Estimating the Concentrations of Natural Isotopes of   238 U and  232Th and Radiation Dose Rates for Wasit Province-Iraq by Gr-460 system

Introduction: While the operator radiation dose rates are correlated to patient radiation dose rates, discrepancies may exist in the effect size of each individual radiation dose predictors. An operator dose rate prediction model was developed, compared with the patient dose rate prediction model, and converted to an instant operator risk chart. Materials and Methods: The radiation dose rates (DRoperator for the operator and DRpatient for the patient) from 12,865 abdomen X-ray acquisitions were selected from 50 unique patients undergoing standard or complex endovascular aortic repair (EVAR) in the hybrid operating room with a fixed C-arm. The radiation dose rates were analyzed using a log-linear multivariable mixed model (with the patient as the random effect) and incorporated varying (patient and C-arm) radiation dose predictors combined with the vascular access site. The operator dose rate models were used to predict the expected radiation exposure duration until an operator may be at risk to reach the 20 mSv year dose limit. The dose rate prediction models were translated into an instant operator radiation risk chart. Results: In the multivariate patient and operator fluoroscopy dose rate models, lower DRoperator than DRpatient effect size was found for radiation protocol (2.06 for patient vs 1.4 for operator changing from low to medium protocol) and C-arm angulation. Comparable effect sizes for both DRoperator and DRpatient were found for body mass index (1.25 for patient and 1.27 for the operator) and irradiated field. A higher effect size for the DRoperator than DRpatient was found for C-arm rotation (1.24 for the patient vs 1.69 for the operator) and exchanging from femoral access site to brachial access (1.05 for patient vs 2.5 for the operator). Operators may reach their yearly 20 mSv year dose limit after 941 minutes from the femoral access vs 358 minutes of digital subtraction angiography radiation from the brachial access. Conclusion: The operator dose rates were correlated to patient dose rate; however, C-arm angulation and changing from femoral to brachial vascular access site may disproportionally increase the operator radiation risk compared with the patient radiation risk. An instant risk chart may improve operator dose awareness during EVAR.

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1948 ORGAN SPECIFIC RADIATION DOSE RATES AND EFFECTIVE DOSE DURING PERCUTANEOUS NEPHROLITHOTOMY

The Journal of Urology ◽

10.1016/j.juro.2012.02.2106 ◽

2012 ◽

Vol 187 (4S) ◽

Author(s):

Michael Lipkin ◽

John Mancini ◽

Agnes Wang ◽

Greta Toncheva ◽

Colin Anderson-Evans ◽

...

Keyword(s):

Radiation Dose ◽

Effective Dose ◽

Percutaneous Nephrolithotomy ◽

Dose Rates ◽

Organ Specific

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Study on Radiation Dose Calculation of PWR Spent Fuel Storage and Transportation

10.1115/icone28-64457 ◽

2021 ◽

Author(s):

Wen Yang ◽

Xing Li ◽

Jinrong Qiu ◽

Lun Zhou

Keyword(s):

Radiation Dose ◽

Normal Condition ◽

Radiation Safety ◽

Spent Fuel ◽

Dose Rates ◽

Storage Pool ◽

Transport Container ◽

Photon Dose ◽

Spent Fuel Storage ◽

Fuel Storage

Abstract With the rapid development of nuclear energy, spent fuel will accumulate in large quantities. Spent fuel is generally cooled and placed in a storage pool, and then transported to a reprocessing plant at an appropriate time. Because spent fuel is content with a high level of radiation, spent fuel storage and transportation safety play important roles in the nuclear safety. Radiation dose safety are checked and validated using source analysis and Monte Carlo method to establish a radiation dose rate calculation model for PWR spent fuel storage pool and transport container. The calculation results show that the neutron and photon dose rates decrease exponentially with increase of water level under normal condition of storage pool. The attenuation multiples of neutron and photon dose rates are 4.64 and 1.59, respectively. According to radiation dose levels in different water height situations, spent fuel pool under loss of coolant accident can be divides into five workplaces. They are supervision zone, regular zone, intermittent zone, restricted zone and radiation zone. Under normal condition of transport container, the dose rates at the surface of the container and at a distance of 1 m from the surface are 0.1759 mSv/h and 0.0732 mSv/h, respectively. The dose rates decrease with the increasing radius of break accident, and dose rate at the surface of the transport container is 0.278 mSv/h when the break radius is 20 cm. Transport container conforms to the radiation safety standards of International Atomic Energy Agency (IAEA). This study can provide some reference for radiation safety analysis of spent fuel storage and transportation.

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Age-dependent Radiation Dose Rates from Canine Sn-117m Treatments

Health Physics ◽

10.1097/hp.0000000000001448 ◽

2021 ◽

Vol Publish Ahead of Print ◽

Author(s):

Matthew G. Arno ◽

Chad Smith

Keyword(s):

Radiation Dose ◽

Dose Rates ◽

Age Dependent

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EVALUATION OF RADIATION DOSE RATE OF RSG-GAS REACTOR

Urania Jurnal Ilmiah Daur Bahan Bakar Nuklir ◽

10.17146/urania.2018.24.3.4909 ◽

2018 ◽

Vol 24 (3) ◽

Author(s):

Amir Hamzah ◽

Hery Adrial ◽

Subiharto Subiharto

Keyword(s):

Radiation Dose ◽

Radiation Exposure ◽

Dose Rate ◽

Nuclear Reactor ◽

Area Measurement ◽

Radiation Dose Rate ◽

Safety Level ◽

Modeling And Analysis ◽

Dose Rates ◽

Limit Value

EVALUATION OF RADIATION DOSE RATE OF RSG-GAS REACTOR. The RSG-GAS reactor has been operated for 30 years. Since the nuclear reactor has been operated for a long time, aging process on its components may occur. One important parameter for maintaining the safety level of the RSG-GAS reactor is to maintain radiation exposure as low as possible, especially in the working area. The evaluation results should be able to demonstrate that the radiation exposure of the RSG-GAS is still safe for workers, communities and the surrounding environments. The purpose of this study is to evaluate radiation exposure in the working area to ensure that the operation of RSG-GAS is still safe for the next 10 years. The scope of this work is confirming the calculation results with the measured radiation dose in the RSG-GAS reactor working area. Measurement of radiation exposure is done by using the installed equipments at some points in the RSG-GAS working area and a portable radiation exposure measurement equipment. The calculations include performance of a modeling and analysis of dose rate distribution based on the composition and geometry data of RSG-GAS by using MCNP. The analysis results show that the maximum dose rate at Level 0 m working area of RSG-GAS reactor is 3.0 mSv/h with a deviation of 6%, which is relatively close to the measurement value. The evaluation results show that the dose rate in RSG-GAS working area is below the limit value established by the Nuclear Energy Regulatory Agency of Indonesia (BAPETEN) of 10 mSv/h (for the average effective dose of 20 mSv/year). Therefore, it is concluded that the dose rate in RSG-GAS working area is safe for personnel..Kata kunci: dose rates, RSG-GAS, radiation safety, MCNP.

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