YB-2 aviation polymethyl methacrylate (PMMA) is irradiated in a xenon arc lamp weather resistance test chamber for 1620 hours. The tensile strength, light transmittance, surface morphology, relative molecular mass, infrared absorption spectrum and glass transition temperature (Tg) of PMMA exposed in xenon arc lamp for different durations are tested and characterized by universal testing machine, optical haze instrument, scanning electronic microscopy (SEM), gel permeation chromatograph (GPC), fourier transform infrared spectrometer (FT-IR) and differential scanning calorimetry (DSC), so as to comprehensively analyze the influence of xenon arc lamp irradiation on the performance of PMMA. The results reveal that under the effect of 1620 hours xenon arc lamp irradiation and periodic spraying water, the light transmittance and glass transition temperature do not change significantly, and no new chemical group is produced. After irradiated 360 hours, tiny cracks occur in the surface of PMMA, indicating that they occur at a certain degree of degradation, meanwhile, the main chain may be broken and the relative molecular mass of surface of the material decreases. After exposure of 720 hours, the tensile strength decreases about 30%.
To guarantee the normal flight and air safety of aircrafts, aviation perspex components such as windshields or canopies must have excellent optical performance, sufficient toughness and long service life. However, for polymer materials such as aviation perspex, exposure to light, hot and humidity conditions is easy to result in color change, transmittance decrease and mechanical performance reduction [
Xenon arc lamp accelerated aging, which is capable to simulate environment with sunlight and humidity-heat, is a kind of accelerated test method suitable to simulate the weather resistance of polymer materials. Due to its relatively high cost, there are few reports concerning the performance change of aviation perspex under xenon arc lamp irradiation both at home and abroad. Therefore, in this research, xenon arc lamp irradiation test of aviation perspex for 1620 hours is carried out to observe, characterize and test the morphology, structure and performance of PMMA, so as to discuss the behaviors of aviation perspex during exposure to xenon arc lamp irradiation.
According to GB/T 16422.2-1999, YB-2 aviation perspex with thickness of 2 mm is placed in an SN-500 xenon weather-ometer. The blackboard temperature is set as 50˚C ± 3˚C, and the spray interval is set as 102 minutes with each spray lasting for 18 minutes. The sampling period is 180 hours (15 days), and the accumulative irradiation time is 1620 hours.
・ Gaseous phase gel permeation chromatograph (GPC). The relative molecular mass of PMMA after exposure to xenon arc lamp irradiation for different durations is characterized by Water 515 gel permeation chromatograph (GPC).
・ Fourier transforms infrared absorption spectrum (FT-IR). The infrared absorption spectrum of PMMA after exposure to xenon arc lamp irradiation for different durations is characterized using VERTEX 720 infrared spectrometer.
・ Characterization of glass transition temperature (Tg). The aviation perspex after irradiated by xenon arc lamp for different durations is tested using a DSC 6200 differential scanning calorimeter. DSC curves are obtained with temperature increasing from 20˚C to 200˚C at a rate of 10˚C/min, and the midpoint temperature is selected as the glass transition temperature according to GB/T 19466.2-2004.
・ Light transmittance. The light transmittance of PMMA after exposure to xenon arc lamp irradiation for different durations is characterized using WGW optical haze instrument.
・ Surface morphology. The surface morphology of PMMA after exposure to xenon arc lamp irradiation for dif- ferent durations is observed using DM 1500 optical microscope and Quanta 200 scanning microscope.
・ Tensile strength. According to GB/T 1040-1992, the tensile strength of PMMA after exposure to xenon arc lamp irradiation for different durations is tested by WDX-50C universal testing machine using II-type specimens, with jig separation speed 2 mm/min.
The surface morphologies of PMMA samples after exposure to xenon arc lamp for different durations are shown as
During spraying in the irradiation process, water will lead to the sudden drop of temperature in the surface of the sample. And when the spraying stops, the temperature will return to the blackboard temperature. Long-term of changing between cold and hot will result in internal stress in the materials, which will lead to cracks in the surface.
The photodegradation reaction of PMMA mainly includes the degradation of lateral ester group and methyl side group, and the random degradation of main chain. The groups in the photodegradation products mainly include O-H (3441 cm−1), C-H (2977 cm−1, 2953 cm−1), C=O (1730 cm−1), C=C (1632 cm−1) and C-O (1148 cm−1), which are the same with those in the perspex molecular chain before degradation. There isn’t any new absorption peak in the infrared absorption spectrum of PMMA after degradation, either the change of peak’s wavenumber.
The infrared absorption spectrum of PMMA before and after the irradiation is shown as
The DSC of PMMA after exposure to xenon arc lamp for different durations is displayed in
Usually, changes in the relative molecular mass of polymers will result in the change of their glass transition temperatures. According to the GPC results, xenon arc lamp irradiation will lead to the decrease of the relative molecular mass of PMMA. Even though it experiences a decrease of about 19.5%, it still keeps an absolute value of 6.2 × 105. Therefore, even after exposure to xenon arc lamp for 1620 hours, there is still no significant change in its glass transition temperature.
Irradiation time/h | 0 | 900 | 1620 |
---|---|---|---|
Tg/˚C | 104.3 | 105.4 | 105.7 |
Light transmittance of aviation perspex after xenon arc lamp irradiation is shown in
The transmittance of aviation perspex is determined by the deflection, absorption and scattering of light ray, which is essentially decided by its structure. When light goes through, the less loss of light, the higher is the transmittance. The change of transmittance directly reflects the change scope of chain structure and aggregation structure in PMMA. After xenon arc lamp irradiation, degradation only occurs in the surface of aviation perspex and its molecular mass still remains at 6.2 × 105. Generally, there is nearly no change in the chain structure and aggregation structure of perspex and consequently no change in the optical performance.
GPC curves of aviation perspex after exposure to xenon arc lamp for different durations is shown as
According to the surface morphology, the degradation of aviation perspex mainly happens in the surface with a relative low degradation degree, which has little influence on the tensile strength. Therefore the tensile strength changes little at the initial irradiation process. With irradiation going on, stress cracking starts to occur in the surface. The tensile stress transmits along the crack direction under tensile stress and cracks become expanded and enlarged [
・ Short-term irradiation of xenon arc lamp has little influence on the structure and performance of aviation perspex. After exposure to xenon arc lamp irradiation for 720 h, the tensile strength gradually decreases with time going on.
・ Xenon arc lamp irradiation leads to a certain extent of degradation in the aviation perspex, with a decreased relative molecular mass, but no new group is produced.
・ After exposure to xenon arc lamp for 1620 hours, the light transmittance of aviation perspex does not experience an obvious decrease (less than 1%), indicating that xenon arc lamp irradiation has little influence on its optical performance. Meanwhile, there is no notable decrease in the glass transition temperature, revealing that aviation perspex has perfect thermo-stability.
・ Under the synergistic effect of long-term xenon arc lamp irradiation and hygrothermal environment, internal stress of aviation perspex was occurred, leading to the relative obvious stress cracking in the surface, which is the typical characteristic of aging.
This work was supported by the Aeronautics Science Foundation (20120956005).