Report lca tools for sustainable procurement final 20100331

LCA related sources and instruments in

Sustainable Procurement Criteria

Niels Jonkers, Eszter Tóth, Ckees van Oijen

Amsterdam, 31 March 2010

IVAM

research and consultancy on sustainability

Plantage Muidergracht 14 - 1018 TV Amsterdam - Postbus 18180 - 1001 ZB Amsterdam

Tel. 020-525 5080, Fax 020-525 5850, internet: www.ivam.uva.nl, e-mail: [email protected]

L C A - B A S E D I N S T R U M E N T S I N S U S T A I N A B L E P R O C U R E M E N T C R I T E R I A

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Colofon ISO Doc. nr. 1024o

Titel LCA related sources and instruments in Sustainable Procurement Criteria

Auteur(s) N. Jonkers

Interne review door C. van Oijen

Deze rapportage is tot stand gekomen /Onderzoek uitgevoerd in opdracht van Agentschap NL

Contactpersonen opdrachtgever:

Nico van den Berg (Agentschap NL)

Voor meer informatie over deze rapportage kunt u contact opnemen met:

Niels Jonkers, [email protected] of 020-525 5080

Gegevens uit deze rapportage mogen worden overgenomen mits onder uitdrukkelijke bronvermelding.

IVAM UvA B.V. aanvaardt geen aansprakelijkheid voor eventuele schade voortvloeiend uit het gebruik

van de resultaten van dit onderzoek of de toepassing van de adviezen.

I V A M R E S E A R C H A N D C O N S U L T A N C Y O N S U S T A I N A B I L I T Y

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Inhoud

1. Introduction 4

1.1 Background 4

1.2 Goal of the project 4

2. Methods 5

2.1 Reference list 5

2.2 Evaluation matrix for instruments and tools 6

2.3 National and international trends 6

3. Results 7

3.1 Reference list 7

3.2 Evaluation matrix for instruments and tools 7

3.2.1 Description of the matrix 7

3.2.2 Use of LCA-based instruments in criteria 8

3.2.3 Usability of new LCA-based instruments in criteria 9

3.2.4 Possible pitfalls for the use of LCA-based instruments in criteria 11

3.3 National and international trends 11

3.3.1 Harmonisation of LCA in Dutch building sector 11

3.3.2 Comparing international Environmental assessment methods for buildings - BRE 12

3.3.3 Scoping Study on Sustainable Procurement Tools and Databases - Defra 12

3.3.4 Taking Green Procurement to the next level - SEMCo 13

3.3.5 Green Public Procurement in the EU - PwC 14

3.3.6 EU-project: Carbon Footprint tool for European Ecolabels 15

3.3.7 International Reference Life Cycle Data System (ILCD) Handbook 16

3.3.8 Directive on renewable energy sources 16

4. Conclusions and recommendations 18

References 21


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1. Introduction

1.1 Background

Since 2010, the national government aims to take sustainability into account in 100% of its procurement.

To put this sustainable procurement of products and services into practice, Agentschap NL has facilitated

the development of sustainability criteria for a number of product groups, commissioned by the Ministry

of Environment (VROM) (Agentschap NL, 2010).

General principles set up by VROM for these criteria documents are to use Life Cycle Thinking as the

approach to environmental criteria, and to prevent resolving one environmental problem by creating

another one elsewhere in the life cycle (shifting of burdens). In addition, the criteria should be as

transparent and verifiable as possible (VROM, 2009).

A tool that can contribute to the fulfillment of these principles is Life Cycle Assessment (LCA). However,

the performance of an LCA is a laborious task requiring extensive expertise, and does not seem to fulfill

the Ministry’s requirement of ‘proportionality’, stating that a reasonable degree of ambition should be

proportional to the effort needed to fulfill this ambition. In addition, a general aim of the government is

to decrease the bureaucratic and administrative workload for companies (VROM, 2009).

For these reasons, Agentschap NL has special interest in the use of LCA-based calculation tools, in which

the advantages of the holistic Life Cycle Approach of LCA can be combined with user-friendliness. In an

LCA-tool, the user does not need LCA-expertise, but should only provide input on parameters such as

energy and material use and waste generation, and the tool uses pre-calculated LCA scenarios to determine

the environmental profile of a product or service.

1.2 Goal of the project

The general question in the current project is: what is the role of LCA-based evaluation tools in (the

development of) Sustainable Procurement criteria?

Specifically, Agentschap NL has asked IVAM to first produce a reference list and characterization of all

the literature and other sources used in the existing Sustainable Procurement criteria documents. Next an

overview and description was made of a number of LCA-based tools which are or may be used in the

criteria. Finally, the national and international developments in this field are highlighted.

The deliverables in the project are the following:

(1) An Excel list with the inventory of all literature and other sources used in the existing sustainable

procurement criteria documents (versions of July 2009). The list includes a categorization of the

references on accessibility and usability

(2) An Excel matrix providing descriptions and characterization of LCA-based evaluation

instruments which are mentioned or used in the criteria documents, or may be used in the future

(3) A short report on the current national and international developments concerning the

development of LCA-tools and their application in sustainable procurement (this report).

(4) A presentation for the ‘sustainable procurement department’ of Agentschap NL on the results of

the project


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2. Methods

2.1 Reference list

A list was assembled in Excel with an inventory of all literature and other sources used in the sustainable

procurement criteria documents. The versions used were from July 2009. Since then updated versions

have been published, but the updates concerned mainly improvements in layout and not changes in the

criteria themselves. Therefore, the reference list produced in this project is still up-to-date.

A total of 52 criteria documents have been studied, concerning 45 product groups.

In addition to the sources in the reference lists, (for the documents on building construction and civil

works product groups) sources mentioned in footnotes and (clear) literature references in the texts were

included in the reference list. References to CPV-codes or legislation, norms and standards are not

included.

