A protective assembly comprises a first region formulated and configured to provide protection from alpha, beta, and electromagnetic radiation and comprising a composite of particles and polymer; a second region formulated and configured to provide protection from ballistic impact and comprising a composite of fibers and polymer; and a third region formulated and configured to provide protection from thermal radiation and comprising a composite of particles, fiber, and polymer. The protective assembly may be provided on an aerospace structure. The protective assembly may be formed on the aerospace structure body using a co-curing process.

The present invention relates to radiation-shielding clothing for limiting the radiation exposure of radiographers and assistants at the time of radiography by using a lightweight lead-free sheet shielding X-rays, the radiation-shielding clothing including: a top main body including a torso portion; and a shielding sheet, at least a part thereof being capable of being coupled to or detached from the top main body using attachment and detachment means, wherein the shielding sheet contains a substrate of a resin material and tungsten or tungsten oxide powder.

A device in which the influence of ?-ray is reduced, and a composition for forming an organic layer. The device includes an ?-ray source, an electronic circuit influenced by ?-ray, and an organic layer including an ?-ray shielding agent, in which an ?-ray shielding ability X of the ?-ray shielding agent is 0.50 or less.

An eye mask apparatus for protecting a patient's eyes while being secured around the patient's head during panoramic dental radiography, the apparatus comprising an elongated lead vinyl sheet having a first end and a second end, wherein said first and second ends have attachment devices to releasably secure said two ends together. The elongated lead vinyl sheet is adapted to be secured around the patient's head at eye level. The elongated lead vinyl sheet is further adapted to cover a slice of the patient's head that is confined between two planes, the two planes being parallel to a transverse plane of the patient's head at eye level. Therefore, the eye mask apparatus protects the slice of the patient's head and the patient's eyes from x-ray radiation during the panoramic dental radiography. The lead vinyl sheet is placed over the patient's eyes prior to radiography.

[Object] To provide a radiation shielding material that includes a resin composition obtained by filling a matrix formed of resin with a radiation-absorbing substance and is capable of obtaining a structure in which transparency is significantly improved as compared with the conventional radiation shielding material while having a radiation shielding effect similar to that of the conventional radiation shielding material. [Solving Means] A radiation shielding material includes: a resin composition containing a proportion of 20 to 80 vol % of fluoride powder containing barium as a constituent element. The fluoride powder is favorably barium fluoride or lithium barium fluoride, the resin favorably has a refractive index (n) of 1.4 to 1.6, and particularly, a difference between a refractive index of the resin and a refractive index of the fluoride powder is favorably within 0.05.

An XRF analyzer can include an x-ray source and an x-ray detector; an x-ray source heat-sink adjacent a side of the x-ray source; and an x-ray detector heat-sink adjacent a side of the x-ray detector. In one embodiment, the x-ray source heat-sink can be separated from the x-ray detector heat sink by a material having a thermal conductivity of less than 20 W/(m*K). In another embodiment, the x-ray source heat-sink can be separated from the x-ray detector heat sink by at least 3 millimeters of a thermally insulating material. In one embodiment, the x-ray source heat-sink can be separated from the x-ray detector heat sink by a segment of the engine component casing. Separation of the heat sinks can help avoid heat from the x-ray source adversely affecting resolution of the x-ray detector.

Lead-free radiation shielding material and processes for producing and using the same are described. The radiation shielding comprising a heavy metal component, such as bismuth, and a polymer component while also being optically transparent. The bismuth can be bonded to the polymer component or can be embedded within the matrix of the polymer component without being bonded to the polymer. As well, the bismuth can be nanoparticles that are contained within the matrix of the polymer component without being bonded to the polymer. The bismuth provides a stable, environmentally benign alternative to lead, while blocking the radiation and also being optically transparent. Other embodiments are described.

A portable XRF analyzer includes a hand shield and a handle. In one embodiment, the XRF analyzer further comprises a power component spaced-apart from an engine component. The handle and the hand shield extend in parallel between the engine component and the power component, attaching the engine component to the power component. In another embodiment, the XRF analyzer further comprises two housing portions, each integrally formed in a single, monolithic body formed together at the same time. The two housing portions are joined together to form an XRF analyzer housing. In another embodiment, the hand shield is shorter than the handle.

An object of the invention is to provide a radiation-shielding material that has a high radiation-shielding capability and can be easily coated, molded and sheeted. Metals or the like having a radiation-shielding capability are blended with an elastomer precursor in a high concentration thereby providing a radiation-shielding material that has a higher radiation-shielding capability than ever before and can be easily coated, molded and sheeted in any desired configuration.

Alpha/beta radiation barrier materials and structures formed to include the barrier materials are described. Barrier materials include a matrix and particulate materials contained in the matrix. The particulates include alpha/beta radiation absorbers. Alpha/beta radiation absorbers of the barrier materials can be molecular, particulates, or defined nanostructures that are capable of absorbing incident alpha/beta particle energies. Matrix materials can include organic or inorganic materials including thermoplastic polymers, thermoset polymers, glasses, ceramics, etc.