SIST EN 16480:2016

SLOVENSKI STANDARD
SIST EN 16480:2016
01-julij-2016
ýUSDONH0LQLPDOQD]DKWHYDQDXþLQNRYLWRVWFHQWULIXJDOQLKYRGQLKþUSDON
Pumps - Minimum required efficiency of rotodynamic water pumps
Pumpen - Geforderte Mindesteffizienz bei Kreiselpumpen für Wasser
Pompes - Rendement minimum requis des pompes à eau rotodynamiques
Ta slovenski standard je istoveten z: EN 16480:2016
ICS:
23.080 ýUSDONH Pumps
SIST EN 16480:2016 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN 16480:2016

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SIST EN 16480:2016


EN 16480
EUROPEAN STANDARD

NORME EUROPÉENNE

May 2016
EUROPÄISCHE NORM
ICS 23.080
English Version

Pumps - Minimum required efficiency of rotodynamic
water pumps
Pompes - Rendement minimum requis des pompes à Pumpen - Geforderte Mindesteffizienz bei
eau rotodynamiques Kreiselpumpen für Wasser
This European Standard was approved by CEN on 4 March 2016.

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, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania,
Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and
United Kingdom.





EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION

EUROPÄISCHES KOMITEE FÜR NORMUNG

CEN-CENELEC Management Centre: Avenue Marnix 17, B-1000 Brussels
© 2016 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN 16480:2016 E
worldwide for CEN national Members.

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SIST EN 16480:2016
EN 16480:2016 (E)
Contents Page
European foreword . 4
Introduction . 5
1 Scope . 7
2 Normative references . 8
3 Terms and definitions . 8
3.1 General . 8
3.2 List of quantities with definitions . 8
3.3 Lists of basic letters and subscripts . 10
3.4 General definitions . 12
4 Minimum Required Efficiencies and Minimum Efficiency Index . 14
4.1 The concept of “house of efficiency” . 14
4.2 Mathematical representation of minimum required efficiency . 15
4.3 Minimum efficiency at part load and overload . 16
4.4 Minimum Efficiency Index . 17
5 Determination of the Efficiency of a Test Pump . 20
5.1 General . 20
5.2 Test Procedures . 20
5.3 Test conditions . 21
5.4 Measuring uncertainties . 22
5.5 Evaluation of test data . 24
6 Proving the Minimum Efficiency Index of a pump size . 29
6.1 General remarks . 29
6.2 Determination of the Minimum Efficiency Index of a pump size . 30
7 Verification of the Minimum Efficiency Index for a pump size . 31
7.1 General remarks . 31
7.2 Procedure and decision . 31
Annex A (normative) Pump types in scope . 35
Annex B (informative) General remarks on the efficiency of rotodynamic pumps . 37
Annex C (informative) Mean Values of a Size Relevant for its Minimum Efficiency Index . 39
Annex D (informative) Methods recommended for manufacturers to determine the mean
values of hydraulic quantities of a size relevant for MEI . 44
D.1 General remarks . 44
D.2 Determination of the mean efficiency of a pump size from a test on one single test
pump . 44
D.3 Determination of the mean efficiency of a pump size from a sample of M test pumps. 46
Annex E (informative) Numerical example. 49
Annex F (informative) Application of mathematical statistics on tests . 54
F.1 Purposes of applying statistics in the frame of qualification and verification . 54
F.2 Confidence interval . 55
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EN 16480:2016 (E)
F.3 Law of error propagation . 57
F.4 Numerical example . 57
Annex G (informative) Measurement uncertainties . 64
G.1 General remarks . 64
G.2 Determination of the overall measurement uncertainty of efficiency . 66
Annex H (informative) Explanations concerning the methodology of the verification
procedure and the probability of the results . 68
Annex I (informative) Reporting of Test Results . 71
I.1 Test Report Requirements . 71
I.2 Pump test sheet . 71
Annex ZA (informative) Relationship between this European Standard and the Essential
Requirements of EU Directive 2009/125/EC, establishing a framework for the
setting of ecodesign requirements of energy related products and implemented by
the European Commission Regulation (EU) No. 547/2012 . 73
Bibliography . 74

