Accelerated Weathering Test Standards for Plastics, Textiles, Automotive, Military and Coatings Paints Varnishes

Long-term outdoor sunlight exposure, high temperature and humidity are the main causes of coating cracking, loss of gloss, fading, yellowing and chalking. The weather resistance of the coating is related to the spectral sensitivity of the coating components. For outdoor paints, UV rays are the main cause of paint aging. The UV accelerated aging test can simulate the damage of the UV part of sunlight to the coating, and reproduce the damage that occurs outdoors for months or even years in days or weeks.

UV test chambers can help to select new materials and evaluate the impact of material formulations on durability, to achieve the purpose of verifying the performance of coatings. The necessary UV accelerated aging test ensures the long-term weather resistance of the coating to avoid losses caused by weather resistance during use. Ultraviolet rays in sunlight are the main cause of photodegradation and photoaging of photo products, so the selection of new products and new materials must be tested for weather resistance of products.

Ultraviolet aging test is a type of test method to evaluate the resistance of new products to ultraviolet light, which is usually tested in a laboratory by an accelerated ultraviolet aging test chamber. Products and materials that need to be tested for UV resistance mainly include: non-metallic materials, organic materials (such as coatings, paints, dyes, fabrics, printing and packaging, adhesives, cosmetics, metals, electronics, electroplating, rubber, plastics and other materials products, etc.).

related page logoASTM G151 Standard Practice for Exposing Nonmetallic Materials in Accelerated Test Devices That Use Laboratory Light Sources
related page logoASTM G154 Standard Practice for Operating Fluorescent Light Apparatus for UV Exposure of Nonmetallic Materials
related page logoASTM G155 Standard Practice for Operating Xenon Arc Light Apparatus for Exposure of Non-Metallic Materials
related page logoASTM G7-21 Standard Practice for Natural Weathering of Materials
related page logoASTM G24-21 Standard Practice for Conducting Exposures To Daylight Filtered Through Glass
related page logoASTM G90-10 Standard Practice for Performing Accelerated Outdoor Weathering of Nonmetallic Materials Using Concentrated Natural Sunlight
related page logoASTM G90-17 Standard Practice for Performing Accelerated Outdoor Weathering of Materials Using Concentrated Natural Sunlight
related page logoASTM D6695-16 Standard Practice for Xenonһarc Exposures of Paint and Related Coatings
related page logoASTM D7869-2017 Standard Practice for Xenon Arc Exposure Test with Enhanced Light and Water Exposure for Transportation Coatings
related page logoASTM D2565-2016 Standard Practice for Xenon-Arc Exposure of Plastics Intended for Outdoor Applications
related page logoASTM D4329-21 Standard Practice for Fluorescent Ultraviolet (UV) Lamp Apparatus Exposure of Plastics
related page logoASTM D4587-11 Standard Practice for Fluorescent UV-Condensation Exposures of Paint and Related Coatings
related page logoASTM D4799 Standard Practice for Accelerated Weathering Test Conditions and Procedures for Bituminous Materials (Fluorescent UV, Water Spray, and Condensation Method)
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related page logoASTM G85-19 Standard Practice for Modified Salt Spray (Fog) Testing
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How to test the weather resistance of paint coatings ? The weather resistance test and evaluation of paint coatings must have sufficient basis, not fabricated out of thin air. At present, two methods are generally promoted internationally: natural exposure and artificial accelerated aging test, and it is emphasized that the two test methods should be combined and comprehensively considered to draw more reliable conclusions. Natural exposure is based on the exposure of Florida, USA. The state is located at the southern end of the United States and is surrounded by the sea.

The sun is abundant and strong throughout the year. The moisture and salt in the air are very high. Compared with other places on the earth, except for a small part of In addition to extreme weather phenomena, the natural conditions here can be regarded as a very harsh environment for coatings. Insert the prepared standard sample of paint and coating into the exposure frame, facing south at an angle of 5° or 45°, regularly test the gloss and color change, and record it. The general test period is in years, and the coating gloss and color change curve can be drawn at the end of the test.

