I.S. EN 12975-2:2006
Superseded
A superseded Standard is one, which is fully replaced by another Standard, which is a new edition of the same Standard.
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THERMAL SOLAR SYSTEMS AND COMPONENTS - SOLAR COLLECTORS - PART 2: TEST METHODS
Hardcopy , PDF
11-27-2013
English
01-01-2006
For Harmonized Standards, check the EU site to confirm that the Standard is cited in the Official Journal.
Only cited Standards give presumption of conformance to New Approach Directives/Regulations.
Foreword
Introduction
1 Scope
2 Normative references
3 Terms and definitions
4 Symbols and units
5 Reliability testing of liquid heating collectors
5.1 General
5.2 Internal pressure tests for absorbers
5.2.1 Inorganic absorbers
5.2.2 Absorbers made of organic materials
(plastics or elastomers)
5.3 High-temperature resistance test
5.3.1 Objective
5.3.2 Apparatus and procedure
5.3.3 Test conditions
5.3.4 Results
5.4 Exposure test
5.4.1 Objective
5.4.2 Apparatus and procedure
5.4.3 Test conditions
5.4.4 Results
5.5 External thermal shock test
5.5.1 Objective
5.5.2 Apparatus and procedure
5.5.3 Test conditions
5.5.4 Results
5.6 Internal thermal shock test
5.6.1 Objective
5.6.2 Apparatus and procedure
5.6.3 Test conditions
5.6.4 Results
5.7 Rain penetration test
5.7.1 Objective
5.7.2 Apparatus and procedure
5.7.3 Test conditions
5.7.4 Results
5.8 Freeze resistance test
5.8.1 Objective
5.8.2 Apparatus and procedure
5.8.3 Test conditions
5.8.4 Results
5.9 Mechanical load test
5.9.1 Positive pressure test of the collector
5.9.2 Negative pressure test of the collector
5.10 Impact resistance test (optional)
5.10.1 Objective
5.10.2 Apparatus and procedure
5.10.3 Test conditions
5.10.4 Results
5.11 Final inspection
5.12 Test report
6 Thermal performance testing of liquid heating collectors
6.1 Glazed solar collectors under steady state conditions
(including pressure drop)
6.1.1 Collector mounting and location
6.1.2 Instrumentation
6.1.3 Test installation
6.1.4 Outdoor steady-state performance test
6.1.5 Steady-state efficiency test using a solar
irradiance simulator
6.1.6 Determination of the effective thermal capacity
and the time constant of a collector
6.1.7 Collector incidence angle modifier
6.1.8 Determination of the pressure drop across a collector
6.2 Unglazed solar collectors under steady state conditions
(including pressure drop)
6.2.1 Collector mounting and location
6.2.2 Instrumentation
6.2.3 Test installation
6.2.4 Outdoor steady state efficiency test
6.2.5 Steady-state efficiency test using a solar irradiance
simulator
6.2.6 Determination of the effective thermal capacity
and the time constant of a collector
6.2.7 Incidence angle modifier (optional)
6.2.8 Determination of the pressure drop across a collector
6.3 Glazed and unglazed solar collectors under
quasi-dynamic conditions
6.3.1 Collector mounting and location
6.3.2 Instrumentation
6.3.3 Test installation
6.3.4 Outdoor efficiency test
6.3.5 Determination of the effective thermal capacity
6.3.6 Collector incidence angle modifier
Annex A (normative) Schematics for durability and
reliability tests
Annex B (normative) Durability and reliability test report
sheets
B.1 Record of test sequence and summary of main
results
B.2 Internal pressure test for inorganic absorbers
B.2.1 Technical details of collector
B.2.2 Test conditions
B.2.3 Test results
B.3 Internal pressure test for absorbers made of organic
materials
B.3.1 Technical details of collector
B.3.2 Test conditions
B.3.3 Test results
B.4 High-temperature resistance test
B.4.1 Method used to heat collectors
B.4.2 Test conditions
B.4.3 Test results
B.5 Exposure test
B.5.1 Test conditions
B.5.2 Test results
B.5.3 Climatic conditions for all days during the test
B.5.4 Time periods in which irradiance and surrounding
air temperature have values greater than those
specified in Table 4
B.5.5 Inspection results
B.6 External thermal shock test:
B.6.1 Test conditions
B.6.2 Test results
B.7 Internal thermal shock test:
B.7.1 Test conditions
B.7.2 Test results
B.8 Rain penetration test
B.8.1 Test conditions
B.8.2 Test results
B.9 Freeze resistance test
B.9.1 Collector type
B.9.2 Test conditions
B.9.3 Test results
B.10 Mechanical load test
B.10.1 Positive pressure test of the collector cover
B.10.2 Negative pressure test of fixings between the
cover and the collector box
B.10.3 Negative pressure test of collector mountings
B.11 Impact resistance test using steel balls
B.11.1 Test conditions
B.11.2 Test procedure
B.11.3 Test results
B.12 Impact resistance test using ice balls
B.12.1 Test conditions
B.12.2 Test procedure
B.12.3 Test results
B.13 Final inspection results
Annex C (normative) Stagnation temperature of liquid
heating collectors
C.1 General
C.2 Determination of stagnation temperature
