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ASTM E2908-12

(Guide)

Standard Guide for Fire Prevention for Photovoltaic Panels, Modules, and Systems

Standard Guide for Fire Prevention for Photovoltaic Panels, Modules, and Systems

SIGNIFICANCE AND USE
5.1 Photovoltaic modules are electrical dc sources. dc sources have unique considerations with regards to arc formation and interruption, as once formed, the arc is not automatically interrupted by an alternating current. Solar modules are energized whenever modules in the string are illuminated by sunlight, or during fault conditions.  
5.2 With the rapid increase in the number of photovoltaic system installations, this guide attempts to increase awareness of methods to reduce the risk of fire from photovoltaic systems.  
5.3 This guide is intended for use by module manufacturers, panel assemblers, system designers, installers, and specifiers.  
5.4 This guide may be used to specify minimum requirements. It is not intended to capture all conditions or scenarios which could result in a fire.
SCOPE
1.1 This guide describes basic principles of photovoltaic module design, panel assembly, and system installation to reduce the risk of fire originating from the photovoltaic source circuit.  
1.2 This guide is not intended to cover all scenarios which could lead to fire. It is intended to provide an assembly of generally-accepted practices.  
1.3 This guide is intended for systems which contain photovoltaic modules and panels as dc source circuits, although the recommended practices may also apply to systems utilizing ac modules.  
1.4 This guide does not cover fire suppression in the event of a fire involving a photovoltaic module or system.  
1.5 This guide does not cover fire emanating from other sources.  
1.6 This guide does not cover mechanical, structural, electrical, or other considerations key to photovoltaic module and system design and installation.  
1.7 This guide does not cover disposal of modules damaged by a fire, or other material hazards related to such modules.  
1.8 Units—The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.9 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.

General Information

Status
Historical
Publication Date
30-Nov-2012
ICS
27.160 - Solar energy engineering
Technical Committee
E44 - Solar, Geothermal and Other Alternative Energy Sources
Drafting Committee
E44.09 - Photovoltaic Electric Power Conversion
Current Stage
Ref Project

Relations

Referred By
ASTM E3010-15(2019)e1 - Standard Practice for Installation, Commissioning, Operation, and Maintenance Process (ICOMP) of Photovoltaic Arrays
Effective Date
01-Dec-2012