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SIST EN 16480:2016
EN 16480:2016 (E)
European foreword
This document (EN 16480:2016) has been prepared by Technical Committee CEN/TC 197 “Pumps -
Minimum required efficiency of rotodynamic water pumps”, 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 November 2016, and conflicting national standards
shall be withdrawn at the latest by November 2016.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CEN [and/or CENELEC] shall not be held responsible for identifying any or all such patent
rights.
This document has been prepared under a mandate given to CEN by the European Commission and the
European Free Trade Association, and supports essential requirements of EU Directive 2009/125/EC.
For relationship with EU Directive 2009/125/EC, see informative Annex ZA, which is an integral part of
this document.
According to the CEN/CENELEC Internal Regulations, the national standards organizations of the
following countries are bound to implement this European Standard: Austria, Belgium, Bulgaria,
Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republic of Macedonia,
France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta,
Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland,
Turkey and the United Kingdom.
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SIST EN 16480:2016
EN 16480:2016 (E)
Introduction
Purpose and content of the standard
The water pumps within the scope of this European Standard are typically produced and sold by pump
manufacturers as series of large to very large numbers. The performance characteristics of pumps of
one size produced by a manufacturer show some scatter caused by manufacturing tolerances, but are
described by mean values and curves which represent that size.
The total consumption of electric energy by water pumps installed in applications within the scope of
this European Standard depends on the total number of installed pumps of each size and on its mean
efficiency. The quality of a size in respect to its mean efficiency is quantitatively described by the
Minimum Efficiency Index (MEI) which is defined and used in this standard. To achieve a certain value
of the Minimum Efficiency Index (MEI), a corresponding minimum value of the mean efficiency of a size
is required.
This European Standard defines – for each pump type and size within the scope of the standard - the
minimum required value of efficiency depending on the value of the Minimum Efficiency Index (MEI).
Also, this standard prescribes how the value of the Minimum Efficiency Index (MEI) of a pump size
indicated by the manufacturer can be verified by an independent institution (e.g. in the frame of market
surveillance). For the manufacturer of the pump size it is generally left free how to prove the indicated
value of the Minimum Efficiency Index (MEI) of a size. Nevertheless, this standard describes also a
method to prove by the manufacturer that the mean values of efficiency meet the requirements for
indicating a certain value of the Minimum Efficiency Index (MEI).
Normally, the qualification of a pump size for a certain MEI value done by the manufacturer will be
based on tests and evaluations made on a sample of pumps of this size. It is essential that tests and
evaluations carried out for the purpose of qualifying the corresponding size fulfil certain requirements:
— From the tests on the sample pumps, it becomes possible to predict for the corresponding size the
confidence intervals within which the true mean values of efficiencies which are relevant for the
qualification are enclosed with a sufficiently high probability. Only in that way, the qualification of
the size in respect to a required and/or indicated value of Minimum Efficiency Index (MEI) will
make sure that the aspired effect of energy saving will be reached.
— If a pump size has been qualified according to the criteria described in this European Standard,
every test on one or more test pump(s) of the same size (with a full impeller diameter) which is
carried out in the frame of a verification procedure shall result with a very high probability in a
confirmation of the qualification.
Caused by technical alignment procedures of the single pump components, e.g. bearings or shaft seals,
the performance of the pump is gained after a certain running-in time.
Ways to prove and to verify the Minimum Efficiency Index (MEI) of a pump size
This European Standard describes different ways how manufacturers can achieve the qualification of a
pump size for a certain value of the Minimum Efficiency Index (MEI) and how this qualification can be
verified by an independent institution.
For the manufacturer, it is generally left free to choose and apply appropriate methods to prove that the
mean efficiency values of a size are at least equal to or higher than particular threshold values of
efficiency. These particular threshold values of efficiency are related to the value of the Minimum
Efficiency Index (MEI) to be indicated for the size. The way to determine these values of efficiency is
