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CEN TR 16957-2016 Bio-based products - Guidelines for Life Cycle Inventory (LCI) for the End-of-life phase.pdf

1、Bio-based products Guidelines for Life Cycle Inventory (LCI) for the End-of-life phasePD CEN/TR 16957:2016BSI Standards PublicationWB11885_BSI_StandardCovs_2013_AW.indd 1 15/05/2013 15:06National forewordThis Published Document is the UK implementation of CEN/TR 16957:2016. The UK participation in i

2、ts preparation was entrusted to TechnicalCommittee MI/2, Bio-based products.A list of organizations represented on this committee can be obtained onrequest to its secretary.This publication does not purport to include all the necessary provisions ofa contract. Users are responsible for its correct a

3、pplication. The British Standards Institution 2016.Published by BSI Standards Limited 2016ISBN 978 0 580 92285 5ICS 13.020.60Compliance with a British Standard cannot confer immunity fromlegal obligations.This Published Document was published under the authority of theStandards Policy and Strategy C

4、ommittee on 30 September 2016.Amendments/corrigenda issued since publicationDate Text affectedPUBLISHED DOCUMENTPD CEN/TR 16957:2016TECHNICAL REPORT RAPPORT TECHNIQUE TECHNISCHER BERICHT CEN/TR 16957 September 2016 ICS 13.020.60 English Version Bio-based products - Guidelines for Life Cycle Inventor

5、y (LCI) for the End-of-life phase Produits biosourcs - Lignes directrices relatives linventaire du cycle de vie (ICV) pour la phase de fin de vie Biobasierte Produkte - Leitlinien fr die Sachbilanzierung von Produkten in der Nachnutzungsphase This Technical Report was approved by CEN on 22 May 2016.

6、 It has been drawn up by the Technical Committee CEN/TC 411. CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latv

7、ia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey andUnited Kingdom. EUROPEAN COMMITTEE FOR STANDARDIZATION COMIT EUROPEN DE NORMALISATION EUROPISCHES KOMITEE FR NORMUNG CEN-CENELEC Management Centre: Avenue Marni

8、x 17, B-1000 Brussels 2016 CEN All rights of exploitation in any form and by any means reserved worldwide for CEN national Members. Ref. No. CEN/TR 16957:2016 EPD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 2 Contents Page European foreword . 3 Introduction 4 1 Scope 5 2 Normative references 5 3 Terms an

9、d definitions . 6 4 Modelling end-of-life options for bio-based products . 6 4.1 General 6 4.2 Documentation requirements 8 4.3 Reuse and/or preparation for reuse 8 4.4 Recycling 9 4.4.1 Mechanical recycling 9 4.4.2 Organic recycling 10 4.5 Recovery 13 4.5.1 Chemical recovery . 13 4.5.2 Energy recov

10、ery 14 4.6 Incineration 14 4.6.1 General . 14 4.6.2 Parameters specific for bio-based waste . 15 4.6.3 Parameters specific for incineration models . 15 4.6.4 Documentation requirements . 16 4.7 Landfill . 16 4.7.1 General . 16 4.7.2 Parameters specific for bio-based waste . 16 4.7.3 Parameters speci

11、fic for landfill model . 16 4.7.4 Documentation requirements . 19 4.8 Wastewater treatment (WWT) . 19 4.8.1 Wastewater aerobic treatment . 19 4.8.2 Parameters specific for aerobic WWT models 20 4.8.3 Product specific parameters 20 4.8.4 Anaerobic primary sludge treatment . 20 4.9 Release of bio-base

12、d products in nature . 21 Annex A (informative) Examples of pathways 22 Bibliography . 24 PD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 3 European foreword This document (CEN/TR 16957:2016) has been prepared by Technical Committee CEN/TC 411 “Bio-based products”, the secretariat of which is held by NEN.

13、 Attention is drawn to the possibility that some of the elements of this document may be the subject of patent rights. CEN shall not be held responsible for identifying any or all such patent rights. PD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 4 Introduction Bio-based products from forestry and agricu

14、lture have a long history of application, such as paper, board and various chemicals and materials. The last decades have seen the emergence of new bio-based products in the market. Some of the reasons for the increased interest lie in the bio-based products benefits in relation to the depletion of

15、fossil resources and climate change. Bio-based products may also provide additional product functionalities. This has triggered a wave of innovation with the development of knowledge and technologies allowing new transformation processes and product development. Acknowledging the need for common sta

