Provided is a radiation shielding device according to various embodiments. The radiation shielding device includes: a body structure forming a receiving space receiving a user's body part, wherein a through passage penetrating an inside of the body structure is formed in the body structure; a shielding unit positioned to reciprocatively move along the through passage, wherein a shielding pad configured to shield the radiation is included in a portion of the shielding unit; and a driver configured to transfer a driving force to the shielding unit to cause the shielding unit to reciprocatively move.

In general, radiation shielding systems that shield radiation from multiple directions are described. In one embodiment, a method of shielding radiation is provided, including supporting a shielding device on an object proximate a radiation source, positioning a first shielding portion in a vertical position relative to the object, positioning a second shielding portion to extend away from the first portion, the second shielding portion attached to the first portion, and shielding radiation from the radiation source by the first shielding portion and the second shielding portion such that the first and second shielding portions provide a radiation shielding zone for a healthcare practitioner.

Fabricating structural components for a spent nuclear fuel container using the steps of forming cylindrical or rectangular channels to produce a structural component for a spent nuclear fuel container and applying a coating that includes tantalum-based material to the cylindrical or rectangular channels.

Provided is a body, a method for manufacturing the body and a method of using of the body for nuclear shielding in a nuclear reactor. The body may include boron, iron, chromium, carbon and tungsten.

A shield structure configured to protect a head and/or neck of a patient during a radiologic procedure comprises a bottom wall, a side wall, and an opening. The bottom wall includes radiation attenuating material and is configured to be positioned between the head and/or neck of the patient and a radiation source so as to shield the patient from radiation directed toward the bottom of the patient. The bottom wall is of a general size to shield the head and/or neck of the patient. The side wall includes radiation attenuating material and is configured to extend upward from the bottom wall so as to shield the patient from radiation directed toward a side of the patient. The opening is configured to receive the head and/or neck of the patient.

A novel eco-friendly method has been developed for the fabrication of high dense (3.3-5.2 g/cc) red mud based material blocks for shielding high energy X- and -rays. The red mud based material blocks with various densities were fabricated by hot compacting partially melted red mud, red mud:Bi.sub.2O.sub.3, red mud:Ba(OH).sub.2 and red mud:Bi.sub.2O.sub.3:Ba(OH).sub.2 samples at 1150 C., 1000 C., 1050 C. and 1000 C., respectively. This material can be used to build radiation shielding structures in medical diagnosis, radiotherapy, industrial radiography, particle accelerators, food sterilization plants, nuclear power plants, and radioactive material storage rooms, without further structural support unlike lead (concrete walls). It is economically viable and will suppress the accumulation of hazardous red mud and associated environmental pollutions.

Fabricating structural components for a spent nuclear fuel container using the steps of forming cylindrical or rectangular channels to produce a structural component for a spent nuclear fuel container and applying a coating that includes tantalum-based material to the cylindrical or rectangular channels.

A personal display apparatus includes a dual-use transparent plate, a detector, and electronic circuitry. The dual-use transparent plate is configured to be worn by a user while the user is viewing a scene, to block, at least partially, X-rays from passing through the transparent plate and reaching an eye of the user, and to display information to be viewed by the user overlaid on the scene. The detector is coupled to the transparent plate and is configured to measure a level of the X-rays. The electronic circuitry is connected to the transparent plate and to the detector, and is configured to exchange display signals with the transparent plate so as to display the information, and to send a control signal indicative of the level of the X-rays measured by the detector.

An industrial process transmitter includes a housing, sensor circuitry, transmitter circuitry, and a radiation shield. The sensor circuitry is contained in the housing, and is configured to sense a process parameter and generate a sensor output that is indicative of the sensed process parameter. The transmitter circuitry is contained in the housing, and is configured to communicate the sensed process parameter to an external unit. The radiation shield substantially surrounds a portion of the housing containing the sensor circuitry and shields the sensor circuitry from gamma radiation.

A radiation-shielded structural enclosure is formed from layers of material having higher and lower Z (atomic) numbers. The enclosure may be formed from layers of titanium that are bonded to opposite sides of a layer of tantalum. A layer of aluminum alloy may be bonded to at least one of the layers of titanium. The enclosure provides structural support for components disposed inside the enclosure and provides radiation shielding for the components.