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EN 17800:2022

(Main)

Life cycle cost (LCC) and life cycle assessment (LCA) for CO2 emissions in ductile iron pipe systems

Life cycle cost (LCC) and life cycle assessment (LCA) for CO2 emissions in ductile iron pipe systems

This document specifies the evaluation method of life cycle cost (LCC) and Life cycle assessment (LCA) of ductile iron pipes and fittings used for water applications and which are in compliance with EN 545.
LCC evaluation is based on concepts and methods developed in ISO 15686 5.
LCA evaluation is based on concepts and methods developed in ISO 15686 6, EN 15804:2012+A2:2019, EN ISO 14040 and EN ISO 14044.
In this document, LCA is limited to the evaluation of environmental impact due to CO2 emissions associated with the consumption of natural resources or energy and waste disposal. The other categories of impacts are not in the scope of this document.
Informative annexes are included in this document as a compilation of references, consensual factors, and scenarios with different DI pipelines.

Lebenszykluskosten (LCC) und Lebenszyklusanalyse (LCA) der CO2-Emissionen von Rohrsystemen aus duktilem Gusseisen

Dieses Dokument legt das Evaluierungsverfahren für die Lebenszykluskosten (LCC) und die Lebenszyklusanalyse (LCA) von Rohren und Formstücken aus duktilem Gusseisen fest, die mit EN 545 übereinstimmen und für die Wassernutzung vorgesehen sind.
Die Evaluierung der LCC basiert auf in ISO 15686 5 entwickelten Konzepten und Methoden.
Die Evaluierung der LCA basiert auf Konzepten und Verfahren, die in ISO 15686 6, EN 15804:2012+A2:2019, EN ISO 14040 und EN ISO 14044 entwickelt wurden.
In diesem Dokument beschränkt sich die LCA auf die Evaluierung der Umweltauswirkung durch die mit dem Verbrauch von Naturgütern oder Energie und mit der Abfallbeseitigung zusammenhängenden CO2 Emissionen. Die anderen Auswirkungskategorien fallen nicht in den Anwendungsbereich dieses Dokuments.
Dieses Dokument enthält informative Anhänge mit einer Zusammenstellung von Referenzangaben, Konsensfaktoren und Szenarien mit verschiedenen Rohrleitungen aus duktilem Gusseisen.

Coût du cycle de vie (CCV) et analyse du cycle de vie (ACV) pour les émissions de CO2 dans les systèmes de canalisations en fonte ductile

Le présent document spécifie la méthode d’évaluation du coût du cycle de vie (CCV) et de l’analyse du cycle de vie (ACV) des tuyaux et raccords en fonte ductile utilisés pour la distribution d’eau et qui sont en conformité avec l’EN 545.
L’évaluation du CCV est basée sur les concepts et méthodes développés dans l’ISO 15686-5.
L’évaluation de l’ACV est basée sur les concepts et méthodes développés dans l’ISO 15686-6, l’EN 15804:2012+A2:2019, l’EN ISO 14040 et l’EN ISO 14044.
Dans le présent document, l’ACV se limite à l’évaluation de l’impact environnemental dû aux émissions de CO2 associées à la consommation de ressources naturelles ou d’énergie et à l’élimination des déchets. Les autres catégories d’impacts ne font pas partie du domaine d’application du présent document.
Le présent document comprend des annexes informatives qui proposent une compilation de données consensuelles, des références et des scénarios utilisant différentes canalisations en fonte ductile.

Stroški življenjskega cikla (LCC) in ocena življenjskega cikla (LCA) cevnih sistemov iz duktilne železove litine zaradi emisije CO2

General Information

Status
Published
Publication Date
20-Dec-2022
ICS
77.140.75 - Steel pipes and tubes for specific use
91.140.60 - Water supply systems
Technical Committee
CEN/TC 203 - Cast iron pipes, fittings and their joints
Drafting Committee
CEN/TC 203/WG 10 - Environmental aspects
Current Stage
6060 - Definitive text made available (DAV) - Publishing
Start Date
21-Dec-2022
Due Date
22-Nov-2022
Completion Date
21-Dec-2022
Ref Project
SIST EN 17800:2023 - Life cycle cost (LCC) and life cycle assessment (LCA) for CO2 emissions in ductile iron pipe systems

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SLOVENSKI STANDARD
SIST EN 17800:2023
01-april-2023
Stroški življenjskega cikla (LCC) in ocena življenjskega cikla (LCA) cevnih
sistemov iz duktilne železove litine zaradi emisije CO2

Life cycle cost (LCC) and life cycle assessment (LCA) for CO2 emissions in ductile iron

pipe systems
Lebenszykluskosten (LCC) und Lebenszyklusanalyse (LCA) der CO2-Emissionen von
Rohrsystemen aus duktilem Gusseisen

Coût du cycle de vie (CCV) et analyse du cycle de vie (ACV) pour les émissions de CO2

dans les systèmes de canalisations en fonte ductile
Ta slovenski standard je istoveten z: EN 17800:2022
ICS:
13.020.60 Življenjski ciklusi izdelkov Product life-cycles
23.040.10 Železne in jeklene cevi Iron and steel pipes
91.140.60 Sistemi za oskrbo z vodo Water supply systems
SIST EN 17800:2023 en,fr,de

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

---------------------- Page: 1 ----------------------
SIST EN 17800:2023
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SIST EN 17800:2023
EN 17800
EUROPEAN STANDARD
NORME EUROPÉENNE
December 2022
EUROPÄISCHE NORM
ICS 77.140.75; 91.140.60
English Version
Life cycle cost (LCC) and life cycle assessment (LCA) for
CO emissions in ductile iron pipe systems

Coût du cycle de vie (CCV) et analyse du cycle de vie Lebenszykluskosten (LCC) und Lebenszyklusanalyse

(ACV) pour les émissions de CO dans les systèmes de (LCA) der CO -Emissionen von Rohrsystemen für

2 2
canalisations en fonte ductile Rohrsysteme aus duktilem Eisen
This European Standard was approved by CEN on 28 November 2022.

CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this

European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references

concerning such national standards may be obtained on application to the CEN-CENELEC Management Centre or to any CEN

member.

This European Standard exists in three official versions (English, French, German). A version in any other language made by

translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC Management

Centre has the same status as the official versions.