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ASTM E2908-12 - Standard Guide for Fire Prevention for Photovoltaic Panels, Modules, and SystemsASTM E2908-12 - Standard Guide for Fire Prevention for Photovoltaic Panels, Modules, and Systems
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ASTM E2908-12 - Standard Guide for Fire Prevention for Photovoltaic Panels, Modules, and Systems
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NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation: E2908 − 12
Standard Guide for
Fire Prevention for Photovoltaic Panels, Modules, and
Systems
This standard is issued under the fixed designation E2908; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 2. Referenced Documents
1.1 This guide describes basic principles of photovoltaic 2.1 ASTM Standards:
module design, panel assembly, and system installation to E772 Terminology of Solar Energy Conversion
reduce the risk of fire originating from the photovoltaic source E2481 Test Method for Hot Spot Protection Testing of
circuit. Photovoltaic Modules
1.2 This guide is not intended to cover all scenarios which 2.2 Other Standards and Documents:
could lead to fire. It is intended to provide an assembly of IEC 61215 Crystalline silicon terrestrial photovoltaic (PV)
generally-accepted practices. modules—Design qualification and type approval
IEC 61730 Photovoltaic (PV) module safety qualification
1.3 This guide is intended for systems which contain pho-
North American Board of Certified Energy Practitioners
tovoltaicmodulesandpanelsasdcsourcecircuits,althoughthe
(NABCEP), Study Guide for Photovoltaic System Install-
recommended practices may also apply to systems utilizing ac
ers
modules.
NFPA 70 US National Electrical Code (article 690)
1.4 This guide does not cover fire suppression in the event
UL 1703 Standard for Flat-Plate Photovoltaic Modules and
of a fire involving a photovoltaic module or system.
Panels
UL 1741 Inverters, Converters, and Controllers for Use in
1.5 This guide does not cover fire emanating from other
Independent Power Systems
sources.
1.6 This guide does not cover mechanical, structural,
3. Terminology
electrical, or other considerations key to photovoltaic module
and system design and installation. 3.1 Definitions of terms used in this standard may be found
in Terminology E772.
1.7 This guide does not cover disposal of modules damaged
by a fire, or other material hazards related to such modules. 3.2 Definitions:
3.2.1 ground fault, n—a condition where there is an unin-
1.8 Units—The values stated in SI units are to be regarded
tended electrical connection between the active PV circuit and
as standard. No other units of measurement are included in this
ground.
standard.
1.9 This standard does not purport to address all of the
4. Summary of Practice
safety concerns, if any, associated with its use. It is the
4.1 Photovoltaic modules and panels should be designed to
responsibility of the user of this standard to establish appro-
minimize the risk of fire and should be assembled with good
priate safety and health practices and determine the applica-
quality-control practices.
bility of regulatory limitations prior to use.
This test method is under the jurisdiction of ASTM Committee E44 on Solar,
Geothermal and OtherAlternative Energy Sources and is the direct responsibility of For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Subcommittee E44.09 on Photovoltaic Electric Power Conversion. contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Current edition approved Dec. 1, 2012. Published December 2012. DOI: Standards volume information, refer to the standard’s Document Summary page on
10.1520/E2908-12. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E2908 − 12
4.2 Photovoltaic systems should be designed to minimize 6.2.1 Both ac and dc circuits may be present in a solar
the risk of fire, and installed with fire safety in mind. Installers photovoltaic system, and both circuits contain potential arc
should be aware of PV-related fires that have occurred and the sources. A dc arc may be sustained over a larger distance and
cause of those fires. longer duration than an ac arc due to the one-directional flow
ofthedccurrent,whichisnoteasilyinterrupted.Thecurrentin
5. Significance and Use an ac arc always goes to zero twice per cycle.
5.1 Photovoltaic modules are electrical dc sources. dc
7. PV Modules and Panels
sources have unique considerations with regards to arc forma-
7.1 Design Against Arcing—Modules shall be designed to
tion and interruption, as once formed, the arc is not automati-
reduce the risk of arcing.
cally interrupted by an alternating current. Solar modules are
7.1.1 Modules shall meet the spacing requirements of IEC
energized whenever modules in the string are illuminated by
61730 or UL 1703 to reduce the occurrence of arcing under
sunlight, or during fault conditions.
both normal operating conditions and fault conditions.
5.2 With the rapid increase in the number of photovoltaic
7.1.2 MaterialsandprocessesusedinthemanufactureofPV
system installations, this guide attempts to increase awareness
modules shall be designed to be durable and reliable over the
ofmethodstoreducetheriskoffirefromphotovoltaicsystems.
entire service life of the PV module.
5.3 This guide is intended for use by module manufacturers, 7.1.3 Failure mechanisms, such as mismatch of thermal
expansion coefficients, metal fatigue, corrosion or vibration,
panel assemblers, system designers, installers, and specifiers.
shall be considered during the selection of materials, module
5.4 This guide may be used to specify minimum require-
lay-out, and assembly.
ments. It is not intended to capture all conditions or scenarios
7.1.4 Material selection shall include consideration of the
which could result in a fire.
operatingtemperaturesofthematerialandagingcharacteristics
of the material.
6. Arcing
7.2 Design for Arc and Fire Suppression:
6.1 dc Arcing:
7.2.1 Materials in close contact to potential arc sources,
6.1.1 An electrical arc can form where an electric potential
such as junction boxes, shall have a minimum arc and
exists between two neighboring conductors. Unlike ac arcs
flammability rating in accordance with IEC 61730 or UL1703.
which may be extinguished during the alternating-cycle of
This helps to reduce the risk of fire in the event of an arcing
current, a dc arc will be maintained indefinitely until inter-
event.
rupted. A dc arc will be sustained until the voltage potential is
7.2.2 According to the 2011 National Electrical Code, an
reduced,anarc-detectiondevicedisruptstheflowofcurrent,or
arc-detection device is required to disconnect the current flow
the effective distance between the conductors becomes too
in the event of arcing. Depending on the location of the device,
large to sustain the arc. Even once the arc is eliminated, the arc
it may protect an individual module or an entire string.
may have been sufficient to cause burning or ignition of
Consideration shall be given to the reliability of such devices,
surrounding materials.
to avoid nuisance trips and costly servicing.
6.1.2 Anarcmaypropagateacrossthesurfaceofthemodule
7.3 Operating Temperature:
(for example, along the gap between rows of cells) as materials
7.3.1 A PV module converts a portion of the sun’s energy
are burned away.
into electrical energy. The portion of the sun’s energy that is
6.1.3 The arc may extinguish and re-ignite under variable
not converted into electrical energy is either reflected, trans-
environmental conditions or with expansion and contraction of
mitted through the module, or transformed into heat energy.
affected materials, and may also extinguish at night and restart
Therefore, a PV module usually operates at a temperature
the next day.
hotter than the surrounding ambient temperature.
6.1.4 Common sources of arcs in PV modules:
7.3.2 Operating Temperature Considerations—The exact
6.1.4.1 Cracks in solar cells (crystalline or thin film).
operating temperature of a module, and of any given compo-
6.1.4.2 Inadequate spacing between parts of different volt-
nent within a module, depends on a variety of factors.
age potentials.
7.3.2.1 Environmental Factors—Wind speed, wind
6.1.4.3 Improper bonding of interconnects to cells.
direction, ambient temperature, solar irradiance, and cloud
6.1.4.4 Improper bonding of interconnects to bus bar.
cover.
6.1.4.5 Improper bonding of bus bar to wiring terminal or
7.3.2.2 Installation Factors—Angle of installation, rack
connector.
type, module spacing, location, wind obstructions, tracking
6.1.4.6 Insufficient allowance for thermal expansion and
versus non-tracking, ventilation, shading events.
contraction of materials, which leads to mechanical fatigue.
7.3.2.3 Module Factors—Cell mismatch (leading to non-
Common examples include cell interconnects and expansion
uniform heat generation), insulated sections (e.g. junction
joints in conduits.
boxes), color, framing, transparency, material thermal
6.1.4.7 Insufficient strain relief between parts; especially
conductivity, thermal convection characteristics, current-
field wiring terminations, solder joints, and internal conduc-
carrying limits of live parts.
tors.
7.3.3 Shading—Shadingeventscancauseshadedcellstoact
6.2 ac Arcing: as power sinks (resistors) as opposed to power generators.
E2908 − 12
Therefore, shaded cells can run much hotter than neighboring 8.1.2 Module-to-Module Connections—All wiring and con-
cells. Although modules are designed to operate in un-shaded nectors used shall be of the type and sizing recommended by
conditions, some degree of localized shading is inevitable in the module manufacturer and in accordance with local codes.
most installations. Refer to Test Method E2481 for additional Wiring shall be suitable for the intended application, including
information. temperature range, wire gauge, UV resistance, water
resistance, and system voltage. Consideration shall be given to
7.3.3.1 Theamountofheatingofacelldependsontheshunt
the extreme and nominal conditions expected throughout the
and series resistance characteristics of the shaded cells, the
module lifetime. The means for connection shall be in accor-
current flowing through the cell, and whether the cells are
dance with the module and connector Installation Guides or
partially illuminated.
any applicable local codes. Wiring shall be mechanically
7.3.3.2 Material Combustion—Materials in contact with
secured, if required, to prevent strain on the electrical
cells shall be able to withstand temperatures under the shaded
connections, with adequate slack to allow for thermal expan-
condition without exceeding material ignition temperature
sion and contraction of the wiring.
ratings. The design may be tested to assess material suitability
8.1.3 Other Wiring—All other wiring in the PVsystem shall
per UL 1703, Section 19, Temperature Test.
be suitable for the intended application and secured if required,
7.3.3.3 Modules shall have adequate protection in the event
with consideration given to the same factors as described for
of shading.
module-to-module wiring. Wiring securement means must be
7.3.3.4 Diodes—A common method for providing shading
able to withstand outdoor conditions, including UV radiation,
protection is through bypass diodes connected in parallel with
over the expected service life of the system, and should be
the cells to be protected. As the forward and reverse charac-
checked routinely as part of regular system maintenance. If
teristics of a PV cell are different, the diodes shall be sized to
wiring is in metallic conduit, particular attention should be
activate in the event of shading of part or all of one or more of
giventoproperinstallationandwiremanagementtechniquesto
the cells to prevent the formation of localized hot spots. The
reduce the possibility of ground faults.
diodes must be able to safely handle the string current.
8.1.4 dc Disconnects—dc disconnects shall be used to allow
Activation of the diode during a cell shading event shall not
safe disconnection of a dc string from an inverter, combiner
result in overheating of the diode, nor materials surrounding
box, charge controller or other electrical components in the
the diode. The diode shall be mounted and connected using a
system. The disconnect shall be rated appropriately for the dc
robust and reliable method, including strain relief as appropri-
current and voltage of the system, in accordance with local
ate. Diode quality and the mounting method should be evalu-
codes. Note that an ac-only disconnect may or may not be
ated for durability. If diodes are mounted mechanically, they
suitable for a dc circuit, as it relies on the alternating-nature of
should be tested under simulated field conditions to ensure that
ac current to disrupt the current flow.
adequate contact is maintained over time.
8.1.5 Inverters—Inverters shall be appropriately sized for
7.4 Documentation:
the intended location, be approved to the local standard, such
7.4.1 Recognition—The module should be certified by an
as UL 1741, and meet local code requirements for connection
approved organization to meet a minimum level of safety. Two
tothegrid.Invertersmayhavebuilt-inarc-detectioncapability,
standards that are commonly used to assess a minimum safety
which disconnects the system in the event of an arc to reduce
level are UL 1703 and IEC 61730.
damage to the system and supporting structures.
7.4.2 Quality System—The PV manufacturer shall have an
8.1.6 Ground Fault Protection—Consideration shall be
established quality system to ensure all modules manufactured given to the grounding scheme, to minimize arcing and
meet a basic level of quality from a fire safety standpoint.
potential current pathways between live parts and ground
Sourcesofdcarcingshallbegivenspecificattention,aswellas potential.
any material or process steps critical to module operating
8.2 Operating Temperature:
temperature.
8.2.1 The operating temperature of a PV module is highly
7.4.3 Installation Guide—Any limitations on installation
dependent upon the installation location and installation meth-
locationorconditionscriticaltothesafeoperatingstateofaPV
ods used.
system shall be indicated in the Installation Guide. This may
8.2.2 The design of a PV system shall be such that the
include ambient conditions, mounting configuration, wiring
operating temperatures of the PV modules and all components
requirements, over-current protection devices and fuse ratings.
fall within the rated values. Materials suitable for the installa-
tion location and operating temperatures under both normal
8. PV Systems
and fault conditions (such as shading and reverse current) shall
8.1 System Design Considerations: be used.
8.2.3 Do not allow concentrated sunlight to fall on the
8.1.1 Series Fuse Protection—In most cases where two
...