Xenon Arc Fading Lamp Test with Air Cooling System

Natural exposure is accurate and intuitive, and the data is credible, but the test period is too long to quickly guide scientific research and production. Therefore, most of the relevant tests are completed by artificial accelerated aging. The artificial accelerated aging test simulates natural conditions, such as controlling a certain temperature, humidity and rainfall cycle, and selecting different wavelengths of light to simulate sunlight. The test period is short and usually only takes 200 to 1000 hours, and a conclusion can be drawn quickly. There are many light sources used in the artificial accelerated aging test, and the common ones are: xenon arc sunlight, fluorescent ultraviolet rays, and carbon arc lamps.

The xenon lamp aging test can be used for the selection of new materials, the improvement of existing materials or the evaluation of changes in the durability of material compositions; it can provide corresponding simulated test environments and accelerated tests for scientific research, product development and quality control. Xenon Lamp Aging Test
The xenon lamp aging test is a test that simulates the full sunlight spectrum. The xenon lamp aging test is currently the best test for simulating artificial climate reliability testing. It can simulate a natural artificial climate test in a short time. It can better simulate changes in products exposed to sunlight in different environments.
The spectral energy distribution of the xenon lamp aging test in the ultraviolet region and the visible region is similar to that of sunlight. The radiation emitted by the xenon lamp is filtered by a filter to filter out shorter ultraviolet light waves with wavelengths below 290 nm and infrared light waves with wavelengths above 1200 nm. The spectrum reaching the surface of the specimen is close to that of sunlight.
Coatings, plastics and other organic materials will lose their gloss, fade, yellow, peel, crack, lose tensile strength and peel off over time when exposed to natural weather conditions and light radiation. Even indoor light or sunlight shining through window panes can cause damage to substances such as pigments or dyes.
The Chinese National Standard specifies 2 standards for paint aging testing: (1) CB/1865-1997 Paints And Varnishes — Artificial Weathering and Exposure to Artificial Radiation — Filtered Xenon-Arc Radiation (2) GB/T16585-1996 Rubber, Vulcanized. Test Method of Resistance to Artificial Weathering (Fluorescent UV lamp)

These two methods can test the durability of paint coatings. The xenon arc radiation is mild, which is more suitable for pigments, plastics, etc., and the test period is longer. Fluorescent UV lamps have good acceleration and are suitable for rapid inspection, and have a wide range of UV wavelength selection, which can adapt to a variety of inspection requirements. There are also accelerated natural exposure tests, such as the EMKAQUA test (in Arizona, USA), which use special mirrors to intensify sunlight, combined with periodic spraying and temperature control. It has been observed that this method correlates well with Florida exposure while aging 5-6 times faster.
related page logoISO 877-1 Plastics Methods of Exposure To Solar Radiation Part 1:General Guidance
related page logoISO 877-2 Plastics Methods of Exposure To Solar Radiation Part 2: Direct Weathering and Exposure Behind Window Glass
related page logoISO 877-3 Plastics Methods of Exposure To Solar Radiation Part 3: Intensified Weathering Using Concentrated Solar Radiation
related page logoISO 2810 Paints and Varnishes Natural Weathering of Coatings Exposure and Assessment
related page logoISO 16474-1 Paints and Varnishes Methods of Exposure To Laboratory Light Sources Part 1:General Guidance
related page logoISO 16474-2 Paints and Varnishes Methods of Exposure To Laboratory Light Sources Part 2: Xenon-Arc Lamps
related page logoISO 16474-3 Paints and Varnishes Methods of Exposure To Laboratory Light Sources Part 3: Fluorescent UV Lamps
related page logoISO 4892-1 Plastics Methods of Exposure To Laboratory Light Sources Part 1: General Guidance
related page logoISO 4892-2 Plastics Methods of Exposure To Laboratory Light Sources Part 2: Xenon-Arc Lamps
related page logoISO 4892-3 Plastics Methods of Exposure To Laboratory Light Sources Part 3: Fluorescent UV Lamps
related page logoBS EN ISO 105 B02 Textiles Tests for Colour Fastness Part B02: Colour Fastness To Artificial Light: Xenon Arc Fading Lamp Test
related page logoISO 105-B06 Textiles Tests for Colour Fastness Part B06: Colour Fastness and Ageing To Artificial Light At High Temperatures: Xenon Arc Fading Lamp Test
related page logoISO 105-B03 Textiles Tests for Colour Fastness Part B03: Colour Fastness To Weathering: Outdoor Exposure
Light, high temperature and humidity, any of these three factors can cause aging damage to automotive paint coatings, but they often act simultaneously, and the harm caused will be greater than any one of the factors alone. High temperature is also an important factor in causing damage to automotive paint coatings. As the temperature increases, the destructive effect of light will also increase. Although temperature does not affect the primary photoreaction, it affects the secondary chemical reaction. Laboratory weathering tests must provide precise temperature control, usually by increasing the temperature to accelerate the aging process. Dew, rain and high humidity are the main causes of damp damage to automotive paint coatings.