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, Türkiye and

United Kingdom.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATIO N
EUROPÄISCHES KOMITEE FÜR NORMUN G
CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels

© 2022 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN 17800:2022 E

worldwide for CEN national Members.
---------------------- Page: 3 ----------------------
SIST EN 17800:2023
EN 17800:2022 (E)
Contents Page

European foreword ............................................................................................................................................ 4

Introduction .......................................................................................................................................................... 5

1 Scope .......................................................................................................................................................... 6

2 Normative references .......................................................................................................................... 6

3 Terms, definitions and abbreviated terms .................................................................................. 6

3.1 Terms and definitions ......................................................................................................................... 6

3.2 Abbreviated terms ................................................................................................................................ 9

4 Basic concept of life cycle cost (LCC) for ductile iron pipe systems.................................... 9

4.1 Definition of life cycle cost ................................................................................................................. 9

4.2 Calculation method ............................................................................................................................ 10

5 Breakdown of life cycle cost ............................................................................................................ 12

5.1 Acquisition cost ................................................................................................................................... 12

5.2 Operation cost ...................................................................................................................................... 13

5.3 Maintenance cost ................................................................................................................................ 13

5.4 End of life cost or revenue ............................................................................................................... 13

6 Basic concept of life cycle assessment (LCA) for ductile iron pipe systems .................. 14

6.1 Definition of CO emissions impact .............................................................................................. 14

6.2 Calculation method of CO emissions .......................................................................................... 14

7 Breakdown of CO emissions ......................................................................................................... 15

7.1 CO emissions at the acquisition stage ....................................................................................... 15

7.2 CO emissions at the operation stage .......................................................................................... 15

7.3 CO emissions at the maintenance stage .................................................................................... 16

7.4 CO emissions at end of life stage ................................................................................................. 16

8 Key drivers for LCC and LCA evaluation ..................................................................................... 17

8.1 General.................................................................................................................................................... 17

8.2 Reference service life (RSL) ............................................................................................................ 17

8.3 Functional unit (FU) ........................................................................................................................... 18

8.4 Water leaks volume ........................................................................................................................... 18

8.5 Failure rate ............................................................................................................................................ 18

9 Quality of data ...................................................................................................................................... 18

Annex A (informative) Pumping cost and CO emissions with pump operation ........................ 20

A.1 Pumping cost ........................................................................................................................................ 20

A.2 Daily pumping energy ....................................................................................................................... 20

A.3 Total head loss ..................................................................................................................................... 21

A.4 CO emissions with pump operation ........................................................................................... 22

Annex B (informative) Scenarios of LCC and CO emissions with different DI pipelines ....... 23

B.1 Scenarios of LCC ................................................................................................................................... 23

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SIST EN 17800:2023
EN 17800:2022 (E)

B.2 Scenarios of CO emissions ............................................................................................................. 24

Annex C (informative) Water leaks and failure rate of ductile iron pipelines ............................ 25

C.1 water leaks evaluation ..................................................................................................................... 25

C.2 Examples of failure rates ................................................................................................................. 25

C.2.1 General ................................................................................................................................................... 25

C.2.2 Example in France .............................................................................................................................. 26

C.2.3 Example in Germany.......................................................................................................................... 26

C.2.4 Example in Spain ................................................................................................................................. 27

Annex D (informative) Circular economy, LCC and CO emissions .................................................. 28

D.1 General ................................................................................................................................................... 28

D.2 Conservation of mechanical characteristics in time .............................................................. 28

D.3 Recyclability ......................................................................................................................................... 28

D.4 Worldwide scrap collecting ............................................................................................................ 28

D.5 Optimum hydraulic conveyance capacity .................................................................................. 29

D.6 Optimum pipe wall thickness ......................................................................................................... 29

D.7 Preservation of soil ............................................................................................................................ 29

Bibliography ....................................................................................................................................................... 30

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SIST EN 17800:2023
EN 17800:2022 (E)
European foreword

This document (EN 17800:2022) has been prepared by Technical Committee CEN/TC 203 “Cast iron

pipes, fittings and their joints”, the secretariat of which is held by AFNOR.

This European Standard shall be given the status of a national standard, either by publication of an

identical text or by endorsement, at the latest by June 2023, and conflicting national standards shall be

withdrawn at the latest by June 2023.

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.

Any feedback and questions on this document should be directed to the users’ national standards body.

A complete listing of these bodies can be found on the CEN website.

According to the CEN-CENELEC Internal Regulations, the national standards organisations of the

following countries are bound to implement this European Standard: 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, Türkiye and the United

Kingdom.
---------------------- Page: 6 ----------------------
SIST EN 17800:2023
EN 17800:2022 (E)
Introduction

Studies on economic and environmental impacts are important for utility decision-makers as they seek

to balance budget concerns over immediate and long-term needs across acquisition, operations, and

maintenance, and planned end of life. For authorities and engineers designing pipeline systems, the life

cycle cost (LCC) and live cycle assessment (LCA) serve as a tool to study various scenarios to determine

the right solution for site-specific conditions and community values, as well as to provide the necessary

data to support those decisions. Impacts on the circular economy should be taken into consideration too.

The intention of this document, dedicated to ductile iron pipe systems, is to define objective

methodologies for LCC and LCA- carbon footprint, respectively, in order to support customers and users

to optimize ductile iron pipe solutions with global cost evaluation, safety requirements and

environmental criteria.
---------------------- Page: 7 ----------------------
SIST EN 17800:2023
EN 17800:2022 (E)
1 Scope

This document specifies the evaluation method of life cycle cost (LCC) and Life cycle assessment (LCA) of

ductile iron pipes and fittings used for water applications and which are in compliance with EN 545.

LCC evaluation is based on concepts and methods developed in ISO 15686-5.

LCA evaluation is based on concepts and methods developed in ISO 15686-6, EN 15804:2012+A2:2019,

EN ISO 14040 and EN ISO 14044.

In this document, LCA is limited to the evaluation of environmental impact due to CO emissions

associated with the consumption of natural resources or energy and waste disposal. The other categories

of impacts are not in the scope of this document.

Informative annexes are included in this document as a compilation of references, consensual factors,

and scenarios with different DI pipelines.
2 Normative references

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 545:2010, Ductile iron pipes, fittings, accessories and their joints for water pipelines — Requirements

and test methods

EN ISO 14044:2006 , Environmental management — Life cycle assessment — Requirements and guidelines

(ISO 14044:2006)
3 Terms, definitions and abbreviated terms

For the purposes of this document, the terms and definitions given in EN 545:2010 and the following

apply.

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

• IEC Electropedia: available at https://www.electropedia.org/
• ISO Online browsing platform: available at https://www.iso.org/obp
3.1 Terms and definitions
3.1.1
life cycle cost

cost of an asset throughout its life cycle, while fulfilling the performance requirements

[SOURCE: ISO 15686-5:2017, 3.1.7, modified]
As impacted by EN ISO 14044:2006/A1:2018 and EN ISO 14044:2006/A2:2020.
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SIST EN 17800:2023
EN 17800:2022 (E)
3.1.2
life cycle assessment

compilation and evaluation of the inputs, outputs and the potential environmental impacts of a product

system

Note 1 to entry: Environmental life cycle assessment and environmental life cycle analysis are synonymous.

