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OSHA TECHNICAL MANUAL - SECTION III: CHAPTER 6

1. Infrared Radiation IR Invisible electromagnetic radiation with wavelengths which lie within the range of 0 70 to 1000 um These wavelengths are often broken up into regions IR A 0 7 1 4 um IR B 1 4 3 0 um and IR C 3 0 1000 pm Intrabeam Viewing The viewing condition whereby the eye is exposed to all or part of a direct laser beam or a specular reflection Irradiance E Radiant flux radiant power per unit area incident upon a given surface Units Watts per square centimeter Sometimes referred to as power density although not exactly correct Laser An acronym for light amplification by stimulated emission of radiation A laser is a cavity with mirrors at the ends filled with material such as crystal glass liquid gas or dye It produces an intense beam of light with the unique properties of coherency collimation and monochromaticity Laser Accessories The hardware and options available for lasers such as secondary gases Brewster windows Q switches and electronic shutters Laser Controlled Area See Controlled Area Laser Device Either a laser or a laser system Laser Medium Active Medium Material used to emit the laser light and for which the laser is named Laser Rod A solid state rod shaped lasing medium in which ion excitation is caused by a source of intense light such as a flash lamp Various materials are used for the rod the earliest of which was synthetic ruby crystal Laser Safety Officer LSO One wh
2. 6G in liquid solution or suspension as lasing media They are tunable over a broad range of wavelengths Semiconductor lasers sometimes called diode lasers are not solid state lasers These electronic devices are generally very small and use low power They may be built into larger arrays e g the writing source in some laser printers or compact disk players D The wavelength output from a laser depends upon the medium being excited Table III 6 1 lists most of the laser types and their wavelength ouput defined by the medium being excited Laser use today is not restricted to the laboratory or specialized industries Table III 6 2 lists some of the major uses of lasers TABLE III 6 1 WAVELENGTHS OF MOST COMMON LASERS Wavelength Wavelength Laser type umeters Laser type umeters Argon fluoride Excimer UV 0 193 Helium neon yellow 0 594 Krypton chloride Excimer UV 0 222 Helium neon orange 0 610 Krypton fluoride Excimer UV 0 248 Gold vapor red 0 627 Xenon chloride Excimer UV 0 308 Helium neon red 0 633 Xenon fluoride Excimer UV 0 351 Krypton red 0 647 Helium cadmium UV 0 325 Rohodamine 6G dye tunable 0 570 0 650 Nitrogen UV 0 337 Ruby CrAIO3 red 0 694 Helium cadmium violet 0 441 Gallium arsenide diode NIR 0 840 Krypton blue 0 476 Nd YAG NIR 1 064 Argon blue 0 488 Helium neon NIR 1 15 Copper vapor green 0 510 Erbium NIR 1 504 Argon green 0 514 Helium neon NIR 3 39 Krypton green 0 528 Hy
3. Eye protection X Spectator control X Service personnel b b b b X X Laser demonstration an x xX Laser fiber optics _ xX X xX X Key X Shall a Shall if embedded Class IIIA Class IIIB Class IV b Shall if embedded Class IIIB or Class IV No requirement Should Shall if MPE is exceeded A CONTROL MEASURES OVERVIEW 1 There are four basic categories of controls useful in laser environments These are engineering controls personal protective equipment administrative and procedural controls and special controls The controls to be reviewed here are based upon the recommendations of the ANSI Z 136 1 standard 16 of 33 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 17 of 33 2 Important in all controls is the distinction between the functions of operation maintenance and service First laser systems are classified on the basis of level of the laser radiation accessible during operation Maintenance is defined as those tasks specified in the user instructions for assuring the performance of the product and may include items such as routine cleaning or replenishment of expendables Service functions are usually performed with far less frequency than maintenance functions e g replacing the laser resonator mirrors or repair of faulty components and often require access to the laser beam by those performing the service functions T
4. Flashing EYE PROTECTION REQUIRED RED SYMBOL APPENDIX III 6 5 GLOSSARY OF LASER TERMS Absorb To transform radiant energy into a different form with a resultant rise in temperature Absorption Transformation of radiant energy to a different form of energy by the interaction of matter depending on temperature and wavelength Accessible Emission Level The magnitude of accessible laser or collateral radiation of a specific wavelength or emission duration at a particular point as measured by appropriate methods and devices Also means radiation to which human access is possible in accordance with the definitions of the laser s hazard classification Accessible Emission Limit AEL The maximum accessible emission level permitted within a particular class In ANSI Z 136 1 AEL is determined as the product of accessible emission Maximum Permissible Exposure limit MPE and the area of the limiting aperture 7 mm for visible and near infrared lasers Aperture An opening through which radiation can pass Argon A gas used as a laser medium It emits blue green light primarily at 448 and 515 nm Attenuation The decrease in energy or power as a beam passes through an absorbing or scattering medium Aversion Response Movement of the eyelid or the head to avoid an exposure to a noxious stimulant bright light It can occur within 0 25 seconds and it includes the blink reflex time Beam A collection of rays that may be parallel convergent
