جستجوی مقالات مرتبط با کلیدواژه « ultraviolet » در نشریات گروه « پزشکی »

The application of ultraviolet photolysis in the removal of microbial contamination can develop the use of wastewater sources. In this research, the efficiency of UVC-LED for removing Escherichia coli was evaluated in pulsed radiation mode with continuous radiation.

In order to conduct this research, 4 UVC-LEDs with a short wavelength of 12 MW were used to produce ultraviolet rays. LEDs create waves with a wavelength of 260-280 nm. The distance between the LED and the plates was considered to be about 0.5 cm, 1 cm, and 2 cm. In order to investigate the effect of discontinuous radiation on UVC-LED performance, 2 Hz and 1 Hz frequency were used. In this case, the power source is connected 2 times and 1 time respectively in every second. The variables of radiation time (t) in seconds, radiation distance (d) in centimeters, and radiation frequency (f) in Hz were used for valuation.

The results showed that in discontinuous irradiation, although the effectiveness increases with the increase of irradiation time, and practically at times higher than 280 seconds, bacteria do not remain in the samples, but the performance of discontinuous irradiation compared to continuous irradiation in removing bacteria at irradiation intervals of 1 cm, 0.5 cm and time 20 s has only achieved logarithm 4 or in other words 99.99% removal, which is considered the weakest performance of continuous radiation. Also, in the discontinuous radiation mode, after 280 s time and 2 cm distance, the radiation performance towards the complete removal of bacteria is equal to the logarithm of 6 or 99.999%, which is equal to the amount of bacteria removal in continuous radiation.

The efficiency of pulsed radiation was greater as compared to continuous radiation.

Use of appropriate pretreatments before drying process can greatly improve quality characteristics of the final dried products. In this study, effects of UV-B irradiation and lime juice as pretreatments on the quality characteristics of dried kiwifruit slices was investigated using hot-air method.

Spray machine was used to spray lime juice at time intervals (0, 2.5, 5, 7.5 min) and UV-B pretreatment was used at various time intervals (zero, 60, 120 min).

Results showed that use of UV-B and lime juice as pretreatments significantly decreased shrinkage, color change and firmness and increased rehydration. Total phenolic compounds, antioxidant capacity and acidity in samples pretreated with UV-B and lime juice increased, compared to the control sample. Simultaneous use of lime juice and UV-B caused significant increases in vitamin C of the samples, which increased from 4.51 mg/100 g in the control sample to 36.01 mg/100 g in the treated sample for 7 min with lime juice and 1 h for UV-B. Results of the sensory evaluation showed that use of UV-B and lime juice as pretreatments resulted in significant improvement in acceptability of the sensory characteristics of dried kiwifruit slices.

Based on the findings of this study, UV-B and lime juice as pretreatments included favorable effects on the quality characteristics of dried kiwifruit samples, which could be used as appropriate pretreatments for hot-air drying fruits.

The most used dyes in textile industries are Azo Group dyes. Azo dyes have complex aromatic compounds, low chemical and biodegradable stability. Due to these properties, treatment of this type of wastewater by conventional methods will not meet environmental standards. The advanced oxidation process has been widely used to treat organic matter from wastewater. In this study, dye purification of azo dye Reactive Red 195 by UV/H2O2 process was investigated. Moreover, the parameters affecting this process have also been determined.

In this study, dye treatment was conducted in the presence of different concentrations of hydrogen peroxide, and at different retention time, temperature and pH values in a continuous photoreactor equipped with UV lamps. Using central composite design and response surface methodology (RSM), effects of various concentrations of hydrogen peroxide, retention time, temperature, and pH on the color and COD removal were studied in the range of 0–2%, 60-240 min, 25-80 oC, and 3-10, respectively.

The results showed that the concentration of hydrogen peroxide and retention time were the most influential parameters on color and COD removal. Color removal significantly enhanced by increasing retention time and H2O2 concentration to 200 min and 1.2%, respectively. pH increase had positive effect on color removal. There were increases in the rate of color and COD removal as the temperature went up to 50 oC. However, temperature of 80 oC negatively impacted AOP process. According to RSM, the optimum factor levels were achieved at 1.28%, 240 min, 49 oC and 10 for concentrations of hydrogen peroxide, reaction time, temperature, and pH, respectively.

According to the result, UV/H2O2 proved to be capable of degrading Reactive Red 195. Almost all the azo dye color destroyed after 209 min while 87.52 % of the COD was removed after 240 min of irradiation.

Because of its very high solubility, nitrate penetrates easily into soil and underground waters. Surface waters such as lakes, reservoirs, and rivers are exposed to nitrate pollution. Photocatalytic processes have a high potential for nitrate removal due to complete oxidation, lack of formation of multi-cycle metabolites and the availability of catalysts. The purpose of this study was to investigate the nitrate removal from aqueous solutions using photocatalyst of titanium dioxide nanoparticle under the influence of ultraviolet light (UV).

This laboratory-experimental study was carried out as discontinuously using a photocatalytic process in a reactor with volume of 1-liter, containing 250 ml of a sample with radiation source of UVC ultraviolet lamp and a power consumption of 9W. The statistical method of the CCD response level, one of the standard methods of RSM, was used to investigate the parameters of pH, titanium dioxide nanoparticle, nitrate concentration and contact time.

The results showed that nitrate removal from aqueous solutions was influenced by factors such as exposure time to ultraviolet light, nitrate concentration, nanoparticle content and pH. The optimum conditions for nitrate removal, based on the appropriate model, were obtained from the response level statistical method including 0.55 g/l titanium dioxide nanoparticle, nitrate concentration of 35.15 mg/l, pH=5 and contact time of 50.22 minutes equal to 62.59%.

The process used in this study, according to the desired conditions, is able to remove nitrate from aqueous solutions, and changing the laboratory conditions can be effective in it eliminating. This process can be recommended as an economic and practical solution to nitrate remove from drinking water.