[SOURCE: EN ISO 14040:2006, 3.2, modified – “throughout its life cycle” at the end of the definition has

been removed; Note 1 to entry has been added]
3.1.3
acquisition cost

all costs included in acquiring an asset by purchase/lease or construction procurement route, excluding

costs during the occupation and use or end-of-life phases of the life cycle of the constructed asset

[SOURCE: ISO 15686-5:2017, 3.1.1]
3.1.4
operation cost

total running costs for water conveyance, including the cost for pumping and cost for water leakage

Note 1 to entry: Operation costs could include rent, rates, insurances, energy, and other environmental/regulatory

inspection costs.
[SOURCE: ISO 15686-5:2017, 3.1.11, modified]
3.1.5
maintenance cost

total labour, material, and other related costs incurred to maintain pipelines in a state in which it can

perform its required functions
[SOURCE: ISO 15686-5:2017, 3.1.9, modified]
3.1.6
end of life cost or revenue

total of costs or fee for disposing of an asset at the end of its service life or interest period, including costs

resulting from pipeline dismantling, waste disposal, and revenue from material recovery

[SOURCE: ISO 15686-5:2017, 3.1.5, modified – “including costs resulting from pipeline dismantling,

waste disposal, and revenue from material recovery” has been added]
3.1.7
period of analysis
period of time over which life cycle costs or whole-life costs are analysed
Note 1 to entry: The period of analysis is determined by the client.
[SOURCE: ISO 15686-5:2017, 3.3.6]
3.1.8
functional unit
quantified performance of a product system for use as a reference unit
[SOURCE: EN 15804:2012+A2:2019, 3.13, from EN ISO 14040:2006]
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SIST EN 17800:2023
EN 17800:2022 (E)
3.1.9
service life

period of time after installation during which a facility or its component parts meet or exceed the

performance requirements
[SOURCE: ISO 15686-1:2011, 3.25]
3.1.10
in-use condition

any circumstance that can impact on the performance of a building or a constructed asset, or a part

thereof, under normal use
[SOURCE: ISO 15686-1:2011, 3.10, modified – Note 1 to entry has been deleted]
3.1.11
reference service life

service life of a pipeline system which is known to be expected under a particular set, i.e. a reference set,

of in-use conditions and which can form the basis for estimating the service life under other in-use

conditions

[SOURCE: ISO 15686-1:2011, 3.22, modified – “product, component, assembly or system” has been

replaced by “pipeline system”]
3.1.12
residual value
value assigned to an asset at the end of the period of analysis
[SOURCE: ISO 15686-5:2017, 3.3.8]
3.1.13
discount rate

factor or rate reflecting the time value of money that is used to convert cash flows occurring at different

times to a common time

Note 1 to entry: This can be used to convert future values to present-day values and vice versa.

[SOURCE: ISO 15686-5:2017, 3.3.1]
3.1.14
failure rate

number of failures (which cause a reparation) per unit length of the pipeline per year

3.1.15
water leak volume

volume of total water lost along the pipeline in m in a period of one year, (including permanent water

losses on line, water losses during failure, reparation and cleaning…)

Note 1 to entry: Evaluation is depending of the measuring equipment and collecting information system put in

force by water authority.
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SIST EN 17800:2023
EN 17800:2022 (E)
3.1.16
nominal size DN

alphanumerical designation of size for components of a pipework system, to be used for reference

purposes, which comprises the letters DN followed by a dimensionless whole number which is indirectly

related to the physical size, in millimetres, of the bore or outside diameter of the end connections

[SOURCE: EN 545:2010]
3.2 Abbreviated terms
FU functional unit
LCC life cycle cost
LCA life cycle assessment
RSL reference service life
SL service life
4 Basic concept of life cycle cost (LCC) for ductile iron pipe systems
4.1 Definition of life cycle cost

The life cycle cost shall be calculated using Formula (1) as a sum of the acquisition cost, the operation

cost such as the electric power usage cost of the pump operation, the maintenance cost such as the

leakage cost, and the end of life cost or revenue. B.1 shows scenarios of LCC with two different pipelines.

(1)
C= C++CC+ C
L A OM E
C is the life cycle cost;

C is the acquisition cost; it includes the pipe and fittings material cost, construction cost, and

designing/survey cost;
C is the operation cost; it includes the pumping cost;
C is the maintenance cost; it includes the leakage cost, repair cost, etc.;

C is the end of life cost or revenue; it includes the disposal cost and benefit of recycling.

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SIST EN 17800:2023
EN 17800:2022 (E)
4.2 Calculation method

The life cycle cost shall be calculated using Formula (2) to (4) by totalizing all the costs in a period of

analysis. Cost in the future is converted into a current value using a discount rate. In a case where the

evaluation period is not just the same as multiples of the service life(SL), the residual value is deducted

from the life cycle cost.
Case 1: t < t
n m
C + C C × tt− / t
( )
OM,,tt A mn m
(2)
CC=+−
()1+ r
()1+ r
t=1
Case 2: t = t
n m
C + C
OM,,tt
CC=++ (3)
LA ∑
()1+ r
()1+ r
t=1
Case 3: t < t < 2 × t
m n m
C + C C ××2 tt− / t
CC ( )
OM,,tt A mn m
CC=++ +− (4)
t tt t
m mn
()1+ r
()1+ r ()11++rr()
t=1
where
C is the life cycle cost;
t is the time in years;
t is the period of analysis, in year;
t is the service life (SL), in year;
C is the acquisition cost;
is the operation cost in the t year;
O,t
is the maintenance cost in the t year;
M,t
C is the end of life cost or revenue;
r is the discount rate.
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SIST EN 17800:2023
EN 17800:2022 (E)
Key
1 acquisition cost
2 operation cost
3 maintenance cost
4 end of life cost or revenue
X time in years
Y costs
Figure 1 — Costs per year
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SIST EN 17800:2023
EN 17800:2022 (E)
Key
1 acquisition cost
2 operation cost
3 maintenance cost
4 end of life cost or revenue
X time in years
Y accumulated costs
Figure 2 — Accumulated costs during the service life
5 Breakdown of life cycle cost
5.1 Acquisition cost

The acquisition cost shall be calculated using Formula (5) as a total of the pipe material cost, construction

cost, and designing/survey cost.
C= A++A A (5)
A PC D
where
C is the acquisition cost;
A is the pipe and fittings material cost;

A is the construction cost (pipe transporting cost, pipe laying cost, trenching cost, backfilling cost

etc.);
A is the designing/survey cost (all the studies useful for the project).
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SIST EN 17800:2023
EN 17800:2022 (E)
5.2 Operation cost

The yearly operation cost shall be calculated using Formula (6) as the pumping cost such as the electric

power usage cost of the pump operation. Details of the computation about the pumping cost are shown

in Annex A.
C O+ O (6)
O,,t P t W,t
where
is the operation cost in the t year;
O,t
is the pumping cost in the t year;
P,t
is the water leak cost in the t year and it shall be calculated as follows:
W,t
O WU×
W,,t Lt P
where
th 3

is the water leak on the pipeline in the t year (evaluated according to Annex C), in m ;