In the reference list, the following characterization of the sources is included:

(1) Title of the source

(2) Product group and criteria document

(3) Type of source (article, book, brochure, database, directive, report, website, etc)

(4) Source (name of website, journal)

(5) Public accessibility (free; free with license/costs; confidential)

(6) Keywords/subject

(7) Context/background (project, policy, legislation, company)

Due to time constraints, not all of the references could be characterized completely. For product groups

or sources that were considered less important, the Context, Keywords and Source have not been

specified.

The following types of sources were considered as specifically important for the current project:

-sources mentioned in more than one product group

-sources concerning sustainability evaluation instruments (LCA, LCC, Cost Benefit Analysis, models, etc) -sources on (eco)labels or certificates -sources with international reputation -sources with important general guidelines/advice from authoritative organizations

The following product groups received specific attention, as LCA-based tools are likely to exist for these

types of products:

-Groenvoorzieningen (Green spaces)

-Kantoorgebouwen (beheer en onderhoud; huur en aankoop; nieuwbouw; renovatie) (Office buildings:

management & maintenance, rental & purchase, renovation, to be newly built)

-Bouw/sloop (Construction Works, Demolition of buildings)

-Kunstwerken & Waterbouwkundige constructies (Hydraulic engineering constructions)

-Conserveringswerken (Preservation works)

-Gemalen (Pumping stations)

-Wegen (Roads)

-Openbare verlichting (Public lighting)

-Grondwerken bouwrijp maken en sanering/bodemreiniging (Earthworks, preparation of building sites &

remediation, soil decontamination)

-Waterzuiveringsinstallaties, slibbehandeling (Water purification & sludge treatment plants)


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2.2 Evaluation matrix for instruments and tools

In order to give some insight into the potential of LCA-based instruments for application in sustainable

procurement criteria, a matrix was produced in which a large number of existing instruments were listed

and characterized. This matrix should allow developers in the future to evaluate the current possibilities

and limitations of the instruments, and to judge if an instrument could be suitable to incorporate into a

specific criterion.

Both instruments mentioned in the criteria documents, used in the criteria, and found in other sources are

considered.

In addition to purely LCA-based instruments, also instruments in which the life cycle approach plays a

major role are evaluated, e.g. Ecolabels and guidelines.

The following aspects of the instruments have been characterized:

a. Field of application (product group, material, work or service)

b. Background of the instrument (developer, methodological background e.g. LCA, Environmental

Product Declaration (EPD), ecolabel)

c. Database used, organization responsible for database

d. Accessibility of instrument

e. Subject of the instrument (what is evaluated?)

f. Is the evaluation qualitative or quantitative?

g. Unit of the result

h. Environmental effects considered in the instrument

i. Role of LCA in the instrument

j. Limitations of the instrument

k. Procurement phase in which instrument can be used

l. Is the instrument usable for more product groups?

m. Reference

The main sources used for the description of the instruments were the websites of the instrument and

manuals.

In some cases, not enough information on the instrument was available to fill in the matrix completely.

Due to time constraints, instruments that were identified in the final stage of the project were not fully

characterized either.

2.3 National and international trends

To give an indication of national and international trends in the development and application of LCA-

based instruments a (limited) amount of international reports on the subject were reviewed and IVAM

colleagues were consulted.


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3. Results

3.1 Reference list

The inventory of literature and other sources from all criteria documents resulted in a list of almost 700

references. Around 80 references were mentioned in more than one document.

The amount of references in the documents varies between 4 and 45, with an average of 15. There is no

clear relation between the amount of literature used and the amount of criteria formulated. The clarity and

completeness of the references is also variable between documents. Most of the mentioned references are

websites, some of which are no longer available.

Most of the references are freely accessible; for some of the instruments, norms or standards, a licence or

fee must be paid.

In general the traceability of the reference is good, but in a number of cases the reference is vague, e.g.

referring to the general website of a ministry instead of a specific page or document on the site.

Scientific publications are found only sporadically in the references.

Most of the references (>80%) are not LCA-related.

In 10 product groups, LCA-based instruments are mentioned in the references. In 22 product groups,

instruments like (eco)labels or certification schemes are mentioned. 23 product groups contain references

to official guidelines or toolboxes.

In the separate Excel-file containing the reference list, sources related to LCA have been marked in green.

Those references have also been listed in an extra worksheet.

Product groups marked orange were considered as the most relevant for the current project and have

been studied in more detail. Cells marked in blue indicate that the list of sources is identical to those of an

other criteria document.

3.2 Evaluation matrix for instruments and tools

3.2.1 Description of the matrix

The instrument evaluation matrix is provided in a separate Excel-file, in which a total of 101 instruments

are listed. The instruments mentioned in the criteria documents (43 in total) are listed first and are marked

green.

The instruments are divided into 3 categories:

1. Instruments for the procurement of specific products/services: LCA-related instruments

2. Instruments related to (eco)labels and certificates

3. Instruments related to official guidelines, toolboxes and management systems

Of the instruments mentioned in the criteria documents, 12 belong to the first category. 15 instruments

related to ecolabels were mentioned in the criteria documents, and most of the mentioned instruments

were of the third category (23 instruments).


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In all of the criteria documents, at least one type of instrument is mentioned.

All of the instruments found in the criteria documents are characterized in the matrix. However, due to

time constraints, not all of the additional instruments that were found are fully characterized.

In an additional worksheet of the Excel-file, an overview is given of which instruments are mentioned in

which criteria documents.

3.2.2 Use of LCA-based instruments in criteria

The Life Cycle Approach is present in most of the instruments in the evaluation matrix, albeit in different

forms.

For complex products such as buildings or construction works, instruments make use of full LCA

calculations, and often even additional sustainability aspects such as safety or future value.

