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SIST EN 62006:2011

Hydraulic machines - Acceptance tests of small hydroelectric installations (IEC 62006:2010)

Hydraulic machines - Acceptance tests of small hydroelectric installations (IEC 62006:2010)

This International Standard defines the test, the measuring methods and the contractual guarantee conditions for field acceptance tests of the generating machinery in small hydroelectric power installations. It applies to installations containing impulse or reaction turbines with unit power up to about 15 MW and reference diameter of about 3 m. The driven generator can be of synchronous or asynchronous type. This International Standard contains information about most of the tests required for acceptance of the hydraulic turbine such as safety approval tests, trial operating and reliability tests, as well for verification of cavitation, noise and vibration conditions, if required. This standard represents the typical methods used on smaller hydroelectric installations, and is divided into three classes as follows (see Table 1 for more detail):
NOTE All classes contain safety tests, trial operating tests, and reliability tests. This standard gives all necessary references for the contract in order to execute the test, evaluate, calculate and compare the result to the guarantee for all the classes A, B and C. The manufacturer or consulting engineer is responsible for ensuring that standardized connections are installed for performing these tests. This standard does not cover the structural details of a hydroelectric installation or its component parts.

Hydraulische Maschinen - Abnahmemessungen an Kleinwasserkraft-Anlagen (IEC 62006:2010)

Machines hydrauliques - Essais de réception des petits aménagements hydroélectriques (CEI 62006:2010)

La CEI 62006:2010 définit les essais, les méthodes de mesure et les conditions de garantie contractuelles relatifs aux essais de réception sur site des machines générant l'énergie dans les petits aménagements hydroélectriques. Elle s'applique aux installations comportant des turbines à impulsion ou à réaction d'une puissance allant jusqu'à 15 MW environ et d'un diamètre de référence de 3 m environ. Le générateur peut être de type synchrone ou asynchrone. La présente Norme internationale contient des informations relatives à la plupart des essais requis pour la réception des turbines hydrauliques tels que les essais pour approuver la sécurité, les essais de fonctionnement et de fiabilité, ainsi que les essais de vérification des conditions de cavitation, de bruit et de vibration, s'ils sont exigés. La présente norme présente les méthodes types utilisées pour les petits aménagements hydroélectriques, et se divise en trois classes, comme suit:   Classe A: Par défaut, programme d'essai normal (relevés sur le panneau de contrôle), pour déterminer la puissance maximale fournie par l'installation.  Classe B: Recommandé, programme d'essai étendu, pour déterminer les caractéristiques de l'aménagement en matière de performances.  Classe C: Optionnel, programme d'essai complet. Pour déterminer le rendement absolu de l'aménagement.  Toutes les classes comportent des essais de sécurité, des essais de fonctionnement et des essais de fiabilité. La présente norme fournit toutes les références nécessaires au contrat afin de réaliser l'essai, d'évaluer, de calculer et de comparer le résultat par rapport à la garantie pour toutes les classes: A, B et C.

Vodni stroji - Prevzemni preskusi majhnih hidroelektrarn (IEC 62006:2010)

Ta mednarodni standard določa preskus, metode merjenja in pogoje pogodbene garancije za terenske prevzemne preskuse generatorskih strojev v majhnih hidroelektrarnah. Velja za inštalacije, ki vsebujejo impulzne ali reakcijske turbine z močjo enote do približno 15 MW in referenčnim premerom približno 3 m. Gnani generator je lahko sinhronega ali asinhronega tipa. Ta mednarodni standard vsebuje informacije o večini preskusov, zahtevanih za odobritev vodne turbine, kot so odobritveni preskusi varnosti, preskusi za preskusno delovanje in zanesljivost, ter za potrditev kavitacije ter pogojev hrupa in vibracij, če je potrebno. Ta standard predstavlja običajne metode, uporabljene pri manjših hidroelektričnih inštalacijah, in je razdeljen v naslednje tri razrede (glej preglednico 1 za podrobnejši opis):
OPOMBA: Vsi razredi vsebujejo preskuse varnosti, preskuse poskusnega delovanja in preskuse zanesljivosti. Ta standard podaja vsa potrebna sklicevanja za pogodbo, da se izvedejo preskusi, da se ocenijo, izračunajo in primerjajo rezultati pri garanciji za vse razrede A, B in C. Proizvajalec ali svetovalni inženir je odgovoren za zagotavljanja, da so vgrajene standardizirane povezave za izvedbo teh preskusov. Ta standard ne zajema podrobnosti o strukturi hidroelektričnih inštalacij ali njihovih sestavnih delov.