L,t
is the unit price, in the t year, of water supply, in currency per cubic meter.
5.3 Maintenance cost

The yearly maintenance cost shall be calculated using Formula (7) as a total of the leakage cost, leak

detection cost, repair cost, and others maintenance cost.
C = M +M +M (7)
M,t D,t R,t O,t
where
is the maintenance cost in the t year;
M,t
is the leak detection cost in the t year;
D,t
is the repair cost in the t year;
R,t
is another maintenance cost in the t year.
O,t
5.4 End of life cost or revenue

The end of life cost or revenue shall be calculated using Formula (9) as a total of the pipeline dismantling

cost and the waste disposal cost, deducting the revenue from material recovery.
(9)
C=EE+− E
E PW R
where
C is the end of life cost or revenue;
E is the pipeline dismantling cost;
E is the waste disposal cost;

E is the potential revenue from material recovery. (Material recovery is considered to be

applicable only to ductile iron pipes.)
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SIST EN 17800:2023
EN 17800:2022 (E)
6 Basic concept of life cycle assessment (LCA) for ductile iron pipe systems
6.1 Definition of CO emissions impact

Environmental life cycle assessment is a technique to assess environmental impacts through all the stages

of product and service life. Associated CO emissions can be quantitatively estimated by the amount of

kg CO equivalent unit, unit which is applicable in all the concerned formulas.

Total CO emissions shall be calculated using Formula (10) as a total amount of CO emissions through

2 2

all life cycle stages such as acquisition stage, operation stage, maintenance stage, and end of life stage.

E= E++EE+ E (10)
T A OM E
where
E is the total CO emissions through all life cycle stages;
T 2
E are the CO emissions at the acquisition stage;
A 2
E are the CO emissions at the operation stage;
O 2
E are the CO emissions at the maintenance stage;
M 2
E are CO emissions at end of life stage.
E 2
6.2 Calculation method of CO emissions

The total amount of CO emissions shall be calculated using Formulae (11) to (13) by totalizing all the

CO emissions in a period of analysis (t ).
2 n
Case 1: t < t
n m
E=E++(E E ) (11)
T A O,,ttM
t=1
Case 2: t = t
n m
(12)
E=E+ (E ++E ) E
T A O,,ttM E
t=1
Case 3: t < t < 2 × t
m n m
E =2×+E (EE+ )+ E (13)
T A ∑ OM,,tt E
t=1
where
E is the total CO emissions through all life cycle stages;
T 2
t is the time in years;
t is the period of analysis, in year;
t is the service life(SL), in year;
---------------------- Page: 16 ----------------------
SIST EN 17800:2023
EN 17800:2022 (E)
E are the CO emissions at the acquisition stage;
A 2
-th
are the CO emissions at operation stage in the t year;
O,t
-th
are the CO emissions at the maintenance stage in the t year;
M,t
E are the CO emissions at end of life stage.
E 2
7 Breakdown of CO emissions
7.1 CO emissions at the acquisition stage

CO emissions at the acquisition stage shall be calculated using Formula (14) as a total of CO emissions

2 2

with pipe manufacture, construction material production, construction machine operation,

transportation, and regeneration treatment of excavated soil.
E= E++E E+ E+ E (14)
A AP AC AO AT AR
where
E are the CO emissions at the acquisition stage;
A 2

E is the CO emissions with pipe manufacture (raw material procurement, transportation to the

AP 2

factory, manufacturing, etc.). The calculation methodology for CO emissions shall take into

account the provision for scrap recycling in ductile iron pipe production. Data are available

from manufacturers or from recognized public or private data’s bases.

E is the CO emissions with construction material production (asphalt pavement materials, road

AC 2
bedding materials, sand, etc.);

E is the CO emissions with construction machine operation for pipe laying work (installation of

AO 2

pipes and valves by crane, crush and loading of existing pavement by a backhoe, excavation

and loading of soil by a backhoe, backfilling by a backhoe, compaction by tamper, road bedding

by tamper or vibratory roller, asphalt paving work by vibratory roller or vibratory compactor,

etc.);

is the CO emissions with transportation of pipes, construction materials, construction

machines, excavated soil, ground-improved soil, and construction wastes;
E is the CO emissions with regeneration treatment of excavated soil.
AR 2
7.2 CO emissions at the operation stage

Yearly CO emissions at the operation stage shall be calculated using Formula (15) as a total of CO

2 2
emissions with pumping operation and due to water leaks.
EE + E (15)
O,,t OP t OW,t
where
-th
is the CO emissions at operation stage in the t year;
O,t
is the CO emissions with pumping operation in the t year;
OP,t
is the CO emission due to water leak in the t year, and calculated as follows:
OW,t
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SIST EN 17800:2023
EN 17800:2022 (E)
E WQ×
OW,t L,t W,co2
where
th 3

is the water leak along the pipeline in the t year (calculated according to Annex C), in m ;

L,t
is the CO emission factor for water supply, in kg CO eq/ m
W,co2
2 2
7.3 CO emissions at the maintenance stage

Yearly CO emissions at the maintenance stage shall be calculated using Formula (16) as a total of CO

2 2

emissions due to leakage, during machine operation for maintenance, production of restoration

materials, and during machine operation for restoration.
E = E +E +E (16)
M,t MM,t MP,t MR,t
where
-th
is the CO emissions at maintenance stage in the t year;
M,t

E is the CO emissions with machine operation for maintenance (inspection, drainage, washing,

MM,t 2
etc.) in the t year;
is the CO emissions with the production of restoration materials in the t year;
MP,t
is the CO emissions with machine operation for restoration work in the t year.
MR,t
7.4 CO emissions at end o
...

SLOVENSKI STANDARD
oSIST prEN 17800:2022
01-januar-2022
Stroški življenjskega cikla (LCC) in ocena življenjskega cikla (LCA) cevnih
sistemov iz duktilne železove litine

Life cycle cost (LCC) and Life cycle assessment (LCA) for ductile iron pipe systems

Lebenszykluskosten (LCK) und Ökobilanz (ÖB) für Rohrsysteme aus duktilem
Gusseisen
Coût du cycle de vie (CCV) et analyse du cycle de vie (ACV) pour les systèmes de
canalisations en fonte ductile
Ta slovenski standard je istoveten z: prEN 17800
ICS:
13.020.60 Življenjski ciklusi izdelkov Product life-cycles
23.040.10 Železne in jeklene cevi Iron and steel pipes
91.140.60 Sistemi za oskrbo z vodo Water supply systems
oSIST prEN 17800:2022 en,fr,de

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

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oSIST prEN 17800:2022
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oSIST prEN 17800:2022
DRAFT
EUROPEAN STANDARD
prEN 17800
NORME EUROPÉENNE
EUROPÄISCHE NORM
December 2021
ICS 77.140.75; 91.140.60
English Version
Life cycle cost (LCC) and Life cycle assessment (LCA) for
ductile iron pipe systems

Coût du cycle de vie (CCV) et analyse du cycle de vie Lebenszykluskosten (LCK) und Ökobilanz (ÖB) für

(ACV) pour les systèmes de canalisations en fonte Rohrsysteme aus duktilem Gusseisen

ductile

This draft European Standard is submitted to CEN members for enquiry. It has been drawn up by the Technical Committee

CEN/TC 203.