16、ndards for bio-based products, the European Commission issued mandate M/492, resulting in a series of standards developed by CEN/TC 411, with a focus on bio-based products other than food, feed and biomass for energy applications. The standards of CEN/TC 411 “Bio-based products” provide a common bas

17、is on the following aspects: Common terminology; Bio-based content determination; Life Cycle Assessment (LCA); Sustainability aspects; Declaration tools. It is important to understand what the term bio-based product covers and how it is being used. The term bio-based means derived from biomass. Bio-

18、based products (bottles, insulation materials, wood and wood products, paper, solvents, chemical intermediates, composite materials, etc.) are products which are wholly or partly derived from biomass. It is essential to characterize the amount of biomass contained in the product by for instance its

19、bio-based content or bio-based carbon content. The bio-based content of a product does not provide information on its environmental impact or sustainability, which may be assessed through LCA and sustainability criteria. In addition, transparent and unambiguous communication within bio-based value c

20、hains is facilitated by a harmonized framework for certification and declaration. PD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 5 1 Scope This Technical Report provides guidance on how to compile an inventory for the end-of-life phase in LCA of bio-based products. All the end-of-life treatments here add

21、ressed are shown in Figure 1. Figure 1 End-of-life treatments addressed in this TR and related clauses NOTE The order of the end-of-life options indicated in Figure 1 respect the Directive 2008/98/EC on waste. This list is not exhaustive, but illustrates the content of this Technical Report. 2 Norma

22、tive references The following documents, in whole or in part, are normatively referenced in this document and are indispensable for its application. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments)

23、applies. EN 16575, Bio-based products - Vocabulary EN 16760, Bio-based products - Life Cycle Assessment PD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 6 3 Terms and definitions For the purposes of this document, the terms and definitions given in EN 16575, EN 16760 and the following apply. 3.1 chemical r

24、ecovery process to recover valuable chemical substances by chemical treatment of used materials by hydrolysis, glycolysis, methanolysis, catalytic reaction, thermal reaction, and other chemical processes SOURCE: ISO 18601:2013, definition 3.1, modified - “packaging” replaced by “materials”, “process

25、 to substitute used packaging for natural resources” deleted. 4 Modelling end-of-life options for bio-based products 4.1 General The end-of-life options for bio-based products are in general the same as the options available for non bio-based products. Each end-of-life option has different environme

26、ntal impacts to be evaluated as part of the LCA. Life cycle inventory data (e.g. emissions to air, water and soil) related to the bio-based product end-of-life option depends on the type of treatment technology, processing conditions, the local infrastructure for collection (e.g. separate collection

27、 of biodegradable waste for composting), sorting and processing, the location (i.e. the contribution of for example the electricity used) and the physical-chemical characteristics of the disposed material such as the chemical composition and the biodegradation behaviour. The end of life options recy

28、cling (mechanical or organic) and chemical recovery can lead to secondary materials, and consequently saving primary materials, keeping the bio-based carbon fixed in the material or preserving nutrients. NOTE 1 Collection, transportation and sorting of the waste from bio-based products are considere

29、d under the LCA but are not detailed in this Technical Report. Regardless of the origin of the process module applied in the LCA study (generic modules from LCA databases, other public data, or modules developed by the practitioner of the LCA study), the parameters shown in Table 1 need to be define

30、d in order to reflect the material properties of the studied bio-based waste. PD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 7 Table 1 Properties of waste from bio-based products Parameters Unit Combustion characteristics Lower Heating Value (LHV) MJ/kg Share of biodegradable carbon actually decomposed i

31、nto inorganic components within a defined time period In composting % In landfill Time period covered % years In incineration % In anaerobic digestion % Water content % (weight) Chemical composition (in dry mass) Carbon (fossil) (C) g/kg Carbon (biogenic) (C) g/kg Hydrogen (H) g/kg Oxygen (O) g/kg S

32、ulphur (S) g/kg Nitrogen (N) g/kg Fluorine (F) g/kg Chlorine (Cl) g/kg Magnesium (Mn) g/kg Potassium (K) g/kg Calcium (Ca) g/kg Arsenic (As) g/kg Cadmium (Cd) g/kg Nickel (Ni) g/kg Cobalt (Co) g/kg Chromium (Cr) g/kg Copper (Cu) g/kg Mercury (Hg) g/kg Manganese (Mg) g/kg Lead (Pb) g/kg Zinc (Zn) g/k

33、g Other elements (e.g. Se and Mo) g/kg PD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 8 NOTE 2 Very low concentrations (ppm) of some of these elements may have a high impact and therefore need to be included in the LCI. The quantity of energy contained in a material is generally expressed through the Low