For less complex products, instruments like Ecolabels are often used. In these labels, often requirements

for toxic ingredients reduction, biodegradability, renewability of resources or requirements for waste

treatment/recycling are included, which are part of the Life Cycle Approach. In for example the product

groups “Papier” (paper), (cleaning products in) “Schoonmaak” (cleaning services) and (lubricants in)

“Vaartuigen” (vessels), sustainable procurement criteria are based on Ecolabels (although the Ecolabel

itself is not a requirement, it can be accepted as proof of compliance).

Instruments such as guidelines or toolboxes are often mentioned in the criteria documents of product

groups related to services, such as maintenance. The Life Cycle Approach in this third category of

instruments is expressed in check lists addressing the origin of raw materials or waste treatment.

Of the LCA-based instruments mentioned in the criteria documents, only a few are actually used in the

criteria. In the criteria for “Renovatie Kantoorgebouwen” (office renovations) and “Nieuw te bouwen

kantoorgebouwen” (newly built offices) criteria are set for minimum scores in one of the tools GPR-

Gebouw or GreenCalc+, with ‘bonus points’ given when the score is better than the minimum

requirement. GPR-Gebouw and GreenCalc+ are also mentioned in the criteria document for

“Kantoorgebouwen Beheer en Onderhoud” (maintenance of office buildings), but are not in the actual

criteria of that product group.

In the criteria for “Kunstwerken” (infrastructural works) and “Waterbouwkundige Constructies” (water

works), and “Wegen” (roads), a “gunningscriterium” (‘bonus criterion’) is formulated in which a non-

specified score in an LCA analysis is required to score ‘bonus points’ (the specification is left to the

judgment of the user). The criteria suggest to use the LCA-based tool DuboCalc for this purpose.

Although the LCA-based instruments are used in criteria for only 3 product groups, the instruments are

mentioned in 5 other documents as well, which indicates their potential for further use. These product

groups all concern more complex products such as buildings and construction works.

Instruments of category 2 (ecolabels etc.) are incorporated more often into the actual criteria. Especially

energy labels or energy certificates are regularly required for energy consuming equipment or for buildings.

However, this is not always done in a consistent way. One reason for this is probably that the product

groups covered by an energy label are limited, so the label cannot be used for all sustainable procurement

product groups.

In the product groups “Hardware”, “Netwerken/telefonie” (networks/ telephone services) and

“Reproductieapparatuur” (reproduction equipment), an Energy Star label is in the criteria, but for the

product group “Grootkeukenapparatuur” (catering equipment) the criteria document mentions that the

requirements for an Energy Star label are often not ambitious enough, and therefore it is not used, and a


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different maximum energy use is defined as criterion. In the criteria document for “Audiovisuele

apparatuur” (audiovisual equipment), the Energy Star label is not mentioned at all, but energy

consumption requirements are based on norms of the International Electrotechnical Commission (IEC).

Energy consumption requirements for “Openbare verlichting” (public lighting) are defined as a minimum

label D in the “Handleiding Energielabeling Openbare Verlichting”, as developed by Agentschap NL and

the “Nederlandse Stichting Voor Verlichtingskunde” (NSVV). The label is based on an international norm

called SLEEC (Street Lighting Energy Efficiency Criterion, EN13201-5).

In the product group “Huur en aankoop kantoorgebouwen” (office buildings purchase & rental), an

energy label C or better is a requirement. This label is based on the “Besluit Energieprestatie van

Gebouwen (BEG)”. A requirement for lamps in that product group is a light efficiency of 50 lumen/Watt

(apparently not based on any label).

For the related product groups “Renovatie Kantoorgebouwen” (office renovations) and “Nieuw te

bouwen kantoorgebouwen” (newly built offices), energy consumption requirements are indirectly set with

the required scores for the “sustainability of a building” tools GreenCalc+ or GPR-Gebouw.

For “Dienstauto’s” (cars), an energy label (A or B, sometimes C) is required based on the “Nederlandse

besluit etikettering energiegebruik personenauto’s”, which is in turn based on the European Directive

1999/94/EC.

3.2.3 Usability of new LCA-based instruments in criteria

Some general requirements can be formulated for the use of LCA-based instruments in sustainable

procurement criteria.

First, the evaluated product or service should have a significant environmental impact. A recent European

study called “Environmental Impact of Products” (EIPRO, 2006) gives some insight into the relative

impacts of products in LCA terms. The objective of this project was to identify those products that have

the greatest environmental impact throughout their life-cycle, from cradle to grave, based on a life-cycle

analysis of the products consumed in the European Union by private households and the public sector.

Three product groups were identified as having the greatest environmental impact:

• food and drink

• private transport

• housing

These three areas are of approximately equal importance, and together are responsible for 70–80% of the

environmental impact of consumption.

Within the area of food and drink, meat and meat products are the most important, followed by dairy

products.

Within transport, the greatest impact is caused by cars, despite major improvements in the environmental

performance in recent years, especially on air emissions.

The products within ‘housing’ include buildings, furniture, domestic appliances, and energy for purposes

such as room and water heating. Energy use is the single most important factor, mainly for room and

water heating, followed by structural work (new construction, maintenance, repair, and demolition). The

next important products are energy-using domestic appliances, e.g. refrigerators and washing machines.

For the remaining product groups investigated, uncertainties are higher, but most of the evidence suggests

that clothing ranks highest, accounting for 2-10% of total environmental impact.


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A second rationale to justify development or implementation of LCA-based tools is that the product or

service to be evaluated is relatively complex: it should not be immediately obvious which choice is the

most environmentally benign. For simple products, instruments of the Ecolabel type are more suitable,

such as the Euro classification for cars, or the Energy Star label.

In contrast, for a product such as weed control (product group “Reiniging openbare ruimte”), it is not

immediately obvious if chemical techniques (using herbicides such as glyphosate) or mechanical or

thermal methods (e.g. brushing or burning) have the lowest environmental impact. The comparison

between the ecotoxicological effects of the chemicals and climate change effects of the fuel consumption

can be modeled with LCA techniques. The result will depend on a number of parameters on consumption

amounts, desired weed control quality of the area to be treated, and local circumstances such as the

nearness of surface water.