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ASTM E2908-12(2023)(Guide)
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SIGNIFICANCE AND USE
5.1 Photovoltaic modules are electrical dc sources. dc sources have unique considerations with regards to arc formation and interruption, as once formed, the arc is not automatically interrupted by an alternating current. Solar modules are energized whenever modules in the string are illuminated by sunlight, or during fault conditions.  
5.2 With the rapid increase in the number of photovoltaic system installations, this guide attempts to increase awareness of methods to reduce the risk of fire from photovoltaic systems.  
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1.1 This guide describes basic principles of photovoltaic module design, panel assembly, and system installation to reduce the risk of fire originating from the photovoltaic source circuit.  
1.2 This guide is not intended to cover all scenarios which could lead to fire. It is intended to provide an assembly of generally accepted practices.  
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4.1 Environmental stress tests, such as those listed in 1.2, are normally used to evaluate module designs prior to production or purchase. These test methods rely on performing electrical tests and visual inspections of modules before and after stress testing to determine the effects of the exposures.  
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SIGNIFICANCE AND USE
4.1 The design of a photovoltaic module or system intended to provide safe conversion of the sun's radiant energy into useful electricity must take into consideration the possibility of partial shadowing of the module(s) during operation. This test method describes a procedure for verifying that the design and construction of the module provides adequate protection against the potential harmful effects of hot spots during normal installation and use.  
4.2 This test method describes a procedure for determining the ability of the module to provide protection from internal defects which could cause loss of electrical insulation or combustion hazards.  
4.3 Hot spot heating occurs in a module when its operating current exceeds the reduced short-circuit current (ISC) of a shadowed or faulty cell or group of cells. When such a condition occurs, the affected cell or group of cells is forced into reverse bias and must dissipate power, which can cause overheating.
Note 1: The correct use of bypass diodes can prevent hot spot damage from occurring.  
4.4 Fig. 1 illustrates the hot spot effect in a module of a series string of cells, one of which, cell Y, is partially shadowed. The amount of electrical power dissipated in Y is equal to the product of the module current and the reverse voltage developed across Y. For any irradiance level, when the reverse voltage across Y is equal to the voltage generated by the remaining (s-1) cells in the module, power dissipation is at a maximum when the module is short-circuited. This is shown in Fig. 1 by the shaded rectangle constructed at the intersection of the reverse I-V characteristic of Y with the image of the forward I-V characteristic of the (s-1) cells.
FIG. 1 Hot Spot Effect  
4.5 Bypass diodes, if present, as shown in Fig. 2, begin conducting when a series-connected string in a module is in reverse bias, thereby limiting the power dissipation in the reduced-output cell.  
FIG. 2 Bypass Diode Effect  
Note 2: If the ...
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1.1 This test method provides a procedure to determine the ability of a photovoltaic (PV) module to endure the long-term effects of periodic “hot spot” heating associated with common fault conditions such as severely cracked or mismatched cells, single-point open circuit failures (for example, interconnect failures), partial (or nonuniform) shadowing, or soiling. Such effects typically include solder melting or deterioration of the encapsulation, but in severe cases could progress to combustion of the PV module and surrounding materials.  
1.2 There are two ways that cells can cause a hot spot problem: either by having a high resistance so that there is a large resistance in the circuit, or by having a low resistance area (shunt) such that there is a high current flow in a localized region. This test method selects cells of both types to be stressed.  
1.3 This test method does not establish pass or fail levels. The determination of acceptable or unacceptable results is beyond the scope of this test method.  
1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E2939-13(2023)(Practice)
Standard Practice for Determining Reporting Conditions and Expected Capacity for Photovoltaic Non-Concentrator Systems