General Information

Status
Published
Publication Date
06-Mar-2011
ICS
27.140 - Hydraulic energy engineering
Technical Committee
IEHT - Electrotechnics - Hydraulic turbins
Current Stage
6060 - National Implementation/Publication (Adopted Project)
Start Date
02-Mar-2011
Due Date
07-May-2011
Completion Date
07-Mar-2011
Ref Project
EN 62006:2011 - Hydraulic machines - Acceptance tests of small hydroelectric installations

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SLOVENSKI STANDARD
SIST EN 62006:2011
01-april-2011
Vodni stroji - Prevzemni preskusi majhnih hidroelektrarn (IEC 62006:2010)
Hydraulic machines - Acceptance tests of small hydroelectric installations (IEC
62006:2010)
Hydraulische Maschinen - Abnahmemessungen an Kleinwasserkraft-Anlagen (IEC
62006:2010)
Machines hydrauliques - Essais de réception des petits aménagements hydroélectriques
(CEI 62006:2010)
Ta slovenski standard je istoveten z: EN 62006:2011
ICS:
27.140 Vodna energija Hydraulic energy engineering
SIST EN 62006:2011 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

---------------------- Page: 1 ----------------------

SIST EN 62006:2011

---------------------- Page: 2 ----------------------

SIST EN 62006:2011

EUROPEAN STANDARD
EN 62006

NORME EUROPÉENNE
February 2011
EUROPÄISCHE NORM

ICS 27.140


English version


Hydraulic machines -
Acceptance tests of small hydroelectric installations
(IEC 62006:2010)


Machines hydrauliques -  Hydraulische Maschinen -
Essais de réception des petits Abnahmemessungen an Kleinwasserkraft-
aménagements hydroélectriques Anlagen
(CEI 62006:2010) (IEC 62006:2010)




This European Standard was approved by CENELEC on 2011-01-02. CENELEC 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 Central Secretariat or to any CENELEC 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 CENELEC member into its own language and notified
to the Central Secretariat has the same status as the official versions.

CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus,
the Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy,
Latvia, Lithuania, Luxembourg, Malta, the Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia,
Spain, Sweden, Switzerland and the United Kingdom.

CENELEC
European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique
Europäisches Komitee für Elektrotechnische Normung

Management Centre: Avenue Marnix 17, B - 1000 Brussels


© 2011 CENELEC - All rights of exploitation in any form and by any means reserved worldwide for CENELEC members.
Ref. No. EN 62006:2011 E

---------------------- Page: 3 ----------------------

SIST EN 62006:2011
EN 62006:2011 - 2 -
Foreword
The text of document 4/254/FDIS, future edition 1 of IEC 62006, prepared by IEC TC 4, Hydraulic
turbines, was submitted to the IEC-CENELEC parallel vote and was approved by CENELEC as
EN 62006 on 2011-01-02.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CEN and CENELEC shall not be held responsible for identifying any or all such patent
rights.
The following dates were fixed:
– latest date by which the EN has to be implemented
at national level by publication of an identical
(dop) 2011-10-02
national standard or by endorsement
– latest date by which the national standards conflicting
(dow) 2014-01-02
with the EN have to be withdrawn
Annex ZA has been added by CENELEC.
__________
Endorsement notice
The text of the International Standard IEC 62006:2010 was approved by CENELEC as a European
Standard without any modification.
In the official version, for Bibliography, the following notes have to be added for the standards indicated:
IEC 60994 NOTE  Harmonized as EN 60994.
IEC 61116 NOTE  Harmonized as EN 61116.
IEC 61260 NOTE  Harmonized as EN 61260.
ISO 4373 NOTE  Harmonized as EN ISO 4373.
ISO 5167 series NOTE  Harmonized in EN ISO 5167 series (not modified)
__________

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SIST EN 62006:2011
- 3 - EN 62006:2011
Annex ZA
(normative)

Normative references to international publications
with their corresponding European publications

The following referenced documents are indispensable for the application 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.