Currently, the criterion for weed control in the product group “Reiniging openbare ruimte” is based on a

qualitative instrument: the guideline “Duurzaam OnkruidBeheer op verhardingen (DOB)”.

A third factor (related to the second) which justifies the use of LCA-based instruments is when complex

products must be compared, but a clear quantitative unit is not available. Buildings are a good example, as

the sustainability of a building cannot be simply expressed in terms of energy or material use. Most of the

LCA-based tools listed in the evaluation matrix also take into account aspects such as safety or future

value of a building. The result of calculations with such a tool can simplify comparisons or ranking of

buildings.

Based on these considerations, the following recommendations for the use of LCA-based instruments in

the criteria can be made:

• the building sector perfectly fits the requirements for the use of LCA-based tools in criteria. In this

sector, the use of LCA-tools is already common practice.

• in the transport sector, current criteria use Euro classification for vehicles. However, it does not

prescribe which transport system should be used for which purpose (an exception is the product group

“Dienstreizen”). A tool which calculates the total emissions of a company that uses a relatively complex

combination of transport systems (e.g. a post delivery company) could rank different companies, and set

targets to motivate companies to use the most environmentally benign transport method for each specific

service. This instrument could have the form of a carbon footprint tool, as the environmental effects

would be caused almost exclusively by fuel consumption.

• as the food and drink sector has one of the highest contributions to the total environmental impact of

products, and the product group is very complex, an LCA-tool addressing this product group can be

considered.

A number of instruments in the form of labels exist for this product group, focusing mainly on Fair Trade

or biological production. However, more quantitative (LCA-based) tools for this sector are not known. A

first step in the direction of such a tool is the recently developed “Vleeswijzer”, which gives both a CO2

emission score and an animal welfare score for different types of meat (Vleeswijzer, 2009).

Currently, the criterion in the product group “Catering” is that 40% of the assortment must be biological

products (as defined in EU-regulation nr. 834/2007), and that at least one other criterion is fulfilled from

a list of various criteria on animal welfare, energy consumption or transport distance.

Some of these ‘optional’ criteria could be quantified with LCA-based tools, which would allow a more

objective comparison of e.g. vegetables produced in a Dutch greenhouse (large energy consumption) or in

Spain (large transport distance). It is clear that not all aspects of sustainability could be modeled with an

LCA-based tool: e.g. animal welfare or the consequences of the use of genetically modified organisms

cannot be quantified in LCA terms.


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• for weed control (product group “Reiniging openbare ruimte”), the existing quantitative LCA-tool would

give a more transparent and objective evaluation of different weed control methods than the current

qualitative criterion (the DOB guideline) does.

• waste treatment is a topic that has been extensively modeled in the LCA society. In procurement

procedures related to biowaste, an LCA-based tool called the “CO2-reductie composteren en vergisten

van gft-afval”-model which calculates CO2 emissions of various biowaste processing methods is used by

several municipalities in the Netherlands to evaluate tenders by competing biowaste processors.

In the current sustainable procurement criteria, waste treatment is addressed in many product groups, but

no consistent approach is taken. A possibility would be to link the criteria for waste treatment to the LCA

calculations done within the framework of the MER-LAP (Landelijk Afvalbeheerplan), in which minimum

environmental standards were defined for the processing of many types of waste (VROM, 2002). These

data could be transformed into a generic tool for waste treatment applicable to all product groups.

• Life Cycle Costing is a relatively new development within the LCA community. As sustainability also

comprises optimization of the ‘profit’ side of a product, it may be considered to include this type of tool

in the sustainable procurement criteria. A first example is the “afwegingsmodel wegen”, in which a Total

Cost of Ownership (TCO) approach is part of the assessment/evaluation.

3.2.4 Possible pitfalls for the use of LCA-based instruments in criteria

The use of LCA-based instruments in the criteria has some possible drawbacks.

First, certain specific qualitative sustainability aspects which are not well addressed in the LCA

methodology may be ‘forgotten’.

Secondly, when a sustainability criterion is simplified to a certain minimum score in a tool, it becomes

unclear how this score is reached. While this gives the applicant/supplier more freedom to incorporate

sustainability in the way they see fit (a possible advantage), this may reduce the procurer’s control over and

insight in the sustainability of a product. For example, the tool GPR-Gebouw: gives a broad overview of

the environmental performance of a building, but less insight into what a good score means: is a good

score for Environment due to material use or due to waste treatment? The weighting of different

sustainability indicators is left entirely to the instrument/ tool maker.

3.3 National and international trends

The following is a discussion of some current trends in the field of development and implementation of

LCA-based tools. As only limited time was devoted to this part of the study, the overview is only meant to

show some examples of current activities in the field, and is far from complete.

3.3.1 Harmonisation of LCA in Dutch building sector

An important national trend concerning the various LCA-based tools in the building sector is the current

progress towards harmonization of these tools. This harmonization occurs at several levels.

First, the developers of the tools (a.o. GreenCalc, EcoQuantum, GPR Gebouw and DuboCalc)

collaborated in 2007/2008 on a common manual for evaluation of environmental performance of

buildings by means of LCA (IVAM, 2007).

A next (ongoing) step is the development of a harmonized database containing environmental data on

materials and building components, which will be used as input for all instruments. Maintenance and

updating of the database will be centrally organized. The following instruments will make use of the

harmonized database: GreenCalc, EcoQuantum, GPR Gebouw, DuboCalc and BREEAM-NL.


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Parties involved in this harmonization project are: Dutch Green Building Council, Stichting

MRPI/NVTB, Rijkswaterstaat, W/E adviseurs, NIBE, IVAM, Onderzoeksinstituut OTB (TU Delft) and

VROM/WWI.