Annex D (normative) Performance test report for glazed
solar collectors
D.1 General
D.2 Solar collector description
D.3 Test results
Annex E (normative) Performance test report for unglazed
solar collectors
E.1 General
E.2 Solar collector description
E.3 Test results
Annex F (normative) Modelling of the coefficients c[1] to c[6]
of the collector model of 6.3
Annex G (normative) Measurement of effective thermal
capacity
G.1 Test installation
G.2 Indoor test procedure
G.2.1 General
G.2.2 Measurements
G.2.3 Calculation of the effective thermal capacity
G.2.4 Determination of effective thermal capacity from
experimental data
G.3 Outdoor or solar irradiance simulator test procedure
Annex H (informative) Comparison of the collector model
of 6.1 to the collector model of 6.3
Annex I (informative) Properties of water
I.1 Density of water (at 1 bar) in kg/m[3]
I.2 Specific heat capacity of water (at 1 bar) in kJ/(kg K)
Annex J (informative) Performance test report summary for
quasi dynamic test method
Annex K (informative) General guidelines for the assessment
of uncertainty in solar collector efficiency
testing
K.1 Introduction
K.2 Measurement uncertainties in solar collector
efficiency testing
Annex L (informative) Determination of the pressure drop
across a collector
L.1 General
L.2 Test installation
L.3 Preconditioning of the collector
L.4 Test procedure
L.5 Measurements
L.6 Pressure drop caused by fittings
L.7 Test conditions
L.8 Calculation and presentation of results
Bibliography
Defines test methods for validating the durability, reliability and safety requirements for liquid heating collectors as specified in EN 12975-1.
DocumentType |
Standard
|
Pages |
142
|
PublisherName |
National Standards Authority of Ireland
|
Status |
Superseded
|
SupersededBy | |
Supersedes |
Standards | Relationship |
UNI EN 12975-2 : 2006 | Identical |
NBN EN 12975-2 : 2006 | Identical |
EN 12975-2:2006 | Identical |
SN EN 12975-2 : 2006 | Identical |
NEN EN 12975-2 : 2006 | Identical |
NF EN 12975-2 : 2006 | Identical |
NS EN 12975-2 : 2ED 2006 | Identical |
BS EN 12975-2:2006 | Identical |
UNE-EN 12975-2:2006 | Identical |
DIN EN 12975-2:2006-06 | Identical |
S.R. 50-2:2012 | BUILDING SERVICES CODE OF PRACTICE - PART 2: THERMAL SOLAR SYSTEMS |
ISO 9845-1:1992 | Solar energy — Reference solar spectral irradiance at the ground at different receiving conditions — Part 1: Direct normal and hemispherical solar irradiance for air mass 1,5 |
ISO 9459-1:1993 | Solar heating — Domestic water heating systems — Part 1: Performance rating procedure using indoor test methods |
ISO 9488:1999 | Solar energy Vocabulary |
ISO 9060:1990 | Solar energy Specification and classification of instruments for measuring hemispherical solar and direct solar radiation |
ISO 9553:1997 | Solar energy — Methods of testing preformed rubber seals and sealing compounds used in collectors |
EN 12975-1:2006+A1:2010 | Thermal solar systems and components - Solar collectors - Part 1: General requirements |
NFP 50 501 : 1980 | LIQUID CIRCULATION SOLAR DETECTING ELEMENTS - MEASUREMENT OF THERMAL PERFORMANCES |
ISO/TR 9901:1990 | Solar energy Field pyranometers Recommended practice for use |
ISO 9847:1992 | Solar energy — Calibration of field pyranometers by comparison to a reference pyranometer |
EN ISO 5167-1:2003 | Measurement of fluid flow by means of pressure differential devices inserted in circular cross-section conduits running full - Part 1: General principles and requirements (ISO 5167-1:2003) |
EN ISO 9488:1999 | Solar energy - Vocabulary (ISO 9488:1999) |
ISO 5167-1:2003 | Measurement of fluid flow by means of pressure differential devices inserted in circular cross-section conduits running full Part 1: General principles and requirements |
ISO 9459-2:1995 | Solar heating — Domestic water heating systems — Part 2: Outdoor test methods for system performance characterization and yearly performance prediction of solar-only systems |
ASHRAE HDBK REFRIGERATION : 2014 | ASHRAE HANDBOOK - REFRIGERATION |
ASHRAE 41.7 : 2015 | METHODS FOR GAS FLOW MEASUREMENT |
ISO 9806-1:1994 | Test methods for solar collectors Part 1: Thermal performance of glazed liquid heating collectors including pressure drop |
ISO 9808:1990 | Solar water heaters — Elastomeric materials for absorbers, connecting pipes and fittings — Method of assessment |
BS 6757:1986 | Methods of test for thermal performance of solar collectors |
ISO 9846:1993 | Solar energy Calibration of a pyranometer using a pyrheliometer |
ISO 9806-2:1995 | Test methods for solar collectors Part 2: Qualification test procedures |
ISO 9806-3:1995 | Test methods for solar collectors — Part 3: Thermal performance of unglazed liquid heating collectors (sensible heat transfer only) including pressure drop |
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