described in this standard. If the way chosen by the manufacturer to prove the MEI value of a size
deviates from the way mentioned in the next paragraph, the manufacturer has to document all tests,
evaluations and/or calculations which are carried out and the methods which are applied to prove the
justification of the indicated MEI value.
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EN 16480:2016 (E)
If the manufacturer decides to determine the mean performance values of the size by one of the
methods described in Annex D of this standard, he has to carry out tests according to the requirements
given in Annex C of this standard and evaluations as described in Annex C of this standard and to prove
– as described in Clause 7 of this standard – that the criteria for the achievement of a certain value of
the Minimum Efficiency Index (MEI) of the size are fulfilled. The test conditions, the results of test
evaluation and the fulfilment of the criteria are documented and stored. The time period to keep
documentation available for the authorities to prove conformity is fixed by the legal text.
The independent institution carries out tests on pumps of the size in question according to the
requirements given in 5.2 to 5.4 of this standard as well as evaluations as described in 5.5 of this
standard and applies the methodology and procedure described in Clause 4 of this standard.
For an independent institution, two ways are possible and specified by this standard to verify the value
of Minimum Efficiency Index (MEI) indicated by the manufacturer:
a) If the documentation of the qualification is presented by the manufacturer to the independent
institution on request, the procedure of verification executed by the independent institution is
based on the documentation of tests and evaluations done and documented by the manufacturer. In
this case, the documentation will be checked by the independent institution in respect to being in
accordance with requirements and criteria given in this standard.
b) If no documentation is presented by the manufacturer on request or if the documentation
presented by the manufacturer on request is not accepted as proof of the indicated value of MEI,
the independent institution carries out tests on pumps of the size in question according to the
requirements given in Annex C of this standard as well as evaluations as described in 5.5 of this
standard and applies the methodology and procedure described in Clause 4 of this standard.
Relevance of Sections of this standard for manufacturers or independent institutions
Clause 4 describes nominal values of minimum required efficiency for a certain value of the Minimum
Efficiency Index (MEI) and is generally relevant when applying this standard.
Clause 5 specifies test procedures, test conditions and evaluations and has to be applied
— by a manufacturer in the case that he decides to determine mean values of a size by tests on sample
pumps of this size (e.g. by methods described in Annex D),
— by an independent institution in the case that the Minimum Efficiency Index (MEI) of a pump size
shall be verified by the procedure described in Clause 7.
Clause 6 describes the procedure to be applied by a manufacturer in order to determine particular
threshold values of efficiency for a certain value of the Minimum Efficiency Index (MEI) of a size and to
prove the justification of this MEI value by the fulfilment of criteria for the mean efficiency values.
Clause 7 describes the methodology and procedure to be applied by an independent institution in the
case that the Minimum Efficiency Index (MEI) of a size indicated by the manufacturer shall be verified
by third party tests on pumps of this size.
Annex C is concerned with mean values of a pump size which are relevant for manufacturers to prove
that a pump size achieves a certain value of the Minimum Efficiency Index (MEI).
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SIST EN 16480:2016
EN 16480:2016 (E)
1 Scope
This European Standard specifies performance requirements (methods and procedures for testing and
calculating) for determining the Minimum Efficiency Index (MEI) of rotodynamic glanded water pumps
for pumping clean water, including where integrated in other products.
The pump types and sizes covered by this standard are described in the Annex A. These pumps are
designed and produced as duty pumps for pressures up to 16 bar for end suction pumps and up to
25 bar for multistage pumps, temperatures between -10 °C and +120 °C and 4” or 6” size for
submersible multistage pumps at operating temperatures within a range of 0 °C and 90 °C.
In addition, this standard specifies how the value of the Minimum Efficiency Index (MEI) of a pump size
indicated by the manufacturer can be checked by market surveillance.
Even if it is left free to the manufacturer of a pump size how to prove the rated value of the Minimum
Efficiency Index (MEI), nevertheless this standard specifies a method to prove that this rated value
meets the requirements within the confidence intervals with a sufficiently high probability.