5. IIIB lasers Laser Activation Warning System An audible tone or bell and or visual warning such as a flashing light is recommended as an area control for Class IIIB laser operation Such a warning system is mandatory for Class IV lasers Such warning devices are to be activated upon system start up and are to be uniquely identified with the laser operation Verbal countdown commands are an acceptable audible warning and should be a part of the SOP Service Access Panels The ANSI Z 136 1 standard requires that any portion of the protective housing that permits direct access to an embedded Class IIIB or Class IV laser intended for removal only by service personnel must have either an interlock or require a tool in the removal process If an interlock is used and is defeatable a warning label indicating this fact is required on the housing near the interlock The design shall not allow replacement of a removed panel with the interlock in the defeated condition 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 22 of 33 The FDA CDRH Federal Laser Product Performance Standard requires warning labels on removable protective housing panels under all conditions Protective Housing Interlock Requirements a Interlocks which cause beam termination or reduction of the beam to MPE levels must be provided on all panels intended to be opened during operation and maintenan
6. Okla pp 131 148 1986 Laser Institute of America Safety information on electrical hazards Laser News Laser Inst of America 6 5 8 14 September 1984 Doyle D J and Kokosa J M Hazardous By Products of Plastics Processing with Carbon Dioxide Lasers In Laser Welding Machining and Materials Processing C Albright Ed Proceedings of ICALEO IFS LTD Bedford U K pp 201 203 1985 Rockwell R James Jr and Moss C E Optical radiation hazards of laser welding processes part I Nd YAG laser The Journal of The American Industrial Hygiene Association 44 8 572 579 August 1983 Rockwell R James Jr and Moss C E Optical radiation hazards of laser welding processes part II carbon dioxide laser The Journal of The American Industrial Hygiene Association 50 8 419 427 August 1989 Rockwell R James Jr Laser accidents are they all reported and what can be learned from them Journal of Laser Applications Laser Institute of America Toledo Ohio pp 53 57 October 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION II CHAPTER 6 24 of 33 1989 http www osha gov dts osta otm otm_iii otm_iti_6 html Underwriters Laboratories Inc UL 1740 Standard for Industrial Robots and Robotic Equipment Underwriters Laboratories Inc Northbrook Ill 1995 APPENDIX III 6 1 FDA CDRH REQUIREMENTS FOR LASER PRODUCTS Class Requirements I TA II IIIA IIIB IV Performanc
7. This is an important factor since as the scope of laser uses has expanded controlling lasers by total enclosure in a protective housing or interlocked room is limiting and in many instances an expensive overreaction to the real hazards The following factors are required in NHZ computations 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html laser power or energy output beam diameter beam divergence pulse repetition frequency prf if applicable wavelength beam optics and beam path and maximum anticipated exposure duration e Note that the ANSI Z 136 MPE value is required in all NHZ calculations Examples of NHZ calculations can be found in the appendix of ANSI Z 136 1 1993 In addition computer software is also available to assist in the computations for NHZ optical densities of protective eye wear and other aspects of laser hazard analysis 2 NHZ Example Summary The intrabeam direct hazard for a Nd YAG laser extends from 792 meters to 1410 meters depending upon whether a 10 second or 8 hour criterion is used as summarized in Table III 6 7 Similarly with a lens on the laser the hazard for a Nd YAG laser exists over a range from 6 3 meters to 11 3 meters The diffuse reflection zone for this laser type is however markedly smaller 0 8 meter to 1 4 meters Nonetheless the analysis suggests that operating personnel and support staff close to t