NOTE  When an international publication has been modified by common modifications, indicated by (mod), the relevant EN/HD
applies.

Publication Year Title EN/HD Year

IEC 60041 1991 Field acceptance tests to determine the EN 60041 1994
hydraulic performance of hydraulic turbines,
storage pumps and pump-turbines


IEC 60193 - Hydraulic turbines, storage pumps and EN 60193 -
pump-turbines - Model acceptance tests


IEC 60308 - Hydraulic turbines - Testing of control EN 60308 -
systems


IEC 60609 Series Hydraulic turbines, storage pumps and EN 60609 Series
pump-turbines - Cavitation pitting evaluation


IEC 60651 - Sound level meters EN 60651 -


IEC 61362 - Guide to specification of hydraulic turbine EN 61362 -
control systems


ISO 1680 - Acoustics - Test code for the measurement EN ISO 1680 -
of airborne noise emitted by rotating electrical
machines


ISO 1940-1 2003 Mechanical vibration - Balance quality - -
requirements for rotors in a constant (rigid)
state -
Part 1: Specification and verification of
balance tolerances


ISO 3746 - Acoustics - Determination of sound power EN ISO 3746 -
levels of noise sources using sound pressure -
Survey method using an enveloping
measurement surface over a reflecting plane


ISO 4412 Series Hydraulic fluid power - Test code for - -
determination of airborne noise levels


ISO 5168 - Measurement of fluid flow - Estimation of - -
uncertainly of a flow-rate measurement


ISO 7919-5 - Mechanical vibration - Evaluation of machine - -
vibration by measurements on rotating shafts -
Part 5: Machine sets in hydraulic power
generating and pumping plants


ISO 10816-3 - Mechanical vibration - Evaluation of machine - -
vibration by measurements on non-rotating
parts -
Part 3: Industrial machines with nominal
power above 15 kW and nominal speeds
between 120 r/min and 15 000 r/min when
measured in situ

---------------------- Page: 5 ----------------------

SIST EN 62006:2011
EN 62006:2011 - 4 -

Publication Year Title EN/HD Year

ANSI/IEEE 810 - Hydraulic Turbine and Generator Integrally - -
Forged Shaft Couplings and Shaft Runout
Tolerances

---------------------- Page: 6 ----------------------

SIST EN 62006:2011

IEC 62006
®
Edition 1.0 2010-10
INTERNATIONAL
STANDARD
NORME
INTERNATIONALE
colour
inside


Hydraulic machines – Acceptance tests of small hydroelectric installations

Machines hydrauliques – Essais de réception des petits aménagements
hydroélectriques

INTERNATIONAL
ELECTROTECHNICAL
COMMISSION
COMMISSION
ELECTROTECHNIQUE
PRICE CODE
INTERNATIONALE
XE
CODE PRIX
ICS 27.140 ISBN 978-2-88912-228-8
® Registered trademark of the International Electrotechnical Commission
Marque déposée de la Commission Electrotechnique Internationale

---------------------- Page: 7 ----------------------

SIST EN 62006:2011
– 2 – 62006 © IEC:2010
CONTENTS
FOREWORD.7
1 Scope.9
2 Normative references .9
3 Terms, definitions and schematic layout .10
3.1 Terms and definitions .10
3.2 Schematic layout of a hydroelectric installation .10
4 Nature and extent of guarantees.11
4.1 Grouping of classes A, B, C.11
4.1.1 General .11
4.1.2 Contract conditions.13
4.2 Scope of performance guarantee.13
4.2.1 General .13
4.2.2 Class A: Maximum power output.13
4.2.3 Class B: Index test .13
4.2.4 Class C: Turbine efficiency .13
4.2.5 Interpretation of losses .13
4.3 Scope of tests .14
4.3.1 Safety tests .14
4.3.2 Trial run and reliability tests.14
4.3.3 Performance test .14
4.4 Aptitude.15
4.5 Warranty .15
5 Safety tests (commissioning) .16
5.1 Pre-start tests .16
5.2 Closing devices .16
5.2.1 General .16
5.2.2 Intake gate or valve .17
5.2.3 Turbine inlet valve .17
5.2.4 Guide vanes (Francis and Kaplan turbines) .17
5.2.5 Needle valve and deflector (Pelton and Turgo turbines).18
5.3 First run operation and control.19
5.4 Bearing run at rated speed .19
5.5 Emergency shutdown (no load) .20
5.6 Electrical protection.20
5.7 Overspeed test.21
5.8 Runaway test .21
5.9 Overpressure, emergency trip and load rejection tests .22
5.9.1 General conditions .22
5.9.2 Testing the guide vanes or needle valves .23
5.9.3 Testing the turbine inlet valve.23
5.9.4 Testing the pressure relief valve.23
5.9.5 Pressure rise .23
5.10 Measured quantities .25
5.10.1 Pressure.25
5.10.2 Speed.25
5.10.3 Control components.25