Figure 1 — Scheme of application of this standard
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SIST EN 16480:2016
EN 16480:2016 (E)
2 Normative references
The following documents, in whole or in part, are normatively referenced in this document and are
indispensable for its application. For dated references, only the edition cited applies. For undated
references, the latest edition of the referenced document (including any amendments) applies.
EN ISO 9906:2012, Rotodynamic pumps — Hydraulic performance acceptance tests — Grades 1, 2 and 3
(ISO 9906:2012)
3 Terms and definitions
3.1 General
For the purposes of this European Standard, the quantities, definitions, symbols and units given in
EN ISO 9906 and in 3.2 apply. 3.2 gives specific definitions of terms - in deviation of EN ISO 9906 - used
in this European Standard, together with any associated symbols which have been allocated and is
based on ISO 80000.
Table 1 gives an alphabetical list of symbols used and Table 2 gives a list of subscripts. As far as
possible, the quantities, definitions and symbols used in this standard comply with those used in
EN ISO 9906. Quantities, definitions and symbols used in EN ISO 9906, but not needed in this standard
are not contained in 3.2 and Tables 1 and 2, while these tables contain some quantities, definitions and
symbols which are not used in EN ISO 9906.
In this European Standard, all formulae are given in coherent SI-units.
3.2 List of quantities with definitions
For the purposes of this document, the following terms and definitions apply. Most of the terms and
definitions come from EN ISO 9906, except for the definition of MEI.
3.2.1
Reynolds number
dimension less number that gives a measure of the ratio of inertial forces to viscous forces and
consequently quantifies the relative importance of these two types of forces for given flow conditions.
In this standard, it is defined by the relation:
Du⋅
imp
Re=
ν
where u is the peripheral velocity at the outer impeller diameter D
imp
3.2.2
(volume) rate of flow
external rate of flow of the pump, i.e. the rate of flow discharged into the pipe from the outlet branch of
the pump
Note 1 to entry: Losses or abstractions inherent to the pump, i.e.:
— discharge necessary for hydraulic balancing of axial thrust;
— cooling of bearings of the pump itself;
— water seal to the packing.
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Note 2 to entry: Leakage from the fittings, internal leakage, etc. is not to be reckoned in the rate of flow. On the
contrary, all derived flows for other purposes, such as cooling of the motor bearings; cooling of a gear box
(bearings, oil cooler), etc. are to be reckoned in the rate of flow.
Note 3 to entry: Whether and how these flows shall be taken into account depends on the location of their
derivation and of the section of flow-measurement respectively.
3.2.3
driver power input
power absorbed by the pump driver
3.2.4
pump efficiency
P
Hydraulic output
hyd
η
Pumppower input
P
2
3.2.5
driver efficiency
P
Pumppower input
2

