FprCEN/TR 17739

SLOVENSKI STANDARD
kSIST-TP FprCEN/TR 17739:2021
01-oktober-2021
Alge in izdelki iz alg - Specifikacije za uporabo v kemijskem in bioenergetskem
sektorju

Algae and algae products - Specifications for chemicals and biofuels sector applications

Algen und algenbasierte Produkte - Spezifikationen für Anwendungen im Chemie- und

Algues et produits d’algues - Spécifications pour les applications dans le secteur de la

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

Algues et produits d'algues - Spécifications pour les Algen und algenbasierte Produkte - Spezifikationen für

applications dans le secteur de la chimie et de la Anwendungen im Chemie- und Biokraftstoffsektor

This draft Technical Report is submitted to CEN members for Vote. It has been drawn up by the Technical Committee CEN/TC

CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia,

Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway,

Poland, Portugal, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and

Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are

Warning : This document is not a Technical Report. It is distributed for review and comments. It is subject to change without

© 2021 CEN All rights of exploitation in any form and by any means reserved Ref. No. FprCEN/TR 17739:2021 E

European foreword ............................................................................................................................................ 3

Introduction .......................................................................................................................................................... 4

1 Scope .......................................................................................................................................................... 5

2 Normative references .......................................................................................................................... 5

3 Terms and definitions ......................................................................................................................... 5

4 Algae products applications as chemical raw materials ........................................................ 8

5 Biofuels from algae ............................................................................................................................. 10

6 Algal product characteristics and test methods ...................................................................... 16

7 Sustainable development ................................................................................................................. 20

8 Algae LCA................................................................................................................................................ 21

Annex A (informative) Raw Material Specifications examples ....................................................... 24

A.1 Example 1 of microalga biomass specifications ...................................................................... 24

A.2 Example 2 of cyanobacterium biomass specifications .......................................................... 26

A.3 Example 3 of macroalgae biomass specifications ................................................................... 30

Annex B (Informative) Technical Data Sheets (TDS) examples ...................................................... 34

B.1 Example of microalga biomass Data Sheet ................................................................................ 34

B.2 Example of cyanobacterium biomass Data Sheet .................................................................... 35

B.3 Example of macroalga biomass Data Sheet ............................................................................... 36

Annex C (Informative) FPR Regulation .................................................................................................... 38

Annex D (Informative) Algae based biostimulant ................................................................................ 40

Annex E (Informative) EU fertilisers contaminants table (Reg 1009/2019 EU) ....................... 41

Annex F (Informative) Algae extracts ....................................................................................................... 44

F.1 Algae extracts for chemical purposes .......................................................................................... 44

F.2 Solvent extraction vs CO -Extraction ........................................................................................... 45

F.3 Algae biomass CO -Exaction ............................................................................................................ 45

F.4 Algae biomass CO2-Extraction ....................................................................................................... 46

Annex G (Informative) Algae biofuels literature overview............................................................... 47

Bibliography ....................................................................................................................................................... 51

This document (FprCEN/TR 17739:2021) has been prepared by Technical Committee CEN/TC 454

The European committee for Standardisation (CEN) was requested by the European Commission (EC) to

draft European standards or European standardisation deliverables to support the implementation of

Article 3 of Directive 2009/28/EC for algae and algae products or intermediates. The request presented

as Mandate M/547, also contributes to the Communication on “Innovating for Sustainable Growth: A Bio

The former working group CEN Technical Board Working Group 218 “Algae” was created in 2016 to

develop a work programme as part of the Mandate. The technical committee CEN/ TC 454 “Algae and

algae products” was established to carry out the work program the secretariat of which is held by NEN.

CEN TC 454 set up a number of topic specific working Groups listed below to develop standards for algae

This document has been prepared by Working Group 5 “Specifications for the chemicals and fuels

applications sector” with the support of UNI as the secretariat, in close collaboration with the other CEN

The interest in algae and algae-based products or intermediates as a renewable and sustainable source

of carbohydrates, proteins, lipids and pigments has increased significantly in Europe.

Algae-based products and intermediates, in this TR referred to as ‘products’, are defined as whole

biomass, extracts or derivatives from algae, including a.o. algae oil and algal meal.

This document will allow the stakeholders to have access to a clear point of reference on the use of algae

Algae as raw materials have specific challenges and show a wide potential from sustainability and blue

The interest in algae and algae-based products or intermediates as a renewable and sustainable source

of carbohydrates, proteins, lipids and pigments has increased significantly in Europe.