---------------------- Page: 8 ----------------------

SIST EN 62006:2011
62006 © IEC:2010 – 3 –
6 Trial operating and reliability tests (commissioning).25
6.1 General .25
6.2 Temperature stability of rotating parts .25
6.2.1 General .25
6.2.2 Temperature guarantees .26
6.3 Speed controller system .26
6.3.1 General .26
6.3.2 Unit operating without regulation .26
6.3.3 Unit operating with a speed governor.27
6.3.4 Unit operating with a voltage governor.28
6.3.5 Unit operating with a controller .28
6.3.6 Measurements when testing the control system .28
6.4 Control of cam correlation .29
7 Performance guarantees and tests .29
7.1 General .29
7.2 Maximum generator (transformer) power output as a function of net head .30
7.2.1 Guarantee .30
7.2.2 Instrumentation.30
7.3 Index test .30
7.3.1 General .30
7.3.2 Index discharge measurement .31
7.3.3 Shape control .31
7.3.4 Index plant efficiency.32
7.3.5 Optimizing cam correlation .33
7.4 Turbine efficiency.33
7.4.1 Efficiency test by absolute discharge measurement.33
7.4.2 Efficiency test by thermodynamic method .34
7.5 Correcting the efficiency using the model curve.34
8 Computation of results and comparison to the guarantee.36
8.1 General .36
8.1.1 Site data.36
8.1.2 Measured values (readings) .36
8.1.3 Scale effect due to water temperature .37
8.1.4 Shifting of the plant characteristic.37
8.2 Power output .37
8.2.1 Plant power output measurement .37
8.2.2 Generator power output measurement.38
8.2.3 Turbine power output measurement.38
8.3 Relative turbine efficiency (index test) .38
8.3.1 General .38
8.3.2 Relative discharge.38
8.3.3 Guarantee of the shape of the plant characteristics .39
8.3.4 Relative index plant efficiency .40
8.4 Absolute turbine efficiency .40
8.4.1 General .40
8.4.2 Absolute discharge .40
8.4.3 Guarantee of the plant efficiency and comparison to the results .40
9 Error analysis .40

---------------------- Page: 9 ----------------------

SIST EN 62006:2011
– 4 – 62006 © IEC:2010
9.1 General .40
9.2 Estimation of systematic (bias) uncertainties .41
9.2.1 General .41
9.2.2 Typical systematic uncertainties .41
9.2.3 Systematic uncertainty for turbines used to indicate discharge .42
9.3 Estimation of random (precision) uncertainties .42
9.3.1 Measurement at a single operation point .42
9.3.2 Measurement over a range of operating condition .44
9.4 Evaluation of the uncertainties .45
9.4.1 General .45
9.4.2 Head .45
9.4.3 Power output .47
9.4.4 Index test measurement .49
9.4.5 Efficiency test by absolute discharge measurement.51
9.4.6 Efficiency test by the thermodynamic method .51
10 Other guarantees .51
10.1 Cavitation.51
10.1.1 General .51
10.1.2 Measurement methods .52
10.1.3 Comparison with specified guarantees.52
10.2 Noise .53
10.2.1 General .53
10.2.2 Measurement methods .53
10.2.3 Comparison with specified guarantees.54
10.3 Vibration.54
10.3.1 General .54
10.3.2 Measurements and measurement methods.54
10.3.3 Comparison with specified guarantees.55
Annex A (normative) Terms, definitions, symbols and units.56
Annex B (normative) Head definition.64
Annex C (normative) Method of speed measurements .77
Annex D (normative) Power output measurement .78
Annex E (normative) Methods of discharge measurement.82
Annex F (informative) Plant condition .95
Annex G (informative) Commissioning .97
Annex H (informative) Performance test efficiency calculation .99
Annex I (informative) Cam correlation test . 106
Bibliography.109

