欧盟生物柴油使用趋势观察

The Planter Pub Date : 2021-10-25 DOI:10.56333/tp.2021.017
F. Yew, Mei Lee Yew
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With a significantly large share of 78 per cent of the total amount of biodiesel used in 2020, it will take some time before they can be replaced completely by UCO, tallows/animal waste oils and second to third generation biofuels. The call to determine the sustainability status of UCO more thoroughly in the future will also be expected to put some brakes on the accelerated use of UCO to replace these crop-based feedstocks. The price of feedstock was of secondary importance when choosing the feedstock in 2012-2020. Rapeseed oil was the most expensive vegetable feedstock and yet it was the main feedstock used. This showed that other factors e.g., feedstock sustainability status as stipulated in the Renewable Energy Directive (RED) and local availability were also important; the European Union (EU)being the world’s largest rapeseed oil producer. Besides, RED also stressed the importance of energy security and to provide jobs and economic development of the local people when executing the RE programme. As such, it is foreseen that rapeseed oil will remain the dominant feedstock. However, vegetable oils have competing uses for food, feed, oleochemicals and biofuels. The ability to use rapeseed as the primary feedstock in huge amounts indefinitely has limitations. As a resource, rapeseed ranked third in quantity produced globally. Palm oil, followed by soya had the largest amounts of resource available for use in the world. Sunflower had the lowest resource availability among the four vegetable oils. As such, overstretching the use of rapeseed and sunflower for biofuel can have other dire consequences such as supply shortages and price increases. Rapeseed alone cannot meet the total demand of EU’s biodiesel needs. 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引用次数: 0