34、er Heating Value (LHV). This parameter points out the maximum energy obtainable from the complete combustion of the material, without considering the heat of the water vapour generated by the combustion. The lower heating value of bio-based product waste can be measured according to EN 15359. LHV ca

35、n be estimated using the following formula, based on the chemical composition of the bio-based material. 2/ 2,2 2,2 9= LHV MJ kg HHV H O H where 9,83 124,27 34,02 19,07 6,28= + + + +HHV O H C S N where HHV is Higher Heating Value (MJ/kg material); O is oxygen (without O from H2O) (kg/kg of material)

36、; H is hydrogen (without H from H2O) (kg/kg of material); C is carbon (kg/kg of material); N is nitrogen (kg/kg of material); S is sulphur (kg/kg of material). NOTE 3 Source: Ecoinvent 15. The share of biodegradable carbon actually decomposed into inorganic components, along with, chemical compositi

37、on of the bio-based material guarantee, for example, a closed biogenic carbon balance in the LCA system model of the bio-based product. 4.2 Documentation requirements The properties of the waste from bio-based products (Table 1) need to be documented along with their data sources to ensure transpare

38、ncy and enable comparability. This is especially relevant in case of cradle-to-grave studies, where those properties are of key importance to correctly model the end-of-life process along the value chain. Biogenic carbon content in any LCA study of bio-based products/materials should be documented.

39、Biogenic carbon emissions (carbon dioxide, methane), originating from decomposition or combustion, of bio-based material need to be documented separately from non-bio-based carbon emissions in order to allow a consistent biogenic carbon balance over the full lifecycle of a bio-based product. 4.3 Reu

40、se and/or preparation for reuse Reuse means any operation by which products or components that are not waste are used again for the same purpose for which they were conceived. Preparing for reuse means checking, cleaning or repairing recovery operations, by which products or components of products t

41、hat have become waste are prepared so that they can be reused without any other pre-processing. PD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 9 Important aspects to consider in the LCA study are the energy use from transportation to collection and logistic points and the use of resources for the prepara

42、tion for reuse (e.g. water use, cleaning agents, energy, etc.). NOTE See also Annex C of ILCD Handbook 17. 4.4 Recycling 4.4.1 Mechanical recycling 4.4.1.1 General In mechanical recycling, waste material is reclaimed in order to enable use of the material in manufacture of a new product. During mech

43、anical recycling, waste for example is ground, cleaned and eventually recycled (e.g. for plastics recycled into flakes or pellets). The quality of the recycled materials differs depending on original material properties and recycling processes applied. This waste treatment pathway is open to bio-bas

44、ed materials. Prerequisite for a valuable mechanical recycling of bio-based material is (a source-separated) waste collection and subsequent sorting. Recycled bio-based material maintains the CO2fixed from the atmosphere during plant growth within the technical material cycle. This might be accounta

45、ble as a type of carbon sequestration. In such case bio-based carbon may therefore be considered as sequestered in the recycled bio-based material until the recycled material (after one or more recycling “loops”) ends up in a final treatment (incineration, composting or anaerobic digestion process).

46、 4.4.1.2 Parameters specific for bio-based waste The key parameters for modelling bio-based waste recycling are listed in Table 2. Table 2 Parameters required for recycling model Energy demand electrical kWh/t waste input Energy demand thermal kWh/t waste input Energy demand mechanical kWh/t waste i

47、nput Operating supplies (e.g. water, detergents) Recycling efficiency (dry weight of waste) (%) kg output materials/ kg input materials x 100 Amount of non-recycled fraction (kg) and its end-of-life Depending on the LCA modelling approach to be used, information on what is substituted, the end use m

48、arket or the quality of the recycled material may be needed. 4.4.1.3 Documentation requirements Bio-based carbon content that is fixed in recycled material needs to be documented in order to guarantee a consistent biogenic carbon balance over the lifecycle. Inventory and impact assessment results ne

49、ed to be presented transparently, separately indicating contributions of recycling processes and any associated credits (e.g. credits for replacement of virgin materials). PD CEN/TR 16957:2016CEN/TR 16957:2016 (E) 10 4.4.2 Organic recycling 4.4.2.1 General During organic recycling, biodegradable materials are exposed to the action of microorganisms. A fundamental change in the molecular structure of the materials occurs. The process can be aerobic (with air) or anaerobic (without air). In the first case, which corresp

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