Figure 1 – Schematic layout of a hydroelectric installation (water to wire system) .11
Figure 2 – Warranty period .16
Figure 3 – Vanes and blades servomotors force measurements (Kaplan on line) .17
Figure 4 – Evaluation of the guide vane (GV) closing characteristic .18
Figure 5 – Needle servomotor force .18
Figure 6 – Automatic start – Synchronization – No load test (Kaplan turbine).19
Figure 7 – Emergency shutdown from no load test (Kaplan turbine) .20

---------------------- Page: 10 ----------------------

SIST EN 62006:2011
62006 © IEC:2010 – 5 –
Figure 8 – Runaway test (Kaplan turbine) .21
Figure 9 – Emergency shutdown due to an electrical fault.22
Figure 10 – Emergency shutdown due to a mechanical fault .23
Figure 11 – Emergency shutdown due to the governor failure .24
Figure 12 – Evaluation of the maximum overpressure .24
Figure 13 – Temperature stability, recording at no load up to stable conditions.26
Figure 14 – Speed governor check at no load .27
Figure 15 – Maximum power output: procedure to compare measured power output at
actual net head to the guarantee.30
Figure 16 – Comparison of the shape of the turbine characteristic to the guarantee.32
Figure 17 – Example of an optimized switch band for 1 and 2 turbine operation.33
Figure 18 – Efficiency test: procedure to compare guaranteed turbine efficiency to the
prototype measurement results, including the overall uncertainties .34
Figure 19 – Hill chart – Showing head loss examples with one and two units in
operation using the same penstock.35
Figure 20 – Shifting of the performance curves .37
Figure 21 – Variation of factor k and exponent x on turbine index efficiency.39
Figure 22 – Random uncertainties of a single operation point, example for penstock
pressure variation and fluctuation .43
Figure 23 – Detection of outlier errors: example to find out offset and reading errors
by plotting in linear and logarithmic form with the same data.44
Figure 24 – Example of scattered points with function of second order .44
Figure 25 – Scattered points smoothed by individual fitting on adjacent sections .45
Figure 26 – Overall uncertainty of head for free water level for low head turbines .46
Figure 27 – Overall uncertainty of head in a closed conduit .47
Figure 28 – Estimated overall uncertainties of the discharge by index measurement
versus full scale differential pressure .50
Figure 29 – Operation range and cavitation limits .52
Figure A.1 – Transient pressure fluctuation at the turbine high pressure reference
section, when a specified load is suddenly rejected .61
Figure A.2 – Transient pressure fluctuation at the turbine high pressure reference
section, when a specified load is suddenly accepted.62
Figure B.1 – High pressure reference and measuring sections.65
Figure B.2 – Measuring section at tail water.66
Figure B.3 – Measuring section at draft tube.66
Figure B.4 – Definition of measuring sections .67
Figure B.5 – Kaplan turbine with horizontal shaft .68
Figure B.6 – Kaplan turbine with vertical shaft .68
Figure B.7 – Francis open flume turbine with vertical shaft .69
Figure B.8 – Francis turbine with horizontal shaft.69
Figure B.9 – Francis turbine with vertical shaft, with stagnation probe .70
Figure B.10 – Francis turbine with horizontal shaft with pressure on suction side.70
Figure B.11 – Pelton turbine with horizontal shaft .71
Figure B.12 – Pelton turbine with vertical shaft .71
Figure B.13 – Turgo turbine with horizontal shaft .72
Figure B.14 – Turgo turbine with vertical shaft .72

---------------------- Page: 11 ----------------------

SIST EN 62006:2011
– 6 – 62006 © IEC:2010
Figure B.15 – Crossflow turbine with horizontal shaft, with draft tube.73
Figure B.16 – Crossflow turbine with horizontal shaft, without draft tube .73
Figure B.17 – Specifications for static pressure taps.74
Figure B.18 – Example: discharge versus guide vane opening.76
Figure C.1 – Overspeed and runaway .77
Figure D.1 – Typical losses of a synchronous generator .79
Figure D.2 – Asynchronous generator: typical power factor and slip factor.80
Figure D.3 – Power measurement using the two wattmeter method.80
Figure D.4 – Power measurement using the three wattmeter method .81
Figure E.1 – Typical arrangements of acoustic transducers .
...