Additional harmonization activities are focusing on the unit of comparison in order to be able to compare

the environmental performance of different types of building, for example a flat with a bungalow.

Finally, more harmonization is still needed on the weighting of scores for different environmental impact

categories to arrive at one final score. Some instruments use the Distance-to-Target method (how far is an

environmental effect away from the policy goal), while other instruments use a monetarization method

(costs of an environmental effect).

3.3.2 Comparing international Environmental assessment methods for buildings - BRE

In a recent report by BRE, some of the internationally best-known methodologies for assessing the

sustainability of buildings are compared (Saunders, 2008). The methods include BREEAM (UK), LEED

(USA), Green Star (Australia) and CASBEE (Japan). Both LEED and Green Star were originally based on

BREEAM, and diverged somewhat from it in later versions. CASBEE has independent origins and

focuses strongly on issues which are of particular importance in Japan, such as earthquake resistance.

The main finding is that the application of sustainability assessment methods in countries other than

where they were designed does not function well. A high variation exists between the systems for the

same “grade”, for example between BREEAM ‘Excellent’, LEED ‘Platinum’ and Green Star ‘Six Stars‘. In

general, the systems give the lowest scores to buildings in the model’s country of origin, and higher scores

to foreign buildings.

These differences can be partly explained by the fact that each system relies on local regulatory minima to

achieve certain aspects of performance. These aspects are therefore omitted from the grading as they are

taken as a ‘given’. In other countries, regulations are different, and certain important sustainability features

may be completely missed in the evaluation. Buildings might be awarded much higher ratings than they

deserve when compared to other buildings that merely follow local regulations, guidelines and standard

practice.

Multinational building corporations are using sustainability evaluation systems regularly, but usually base

the choice of a system on the location of their corporate headquarters. In order to improve international

comparability of buildings, harmonization of the models is needed. More transparency will allow better

comparison of the relative merits of each system which will help to promote the sharing of best practice.

Facilitating this should therefore be a key future role for an independent body such as the World Green

Building Council working closely with all scheme operators. Such an organization should work towards:

· the development of a set of standards which exclude as much ‘home territory regulatory effects’ as

possible to facilitate comparison

· improve communication between the various scheme operators, to facilitate sharing of best practices

and setting key common minimum standards

· dual or multi certification to allow multinational companies to demonstrate the environmental

performance of their buildings in the countries in which they are based and compare more easily with the

buildings they occupy overseas

3.3.3 Scoping Study on Sustainable Procurement Tools and Databases - Defra

In 2009, the British Department for Environment, Food and Rural Affairs (Defra) published a study

reviewing the currently available Sustainable Procurement Tools and Databases (Defra, 2009). First, a

literature search was done to make an inventory of what is currently available for public-sector procurers.


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Then, procurement experts were consulted to find out which tools they actually use, and what aspects and

functionality they find useful, and what else might be required.

The report reviewed, assessed and categorized 78 instruments. Many of the tools reviewed consisted of

general guidance, flow diagrams/procedural guidance and risk assessments. To a lesser extent, tools were

found that provided product specifications. The main gaps appear to be on whole-life costing and life

cycle assessment, or other similar quantitative analysis. Although such tools do exist, many of them only

provide the background or reasons behind doing whole-life costing, rather than actually assisting the

procurer to calculate the costs.

The procurement stage in which most tools can be applied was mainly in the middle of the procurement

cycle; setting specifications, and then assessing and awarding contracts. This is the phase in which

comparisons are undertaken, scoring of competing tenders is made and quantitative analysis can be done.

Similar results were found in the current Dutch study, see section 3.2.1.

From the (British) user consultation, the following needs were identified:

• incorporating life cycle analysis more firmly into tools, to improve in understanding environmental

impacts and avoid potential shifting of environmental burdens,

• greater understanding and inclusion of whole-life costing in the procurement process, and suitable tools

to allow for this,

• the efficiency and usefulness of a tool should be measured.

• a well-defined, central and stand-alone tool library or gateway, which can be updated when necessary, is

required. The library could potentially be tailored to measure tool use frequency, and ‘rating’

• cultural changes are needed: at present sustainability is not fully embedded into the minds of all

procurement professionals. In the procurement cycle, it should always be considered that the product or

service may not be needed at all. Procurement should not be viewed in two versions (conventional and

sustainable); rather, all procurement should inherently be sustainable.

It was also mentioned that the British Standards Institute (BSI) is developing a Procurement Standard,

BS8903. It will be relevant to public, private and third sector organisations and include case studies and

best practice examples.

No mention was made of any specific product groups that require more extensive evaluation tools.

3.3.4 Taking Green Procurement to the next level - SEMCo

A recent study by the Swedish Environmental Management Council (SEMCo, 2009) reported on their

experiences with Green Procurement in Sweden. In recent years, green procurement has emerged as a

potentially powerful tool, for gaining environmental and sometimes even cost benefits and to minimize

risks, and also driving research into new and innovative technologies.

SEMCo develops criteria are for three levels of stringency and ambition:

• Level 1: Basic requirements - covering products that fulfill the basic level of environmental performance

(somewhat exceeding legal requirements).

• Level 2: Advanced requirements - covering products in the best environmental performance quartile

(25%), about the same level as current eco-labelling criteria.

• Level 3: Spearhead criteria - covering products at the absolute forefront of existing environmental

developments/innovations, based, for example, on the concept of Best Available Technology (BAT).

Life Cycle Costing is normally included in procurement criteria developed by SEMCo, when found

relevant. SEMCo has developed a general tool for LCC calculations based on the net present value

method, applicable to most products. LCC calculations are best suited to products with high energy

consumption in use, e.g. vehicles, lighting, and office machines, where operating and maintenance costs

are relatively high during the product life cycle, and are therefore important to consider in the


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procurement process. It can also be used to estimate how much an environmentally compatible, green

alternative would cost in comparison with a conventional product – maybe even resulting in a cost saving

rather than an increase.