If this draft becomes a European Standard, CEN members are bound to comply with the CEN/CENELEC Internal Regulations

which stipulate the conditions for giving this European Standard the status of a national standard without any alteration.

This draft European Standard was established by CEN in three official versions (English, French, German). A version in any other

language made by translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC

Management Centre has the same status as the official versions.

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

United Kingdom.

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

aware and to provide supporting documentation.

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

notice and shall not be referred to as a European Standard.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION
EUROPÄISCHES KOMITEE FÜR NORMUNG
CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels

© 2021 CEN All rights of exploitation in any form and by any means reserved Ref. No. prEN 17800:2021 E

worldwide for CEN national Members.
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oSIST prEN 17800:2022
prEN 17800:2021 (E)
Contents Page

European foreword ............................................................................................................................................ 4

Introduction .......................................................................................................................................................... 5

1 Scope .......................................................................................................................................................... 6

2 Normative references .......................................................................................................................... 6

3 Terms and definitions ......................................................................................................................... 6

4 Basic concept of Life Cycle Cost (LCC) for ductile iron pipe systems.................................. 7

4.1 Definition of life cycle cost ................................................................................................................. 7

4.2 Calculation method .............................................................................................................................. 8

5 Breakdown of life Cycle Cost ........................................................................................................... 10

5.1 Acquisition cost ................................................................................................................................... 10

5.2 Operation cost ...................................................................................................................................... 11

5.3 Maintenance cost ................................................................................................................................ 11

5.4 End of life cost or revenue ............................................................................................................... 11

6 Basic concept of life cycle assessment (LCA) for ductile iron pipe systems .................. 12

6.1 Definition of environmental life cycle assessment ................................................................. 12

6.2 Calculation method of CO emissions ......................................................................................... 12

6.3 Other impacts ....................................................................................................................................... 13

7 Breakdown of CO emissions ......................................................................................................... 14

7.1 CO emissions at the acquisition stage ....................................................................................... 14

7.2 CO emissions at the operation stage.......................................................................................... 14

7.3 CO emissions at the maintenance stage ................................................................................... 14

7.4 CO emissions at end of life stage ................................................................................................. 15

8 Key drivers for LCC and LCA evaluation ..................................................................................... 15

8.1 Reference Service Life (RSL) ........................................................................................................... 15

8.1.1 General.................................................................................................................................................... 15

8.1.2 RSL of DI pipeline ................................................................................................................................ 15

8.1.3 In-use conditions ................................................................................................................................. 16

8.2 Functional Unit (FU) .......................................................................................................................... 16

8.2.1 General.................................................................................................................................................... 16

8.2.2 FU for DI pipeline: ............................................................................................................................... 16

8.2.3 Service Safety conditions ................................................................................................................. 16

8.3 Leakage incident ................................................................................................................................. 17

9 LCC and LCA reduction in Circular economy ............................................................................. 17

9.1 General.................................................................................................................................................... 17

9.2 Conservation of mechanical characteristics in time .............................................................. 17

9.3 Recyclability ......................................................................................................................................... 18

9.4 Conveyance capacity .......................................................................................................................... 18

9.5 Preservation of soil ............................................................................................................................ 18

9.6 Ferule collecting and Rate of reuse .............................................................................................. 18

9.7 Optimum pipe wall thickness ......................................................................................................... 18

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oSIST prEN 17800:2022
prEN 17800:2021 (E)

10 Quality of data ...................................................................................................................................... 18

Annex A (informative) Pumping cost and CO emissions with pump operation ...................... 20

A.1 Pumping cost ........................................................................................................................................ 20

A.2 Daily pumping energy ....................................................................................................................... 20

A.3 Total head (H) ...................................................................................................................................... 20

A.4 CO emissions with pump operation ........................................................................................... 22

Annex B (informative) Scenarios of LCC and LCA with different DI pipelines ........................... 23

B.1 Scenario of LCC with different DI pipelines ............................................................................... 23

B.2 Scenario of LCA with different DI pipelines .............................................................................. 24

Annex C (informative) Leakage incident rate of ductile iron pipes ............................................... 26

C.1 Water leakage evaluation ................................................................................................................ 26

C.2 Example of leakage incident rate of a ductile iron pipe network ..................................... 26

C.2.1 General ................................................................................................................................................... 26

C.2.2 Example in France .............................................................................................................................. 27

C.2.3 Example in Germany.......................................................................................................................... 27

C.2.4 Example in Spain ................................................................................................................................. 27

Bibliography ....................................................................................................................................................... 29

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oSIST prEN 17800:2022
prEN 17800:2021 (E)
European foreword

This document (prEN 17800:2021) has been prepared by Technical Committee CEN/TC 203 “Cast iron

pipes, fittings, and their joints”, the secretariat of which is held by AFNOR.
This document is currently submitted to the CEN Enquiry.
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oSIST prEN 17800:2022
prEN 17800:2021 (E)
Introduction

Studies on economic and environmental impacts are important for utility decision-makers as they seek

to balance budget concerns over immediate and long-term needs across acquisition, operations, and

maintenance, and planned end of life. For authorities and engineers designing pipeline systems, the life

cycle cost (LCC) and live cycle assessment(LCA) serve as a tool to study various scenarios to determine

the right solution for site-specific conditions and community values, as well as to provide the necessary

data to support those decisions. Impacts on the circular economy should be taken into consideration too.

The intention of this document, dedicated to DI pipe systems, is to state the concepts of Life Cycle

Cost(LCC), Live Cycle assessment(LCA), reference service life (RSL), the functional unit (FU), to define

objective methodologies for LCC and LCA, respectively, in order to support customers and users to

optimize DI pipe solutions with global cost evaluation, safety requirements and environmental criteria.