SIGNIFICANCE AND USE
5.1 This practice can be used to determine an expected capacity for an existing or a proposed photovoltaic system in a particular location during a specified period of time (see data collection period in Test Method E2848).  
5.2 The expected capacity calculated in accordance with this practice can be compared with the capacity measured according to Test Method E2848 when the RC are the same.  
5.3 The comparison of expected capacity and measured capacity can be used as a criterion for plant acceptance.  
5.4 The user of this practice must select the performance simulation period over which the reporting conditions and expected capacity will be derived. Seasonal variations will likely cause both of these to change with differing performance simulation periods.  
5.5 When this practice is used in conjunction with Test Method E2848, the performance simulation period and the data collection period must agree. If they do not agree, the comparison between expected and measured capacity will not be meaningful.  
5.6 Historical or measured5 plane-of-array irradiance, ambient air temperature, and wind speed data can be used to select reporting conditions and calculate expected capacity. If historical data are used, the data collection period should match the time period of the measured data in terms of season and length.  
5.7 The simulated power output that is used to calculate the expected capacity should be derived from a performance model designed to represent the photovoltaic system which will be reported per Test Method E2848.
SCOPE
1.1 This practice provides procedures for determining the expected capacity of a specific photovoltaic system in a specific geographical location that is in operation under natural sunlight during a specified period of time. The expected capacity is intended for comparison with the measured capacity determined by Test Method E2848.  
1.2 This practice is intended for use with Test Method E2848 as a procedure to select appropriate reporting conditions (RC), including solar irradiance in the plane of the modules, ambient temperature, and wind speed needed for the photovoltaic system capacity measurement.  
1.3 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E822-92(2023)(Practice)
Standard Practice for Determining Resistance of Solar Collector Covers to Hail by Impact with Propelled Ice Balls