8. corporations implement an internal laser policy and establish safety practices based upon the ANSI Z 136 1 standard as well as their own corporate safety requirements C CLASS I CLASS II CLASS I A AND CLASS IIIA LASERS Accident data on laser usage have shown that Class I Class II Class I A and Class IIIA lasers are normally not considered hazardous from a radiation standpoint unless illogically used Direct exposure on the eye by a beam of laser light should a ways be avoided with any laser no matter how low the power D BEAM PATH CONTROLS There are some uses of Class IIIB and Class IV lasers where the entire beam path may be totally enclosed other uses where the beam path is confined by design to significantly limit access and yet other uses where the beam path is totally open In each case the controls required will vary as follows 1 Enclosed Total Beam Path a Perhaps the most common form of a Class I laser system is a high power laser that has been totally enclosed embedded inside a protective enclosure equipped with appropriate interlocks and or labels on all removable panels or access doors Beam access is prevented therefore during operation and maintenance b Such a completely enclosed system if properly labeled and properly safeguarded with protective housing interlocks and all other applicable engineering controls will fulfill all requirements for a Class I laser and may be operated in the enclosed mann
9. entry Training is required for all personnel who may frequently require entry into the area b Such defeatable controls shall be designed to allow both rapid egress by the laser personnel at all times and admittance to the laser controlled area in an emergency condition A readily accessible panic button or control disconnect switch shall be available for deactivating the laser under such emergency conditions c Under conditions where the entire beam path is not completely enclosed access to the laser controlled area shall be limited only to persons wearing proper laser protective eye wear when the laser is capable of emitting a beam In this case all other optical paths for example windows from the facility shall be covered or restricted in such a way as to reduce the transmitted intensity of the laser radiation to levels at or below the MPE for direct irradiation of the eye Procedural Entryway Controls A blocking barrier screen or curtain that can block or filter the laser beam at the entryway may be used inside the controlled area to prevent the laser 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html light from exiting the area at levels above the applicable MPE level In this case a warning light or sound is required outside the entryway that operates when the laser is energized and operating All personnel who work in the facility shall be appropriately tra
10. limits are however more relaxed for wavelengths between 0 550 and 1 40 um ANSI recognizes a decreased biological hazard in the red and infrared regions that is not recognized by the CDRH c The ANSI Z 136 MPE level for a very long term exposure by a helium neon laser is in fact seventeen times greater than the CDRH standard In the 1976 revision ANSI Z 136 introduced the correction factor CB which has a value of 17 5 at the 0 633 um HeNe laser wavelength and thus permitted a radiant exposure of 185 mJ cm2 accumulated exposure for times from T 453 seconds to 104 seconds and about 18 w cm2 7 w in a 7 mm limiting aperture for continuous operation of exposure durations exceeding 104 seconds 3 ANSI Z 136 1 Repetitively Pulsed Exposures 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION II CHAPTER 6 11 of 33 a The ANSI Z 136 standard requires a decrease in the maximum permissible exposure MPE for scanned or repetitive pulse radiation as compared to continuous wave radiation for pulse repetition frequencies PRF in the general range of 1000 15000 Hz Because of pulse additivity scanned or repetitively pulsed radiation with repetition rates less than 15 KHz have lower retinal damage threshold levels than CW radiation of comparable power b The ANSI Z 136 Standard includes a reduction factor of the threshold for each of the single pulses based on biological data that are not yet well explained by any theory The FDA CDRH st
11. or divergent Beam Diameter The distance between diametrically opposed points in the cross section of a circular beam where the intensity is reduced by a factor of e 0 368 of the peak level for safety standards The value is normally chosen at e2 0 135 of the peak level for manufacturing specifications Beam Divergence Angle of beam spread measured in radians or milliradians 1 milliradian 3 4 minutes of arc or approximately 1 mil For small angles where the cord is approximately equal to the arc the beam divergence can be closely approximated by the ratio of the cord length beam diameter divided by the distance range from the laser aperture Blink Reflex See aversion response 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 30 of 33 Brightness The visual sensation of the luminous intensity of a light source The brightness of a laser beam is most closely associated with the radio metric concept of radiance Carbon Dioxide Molecule used as a laser medium Emits far energy at 10 600 nm 10 6 pm Closed Installation Any location where lasers are used which will be closed to unprotected personnel during laser operation CO Laser A widely used laser in which the primary lasing medium is carbon dioxide gas The output wavelength is 10 6 ym 10600 nm in the far infrared spectrum It can be operated in either CW or pulsed Coherence A term describ