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oSIST prEN 17800:2022
prEN 17800:2021 (E)
1 Scope

This document specifies the evaluation method of life cycle cost (LCC) and Life cycle assessment (LCA) of

ductile iron pipes and fittings used for water applications

Informative annexes are included in this document as a compilation of references, consensual factors,

and scenarios with different DI pipelines.
2 Normative references
There are no normative references in this document.
3 Terms and definitions
For the purpose of this document, the following terms and definitions apply.
3.1
life cycle cost
LCC

cost of an asset throughout its life cycle, while fulfilling the performance requirements

3.2
acquisition cost

all costs included in acquiring an asset by purchase/lease or construction procurement route, excluding

costs during the occupation and use or end-of-life phases of the life cycle of the constructed asset

3.3
operation cost
total running costs for water conveyance, including the pumping cost

Note 1 to entry: Operation costs could include rent, rates, insurances, energy, and other environmental/regulatory

inspection.
3.4
maintenance cost
total labor, material, and other related costs incurred to maintain pipelines
3.5
end of life cost or revenue

total of costs or fee for disposing of an asset at the end of its service life (3.8) or interest period, including

costs resulting from pipeline dismantling, waste disposal, and revenue from material recovery

3.6
period of analysis

period of time over which life cycle costs (3.1) or whole-life costs are analyzed

Note 1 to entry: The period of analysis is determined by the client.
3.7
functional unit

the way in which the identified functions or performance characteristics of the product are quantified

[SOURCE: EN 15804]
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oSIST prEN 17800:2022
prEN 17800:2021 (E)
3.8
reference service life
RSL

service life of a construction product which is known to be expected under a particular set, i.e., a reference

set, of in-use conditions and which can form the basis for estimating the service life under other in-use

conditions
[SOURCE: EN 15804]
3.9
residual value
the value assigned to an asset at the end of the period of analysis (3.6)
3.10
discount rate

factor or rate reflecting the time value of money that is used to convert cash flows occurring at different

times to a common time

Note 1 to entry: This can be used to convert future values to present-day values and vice versa.

3.11
leakage incident rate
number of pipe bodies’ damages or water leak per unit length of the pipeline
3.12
nominal size

alphanumerical designation of size for components of a pipework system, to be used for reference

purposes, which comprises the letters DN followed by a dimensionless whole number which is indirectly

related to the physical size, in millimeters, of the bore or outside diameter of the end connections

[SOURCE: EN 545]
4 Basic concept of Life Cycle Cost (LCC) for ductile iron pipe systems
4.1 Definition of life cycle cost

The life cycle cost is calculated using Formula (1) as a sum of the acquisition cost, the operation cost such

as the electric power usage cost of the pump operation, the maintenance cost such as the leakage cost,

and the end of life cost or revenue. B.1 shows scenarios of LCC with two different pipelines.

C= C++CC+ C (1)
L A OM E
C is the life cycle cost;

is the acquisition cost; it includes the pipe and fittings material cost, construction cost, and

designing/survey cost;
C is the operation cost; it includes the pumping cost;
C is the maintenance cost; it includes the leakage cost, repair cost, etc.;

C is the end of life cost or revenue; it includes the disposal cost and benefit of recycling.

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oSIST prEN 17800:2022
prEN 17800:2021 (E)
4.2 Calculation method

The life cycle cost is calculated using Formula (2) to (4) by totalizing all the costs in a period of analysis.

Cost in the future is converted into a current value using a discount rate. In a case where the evaluation

period is not just the same as multiples of the service life, the residual value is deducted from the life cycle

cost.
Case 1 t < t
n m
CC+ C × tt− / t
( )
OM,,tt A mn m
CC=+− (2)
()1+ r
()1+ r
t=1
Case 2 t = t
n m
CC+
OM,,tt
CC=++ (3)
()1+ r
()1+ r
t=1
Case 3 t < t < 2 × t
m n m
CC+ C ××2 tt− / t
( )
OM,,tt A mn m
CC=++ +− (4)
t tt t
m mn
()1+ r
()1+ r ()11++rr()
t=1
where
C is the life cycle cost;
t is the time in year;
t is the period of analysis;
t is the service life;
C is the acquisition cost;
is the operation cost in the t year;
O,t
is the maintenance cost in the t year;
M,t
is the end of life cost or revenue;
r is the discount rate.
---------------------- Page: 10 ----------------------
oSIST prEN 17800:2022
prEN 17800:2021 (E)
Key
1 acquisition cost
2 operation cost
3 maintenance cost
4 end of life cost or revenue
X time in year
Y cost
LCC
Figure 1 — Costs per year
---------------------- Page: 11 ----------------------
oSIST prEN 17800:2022
prEN 17800:2021 (E)
Key
1 acquisition cost
2 operation cost
3 maintenance cost
4 end of life cost or revenue
X time in year
Y cost
Y LCC
Figure 2 — Accumulated costs during the service life
5 Breakdown of life Cycle Cost
5.1 Acquisition cost

The acquisition cost is calculated using Formula (5) as a total of the pipe material cost, construction cost,

and designing/survey cost.
C= A++A A (5)
A PC D
where
C is the acquisition cost;
A is the pipe and fittings material cost;

A is the construction cost (pipe laying cost, trenching cost, backfilling cost etc.);

A is the designing/survey cost (all the studies useful for the project).
---------------------- Page: 12 ----------------------
oSIST prEN 17800:2022
prEN 17800:2021 (E)
5.2 Operation cost

The yearly operation cost is calculated using Formula (6) as the pumping cost such as the electric power

usage cost of the pump operation. Details of the computation about the pumping cost are shown in

Annex A.
C = O (6)
OP,,tt
where
is the operation cost in the t year;
O,t
is the pumping cost in the t year.
P,t
5.3 Maintenance cost

The yearly maintenance cost is calculated using Formula (7) as a total of the leakage cost, leak detection

cost, repair cost, and others maintenance cost.
(7)
C= MM++ M+ M
M,t L,t DR,t ,,ttO
where
is the maintenance cost in the t year;
M,t
is the leakage cost (cost of water losses) in the t year;
L,t
is the leak detection cost in the t year;
D,t
is the repair cost in the t year;
R,t
is another maintenance cost in the t year.
O,t

The yearly leakage cost is calculated using Formula (8) as a total of water loss costs due to leakage and

pipeline cleaning during damage.
M = DP×× L+ V× U (8)
( )
L,t RL V C P
where
D is the damage ratio, in incident numbers per kilometer per year;
P is the total pipeline length, in km;
L is the water leakage volume, in cubic meters per incident;
V is the water volume for cleaning, in cubic meters per incident;
U is the unit price of water supply, in currency per cubic meter.
5.4 End of life cost or revenue

The end of life cost or revenue is calculated using Formula (9) as a total of the pipeline dismantling cost

and the waste disposal cost, deducting the revenue from material recovery.
C=EE+− E (9)
E PW R
---------------------- Page: 13 ----------------------
oSIST prEN 17800:2022
prEN 17800:2021 (E)
where
C is the end of life cost or revenue;
E is the pipeline dismantling cost;
E is the waste disposal cost;
is the revenue from material recovery.
Material recovery is considered to be applicable only to ductile iron pipes.
6 Basic concept of life cycle assessment (LCA) for ductile iron pipe systems
6.1 Definition of environmental life cycle assessment

Environmental life cycle assessment is a technique to assess environmental impacts through all the stages

of product and service life. Environmental impact associated with the consumption of natural resources

or energy and waste disposal can be quantitatively estimated as the amount of CO emissions.