The biochemical composition of algae with regard to the ratio of usable components is unique and the

selected conversion pathway determines the kind of products that can be obtained.

Algae are available and used in many countries as fertiliser, biostimulant, animal feed, medicine, cosmetic

and food ingredients, and can provide different compounds depending on species. Due to the high interest

in replacing fossil feedstock for chemicals and fuels by biological ones, as algae, several pilot initiatives

have been undertaken in last decades. Results strongly vary, as many techno-economic parameters are

Cultivation of algae has advantages over other sources of biomass, since they can be cultivated on

marginal lands and unused aquatic areas, generating new economic opportunities for poor soil and

Due to their relatively simple cellular structure, algae have a large biomass productivity per unit area.

Algae are of great ecological importance, since they act in the capture of atmospheric CO and can be used

as wastewater treatment, due to their capacity to remove nutrients, as their growth requires sunlight,

The purpose of this document is to provide an overview on how quality indicating parameters for algae

and algae products and intermediates relevant for chemical and bioenergy applications can be handled

and to identify the need for future standards development for chemicals, bioenergy and biofuels

This document does not provide instructions on handling of technical requirements in existing

The following documents are referred to in the text in such a way that some or all of their content

constitutes requirements of this document. For dated references, only the edition cited applies. For

undated references, the latest edition of the referenced document (including any amendments) applies.

EN 14214, Liquid petroleum products - Fatty acid methyl esters (FAME) for use in diesel engines and heating

EN 16734, Automotive fuels - Automotive B10 diesel fuel - Requirements and test methods

EN 16709, Automotive fuels - High FAME diesel fuel (B20 and B30) - Requirements and test methods

EN 16723-1, Natural gas and biomethane for use in transport and biomethane for injection in the natural

gas network - Part 1: Specifications for biomethane for injection in the natural gas network

EN 14103, Fat and oil derivatives - Fatty Acid Methyl Esters (FAME) - Determination of ester and linolenic

prEN 17477:—, Algae and algae products - Identification of the biomass of microalgae, macroalgae,

cyanobacteria and Labyrithulomycetes - Detection and identification with morphological and/or molecular

For the purposes of this document, the terms and definitions given in EN 17399:2020 and the following

ISO and IEC maintain terminological databases for use in standardization at the following addresses:

technical dossier, several pages long, about the product, usually prepared by manufacturer, directed to

provide all product approval information to the customer and usually attached to commercial contract

Note 1 to entry: Examples of models of RMS for some algae categories are reported in Annex A.

technical document, one (or few) page long, showing the technical (bio- and physicochemical)

parameters adopted to characterize the product and therefore being the paradigm of the Certificate of

Note 1 to entry: It includes ranges of different parameters used to define the product characteristics or applicable

Note 2 to entry: Examples of Models of TDS for some algae categories are reported in Annex B.

Note 3 to entry: In cases where the producer wants to make statements regarding the algal product as a bio-based

one (or few) page document issued from a laboratory (or laboratories) and reporting test results for a

specific lot, usually in front of TDS parameters, including references to test method

document issued with the aim of providing information about product compliance in respect of human

development that meets the environmental, social and economic needs of the present without

products of liquid, solid or intermediate consistency, obtained from algal biomass and containing

Note 1 to entry: For some preparations, the biomass to be extracted undergoes a preliminary treatment, for

energy from renewable non-fossil sources, namely wind, solar (solar thermal and solar photovoltaic) and

geothermal energy, ambient energy, tide, wave and other ocean energy, hydropower, biomass, landfill

[SOURCE: Directive (EU) 2018/2001 of the European Parliament and of the Council of 11 December 2018

liquid fuel for energy purposes other than for transport, including electricity and heating and cooling,

biofuels which technology is more innovative and less mature that are produced from feedstock which

Note 1 to entry: this feedstock includes algae if cultivated on land in ponds or photobioreactors.

an electronic document which has the sole function of providing evidence to a final customer that a given

biofuels, bioliquids and biomass fuels, the feedstock of which was produced within schemes which avoid

displacement effects of food and feed-crop based biofuels, bioliquids and biomass fuels through improved

agricultural practices as well as through the cultivation of crops on areas which were previously not used

Note 1 to entry: Crops which were produced in accordance with the sustainability criteria for biofuels, bioliquids

For multi-constituent natural ingredients, with variable composition, it is essential that the producers

provide clearly defined specifications in view of the range of variability of the components.