η
dr
Driver power input
P
1
3.2.6
overall efficiency
P
hyd Pumppower output

η
tot
Driver power input
P
1
3.2.7
specific speed
dimensional number characterizing the impeller type (radial, semi-axial, axial) of rotodynamic pumps
Q
BEP
nn⋅
sN
0.75
H
BEP
Note 1 to entry: For multistage pumps, H is the head per stage which results from dividing the total pump
BEP
head at the point of best efficiency by the number of stages.
Note 2 to entry: The specific speed of an individual pump or the mean specific speed of a pump size is a
(dimensional) value which characterizes the impeller shape (radial, semi-axial, axial) of the pump or the size. The
numerical value of the specific speed is defined by an equation given in 3.2.7 by using special units for the
quantities contained in this equation. As described in Clause 4, the specific speed is one of the parameters which
the nominal values of minimum required efficiency depend on.
3.2.8
minimum efficiency index
MEI
value which determines the minimum required efficiency for the qualification criteria and, thereby, is a
measure of the quality of a pump size in respect to efficiency
Note 1 to entry: Dimensionless scale unit for hydraulic pump efficiency at BEP, PL and OL.
9
=
==
==
==

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SIST EN 16480:2016
EN 16480:2016 (E)
Note 2 to entry: The MEI is the result of a statistical analysis of the performances of a large number of
commercial pump sizes, and corresponds to the various “quartiles” of the statistical distribution.
For example, MEI = 0,40 corresponds to the efficiency performance level that 40 % of the pumps on the market do
not meet.
3.3 Lists of basic letters and subscripts
Table 1 — Alphabetical list of basic letters used as symbols
Symbol Quantity Unit
2
A Area m
C Constant pure number
D Diameter m
e Measurement uncertainty, relative value pure number
-1
f Frequency s , Hz
2
g Acceleration due to gravity m/s
H Pump total head m
k Number of instrument readings or sample pumps pure number
m Mass kg
M Number of pumps of a sample pure number
-1 -1
n Speed of rotation s , min
N Number of instrument readings pure number
-1
n Specific speed min
s
p Pressure Pa
p Probability pure number
P Power W
3
Q (Volume) rate of flow m /s
s Standard deviation of a sample according to special quantity
t Tolerance factor, relative value pure number
t Time s
t Student´s factor pure number
T Torque Nm
u Peripheral velocity m/s
U Mean velocity m/s
U Voltage V
v Local velocity m/s
3
V Volume m
x General quantity according to special quantity
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EN 16480:2016 (E)
Symbol Quantity Unit
y General quantity according to special quantity
z Height above reference plane m
z Number of produced pumps pure number
η Efficiency pure number
θ Temperature °C
2
ν Kinematic viscosity m /s
3
ρ Density kg/m
ω Angular velocity rad/s
σ Standard deviation of normal distribution according to special quantity
For a list of concise designations (short term description) of pump types in scope, see Annex B.
Table 2 — List of letters and figures used as subscripts
Subscript Meaning
1 electrical
2 mechanical
abs absolute
amb ambient
annual per year
curve on fitting curve
BEP at best efficiency point
dr driver
D datum
exp experimentally determined
G guaranteed
H pump total head
I numbering index
J numbering index
imp impeller
man manufacturing
max maximum permissible
mean mean value of pump series
min,requ minimum required
N nominal
OL overload
Pd pre-defined
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Subscript Meaning
P power
PL part load
Q (volume) flow rate
R random
S specific, systematic
sync synchronous
tot total, overall
true true value
T torque
T translated
v vapour
x of quantity x
y % for probability of y %
η efficiency
hyd hydraulic
3.4 General definitions
3.4.1
qualification
procedure where the manufacturer of the pump size proves, by appropriate methods, the fulfilment of
the efficiency criteria defined in this standard
Note 1 to entry: Generally, the qualification criteria refer to the mean values of the size which are valid for the
full impeller diameter and which will be determined by tests and evaluations on pumps of the respective size.
These mean efficiency values and their confidence intervals are compared to nominal values of minimum required
efficiency. Also, these values depend on parameters (see Clause 4) the values of which partly result from the tests
and are determined with some uncertainty or tolerance. Therefore, so-called particular threshold values of
efficiency are determined and used in the frame of the qualification procedure for comparison with the mean
values.
3.4.2
verification
procedure where an independent institution checks the result of the qualification procedure, in the
frame of market surveillance
Note 1 to entry: In this case, the tests and the evaluation of the test data are carried out according to Clause 5 of
this European Standard. The approval decision is taken according to the procedure described in Clause 7 of this
European Standard.
3.4.3
independent institution/market surveillance
organization mandated by the market surveillance for verification of MEI values indicated by
manufacturers
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EN 16480:2016 (E)
Note 1 to entry: These organizations are generally called independent institutions whatever the special type of
the institution (non-governmental organization (NGO), neutral institute, market surveillance authorities or
similar) may be.
Note 2 to entry: Neutral institutions or similar organizations can also be mandated by a manufacturer for the
qua
...