SIGNIFICANCE AND USE
2.1 In many geographic areas there is concern about the effect of falling hail upon solar collector covers. This practice may be used to determine the ability of flat-plate solar collector covers to withstand the impact forces of hailstones. In this practice, the ability of a solar collector cover plate to withstand hail impact is related to its tested ability to withstand impact from ice balls. The effects of the impact on the material are highly variable and dependent upon the material.  
2.2 This practice describes a standard procedure for mounting the test specimen, conducting the impact test, and reporting the effects.  
2.2.1 The procedures for mounting cover plate materials and collectors are provided to ensure that they are tested in a configuration that relates to their use in a solar collector.  
2.2.2 The corner locations of the four impacts are chosen to represent vulnerable sites on the cover plate. Impacts near corner supports are more critical than impacts elsewhere. Only a single impact is specified at each of the impact locations. For test control purposes, multiple impacts in a single location are not permitted because a subcritical impact may still cause damage that would alter the response to subsequent impacts.  
2.2.3 Resultant velocity is used to simulate the velocity that may be reached by hail accompanied by wind. The resultant velocity used in this practice is determined by vector addition of a 20 m/s (45 mph) horizontal velocity to the vertical terminal velocity.  
2.2.4 Ice balls are used in this practice to simulate hailstones because natural hailstones are not readily available to use, and ice balls closely approximate hailstones. However, no direct relationship has been established between the effect of impact of ice balls and hailstones. Hailstones are highly variable in properties such as shape, density, and frangibility.2 These properties affect factors such as the kinetic energy delivered to the cover plate, the period during ...
SCOPE
1.1 This practice covers a procedure for determining the ability of cover plates for flat-plate solar collectors to withstand impact forces of falling hail. Propelled ice balls are used to simulate falling hailstones. This practice is not intended to apply to photovoltaic cells or arrays.  
1.2 This practice defines two types of test specimens, describes methods for mounting specimens, specifies impact locations on each test specimen, provides an equation for determining the velocity of any size ice ball, provides a method for impacting the test specimens with ice balls, and specifies parameters that must be recorded and reported.  
1.3 This practice does not establish pass or fail levels. The determination of acceptable or unacceptable levels of ice-ball impact resistance is beyond the scope of this practice.  
1.4 The size of ice ball to be used in conducting this test is not specified in this practice. This practice can be used with various sizes of ice balls.  
1.5 The categories of solar collector cover plate materials to which this practice may be applied cover the range of:  
1.5.1 Brittle sheet, such as glass,  
1.5.2 Semirigid sheet, such as plastic, and  
1.5.3 Flexible membrane, such as plastic film.  
1.6 Solar collector cover materials should be tested as:  
1.6.1 Part of an assembled collector (Type 1 specimen), or  
1.6.2 Mounted on a separate test frame cover plate holder (Type 2 specimen).  
1.7 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only.  
1.8 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.9 This international standard was developed in accordance with internatio...