The variability should not change significantly and minimum levels of active components should be

In cases where the producer wants to make statements regarding the algal product as a bio-based product

A considerable attention has been paid, in recent years, to alternative feedstock for bioplastics

production. Microbial production of exopolysaccharides (EPSs) is an interesting field of research, in view

of the increasing demand for natural biofilm products for medical, and industrial applications. Microalgal

EPSs have potential antioxidant, antibacterial, and emulsifying activities and may be potentially obtained

from direct extraction from algae. Specifically, polymers such as starch or polyhydroxyalkanoates (PHAs),

which are already being used in plastic production, are of interest. Starch on the other hand is not a

polymer with plastic properties. It can be modified with additives to achieve thermoplastic properties or

used as a filler in other plastics. Similarly, saccharides found in algae can be used as feedstock for the

production of building blocks for bio-based plastic, such as lactic and succinic acid [1] [2] [3].

Moreover, PHAs are widely produced by heterotrophic bacteria. These compounds can replace

commercial plastics, such as polyethylene and polypropylene, because of their high biodegradability and

biocompatibility. One of the best-studied and commercially available biopolymers is poly-b-

hydroxybutyrate (PHB) see Figure 1, which constitutes the intracellular components of microbial cells,

and that can be accumulated in significant amount under specific growth conditions. PHAs possess

inherent thermoplastic properties and will not need to be modified to create a plastic film.

Properties will depend on the exact structure of the PHA, the purity of the extracted material, molecular

However, if a plastic is produced with PHAs and additives or fillers the degradation process can become

Life-Cycle analysis has been a valuable tool to assess the environmental impact of bio-plastics along their

life cycle. Taking into account the various challenges of this field and the constant development, a specific

methodology was proposed in order to assess the potential environmental impacts of the use of

alternative feedstocks (biomass, recycled plastics, CO ) in comparison to current feedstocks (oil and gas)

EN 16760 "Bio-based products – Life cycle assessment" is applicable for bioplastics produced from algae,

Beside LCA issues, methodology for assessing standards for alternative feedstock for bioplastic

production is a field still under development. The current production relies on few feedstocks, and there

is a need to enlarge the basket of potential alternatives, if the sector aims to continue on the current

It could be of interest to focus the analysis of the current legislative framework on the availability of

quality standards for alternative feedstock, including algae as potential interesting and widely available

Fertilisers are defined and regulated by Reg 1009/2019 EU (Fertiliser Product Regulation, FPR) [5].

Whereas microalgae only recently got this application due to high cost, and mainly as biostimulants,

seaweeds have long history of use as fertilisers since 3000 BC thanks to availability from wild gathering,

which action improved the sea life environment and helped to prevent the accumulation of dead seaweed

According to FPR, algae are included together with plants as i) raw material for EU fertiliser product or

ii) input material for the production of biogas in anaerobic fermenters, from which the digestate can be

contained in EU fertiliser product. However, in both cases cyanobacteria (“blue-green algae”) are

excluded; this gap excludes actually Arthospira sp. (Spirulina) from EU fertiliser and might be fixed by

appropriate amendment of FPR e.g. inclusion of safe cyanobacteria in microorganism category. More

Plant biostimulants are substances, mixtures and micro-organisms which, differently from straight

fertilisers, are not as such inputs of nutrients, but nevertheless stimulate plants’ natural nutrition

processes. They act in addition to fertilisers, with the aim of optimising the efficiency of those fertilisers

and reducing the nutrient application rates and are by nature more similar to fertilising products than to

most categories of plant protection products. Such products are therefore eligible for CE marking under

Reg 1009/2019 and excluded from the scope of Reg (EC) No 1107/2009 on Plant protection products

Plant biostimulants constitute Product Function Category (PFC) 6 of fertilisers, products made to

stimulate plant nutrition processes independently of the product’s nutrient content with the sole aim of

improving one or more of the following characteristics of the plant or the plant rhizosphere:

An example of main product requirements and conformity assessment for a plant biostimulant composed

of algae-based material (under FPR) to be marketed as EU fertiliser is given in Annex D.

A table of regulated contaminants filled from Reg 1009/2019 EU is given in Annex E.

The product characteristics specified from clause 5.2 to clause 5.5 should comply with the relevant

In case the product characteristics are referred to algae and algae products raw materials, existing

standards are referenced when applicable and recommendations for possible developments provided.