The report stresses that in order for procurement activities to be credible and a driving force in

environmental work, the use of environmental criteria should be checked and followed up. It is important

to formulate environmental criteria that can be verified and checked, and that purchasers have

information on the type of verification to request from suppliers. Too often, the implementation and

follow-up of environmental criteria for the contract duration are not handled in a satisfactory way.

The documentation for substantiating compliance with requirements in green procurement should be

further improved. Environmental management systems (EMSs) focusing on the environmental

performance of an organisation and environmental product declarations (EPDs) focusing on the

environmental performance of goods and services have considerable potential for greater use in

procurement contexts.

The use of EMSs in green procurement is generally felt to be problematic, as the demands placed on

EMSs in practice usually lack a direct connection to the subject matter of the contract. Many

organisations, especially small and medium-sized companies (SMEs) that have introduced EMSs for the

purpose of gaining a market advantage in public and private procurement activities are disappointed, as

the existence of an EMS usually does not lead to the desired positive market effect.

EPDs are not commonly used yet as documentation or verification in green procurement. This is partly

because not many products have an environmental declarations and partly because of uncertainty

regarding the type of information to include in an environmental declaration, whether or not they are

available, and which suppliers can actually provide them.

The way forward for SEMCo’s work with procurement criteria will take three different paths – simplifying

criteria to make them more understandable and useful for a broader audience; continuing quality

maintenance and updating of the existing set of criteria; and developing procurement criteria further at

different levels of ambition (e.g. ‘spearhead criteria’) – all of which will contribute to transforming the

SEMCo procurement criteria “from being as complete as possible to the better practical application”.

3.3.5 Green Public Procurement in the EU - PwC

In 2008, PricewaterhouseCoopers, Significant and Ecofys, performed a study in which the current level of

Green Public Procurement (GPP) in the seven best performing Member States is monitored by measuring

quantitative levels of GPP (numbers and value of “green” contracts as compared to overall number and

value of public procurement contracts) and measuring the CO2 and financial impact of GPP (PwC, 2008).

This study focused on the Green-7 Member States (most actively involved in GPP, taking the inclusion of

environmental criteria in their procurement procedures seriously, both in policy and practice). Within

the majority of public institutions, the procurement policy contains an environmental section. Mostly

middle management or a higher level is responsible for realizing ambitions on sustainable procurement.

It is concluded that in 2006/2007, GPP in the Green-7 has led to average CO2 reductions of 25% and

average life cycle cost reductions of around 1%. This means that public purchasers have the possibility to

substantially reduce CO2 emissions, without this leading to extra costs of ownership. Although direct

purchasing costs are generally increased by GPP, this can be compensated by reductions in operational

costs in the long term.


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Although in The Netherlands the level of GPP in terms of procurement value is the lowest of the Green-

7, the CO2 reduction is the highest at 47%. This results from the large amounts of comprehensive green

purchases of electricity. In addition, the CO2 impact of textiles, cleaning services and paper are also high

in the Netherlands.

Regarding to the financial impact of GPP per product group in the Netherlands, positive impacts of

paper, textiles and electricity are compensated by the negative impact of cleaning services, construction

and transport. As a result, the overall financial impact arrives at a value very close to zero (-0,17%).

A general conclusion is that only for the product groups transport, construction and cleaning services,

GPP leads to reductions in both the CO2 impact and the financial impact. These are the product groups

that public purchasers could focus on when implementing GPP. However, when also taking into account

the product groups with the highest CO2 emissions (but where GPP leads to increased costs),

construction and electricity are the product groups to focus on.

3.3.6 EU-project: Carbon Footprint tool for European Ecolabels

A recent EU-project “EU Ecolabel—the Carbon Footprint Measurement Toolkit” (Service Contract N.

070307/220/486031/SER/G2) aimed at developing and checking a carbon footprint calculator procedure

suitable for the evaluation of greenhouse gas emissions as criteria in the EU Ecolabel (Baldo, 2009).

The main outcome of the project is a simple, flexible Excel-based preliminary tool, mainly aimed at policy

makers. The tool should give the possibility of a multilevel interpretation of the results, and in the

definition of rules in order to provide the most suitable and scientifically correct approach for the

inclusion of carbon footprint criteria in the EU Ecolabel.

The actual tool does not seem to be available yet. In the project, the tool was tested for 5 example

products. An example of the results (for the product ‘hard floor coverings’) is shown in the figure below.

The tool should be based on a central public database, such as the International Reference Life Cycle Data

System, developed by the European Commission's Joint Research Centre. Users and Ecolabel applicants

should also have the possibility to add their own data to the system. The responsibility for the functional

unit to be considered, the data input and interpretation of the results should lie with the AHWG (ad hoc

working group) which is responsible for the revision of the criteria of a specific Ecolabel.

Although in this project a step is taken towards the wider application of LCA/carbon footprint in the

evaluation and comparison of the sustainability of products, some problems can be identified in the

approach.

First, no indication is given when a carbon footprint of a product would be useful. This decision will have

to be taken for each product separately.

Then, at each revision of each Ecolabel, an LCA specialist would have to participate in the AHWG, to

address the methodological questions concerning the carbon footprint calculations.

Finally, it is not clear what the exact function of the carbon footprint score should be: would it be purely

to compare products, or would a criterion be set with a maximum score (and how would that be

defined?).

For these reasons, it seems that the practical application of the carbon footprint calculator in Ecolabels

cannot be expected very soon.


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3.3.7 International Reference Life Cycle Data System (ILCD) Handbook

In March 2010, the European Commission's Joint Research Centre launched the International Reference

Life Cycle Data System (ILCD) Handbook (JRC, 2010). The handbook is a series of technical documents

providing detailed guidance on all the steps required to conduct a Life Cycle Assessment (LCA). The

Handbook’s main goal is to ensure quality and consistency of life cycle data, methods and assessments.