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ASTM E781-86(2023)(Practice)
Standard Practice for Evaluating Absorptive Solar Receiver Materials When Exposed to Conditions Simulating Stagnation in Solar Collectors with Cover Plates

SIGNIFICANCE AND USE
4.1 Although this practice is intended for evaluating solar absorber materials and coatings used in flat-plate collectors, no single procedure can duplicate the wide range of temperatures and environmental conditions to which these materials may be exposed during in-service conditions.  
4.2 This practice is intended as a screening test for absorber materials and coatings. All conditions are chosen to be representative of those encountered in solar collectors with single cover plates and with no added means of limiting the temperature during stagnation conditions.  
4.3 This practice uses exposure in a simulated collector with a single cover plate. Although collectors with additional cover plates will produce higher temperatures at stagnation, this procedure is considered to provide adequate thermal testing for most applications.
Note 1: Mathematical modeling has shown that a selective absorber, single glazed flat-plate solar collector can attain absorber plate stagnation temperatures as high as 226 °C (437 °F) with an ambient temperature of 37.8 °C (100 °F) and zero wind velocity, and a double glazed one as high as 245 °C (482 °F) under these conditions. The same configuration solar collector with a nonselective absorber can attain absorber stagnation temperatures as high as 146 °C (284 °F) if single glazed, and 185 °C (360 °F) if double glazed, with the same environmental conditions (see “Performance Criteria for Solar Heating and Cooling Systems in Commercial Buildings,” NBS Technical Note 1187).4  
4.4 This practice evaluates the thermal stability of absorber materials. It does not evaluate the moisture stability of absorber materials used in actual solar collectors exposed outdoors. Moisture intrusion into solar collectors is a frequent occurrence in addition to condensation caused by diurnal breathing.  
4.5 This practice differentiates between the testing of spectrally selective absorbers and nonselective absorbers.  
4.5.1 Testing Spectrally Selective...
SCOPE
1.1 This practice covers a test procedure for evaluating absorptive solar receiver materials and coatings when exposed to sunlight under cover plate(s) for long durations. This practice is intended to evaluate the exposure resistance of absorber materials and coatings used in flat-plate collectors where maximum non-operational stagnation temperatures will be approximately 200 °C (392 °F).  
1.2 This practice shall not apply to receiver materials used in solar collectors without covers (unglazed) or in evacuated collectors, that is, those that use a vacuum to suppress convective and conductive thermal losses.  
1.3 The values stated in SI units are to be regarded as the standard.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E744-07(2022)(Practice)
Standard Practice for Evaluating Solar Absorptive Materials for Thermal Applications