In the current worldwide energy matrix, there is a strong dependence on non-renewable energy sources,

mainly coal, oil and natural gas. Considering the production of sustainable energy sources, the use of

biofuels has become an important alternative, due to a reduction in CO2 emissions into the atmosphere.

Biomass production aimed for biofuels has general sustainability standards: ISO 13065 as well as

EN 16214-1, EN 16214-3 and EN 16214-4, where the first is applicable to all types of bioenergy.

Concerning liquid biofuels, it is usual to classify them as first, second and third generation. The most well-

known first-generation biofuel is ethanol, extracted from the fermentation of sugar and starch present in

plants in addition to biodiesel produced from oilseed plants. Second-generation biofuels are those

produced from the processing of the lignocellulosic fraction of biomass from higher plants. Biofuels from

Algae are explicitly mentioned in The Renewable Energy Directive recast (RED II) [6] as feedstock for the

production of biogas for transport and advanced biofuels, and can be counted twice if cultivated on land

in ponds or photobioreactors. Additionally, algae are listed in RED II as feedstock that can be processed

only with advanced technologies. Feedstock that can be processed into biofuels, or biogas for transport,

with mature technologies, such as used cooking oils and animal fats, have a share limited to 1,7% (energy

Bioethanol, biohydrogen, biodiesel and biogas (biomethane) have been proposed from algae through

processes such as fermentation, dark fermentation/photobiological production, lipid

extraction/transesterification and anaerobic digestion, respectively. On the other hand, different

thermochemical processes have been proposed for algae, such as pyrolysis, gasification, torrefaction and

hydrothermal liquefaction, depending on process conditions (pressure, temperature, reaction time,

oxygen availability and feedstock water content, among others). Thermochemical conversion processes

yield bio-oil (which can be eventually converted in drop-in liquid biofuels), biogas/syngas and char.

There is still need for algae-based process development and intensification in order to make full use of

the wide range of bio-based products, biofuels and environmental services algae and algae products can

generate (such as CO and other GHG biosequestration, waste water treatment – phycoremediation- and

heavy metals tertiary treatment, among others). Besides bioenergy production from algae, a wide range

of commercially valuable bio-based products/materials and/or high added value products can be

extracted, fractionated and purified, following the biorefinery approach. For commercial viability, a

matrix approach leading to numerous products is preferred for successful operation of algal biorefineries.

Fuels are characterized by energy density and technical parameters related to engine suitability (e.g.

No algae fuels are currently present in the market even if several Institutions (EU Commission, U.S.

Department of Energy) are interested and several Companies are working on that topic. According to

available literature, algae derived fuel feedstock allow for entering in already developed conversion

pathways, e.g., gaseous fuels like biomethane, and liquid fuels for diesel substitution like biodiesel or

It is worth to note that algae are considered for their photosynthetic potential as alternatives to terrestrial

plants (the actual main source of biodiesel, hydrogenated vegetable oil (HVO) and biogas besides waste

products) whereby the carbon-based molecule is biosynthesized converting solar energy in chemical

energy. Algae have neither to be considered as an intermediate nor as a finished fuel, but as a raw material

for certified fuels production, therefore no algae specific standards have to be mentioned in this section.

NOTE The only relevant exemption is represented by the aviation sector. In aviation not only the final fuel, but

The American Society for Testing and Materials (ASTM) issued two technical norms regulating the sector:

ASTM D4054 (Standard Practice for Qualification and Approval of New Aviation Turbine Fuels and Fuel

Additives), which describes the qualification process for an alternative fuel to be considered compliant

for use in ASTM D7566– 17a (Standard Specification for Aviation Turbine Fuel Containing Synthesized

Currently eight production pathways are already fully certified for blending with fossil aviation jet fuel.

These aviation biofuels are drop-in fuels: they can be directly blended with fossil (ASTM D1655:

At the time of writing, no specific algae-based pathway results certified for aviation [7].

A first categorisation of liquid fuels can be performed on the base of their possibility to be directly mixed

to regular fuel without specific limitations. The term “drop-in” fuel is generally used to describe an

alternative fuel, that can be blended into a regular fuel, without compromising any functionality of the

engine. Hydrogenated Vegetable Oil (HVO) is usually recognised as a drop-in fuel, while biodiesel and

The final characteristics of the alternative fuels, which derive from the feedstock/conversion process

couple, determines whether the final product can be considered a drop-in fuel or has to respect a blending