Release of several types of pollutants to the environment and implementation of ever strict environmental rules and the inability of traditional treatment methods to completely eliminate or reduce the pollutants to a standards level lead to study and develop of new trea More
Release of several types of pollutants to the environment and implementation of ever strict environmental rules and the inability of traditional treatment methods to completely eliminate or reduce the pollutants to a standards level lead to study and develop of new treatment processes such as the electron beams. The electron beams irradiation to water and wastewater resulting generation of reducing and oxidizing species (OH•, H•, e-aq) that react quickly and non-selectively with contaminants in the water and wastewater and then decompotion them. In this paper, the history of using of electron beam and its applications in environmental pollution control in various scales, electron accelerators as electron beams production tools, reactors used for irradiation, Factors affecting the efficiency of this method, electron beams systems and advantages and disadvantages of electron beams is presented. Due to the strengths of this method than conventional methods and also lower costs and better performance, especially in the field of disinfection, sewage, sludge and color removal of wastewater industries, in the near future, is not far from the mind to be introduced as one of the key technologies in protecting the environment.
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Today, electron therapy has a lot of advantages such as: its homogenous, dose in the target volume, low absorbed dose for the normal tissues, non-effective transmitted dose of air bubble which surrounded the target (in comparison of photon treatments), controllability i More
Today, electron therapy has a lot of advantages such as: its homogenous, dose in the target volume, low absorbed dose for the normal tissues, non-effective transmitted dose of air bubble which surrounded the target (in comparison of photon treatments), controllability in turning on and electron beam flux adjustment during the treatment. It has no interchangeable case in the most treatment centers. Electron can use for up to 20cm depth in radiation therapies. In this study, we demonstrate, for the first time, a design of flexible guider for the electron accelerator output, which may increase the treatment ability effectively. One of the important of its advantages is non-limited ability in treatment of tumors in case of deep depth, in other words overcome to limitation of surface cancer treatment and providing a safe condition for other normal tissues during the radiation therapy. One of the important of its advantages is non-limited ability in treatment of tumors in case of deep depth, in other words overcome to limitation of surface cancer treatment and providing a safe condition for other normal tissues during the radiation therapy. in other words overcome to limitation of surface cancer treatment and providing a safe condition for other normal tissues during the radiation therapy.
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In this research, the electron beam welding process of P91 steel plates was simulated by the finite element method in two dimensions and in a short time with acceptable accuracy in two steps (non-coupled thermal and mechanical analysis). The simulation results were vali More
In this research, the electron beam welding process of P91 steel plates was simulated by the finite element method in two dimensions and in a short time with acceptable accuracy in two steps (non-coupled thermal and mechanical analysis). The simulation results were validated with experimental and numerical results presented by other researchers. Moreover, by applying post weld heat treatment, the residual stresses were reduced. Then, the effect of heat treatment cycle parameters such as heat input power, heating time, holding time and cooling rate were investigated on the quantity of residual stress reduction. By examining the results of the effects of the parameters, an optimum heat treatment cycle is introduced to maximum reduction of the residual stress. Using this optimum heat treatment cycle, the residual stress value was reduced to 55 percent.
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این پژوهش به ­منظور مقایسه تأثیر تیمارهای پرتو الکترون و اشعه گاما در دزهای 25، 50 و 75 کیلوگری، بر کینتیک تجزیه شکمبه­ای و قابلیت هضم برون تنی کنجاله آفتاب­گردان انجام گرفت. پرتوهای یون­ساز الکترون و گاما اثر معنیداری بر فراسنجه­های تجزیه پذیری ما More
این پژوهش به ­منظور مقایسه تأثیر تیمارهای پرتو الکترون و اشعه گاما در دزهای 25، 50 و 75 کیلوگری، بر کینتیک تجزیه شکمبه­ای و قابلیت هضم برون تنی کنجاله آفتاب­گردان انجام گرفت. پرتوهای یون­ساز الکترون و گاما اثر معنیداری بر فراسنجه­های تجزیه پذیری ماده خشک، پروتئین خام و اسیدهای آمینه کنجاله آفتاب­گردان داشتند (05/0P<). تجزیه پذیری مؤثر شکمبه­ای ماده خشک در کنجاله آفتاب­گردان پرتوتابی شده با تابش الکترون و اشعه گاما، کمتر از کنجاله آفتاب­گردان پرتوتابی نشده بود (05/0P<). تیمار پرتو گاما در دز 75 کیلوگری، تجزیه پذیری مؤثر شکمبه­ای پروتئین خام را در مقایسه با شاهد کاهش داد (05/0P<). تجزیه پذیری مؤثر شکمبه­ای پروتئین خام به ­وسیله تابش الکترون تحت تأثیر قرار نگرفت (05/0P>). عمل­آوری پرتوتابی باعث کاهش تجزیه اسیدهای آمینه بعد از 16 ساعت انکوباسیون شکمبه­ای شد (05/0P<). تأثیر پرتو گاما در کاهش تجزیه پذیری شکمبه­ای اسیدهای آمینه بیشتر از تابش الکترون بود (05/0P<). قابلیت هضم برون­تنی پروتئین خام در کنجاله آفتاب عمل­آوری شده با تابش الکترون و اشعه گاما بهبود یافت (05/0P<). این پژوهش، بر پایه مطالعات برون­تنی و تکنیک کیسه­های نایلونی، نشان داد که عمل­آوری با تابش الکترون و اشعه گاما می­تواند به ­عنوان یک روش مؤثر برای بهبود ارزش تغذیه­ای کنجاله آفتابگردان مورد استفاده قرار گیرد.
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