Statistics show that cars placed outdoors will be wet for a long time every day. Dew formed by moisture is a major factor in outdoor humidity, and dew is more harmful to car paint coatings than rain because it adheres to the paint coating for a longer time, causing more severe moisture absorption.With the development of the automobile industry, there are more and more electronic control components, navigation, entertainment, wireless multimedia electronic components, etc. The system of the car is becoming more and more complex, and the importance of the reliability of electronic components is also highlighted, which directly determines the driving safety of the vehicle and the reliability of the product.

At present, there are two main test methods for weather resistance and aging resistance of interior and exterior parts, namely artificial accelerated aging test and natural climate exposure aging test. Most Chinese auto companies focus on controlling the aging performance of parts and components, supplemented by the evaluation of vehicle outdoor exposure. Combining the two can achieve the purpose of shortening the material development cycle and reducing quality risks. The test and evaluation of the aging performance of the parts are mainly carried out through the artificial accelerated aging test in the laboratory. The main problem is that the correlation research between artificial accelerated aging test and natural climate exposure aging test is not deep enough.

Nowadays, the light sources used in artificial accelerated aging test equipment mainly include carbon arc lamps, ammonia arc lamps and fluorescent ultraviolet lamps, among which nitrogen arc lamps and fluorescent ultraviolet lamps are the most widely used. According to the different working conditions of interior and exterior parts, the test standard has two test conditions: interior and exterior. Different organizations and institutions have developed relevant standards, such as ISO, SAE, ASTM, GB, etc. Some auto companies have established corporate standards through years of research and accumulation, such as GM, VW, FORD, etc.
The ultraviolet spectrum and visible spectrum of nitrogen arc lamp are very close to the solar spectrum, which is the closest to the solar spectrum among the existing artificial light sources, and the simulation is relatively good. Nitrogen Arc Lamp
According to the cooling method of the lamp, the nitrogen lamp aging tester is divided into two types: water-cooled and air-cooled, and the operating cost is high (the cost of the lamp as a consumable is high).
Different models (such as B-313 nm, A-340 nm) have different peaks of UV spectrum of fluorescent UV lamps. Fluorescent UV Lamps
The UV spectrum of UVB 313 nm (270-360 nm) may accelerate the aging of some polymer materials more than the carbon arc lamp or ammonia arc lamp is large, and the ultraviolet spectrum (312~400 nm) of UVA 340 nm is consistent with the sunlight spectrum.
Fluorescent UV lamps do not simulate the solar spectrum as well as ammonia arc lamps, but have lower operating costs.
Xenon Arc Light Apparatus for Exposure of Non-Metallic Materials

Why do UV testing ? What lights are there for UV testing ? What is the wavelength of UV aging tester ? The UV aging test is a process of simulating the various factors involved in the actual use conditions of the product to carry out the corresponding conditions to strengthen the experiment. The UV aging test experiment is mainly aimed at plastic materials. The common aging mainly includes light aging, damp heat aging , hot air aging. Some outdoor products are exposed to sunlight for a long time, so the yellowing resistance test and aging resistance test of the product are very important.