This was inspired by their Sustainable Consumption and Production Action Plan stating that “..consistent

and reliable data and methods are required to assess the overall environmental performance of

products..”. Its main target audience is LCA practitioners, data providers, and reviewers.

The existing ISO 14040/44 standards for LCA already provide a framework for Life Cycle Assessment.

However, the JRC is of the opinion that this framework leaves the practitioner with a too wide range of

choices that can change the results and conclusions. The ILCD Handbook will provide more guidance to

support consistent and robust results and coherent requirements derived from LCAs, and improve the

compatibility and consistency of data generation and reporting requirements. The Handbook also aims to

increase stakeholder acceptance of the tool LCA and its results.

3.3.8 Directive on renewable energy sources

In the European Commission Directive on the promotion of the use of energy from renewable sources

(2009/28/EC, formerly Biofuel Directive, EC, 2009), a target of a 20% share of renewables in final energy

consumption for the EU in 2020 has been set (for The Netherlands: 14%).

Among the options for renewable energy are biofuels. To determine whether a biofuel can be considered

as renewable, environmental sustainability criteria for biofuels and other bioliquids, have been developed

(Article 15). For example, the raw materials shall not originate from lands with a “high biodiversity value”

or “high carbon stock” (e.g. wetlands, peat land) areas.

In addition, the biofuel should lead to greenhouse gas emission savings of at least 35%, compared to its

fossil alternative. A calculation tool has been developed to determine the GHG emission savings for

various biofuels. An annex lists precalculated CO2-savings for common biofuels, e.g. bio-ethanol, rapeseed

biodiesel, palm oil biodiesel and biogas. Then, a calculation method is presented to determine the carbon

footprint of other biofuels by considering emissions during the whole life cycle: from emissions in

agriculture, processing, transport, land use change, avoided electricity production, carbon capture and

sequestration (CCS) and the use of the fuel. A third Annex presents a database with typical GHG

emissions for the various life cycle stages for a number of biofuels.


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Within the framework of the European Ecolabel, discussions are on-going to introduce this type of

calculation in the criteria as well, for example in order to quantify the renewability of raw materials for

biolubricants.


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4. Conclusions and recommendations

The background literature of all sustainable procurement criteria has been compiled in a reference list, and

amounts to around 700 references. Most of the references are not directly LCA related.

LCA-based instruments are regularly mentioned in the criteria documents, but are present in the actual

criteria in only a few cases (GPR-Gebouw, GreenCalc+, see paragraph 3.2.2). LCA-based instruments are

used for complex product groups, such as buildings, where the most sustainable alternative is not obvious.

Instruments such as (eco)labels and certificates are found more often in the criteria documents. These

instruments refer to more concrete products such as paper or cleaning agents.

Instruments of the category ‘guidelines and directives’ are found most often in the criteria documents, and

usually focus on services or activities such as maintenance and waste treatment.

Overall it can be concluded that although Life Cycle Thinking is present in all sustainable procurement

criteria documents, the actual quantitative assessment of sustainability using LCA-based tools is an

exception in the criteria. LCA-based tools could be developed further for the complex product groups,

where sustainability can be improved in different ways. For buildings, a number of tools are already

available, and further harmonization of the tools is in progress. For waste treatment, LCA studies exist,

and for specific applications LCA tools have been developed (e.g. a tool for biowaste treatment methods

(GFT, 2008), and LCA studies on different collection/treatment options for household waste (IVAM,

2009), and the studies for MER-LAP (2002)). No ready-to-use tool for waste as a whole could be found.

For the other more complex product groups, no directly applicable LCA-based tools could be found

either (for some specific products within product groups, tools do exist, e.g. such as the Vleeswijzer

(2009) within “Catering”).

National and international trends show the increase in the use of LCA-based tools (e.g. Carbon Footprint)

in Ecolabel criteria and in regulations such as the EU renewable energy directive. Efforts are on-going in

the harmonization of tools to arrive at common calculation methods (e.g. Dutch Green Building Council

or BREEAM International) and LCA databases (e.g. the EU-JRC International Reference Life Cycle Data

System).

Recommendations:

References

References in criteria documents could be structured more clearly. We propose to make different headings

for references related to:

• Laws, regulations, guidelines and norms

• LCA, LCC instruments, Life Cycle Thinking

• (eco)labels, certificates

In addition, the distinction between types of references can be made more clear:

• Literature: articles, books, reports

• Instruments, models, tools

• Websites of governmental or other institutes, ecolabel agencies, branch organisations, suppliers,

contacts with experts

References should also be checked for completeness (for example, in criteria document “Nieuw te

bouwen kantoorgebouwen”, references to the GPR-Gebouw and GreenCalc+ tools should be included in

the reference list).


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Tool evaluation matrix

In order to optimize the produced evaluation matrix for LCA-based tools for application by criteria

developers, the following improvements are suggested:

• Complete the data that is still lacking for the instruments that were described only briefly in the

matrix.

• Comparability of instruments could be improved by adding menus with a predefined list of

possible ‘answers’ for some of the columns (e.g. for ‘type of instrument’ or ‘environmental effect

categories addressed’).

• More information could be included on the type of user of the instrument (e.g. ‘certified auditor’

or ‘procurer’) and the level of input data needed (e.g.: ‘location visit’, ‘list of materials used’ or

‘check presence of certificate’).

• More technical details could be included, such as the system boundaries of the instrument (e.g. the

Dutch, European or world market), and representativeness of the data/method.

• A column could be added to further specify the type of instrument into the categories ‘LCA-based

tools’ ‘Labels and certificates’ and ‘guidelines and toolboxes’, which is now done with different

shades of green in the matrix. Also, an additional categorization could be made into the outcome of

the instrument: a classification (‘Excellent’, ‘class 7’ or ‘Gold’) a quantitative result ‘tonnes of CO2’

or ‘hectares land use’, or a non-quantitative result (‘the guideline was followed’).