摘要

2011-2020年,欧盟生产生物柴油的主要原料是植物油、废食用油、松木油、牛油和动物油。菜籽、棕榈油、大豆和向日葵是四种植物油原料,占生物柴油总使用量的67- 87%。尽管生物柴油的使用量随着时间的推移而增加,但来自这四种原料的生物柴油占总量的比例从2012年的87%下降到2020年的78%。这一损失主要由UCO、牛脂、动物废油和润滑脂填补;在此期间,它们的使用量增加了2.5倍。它们将在2021-2030年继续大量使用,并将导致棕榈油、大豆油和葵花籽油作为生物燃料原料的份额下降。预计2021-2030年仍将需要植物油作为生物燃料原料。到2020年,生物柴油将占生物柴油总量的78%,要完全被生物柴油、动物油脂/动物废油和第二代到第三代生物燃料所取代,还需要一段时间。关于今后更彻底地确定UCO的可持续性状况的呼吁,预计也将在一定程度上阻止加速使用UCO来取代这些以作物为基础的原料。在2012-2020年选择原料时,原料价格是次要的。菜籽油是最昂贵的蔬菜原料,但它是主要的原料。这表明,其他因素,如可再生能源指令(RED)规定的原料可持续性状况和当地可用性也很重要;欧盟(EU)是世界上最大的菜籽油生产国。此外,在执行可再生能源计划时,RED还强调了能源安全以及为当地人民提供就业和经济发展的重要性。因此,可以预见菜籽油仍将是主要的原料。然而,植物油在食品、饲料、油脂化学品和生物燃料方面有着竞争性的用途。无限期地大量使用油菜籽作为主要原料的能力是有限的。作为一种资源,油菜籽的产量在全球排名第三。棕榈油是世界上可用资源最多的,其次是大豆。4种植物油中,向日葵的资源利用率最低。因此,过度使用油菜籽和向日葵作为生物燃料可能会带来其他可怕的后果,如供应短缺和价格上涨。单靠油菜籽无法满足欧盟生物柴油的总需求。该研究表明,即使欧盟本地种植的菜籽油全部用于生产生物柴油,到2020年也只能满足其生物柴油需求的58%。由于菜籽原料无法满足欧盟生物柴油的总需求,预计在2021-2030年期间,将不得不补充其他原料,特别是棕榈油和大豆油。根据授权法规,棕榈油被归类为具有高iluc风险的不可持续生物燃料原料。顺便说一句,它是唯一被分类的原料。因此,可以设想,大豆的使用量将越来越大,而棕榈油的使用量将会减少。根据授权法规,棕榈油的使用将从2020年开始受到限制,并一直持续到最迟在2030年完全淘汰。然而,如果欧盟对棕榈油的贸易歧视能够被目前正在进行的世界贸易组织(wto)制止,形势可能仍会朝着有利于棕榈油的方向转变。关键词:生物柴油,作物生物燃料,植物油,废油,资源可用性,棕榈油,菜籽油。
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OBSERVATIONS ON BIODIESEL USAGE TRENDS IN EUROPEAN UNION
Vegetable oils, used cooking oils (UCO), pine, tallow and animal oils were the main feedstocks to produce biodiesel in EU in 2011-2020. Rapeseed, palm oil, soya and sunflower were the four vegetable oils feedstocks and contributed to 67- 87 per cent of the total biodiesel usage. Although the amounts of biodiesel usage increased over time, the share of biodiesel from these four feedstocks relative to the total amount, decreased from 87 per cent in 2012 to 78 per cent in 2020. This loss was filled up by, principally, UCO, tallows, animal waste oils and greases; their amounts used increased by 2.5 times over the period. They will continue to be used in larger quantities in 2021-2030 and will cause the share of palm, soya and sunflower oils as biofuel feedstocks to decrease. It is anticipated that vegetable oils will still be needed as biofuel feedstock in 2021-2030. With a significantly large share of 78 per cent of the total amount of biodiesel used in 2020, it will take some time before they can be replaced completely by UCO, tallows/animal waste oils and second to third generation biofuels. The call to determine the sustainability status of UCO more thoroughly in the future will also be expected to put some brakes on the accelerated use of UCO to replace these crop-based feedstocks. The price of feedstock was of secondary importance when choosing the feedstock in 2012-2020. Rapeseed oil was the most expensive vegetable feedstock and yet it was the main feedstock used. This showed that other factors e.g., feedstock sustainability status as stipulated in the Renewable Energy Directive (RED) and local availability were also important; the European Union (EU)being the world’s largest rapeseed oil producer. Besides, RED also stressed the importance of energy security and to provide jobs and economic development of the local people when executing the RE programme. As such, it is foreseen that rapeseed oil will remain the dominant feedstock. However, vegetable oils have competing uses for food, feed, oleochemicals and biofuels. The ability to use rapeseed as the primary feedstock in huge amounts indefinitely has limitations. As a resource, rapeseed ranked third in quantity produced globally. Palm oil, followed by soya had the largest amounts of resource available for use in the world. Sunflower had the lowest resource availability among the four vegetable oils. As such, overstretching the use of rapeseed and sunflower for biofuel can have other dire consequences such as supply shortages and price increases. Rapeseed alone cannot meet the total demand of EU’s biodiesel needs. The study showed that even if the entire production of rapeseed oil from locally grown crop in EU was used for biodiesel production, it could only meet 58 per cent of its biodiesel demand in 2020. Since rapeseed feedstock cannot meet the total demand of biodiesel in EU, it is anticipated that in 2021-2030, it will have to be supplemented with other feedstocks particularly palm and soya oils. Under the Delegated Regulation, palm oil is classified as an unsustainable biofuel feedstock with high ILUC-risk. Incidentally, it is the only feedstock classified as such. It is, thus, envisaged that soya will be used in larger and larger amounts at the expense of palm oil. Under the Delegated Regulation the use of palm oil will be restricted starting in 2020 and continue until its use is phased out completely by 2030 at the latest. However, the tide may still change in favour of palm oil if its trade discrimination by EU can be stopped by World Trade Organisation where a trade dispute is ongoing currently. Keywords: Biodiesel, crop-based biofuels, vegetable oils, used cooking oil, resource availability, palm oil, rapeseed.
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