To understand the service life of the product outdoors, it is necessary to carry out a UV aging test simulation test, that is, a UV test. Since the intensity of the UV test in the laboratory is greater than that of the outdoor light, the UV aging test can save the staff’s time. The test time can get the service life of the product outdoors in a short time.

Which products need to be UV tested ? UV test is very important, UV aging test is mainly used to test plastics, lamps, paint inks, resins, printing and packaging, aluminum profiles, automobile and motorcycle industries, cosmetics, etc. UV testing to reproduce damage from sunlight, rain and dew. The device conducts the test by exposing the material to be tested to a controlled alternating cycle of sunlight and moisture while raising the temperature. UV test chamber uses UV fluorescent lamps to simulate sunlight, and can also simulate moisture effects by condensation or spray.
The chemical bonds of polymer materials have different sensitivities to different wavelengths of sunlight in sunlight, and generally correspond to a threshold. The short-band ultraviolet rays of sunlight are the main reasons for the aging of physical properties of most polymers, such as CN (carbon-nitrogen) bonds. The threshold of action is 393 nm. However, long-wavelength UV light and even visible light can also damage certain dyes and pigments, causing discoloration and fading. Lighting Weathering Test Principle
The higher the temperature, the faster the chemical reaction speed. The aging reaction is a photochemical reaction. The temperature does not affect the photoinduced reaction speed in the photochemical reaction, but affects the subsequent chemical reaction speed. Therefore, the effect of temperature on material aging is often nonlinear. Temperature
Water will directly participate in the material aging reaction. Relative humidity, dew and rain are the main forms of water in nature. Studies have shown that outdoor materials will be in a wet state for a long time every day (up to 8 to 12 hours per day on average). And dew is the main cause of outdoor humidity. Dew is more harmful than rain because it sticks to the material longer and creates more severe wet erosion. Humidity
There are many kinds of textiles, in addition to ordinary textiles such as clothes and fabrics, it also includes some outdoor textiles, such as tents, rain cloths, sunshades, outdoor clothing, industrial cloths and covers. When it comes to outdoor textiles, not only light affects them, but also water and high temperatures. Therefore, it is necessary to simulate outdoor application conditions when designing accelerated aging test conditions. The materials of outdoor textiles include not only vegetable fibers, but also polyester and coatings. Weathering damage is mainly caused by three factors: light, temperature and humidity. Any one of these 3 factors can cause material aging, and their combined effect is greater than the damage caused by any one of them.

Plastics have good chemical properties, mechanical properties, electrical properties and dimensional stability. But its biggest disadvantage is that it is not resistant to aging, and the aging mechanism is also very complicated. At present, the change of mechanical properties caused by aging is generally analyzed through experiments, such as the change of mechanical properties through artificial accelerated aging.