• A glossary describing the main concepts (Substance/material flow analysis, Product

stewardship,…) and abbreviations (LCC, TCO,…) would be useful for non-expert users.

• For some of the toolboxes/guidelines a more in-depth study of the main tools and labels to which

those documents refer may give valuable insights (e.g. ‘Toolbox energiebesparing in de GWW-

sector’, ‘European Commission Green Public Procurement (GPP) Training Toolkit Purchasing

Recommendations’ and “Methodologische gids voor de aankoop (Belgische overheid, 2004)”.

Consistency of criteria

In the next revision of criteria documents, the consistency between criteria for different product groups

can be further improved. Some sustainability aspects that play a role in many criteria documents are:

• criteria for vehicles: most criteria documents demand a Euro-4 classification or better, and do not

set criteria for “Het Nieuwe Rijden” (as the environmental benefit of the latter guideline has not

been proven). This is the case for criteria documents “Post”, “Leerlingenvervoer”, “Aangepast

vervoer”, “Verhuisdiensten”, “Beveiliging” and “Dienstauto’s”. However, for product group

“Reiniging Bedrijfskleding” transport is discussed in the document, but no criteria have been

defined.

• energy use requirements of electrical equipment could be more standardized, e.g. according to the

Energy Star labeling method. For some product groups (e.g. “Hardware” and “Netwerken”, Energy

Star is in the requirements, while for others it is deemed not ambitious enough

(“Grootkeukenapparatuur”, see also paragraph 3.2.2).

• waste treatment is an issue in virtually all product groups. In only a few criteria documents, a

specific criterion is formulated on this aspect (e.g. asphalt granules (teerhoudend asfaltgranulaat) in

“Kunstwerken”, “Waterbouwkundige Constructies” and “Wegen”). A general criterion for waste

treatment could be formulated e.g. on the basis of the MER-LAP (Landelijk Afvalbeheerplan) LCA

studies.

• lubricants are used in several product groups (e.g. “Vaartuigen” and “Waterbouwkundige

Constructies”). A consistent criterion for the use of (bio)lubricants could be formulated for these

product groups. A starting point for such a criterion could be the existing ecolabels for lubricants.


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LCA-tools

Possible new LCA-based instruments could be developed for the following subjects (see paragraph 3.2.3):

• waste treatment techniques

• transport methods

• weed control

• food and drink

• Life Cycle Costing

The use of instruments by public procurement professionals should be monitored and evaluated, by

questionnaires and interviews, to assess which problems the users encounter and what further needs they

have. These evaluations can give insight into

• the practical problems of finding the right input data for the instruments or with interpretation of

the results,

• whether any important sustainability issues are left out of the consideration (and additional

instruments are needed to quantify them),

• whether the instruments improve the freedom of an applicant to apply sustainability as they see

fit, or that the instruments have a restrictive effect,

• whether the public procurement professional still has insight into the exact contribution of a

product/service to sustainability, or that this information remains hidden behind a ‘single score’

(e.g. is it clear if a good score of a building in GPR-Gebouw is because of a low energy

consumption or because of the choice for sustainable building materials?)

• whether the instrument helps to clearly communicate on the sustainability of a product


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References

Agentschap NL, 2010a www.senternovem.nl/duurzaaminkopen/Criteria/

Agentschap NL, 2010b www.senternovem.nl/sustainableprocurement/index.asp

Baldo, 2009 Baldo G.L.; Marino, M.; Montani, M.; Ryding S.O. “The carbon footprint measurement

toolkit for the EU Ecolabel” Int J Life Cycle Assess (2009) 14:591–596.

Defra, 2009 Cadman, J.; Allen, J.; Tahsildar, N.: “Scoping Study on Sustainable Procurement Tools and

Databases”, report for Defra (Department for Environment, Food and Rural Affairs),

September 2009.

EC, 2009 Directive 2009/28/EC of the European Parliament and of the Council, on the promotion of

the use of energy from renewable sources, 23 April 2009.

EIPRO, 2006 JRC, “Environmental Impact of Products (EIPRO) - Analysis of the life cycle environmental

impacts related to the final consumption of the EU-25”, European Commission – JRC

(IPTS/ESTO), May 2006.

GFT, 2008 www.gft-afval.nl/html/co2rekenmodel.html

IVAM, 2007 Anink, D.; Van Ewijk, H.; Haas, M. “Handleiding Milieuprestaties Gebouwen”, collaborative

report IVAM, W/E & NIBE, 2007.

IVAM, 2009 Krutwagen, B.; Van Ewijk, H.; Jonkers, N. “Quickscan CO2-effecten inzameling integraal/

deelfracties huishoudelijk afval (kunststof, glas, textiel, papier, gft en hout)” IVAM report

0919, 2009.

JRC, 2010 European Commission, Joint Research Centre (JRC), European Platform on Life Cycle

Assessment “International Reference Life Cycle Data System (ILCD) Handbook”, 2010.

http://lct.jrc.ec.europa.eu/publications/

PwC, 2008 PricewaterhouseCoopers, “Collection of statistical information on Green Public Procurement

in the EU - Report on data collection results”, PwC, Significant and Ecofys, 2009.

Saunders, 2008 Saunders, T. “A discussion document comparing international Environmental assessment

methods for buildings.” BRE, 2008.

SEMCo, 2009 Swedish Environmental Management Council (SEMCo), “Green Procurement – Taking it to

the next level”, SEMCo report 2009:3.

Vleeswijzer, 2009 www.vleeswijzer.nl/wijzer/

VROM, 2009 VROM informatieblad “Duurzaam Inkopen - Actualisering proces van criteriaontwikkeling”,

2009.

VROM, 2002 Ministerie van VROM, “Milieueffectrapport Landelijk Afvalbeheerplan 2002-2012 MER-

LAP”, 2002.

Report lca tools for sustainable procurement final 20100331

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