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although it is recognized that other standards specify different tolerances.
Brushless excitation system is not included in this document.
Wherever this document specifies that documents, drawings or information is supplied by a
manufacturer (or by manufacturers), each individual manufacturer will furnish the appropriate
information for their own supply only.

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SIST EN IEC 63132-1:2020(Main)
Guidance for installation procedures and tolerances of hydroelectric machines - Part 1: General aspects (IEC 63132-1:2020)
EN IEC 63132-1:2020

The purpose of this part of IEC 63132 is to establish, in a general way, suitable procedures and
tolerances for the installation of hydroelectric turbines and generators. This document presents
a typical assembly. There are many possible ways to assemble a unit. The size of the machines,
design of the machines, layout of the powerhouse and delivery schedule of the components are
some of the elements that could result in additional steps, the elimination of some steps and/or
assembly sequences.
It is understood that a publication of this type will be binding only if, and to the extent that, both
contracting parties have agreed upon it.
Installations for refurbishment projects or for small hydro projects are not in the scope of this
document. An agreement between all parties is necessary.
This document excludes matters of purely commercial interest, except those inextricably bound
up with the conduct of installation.
The tolerances in this document have been established upon best practices and experience,
although it is recognized that other standards specify different tolerances.
Wherever this document specifies that documents, drawings or information is supplied by a
manufacturer (or manufacturers), each individual manufacturer will furnish the appropriate
information for their own supply only.

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SIST EN IEC 60193:2019(Main)
Hydraulic turbines, storage pumps and pump-turbines - Model acceptance tests (IEC 60193:2019)
EN IEC 60193:2019

This document applies to laboratory models of any type of impulse or reaction hydraulic turbine,
storage pump or pump-turbine.
This document applies to models of prototype machines either with unit power greater than
5 MW or with reference diameter greater than 3 m. Full application of the procedures herein
prescribed is not generally justified for machines with smaller power and size. Nevertheless,
this document may be used for such machines by agreement between the purchaser and the
supplier.
In this document, the term "turbine" includes a pump-turbine operating as a turbine and the
term "pump" includes a pump-turbine operating as a pump.
This document excludes all matters of purely commercial interest, except those inextricably
bound up with the conduct of the tests.
This document is concerned with neither the structural details of the machines nor the
mechanical properties of their components, so long as these do not affect model performance
or the relationship between model and prototype performances.
This document covers the arrangements for model acceptance tests to be performed on
hydraulic turbines, storage pumps and pump-turbines to determine if the main hydraulic
performance contract guarantees (see 4.2) have been satisfied.
It contains the rules governing test conduct and prescribes measures to be taken if any phase
of the tests is disputed.
The main objectives of this document are:
– to define the terms and quantities used;
– to specify methods of testing and of measuring the quantities involved, in order to ascertain
the hydraulic performance of the model;
– to specify the methods of computation of results and of comparison with guarantees;
– to determine if the contract guarantees that fall within the scope of this document have been
fulfilled;
– to define the extent, content and structure of the final report.
The guarantees can be given in one of the following ways:
– guarantees for prototype hydraulic performance, computed from model test results
considering scale effects;
– guarantees for model hydraulic performance.
Moreover, additional performance data (see 4.4) can be needed for the design or the operation
of the prototype of the hydraulic machine. Contrary to the requirements of Clauses 4 to 6 related
to main hydraulic performance, the information of these additional data given in Clause 7 is
considered only as recommendation or guidance to the user (see 7.1).
It is particularly recommended that model acceptance tests be performed if the expected field
conditions for acceptance tests (see IEC 60041:1991) would not allow the verification of
guarantees given for the prototype machine.
A transposition method taking into account the model and prototype wall surface roughness for
the performance conversion on pump-turbines, Francis turbines, and axial machines is
described in IEC 62097. This method requires model and prototype surface roughness data and
is takes into account the shift in nED, QED and PED factors for determining the transposition of
efficiency between model and prototype. However, in the case of Francis machines with semispiral
casing and axial machines, the transposition method has not been fully validated due to
a lack of data. In addition, IEC 62097 does not apply to storage pumps, Pelton turbines, and
Dériaz. Therefore, for these and otherwise specifically agreed upon cases where hydraulically
smooth flow conditions are assumed on the model and the prototype, the transposition formula
and procedure given in Annex D and Annex I can be applied. Applications and limitations of
both this document and IEC 62097 transposition methods are discussed in Annex E.
The method for performance conversion from model to prototype needs to be clearly defined in
the main hydraulic performance contract.