Total CO emissions are calculated using Formula (10) as a total amount of CO emissions through all life

2 2

cycle stages such as acquisition stage, operation stage, maintenance stage, and end of life stage.

E= E++EE+ E (10)
T A OM E
where
E is the total CO emissions through all life cycle stages;
T 2
E are the CO emissions at the acquisition stage;
A 2
E are the CO emissions at the operation stage;
O 2
E are the CO emissions at the maintenance stage;
M 2
E are CO emissions at end of life stage
E 2
6.2 Calculation method of CO emissions

The total amount of CO emissions is calculated using Formulae (11) to (13) by totalizing all the CO

2 2
emissions in a period of analysis.
Case1 t < t
n m
E=E++(E E ) (11)
T A O,,ttM
t=1
Case2 t = t
n m
E=E+ (E ++E ) E (12)
T A ∑ O,,ttM E
t=1
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oSIST prEN 17800:2022
prEN 17800:2021 (E)
Case3 t < t < 2 × t
m n m
E =2×+E (EE+ )+ E (13)
T A OM,,tt E
t=1
where
E is the total CO emissions;
T 2
t is the time in year;
t is the period of analysis;
is the service life;
E are the CO emissions at the acquisition stage;
A 2
-th
are the CO emissions at operation stage in the t year;
O,t
-th
are the CO emissions at the maintenance stage in the t year;
M,t
E are the CO emissions at end of life stage;
E 2
6.3 Other impacts

Environmental impact can also be evaluated in other categories which are listed below. These categories

are not in the scope of this standard.
Impact on the environment:
— climate change
— air, water, and soil pollution
— ozone depletion
— eutrophication
— acidification
— reduction of biological diversity
Impact on human health:
— hazardous substance emissions
— smog formation
Impact on natural resource consumption:
— depletion of resources
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oSIST prEN 17800:2022
prEN 17800:2021 (E)
7 Breakdown of CO emissions
7.1 CO emissions at the acquisition stage

CO emissions at the acquisition stage are calculated using Formula (14) as a total of CO emissions with

2 2

pipe manufacture, construction material production, construction machine operation, transportation,

and regeneration treatment of excavated soil.
E= E++E E+ E+ E (14)
A AP AC AO AT AR
where
E are the CO emissions at the acquisition stage;
A 2

E is the CO emissions with pipe manufacture (raw material procurement, transportation to the

AP 2

factory, manufacturing, etc.). The calculation methodology for CO emissions shall take into

account the provision for scrap recycling in ductile iron pipe production. Data are available

from manufacturers or from recognized public or private data’s bases.

E is the CO emissions with construction material production (asphalt pavement materials, road

AC 2
bedding materials, sand, etc.);

E is the CO emissions with construction machine operation for pipe laying work (installation of

AO 2

pipes and valves by crane, crush and loading of existing pavement by a backhoe, excavation

and loading of soil by a backhoe, backfilling by a backhoe, compaction by tamper, road bedding

by tamper or vibratory roller, asphalt paving work by vibratory roller or vibratory compactor,

etc.);

E is the CO emissions with transportation of construction materials, construction machine

AT 2
excavated soil, ground-improved soil, and construction wastes;
E is the CO emissions with regeneration treatment of excavated soil.
AR 2
7.2 CO emissions at the operation stage

Yearly CO emissions at the operation stage are calculated using Formula (15) as a total of CO emissions

2 2
with pump operation.
EE= (15)
O,,ttOP
Where
-th
is the CO emissions at operation stage in the t year;
O,t
is the CO emissions with pump operation in the t year.
OP,t

Annex B (informative) is showing the general relative high portion of CO emission at the operation Stage.

7.3 CO emissions at the maintenance stage

Yearly CO emissions at the maintenance stage are calculated using Formula (16) as a total of CO

2 2

emissions due to leakage, during machine operation for maintenance, production of restoration

materials, and during machine operation for restoration.
EE= + E + E + E (16)
M,t ML,t MM,,ttMP MR,t
---------------------- Page: 16 ----------------------
oSIST prEN 17800:2022
prEN 17800:2021 (E)
where
-th
is the CO emissions at maintenance stage in the t year;
M,t
is the CO emissions with leakage in the t year;
ML,t

E is the CO emissions with machine operation for maintenance (inspection, drainage, washing,

MM,t 2
etc.) in the t year;
is the CO emissions with the production of restoration materials in the t year;
MP,t
is the CO emissions with machine operation for restoration work in the t year.
MR,t
7.4 CO emissions at end of life stage

CO emissions at end of life stage are calculated using Formula (17) as a total of CO emissions with

2 2

machine operation for existing pipeline dismantling, construction waste disposal, transportation of

construction materials and others, and reduction effect with recycling.
E= E++E E− E (17)
E EM EC ET ER
where
E is the CO emissions at end of life stage;
E 2
E is the CO emissions with machine operation for existing pipeline dismantling;
EM 2
E is the CO emissions with construction waste disposal;
EC 2

E is the CO emissions with transportation of construction materials, construction machines,

ET 2
excavated soil, and construction wastes;

E is the reduction effect of CO emissions with recycling of excavated pipes as raw materials.

ER 2
Material recovery is considered to be applicable only to ductile iron pipes.
8 Key drivers for LCC and LCA evaluation
8.1 Reference Service Life (RSL)
8.1.1 General

The reference service life (RSL) of a construction product is the service life which is known to be expected

under a particular set of in-use conditions, and which may form the basis of estimating the service life

under other in-use conditions.
8.1.2 RSL of DI pipeline

RSL of a DI pipeline is dependent on the properties of DI pipes and on the reference in-use conditions. It

takes into account the components of a DI pipeline, that are pipes and fittings material, linings and

coatings, and assembling accessories (rubber gasket, bolts...).

A RSL of 100 years is commonly recognized for a ductile iron pipeline. Such RSL is referring to the

declared in-use conditions stated in 8.1.3.

The expected service life can be forecasted by reducing or increasing the RSL, considering the local

environment features (hydrogeology, operations ...), the nature of the pipe coatings, and the nature of the

pipe linings. (see [10], [8], [17])
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oSIST prEN 17800:2022
prEN 17800:2021 (E)
8.1.3 In-use conditions

RSL of DI pipe is under the following “set of in-use conditions”, including quantitative and qualitative

data, as recommended in EN 15804.
Table 1 — Technical characteristics of the pipe
Technical characteristics of the pipe in compliance with EN 545
Appropriate code of designing in compliance with EN 805 and
manufacturer’s recommendations
Installation conditions in compliance with EN 545, Annex F and
manufacturer’s recommendations
Buried environment; corrosiveness of in compliance with EN 545, Annex D
soil, with suitable external coatings
Fluid transported: water aggressiveness in compliance with EN 545, Annex E.
with suitable internal linings
Typical Service conditions compliance to service pressure
Maintenance conditions sporadic
8.2 Functional Unit (FU)
8.2.1 General

The functional unit of a construction product is defined as the way in which the identified functions or

performance characteristics of the product are quantified.
8.2.2 FU for DI pipeline:

When using pipes to conduct water, the functional Unit for DI pipeline is defined as: ”Transporting water

in 1m of DI pipeline in a given diameter* with a speed of 1 m/s and service Pressure Ps, during 100 years

(RSL), with the stated service safety conditions.