SIGNIFICANCE AND USE
4.1 The methods in this practice are intended to aid in the assessment of long-term performance by comparative testing of absorptive materials. The results of the methods, however, have not been shown to correlate to actual in-service performance.  
4.2 The testing methodology in this practice provides two testing methods, in accordance with Fig. 1.
FIG. 1 Outline of Test Method Options  
4.2.1 Method A, which aims at decreasing the time required for evaluation, uses a series of individual tests to simulate various exposure conditions.  
4.2.2 Method B utilizes a single test of actual outdoor exposure under conditions simulating thermal stagnation.  
4.2.3 Equivalency of the two methods has not yet been established.
SCOPE
1.1 This practice covers a testing methodology for evaluating absorptive materials used in flat plate or concentrating collectors, with concentrating ratios not to exceed five, for solar thermal applications. This practice is not intended to be used for the evaluation of absorptive surfaces that are (1) used in direct contact with, or suspended in, a heat-transfer liquid, (that is, trickle collectors, direct absorption fluids, etc.); (2) used in evacuated collectors; or (3) used in collectors without cover plate(s).  
1.2 Test methods included in this practice are property measurement tests and aging tests. Property measurement tests provide for the determination of various properties of absorptive materials, for example, absorptance, emittance, and appearance. Aging tests provide for exposure of absorptive materials to environments that may induce changes in the properties of test specimens. Measuring properties before and after an aging test provides a means of determining the effect of the exposure.  
1.3 The assumption is made that solar radiation, elevated temperature, temperature cycles, and moisture are the primary factors that cause degradation of absorptive materials. Aging tests are described for exposure of specimens to these factors.  
Note 1: For some geographic locations, other factors, such as salt spray and dust erosion, may be important. They are not evaluated by this practice.  
1.4 The values stated in SI units are to be regarded as the standard.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E881-92(2022)(Practice)
Standard Practice for Exposure of Solar Collector Cover Materials to Natural Weathering Under Conditions Simulating Stagnation Mode

SIGNIFICANCE AND USE
4.1 This practice describes a weathering box test fixture and establishes limits for the heat loss coefficients. Uniform exposure guidelines are provided to minimize the variables encountered during outdoor exposure testing.  
4.2 Since the combination of elevated temperature and solar radiation may cause some solar collector cover materials to degrade more rapidly than either exposure alone, a weathering box that elevates the temperature of the cover materials is used.  
4.3 This practice may be used to assist in the evaluation of solar collector cover materials in the stagnation mode. No single temperature or procedure can duplicate the range of temperatures and environmental conditions to which cover materials may be exposed during stagnation conditions. To assist in evaluation of solar collector cover materials in the operational mode, Practice E782 should be used. Insufficient data exist to obtain exact correlation between the behavior of materials exposed in accordance with this practice and actual in-service performance.  
4.4 This practice may also be useful in comparing the performance of different materials at one site or the performance of the same material at different sites, or both.  
4.5 Means of evaluating the effects of weathering are provided in Practice E765, and in other ASTM test methods that evaluate material properties.  
4.6 Exposures of the type described in this practice may be used to evaluate the stability of solar collector cover materials when exposed outdoors to the varied influences that comprise weather. Exposure conditions are complex and changeable. Important factors are material temperature, climate, time of year, presence of industrial pollution, etc. Generally, because it is difficult to define or measure precisely the factors influencing degradation due to weathering, results of outdoor exposure tests must be taken as indicative only. Repeated exposure testing at different seasons over a period of more than one year is req...
SCOPE
1.1 This practice covers a procedure for the exposure of solar collector cover materials to the natural weather environment at elevated temperatures that approximate stagnation conditions in solar collectors having a combined back and edge loss coefficient of less than 1.5 W/(m2·°C).  
1.2 This practice is suitable for exposure of both glass and plastic solar collector cover materials. Provisions are made for exposure of single and double cover assemblies to accommodate the need for exposure of both inner and outer solar collector cover materials.  
1.3 This practice does not apply to cover materials for evacuated collectors, photovoltaic cells, flat-plate collectors having a combined back and edge loss coefficient greater than 1.5 W/(m2·°C), or flat-plate collectors whose design incorporates means for limiting temperatures during stagnation.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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