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SIST EN IEC 62097:2019(Amendment)
Hydraulic machines, radial and axial - Methodology for performance transposition from model to prototype (IEC 62097:2019)
EN IEC 62097:2019

This International Standard establishes the prototype hydraulic machine efficiency from model
test results, with consideration of scale effect including the effect of surface roughness.
This document is intended to be used for the assessment of the results of contractual model
tests of hydraulic machines.

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SIST EN IEC 62364:2019(Main)
Hydraulic machines - Guide for dealing with hydro-abrasive erosion in Kaplan, Francis, and Pelton turbines (IEC 62364:2019)
EN IEC 62364:2019

This document gives guidelines for:
a) presenting data on hydro-abrasive erosion rates on several combinations of water quality, operating conditions, component materials, and component properties collected from a variety of hydro sites;
b) developing guidelines for the methods of minimizing hydro-abrasive erosion by modifications to hydraulic design for clean water. These guidelines do not include details such as hydraulic profile shapes which are determined by the hydraulic design experts for a given site;
c) developing guidelines based on “experience data” concerning the relative resistance of materials faced with hydro-abrasive erosion problems;
d) developing guidelines concerning the maintainability of materials with high resistance to hydro-abrasive erosion and hardcoatings;
e) developing guidelines on a recommended approach, which owners could and should take to ensure that specifications communicate the need for particular attention to this aspect of hydraulic design at their sites without establishing criteria which cannot be satisfied because the means are beyond the control of the manufacturers;
f) developing guidelines concerning operation mode of the hydro turbines in water with particle materials to increase the operation life.
It is assumed in this document that the water is not chemically aggressive. Since chemical aggressiveness is dependent upon so many possible chemical compositions, and the materials of the machine, it is beyond the scope of this document to address these issues.
It is assumed in this document that cavitation is not present in the turbine. Cavitation and hydro-abrasive erosion can reinforce each other so that the resulting erosion is larger than the sum of cavitation erosion plus hydro-abrasive erosion. The quantitative relationship of the resulting hydro-abrasive erosion is not known and it is beyond the scope of this document to assess it, except to suggest that special efforts be made in the turbine design phase to minimize cavitation.
Large solids (e.g. stones, wood, ice, metal objects, etc.) traveling with the water can impact turbine components and produce damage. This damage can in turn increase the flow turbulence thereby accelerating wear by both cavitation and hydro-abrasive erosion. Hydroabrasive erosion resistant coatings can also be damaged locally by impact of large solids. It isbeyond the scope of this document  to address these issues.
This document focuses mainly on hydroelectric powerplant equipment. Certain portions can
also be applicable to other hydraulic machines.

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SIST EN 62256:2017(Main)
Hydraulic turbines, storage pumps and pump-turbines - Rehabilitation and performance improvement (IEC 62256:2017)
EN 62256:2017

This document covers turbines, storage pumps and pump-turbines of all sizes and of the
following types:
• Francis;
• Kaplan;
• propeller;
• Pelton (turbines only);
• bulb turbines.
This document also identifies without detailed discussion, other powerhouse equipment that
could affect or be affected by a turbine, storage pump, or pump-turbine rehabilitation.
The object of this document is to assist in identifying, evaluating and executing rehabilitation
and performance improvement projects for hydraulic turbines, storage pumps and pumpturbines.
This document can be used by owners, consultants, and suppliers to define:
• needs and economics for rehabilitation and performance improvement;
• scope of work;
• specifications;
• evaluation of results.
This document is intended to be:
• an aid in the decision process;
• an extensive source of information on rehabilitation;
• an identification of the key milestones in the rehabilitation process;
• an identification of the points to be addressed in the decision processes.
This document is not intended to be a detailed engineering manual nor a maintenance
document.

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