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Patty's Industrial Hygiene, Physical and Biological Agents. Группа авторовЧитать онлайн книгу.

Patty's Industrial Hygiene, Physical and Biological Agents - Группа авторов


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solar spectrum at the earth's surface.

      3.3 Gas Discharge Lamps and Arc Lamps

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      Source: From Ref. (13). Reproduced by permission of Newport Corporation, Oriel Product Line.

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      Source: Adapted from Newport Corporation, Oriel Product Line.

      High‐intensity discharge (HID) lamps are defined as electrical discharge lamps in which the arc is stabilized by wall temperature and the arc tube has a wall loading greater than 3 W cm−2 (14). HID lamps include some mercury lamps, as well as metal halide lamps, high‐pressure sodium vapor lamps, and xenon arc lamps. Metal halide lamps contain mercury in the arc tube and are capable of emitting significant amounts of UV radiation.

      Chemicals known as phosphors absorb short‐wavelength optical radiation and fluoresce radiation of longer wavelengths, usually in a broad band. Fluorescent lamps are low‐pressure mercury‐vapor tubes with a coating of phosphors on the inside of the tube. Depending on the intended application, phosphors may be selected that fluoresce broadly in the visible region (“fluorescent lights”), the UV‐A region (“black lights” and phototherapy lamps), or the UV‐A and UV‐B regions (sunlamps for tanning).

      3.4 Electrical Discharges

      Electrical discharges used in arc welding and plasma arc cutting are a common source of potentially hazardous visible, UV‐A, UV‐B, and UV‐C radiations. Emission spectra from welding and cutting arcs consist of numerous spectral peaks that may be superimposed on a continuum. The spectral distribution of the radiation depends on the shielding gas for the arc, the composition of the electrodes and the base metal, and the welding current.

      3.5 Light‐Emitting Diodes

      LEDs are solid‐state electronic devices that emit noncoherent optical radiation, generally over a moderately narrow wavelength band several tens of nanometers wide. LEDs are increasingly being used for illumination because they are relatively efficient at converting electrical power into visible or UV radiation; some LEDs now on the market have efficiencies of 40–50%. UV and blue LEDs may emit potentially hazardous levels of radiation.

      3.6 Excimer Lamps

      Excimer lamps are being used increasingly as sources of noncoherent UV radiation. An excimer is a diatomic molecule, typically a homonuclear noble gas or noble gas–halogen complex, in an excited electronic state that is more stable than its ground state, such that the molecule breaks apart when the excitation energy is released in the form of a UV photon. Depending on the excimer, the radiation is emitted in one or more narrow wavelength bands in the UV‐C region. Phosphors may be used to shift and broaden the emission spectrum of the lamp for various applications.

      4.1 Exposure Guidelines

      Because the biological effects of exposure to optical radiation depend on the wavelength, assessment of broadband optical radiation hazards must take into account both the spectral distribution of the radiation received and the biological action spectra for the effects of interest. Exposure criteria have been developed for the assessment of the potential for some adverse health effects associated with various portions of the optical radiation spectrum.

      4.1.1 UV Hazards to Skin and Eye

      Guidelines for exposure to UV radiation have been developed by the American Conference of Governmental Industrial Hygienists (ACGIH) (15), the International Commission on Non‐Ionizing Radiation Protection (ICNIRP) (16), and the CIE (17).

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