Plastic aging is a process in which the performance of plastic products changes from good to bad. Due to the wide variety of plastics, the use environment and use conditions are very different, so the aging phenomenon and characteristics are also different. At present, some phenomena of plastic aging can be summarized into the following four changes.
Sticky, hardened, brittle, deformed, discolored, lost gloss, blistered, cracked and even chalked up. Appearance Changes
There are mainly changes in properties such as dissolution, swelling, rheology, cold resistance, heat resistance, air permeability and water permeability. The main manifestation of swelling is the change in size. Changes in Physical Properties
There are mainly changes in tensile strength, bending strength, impact strength, hardness and elasticity, elongation, stress relaxation and other properties. Changes in Mechanical Properties
Such as surface resistance, volume resistance, insulation resistance, dielectric constant, electrical breakdown performance and other performance changes. Changes in Electrical Properties
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related page logoCIE 241-2020 Recommended Reference Solar Spectra for Industrial Applications
related page logoEN 927-6 Paints and Varnishes – Coating Materials and Coating Systems for Exterior Wood – Part 6: Exposure of Wood Coatings to Artificial Weathering Using Fluorescent UV Lamps and Water
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Outdoor exposure and accelerated aging test chambers are the main methods for testing the weathering properties of materials. The coating industry in China and abroad has carried out outdoor atmospheric aging tests for a long time. China has outdoor exposure fields of various scales in Hainan, Guangzhou, Dunhuang and other places. Internationally, Florida and Arizona in the United States and Allunga in Australia are usually used as benchmark exposure sites. Outdoor exposure testing has many advantages, such as being realistic, cheap, and easy to operate. The outdoor exposure test time is relatively long, so it is necessary to carry out the laboratory accelerated aging test.

In terms of accelerated aging test, except for a few Japanese companies that still use carbon arc lamps, the main test methods are ultraviolet light and xenon lamps. However, the xenon arc accelerated aging test chamber cannot simulate all aging parameters, and there are some test variables that are prone to cause erroneous test results, resulting in erroneous conclusions. However, the results of outdoor exposure can be used as a reference to check the authenticity of the accelerated aging test, which will make the accelerated aging test more practical.

The temperature and humidity treatment test simulates the temperature and humidity experienced by the transportation unit during transportation, and considers the resistance of the transportation unit to temperature and temperature. Temperature and humidity have a greater impact on corrugated and plastic packaging, but not so much on wood packaging and metal packaging. Corrugated packaging is sensitive to humidity. Humidity will affect the water content of corrugated paper, which in turn will affect the strength of corrugated packaging. High temperature will greatly reduce the strength of corrugated paper, resulting in collapse and rupture of corrugated packaging.

During storage or transportation, if the corrugated packaging at the bottom is not strong enough to cause collapse, the entire stack will collapse or the top load will be directly pressed to the contents, causing pressure damage to the contents. For some shipping or transportation or storage in hot and humid areas, it is still necessary to do temperature and humidity treatment tests during simulated transportation tests.
How to evaluate the anti-aging performance and life of plastics ? The natural aging test is to test the sample under natural conditions, and analyze the change of its performance before and after to evaluate the weather resistance of the material. The natural conditions include natural atmospheric conditions, natural storage conditions, and seawater exposure conditions. This method has a longer test period and is suitable for specific exposure test sites. Natural Aging Test
The artificial aging test is to expose the material to the specified environmental conditions, simulating the natural conditions of light, heat, oxygen, humidity, rain, etc., by testing the irradiance or radiation on the surface of the sample and the change in the performance of the sample. Evaluate the weatherability of materials. Artificial Aging Test
The performance before and after aging can be compared with the following: appearance change, mechanical property change, molecular weight and distribution change, electrical property change, size change, volume change, mass change, etc. In the actual analysis process, one or more physical properties can be selected for evaluation according to the key impact performance of the product. Comparison of Physical Properties Before and After Aging
Plastic packaging is not too sensitive to humidity, but is more sensitive to temperature. The high temperature environment will cause the plastic packaging to soften, creep and reduce its strength. The low temperature environment will cause the embrittlement and impact resistance of plastic packaging to decrease. Neither wood packaging nor metal packaging are too sensitive to short-term temperature and humidity. Long-term temperature and humidity will cause some electrochemical corrosion of metals, which requires an evaluation of the corrosion resistance of the metal material itself.

Wood packaging will also cause wood decay and strength reduction in a long-term temperature and humidity environment. Wood packaging has a certain service life. In terms of the impact of this single item in simulated transportation, the defect may not be exposed, but it may be damaged after experiencing the combined effects of subsequent shock, compression and vibration. The packaging simulation transportation test is a sequential comprehensive simulation, which needs to be carried out comprehensively to achieve the purpose of verification.

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