* Where possible, the hydraulic (functional) diameter should be used considering all aspects that can

influence the water flow throughout the entire pipeline.
...

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Devices to prevent pollution by backflow of potable water - Air gap with non-circular overflow (unrestricted) - Family A - Type B
kSIST FprEN 13077:2022

This document specifies the characteristics and the requirements of air gap with non-circular overflow (unrestricted) Family A, Type B for nominal flow velocity not exceeding 3 m/s. Air gaps are devices for protection of potable water in water installations from pollution by backflow. This document applies to air gaps in factory-assembled products and to constructed air gaps in situ and specifies requirements and methods to verify and ensure compliance with this document during normal working use.
The fluid in the receiving vessel is assumed to have similar properties to water. Where this is not the case, additional care or tests could be required to verify the efficacy of the solution in practical use.
The AB device is intended to be used in potable water installations according to EN 806 (all parts).

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CEN
EN ISO 8062-3:2023(Main)
Geometrical product specifications (GPS) - Dimensional and geometrical tolerances for moulded parts - Part 3: General dimensional and geometrical tolerances and machining allowances for castings using ± tolerances for indicated dimensions (ISO 8062-3:2023)
SIST EN ISO 8062-3:2023

This document specifies general dimensional and geometrical tolerances as well as machining allowance grades for castings using ± tolerances for indicated dimensions as delivered to the purchaser according to ISO/TS 8062-2. It is applicable for tolerancing of dimensions and geometry of castings in all cast metals and their alloys produced by various casting manufacturing processes.
This document does not apply to 3D CAD models used without indicated dimensions.
This document applies to both general dimensional and general geometrical tolerances (referred to in or near the title block of the drawing), unless otherwise specified and where specifically referred to on the drawing by one of the references in Clause 11.
The dimensional tolerances covered by this document are tolerances for linear dimensions.
The geometrical tolerances covered by this document are tolerances for:
—     straightness;
—     flatness;
—     roundness;
—     parallelism;
—     perpendicularity;
—     symmetry;
—     coaxiality.
This document does not cover other position tolerances, angular dimensional tolerances or cylindricity tolerances.
This document can be used for the selection of tolerance values for individual indications.

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CEN
EN 17824:2023(Main)
Railway applications - Ground based services - Exhaust treatment fluid (AUS 32) refilling equipment
SIST EN 17824:2023

This European Standard specifies interface requirements on vehicles and on ground based refilling and storage equipment for any railway vehicle fitted with internal combustion engine (s) requiring a NOx reduction agent AUS 32 (32 % aqueous urea solution) as specified in ISO 22241-1.
It is also applicable to mobile or temporary refilling points for AUS 32.

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EN ISO 21805:2023(Main)
Guidance and recommendations on design, selection and installation of vents to safeguard the structural integrity of enclosures protected by gaseous fire-extinguishing systems (ISO 21805:2023)
kSIST FprEN ISO 21805:2022

This document gives guidelines for fulfilling the requirements contained in ISO 6183:2022, 6.4.1 and 7.4.1 and ISO 14520‑1:2023, 5.2.1 h) and 5.3 h), in respect to over- and under-pressurization venting and post-discharge extract.
It considers the design, selection and installation of vents to safeguard the structural integrity of enclosures protected by fixed gaseous extinguishing systems and the post-discharge venting provisions where used.

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EN 17683:2023(Main)
Animal feeding stuffs - Methods of sampling and analysis - Determination of pyrrolizidine alkaloids in animal feeding stuff by LC-MS/MS
kSIST FprEN 17683:2022

This document specifies a method for the quantitative determination of pyrrolizidine alkaloids (PA) in the concentration ranges shown in Table 1 in complete and supplementary feed and in forages by liquid chromatography tandem mass spectrometry (LC-MS/MS) after solid phase extraction (SPE) clean-up.
Table 1 - Summary of concentration ranges per PA tested in the collaborative trial
NOTE 1   A second method was part of the method validation collaborative main trial. For this method PA-N-Oxides are reduced by adding zinc powder to the extract of the feed material. The following steps correspond to the first and main method. Quantitative results for each PA except the otonecine type PA senkirkine represent the sum of the free PA base and its corresponding N-oxide.
NOTE 2   Due to insufficient numbers of data for some analyte-matrix combinations statistical evaluation was not valid for standardization. Received data indicated the methods applicability in experienced laboratories with appropriate quality assurance measures. Therefore, the method description is included as an informative annex (Annex D).

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EN 16307-3:2023(Main)
Industrial trucks - Safety requirements and verification - Part 3: Supplementary requirements for trucks with elevating operator position and trucks specifically designed to travel with elevated loads (additional requirements to EN 16307-1)
oSIST prEN 16307-3:2018

This document specifies requirements for the types of industrial trucks specified in the scope of EN ISO 3691-3:2016.
This document is intended to be used in conjunction with EN ISO 3691-3:2016. These requirements are supplementary to those stated in EN ISO 3691-3:2016.
This document deals with the following significant hazards, hazardous situations or hazardous events relevant when it is used as intended and under conditions of misuse which are reasonably foreseeable by the manufacturer:
-   acceleration, deceleration (kinetic energy);
-   machinery mobility.
This document specifies supplementary requirements to EN ISO 3691-1:2015, EN ISO 3691-3:2016 and EN 16307-1:2020:
-   brakes operation without guidance system;
-   operator fall protection;
-   information for use (instruction handbook and marking).
Annex A (informative) contains the list of significant hazards covered by this document.

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EN 12729:2023(Main)
Devices to prevent pollution by backflow of potable water - Controllable backflow preventer with reduced pressure zone - Family B - Type A
kSIST FprEN 12729:2022

This document specifies the field of application, the dimensional, the physico-chemical, the design, the hydraulic, the mechanical, and the acoustic characteristics of controllable backflow preventers with reduced pressure zone, Family B, Type A.
This document covers controllable backflow preventers of Family B, Type A, with reduced pressure zones, intended to prevent pollution of potable water by backflow, caused by backsiphonage or by backpressure.
It is applicable to controllable backflow preventers in denominations DN 6 up to DN 250.
It covers controllable backflow preventers of PN 10 that are capable of working without modification or adjustment:
- at any pressure, up to 1 MPa (10 bar);
- with any pressure variation, up to 1 MPa (10 bar);
- in permanent duty at a limited temperature of 65 °C and for maximum 1 h at 90 °C.
It specifies also the test methods and requirements for verifying their characteristics, the marking and the presentation at delivery.

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