis of polyvinyl chloride (PVC) and waste paper blends. Energy 232, 121005.
Wang, R., Yishui, T., Zhao, L., Yao, Z., Meng, H., Hou, s., 2014. Industrial analysis and determination of calorific value for biomass based on thermogravimetry. Transactions of the Chinese Society of Agricultural Engineering 30.
Wang, S., zhang, Y., Shan, R., Gu, J., Huhe, T., Ling, X., Yuan, H., Chen, Y., 2022. High-yield H2 production from polypropylene through pyrolysis-catalytic reforming over activated carbon based nickel catalyst. Journal of Cleaner Production 352, 131566.
Wang, X., Jin, Q., Zhang, J., Li, Y., Li, S., Mikulčić, H., Vujanović, M., Tan, H., Duić, N., 2018. Soot formation during polyurethane (PU) plastic pyrolysis: The effects of temperature and volatile residence time. Energy Conversion and Management 164, 353-362.
Wu, J., Zhang, X., Xie, Z., Zhang, Q., Wang, C., Jiao, G., Yang, J., 2022a. Tunable polymorphic crystal modification, phase transition and biodegradability of poly(1,4-butylene adipate) by a bio-derived metabolite with low molecular weight. Polymer Degradation and Stability 200, 109935.
Wu, X., Bourbigot, S., Li, K., Zou, Y., 2022b. Co-pyrolysis characteristics and flammability of polylactic acid and acrylonitrile-butadiene-styrene plastic blend using TG, temperature-dependent FTIR, Py-GC/MS and cone calorimeter analyses. Fire Safety Journal 128, 103543.
Xu, D., Yang, S., Su, Y., Shi, L., Zhang, S., Xiong, Y., 2021. Simultaneous production of aromatics-rich bio-oil and carbon nanomaterials from catalytic co-pyrolysis of biomass/plastic wastes and in-line catalytic upgrading of pyrolysis gas. Waste Management 121, 95-104.
Xue, Y., Zhou, S., Brown, R.C., Kelkar, A., Bai, X., 2015. Fast pyrolysis of biomass and waste plastic in a fluidized bed reactor. Fuel 156, 40-46.
Yan, F., Zhang, L., Hu, Z., Cheng, G., Jiang, C., Zhang, Y., Xu, T., He, P., Luo, S., Xiao, B., 2010. Hydrogen-rich gas production by steam gasification of char derived from cyanobacterial blooms (CDCB) in a fixed-bed reactor: Influence of particle size and residence time on gas yield and syngas composition. International Journal of Hydrogen Energy 35, 10212-10217.
Yao, D., Li, H., Dai, Y., Wang, C.H., 2021. Impact of temperature on the activity of Fe-Ni catalysts for pyrolysis and decomposition processing of plastic waste. Chemical Engineering Journal 408.
Yousef, S., Eimontas, J., Zakarauskas, K., Striūgas, N., 2022. A new sustainable strategy for oil, CH4 and aluminum recovery from metallised food packaging plastics waste using catalytic pyrolysis over ZSM-5 zeolite catalyst. Thermochimica Acta 713, 179223.
Zhang, H., Zhou, X.L., Shao, L.M., Lü, F., He, P.J., 2021. Upcycling of PET waste into methane-rich gas and hierarchical porous carbon for high-performance supercapacitor by autogenic pressure pyrolysis and activation. Science of The Total Environment 772, 145309.
Zhang, X., Lei, H., Yadavalli, G., Zhu, L., Wei, Y., Liu, Y., 2015. Gasoline-range hydrocarbons produced from microwave-induced pyrolysis of low-density polyethylene over ZSM-5. Fuel 144, 33-42.
Zhang, Y., Ji, G., Chen, C., Wang, Y., Wang, W., Li, A., 2020. Liquid oils produced from pyrolysis of plastic wastes with heat carrier in rotary kiln. Fuel Processing Technology 206, 106455.
Zhao, X., Zhan, L., Xie, B., Gao, B., 2018. Products derived from waste plastics (PC, HIPS, ABS, PP and PA6) via hydrothermal treatment: Characterization and potential applications. Chemosphere 207, 742-752.
Zhou, L., Wang, Y., Huang, Q., Cai, J., 2006. Thermogravimetric characteristics and kinetic of plastic and biomass blends co-pyrolysis. Fuel Processing Technology 87, 963-969.
江康鈺,姚彥丞,呂承翰,陳又新,「塑膠廢棄物共同熱裂解與協同效應之動力學 研究」,中華民國環境工程學會 2016 廢棄物處理技術研討會,桃園市,2016。
行政院環境保護署,網址:https://waste.epa.gov.tw/RWD/Statistics/?page=Year1,2021。
行政院主計總處,網址:https://www.dgbas.gov.tw/lp.asp?CtNode=1481&CtUnit=690&BaseDSD=7&mp=1,民國110年。
姚彥丞,「塑膠廢棄催化裂解產能效率與裂解油物種特性變化之評估研究」,中華民國環境工程學會 2017 廢棄物處理技術研討會,臺北市,2017。
張佳琪,「生質塑膠熱裂解產能效率之評估研究」,中華民國環境工程學會 2021 廢棄物處理技術研討會,台中市,2021。
陳宣宇,「含鋁塑膠包裝廢棄物熱處理回收鋁及能源之可行性」,中華民國環境工程學會 2021 廢棄物處理技術研討會,台中市,2021。
楊鎧丞,「應用共裂解技術轉換工程塑膠為能源之可行性研究」,國立中央大學環境 工程研究所,碩士論文,2022。
歐盟,網址:
https://plasticseurope.org/wp-content/uploads/2021/12/Plastics-the-Facts-2021-web-final.pdf,2021
戴華山,郭耀升,許祉祥,張一岑,「以熱裂解模式探討聚丙烯(PP)循環再利用之特徵研究」,中華民國環境工程學會 2010 廢棄物處理技術研討會,高雄, 2010。
戴華山,許祉祥,賀偉雄,王永泰,「廢棄生質塑膠(PLA)容器之熱裂解動力學性質研究」,中華民國環境工程學會 2012 廢棄物處理技術研討會,高雄,2012。 |