12. to produce various colors of light The color of light may be tuned by adjusting optical tuning elements and or changing the dye used Ultraviolet UV Radiation Electromagnetic radiation with wavelengths between soft X rays and visible violet light often broken down into UV A 315 400 nm UV B 280 315 nm and UV C 100 280 nm Visible Radiation light Electromagnetic radiation which can be detected by the human eye It is commonly used to describe wavelengths in the range between 400 nm and 700 780 nm Wavelength The length of the light wave usually measured from crest to crest which determines its color Common units of measurement are the micrometer micron the nanometer and earlier the Angstrom unit YAG Yttrium Aluminum Garnet a widely used solid state crystal composed of yttrium and aluminum oxides and a small amount of the rare earth neodymium TABLE OF CONTENTS ToP NEXT CHAPTER A Back to Top www osha gov www dol gov Contact Us Freedom of Information Act Customer Survey Privacy and Security Statement Disclaimers Occupational Safety amp Health Administration 200 Constitution Avenue NW Washington DC 20210 6 17 08 10 41 AM
13. when not in use G ENTRYWAY CONTROL MEASURES CLASS IV In addition there are specific controls required at the entryway to a Class IV laser controlled area These can be summarized as follows All personnel entering a Class IV area shall be adequately trained and provided proper laser protective eye wear All personnel shall follow all applicable administrative and procedural controls All Class IV area and entryway controls shall allow rapid entrance and exit under all conditions The controlled area shall have a clearly marked Panic Button nonlockable disconnect switch that allows rapid deactivation of the laser Class IV areas also require some form of area and entryway controls In the past doorway interlocking was customary for Class IV installations The ANSI Z 136 Standard now provides four options that allow the LSO to provide an entryway control suited for the installation The options include 1 Nondefeatable Entryway Controls A nondefeatable control such as a magnetic switch built into the entryway door which cuts the beam off when the door is opened is one option In this case training is required only for those persons who regularly work in the laser area Defeatable Entryway Controls a Defeatable controls may be used at an entryway for example during long term testing in a laser area In this case the controls may be temporarily made inactive if it is clearly evident that there is no hazard at the point of
14. 36 1 1993 VI CONTROL MEASURES AND SAFETY PROGRAMS The specific control measures specified in the ANSI Z 136 1 standard are summarized in Table III 6 9 The details of these controls are outlined the following sections 15 of 33 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html TABLE III 6 9 ENGINEERING CONTROL MEASURES FOR THE FOUR LASER CLASSES ANSI Z 136 1 1993 eresseresssessae Class Control measures I IA II IIIA IIIB IV Protective housing X X X X xX X Without protective housing LSO shall establish alternate controls Interlocks on protective housing a a a X X X Service access panel b b b b b X Key switch master X Viewing portals _ gt gt gt gt Collecting optics gt gt gt gt Totally open beam path xX X Limited open beam path X X Remote interlock connector X Beam stop or attenuator X Activation warning system X Emission delay Class IIIB laser controlled area X Class IV laser controlled area X Laser outdoor controls X X Temporary laser controlled area b b b b _ Remote firing amp monitoring Labels X X X xX X Area posting x X Administrative amp procedural controls N X x X x X Standard operating procedures X Output emission limitations LSO determines Education and training X xX X Authorized personnel X X Alignment procedures x X x X
15. ANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 8 of 33 associated equipment and therefore are always considered as Class I in normal operation 3 The only risk for exposure would occur during installation and service when light guide cables are disconnected or during an infrequent accidental cable break 4 Under the requirements of the ANSI Z 136 2 1988 Standard For the Safe Use of Optical Fiber Communication Systems Utilizing Laser Diode and LED Sources Optical Fiber Communication Systems OFCS are assigned into one of four service group SG designations SG1 SG2 SG3a SG3b depending on the potential for an accessible beam to cause biological damage 5 The service group designations relate to the potential for ocular hazards to occur only during accessible beam conditions This would normally occur only during periods of service to a OFCS Such designations apply only during periods of service in one of the following four service groups a Service Group 1 An OFCS that is SG1 has a total output power that is less than the Accessible Emission Limit AEL for Class I and there is no risk of exceeding the Maximum Permissible Irradiance MPI when viewing the end of a fiber with a microscope an eye loupe or with the unaided eye b Service Group 2 An OFCS is SG2 only if wavelengths between 0 400 and 0 700 mm are emitted and is potentially hazardous if viewed for more than 0 25 second Not
16. ECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html limits based on bioeffects of the eye and skin introduces a general classification scheme specifies the recommended control measures outlines suggested medical surveillance practice specifies training requirements and recommends practices for other nonbeam concerns ANSI Z 136 2 1988 FOR THE SAFE USE OF OPTICAL FIBER COMMUNICATION SYSTEMS UTILIZING LASER DIODE AND LED SOURCES This ANSI Standard provides guidance for the safe use of optical fiber communications systems OFCS utilizing laser diodes and or LED sources by defining control measures for each of four service group SG classifications This concept eliminates measurements and or calculations The standard is limited to OFCS that emit at power levels at or below 0 5 W The Z 136 2 standard addresses the same general topics as the base Z 136 1 standard The significant variation between the two standards lies in the definition of a Maximum Permissible Irradiance MPI value based upon a 5 mm limiting aperture in the visible and near infrared spectral regions This is in contrast to the larger 7mm limiting aperture used in this spectral region in the ANSI Z 136 1 Standard ANSI Z 136 3 1988 FOR THE SAFE USE OF LASERS IN HEALTH CARE FACILITIES The ANSI Z 136 3 Standard provides guidance for the safe use of lasers for diagnostic and therapeutic uses in health care facilities The
17. I 6 8 It should be stressed these values are for intrabeam viewing worst case only Viewing Class IV diffuse reflections such as during alignment tasks require in general less OD These should be determined for each situation and would be dependent upon the laser parameters and viewing distance 14 of 33 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html TABLE III 6 8 OPTICAL DENSITIES FOR PROTECTIVE EYEWEAR FOR VARIOUS LASER TYPES Optical density for exposure durations Laser type Wavelength aS and power mm 0 25 10 600 30 000 XeCl 3 50 Watts 0 303 es 6 2 8 0 9 7 XeFIl 50 Watts 0 351 z 4 8 6 6 8 3 Argon 1 0 Watts 0 514 3 0 3 4 5 2 6 4 Krypton 1 0 Watt 0 530 3 0 3 4 5 2 6 4 Krypton 1 0 Watt 0 568 3 0 3 4 4 9 6 1 HeNe 0 005 Watt 0 633 0 7 1 1 i7 2 9 Krypton 1 Watt 0 647 3 0 3 4 3 9 5 0 GaAs 50 mW 0 840 1 8 2 3 3 7 Nd YAG 100 Watt a 4 7 5 2 5 2 Nd YAG 1 06 Q switch P 1 0642 4 5 5 0 5 4 Nd YAG 50 Watts 4 4 4 9 4 9 1 333 6 2 8 0 9 7 1000 Watts 10 62 a Repetitively pulsed at 11 Hertz 12 nanosecond pulses 20 mJ pulse b OD for UV and FIR beams computed using a 1 mm limiting aperture which presents a worst case scenario All visible and NIR computations assume a 7 mm limiting aperture c Nd YAG operating at a less common 1 33 um wavelength Note All OD values determined using MPE criteria of ANSI Z 1
18. LPPS and or ANSI standards 2 It should be stressed that classification is a required specification provided by the laser manufacturer and the label that specifies the class is found in only one location on the laser product The class of the laser will be specified only on the lower left hand corner position three of the warning logotype label The logotype is the rectangular label that has the laser sunburst symbol and the warning statement of CAUTION Class II and some Class IIIA or DANGER some Class IIIA all Class IIIB and Class IV This label will also have the type of laser designated HeNe Argon CO etc and the power or energy output specified 1 mW CW MAX 100 mJ pulsed etc 3 Class I lasers have no required labeling indicating the Class I status Although the FLPPS requires no classification labeling of Class I lasers it does require detailed compliance with numerous other performance requirements i e protective housing identification and compliance labeling interlocking etc D ANSI Z 136 2 OPTICAL FIBER SERVICE GROUP DESIGNATIONS 1 Optical Fiber Communication Systems OFCS and the associated optical test sets use semiconductor lasers or LED transmitters that emit energy at wavelengths typically in the range from 0 650 to 1 20 mm into the light guide fiber optic cables 2 All OFCS are designed to operate with the beam totally enclosed within the fiber optic and 7 of 33 6 17 08 10 41 AM OSHA TECHNICAL M
19. O 1 1 1 Ct 1 Ct 1 1 1 Ct 1 1 1 Ct PRESENT YES NO Ct Ct 1 Ct 1 Ct 1 Ct 1 Ct APPENDIX ITI 6 3 THE AMERICAN NATIONAL STANDARDS INSTITUTE ANSI An American National Standard implies a consensus of those substantially concerned with its scope and provisions These standards are intended as a guide to aid the manufacturer the consumer and the general public There is however no inherent requirement for anyone or any company to adhere to an ANSI standard Compliance is voluntary unless specifically required by some alliance For example the Federal Department of Energy requires adherence to the ANSI Z 136 1 by their internal staff as well as all contractor organizations At present the following ANSI standards can be useful in laser safety matters ANSI Z 136 1 1993 FOR THE SAFE USE OF LASERS http www osha gov dts osta otm otm_iii otm_iti_6 html This is the master or parent standard in the Z 136 series Originally published in 1973 this standard has gone through revisions in 1976 1980 1986 and 1993 Revisions are currently being considered by the committee for the next publication which should occur in 1991 The Z 136 1 1993 standard includes the basis of laser hazard assessment including the Nominal Hazard Zone NHZ concept and measurements establishes Maximum Permissible Exposure MPE 6 17 08 10 41 AM OSHA T
20. OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 1 of 33 U S Department of Labor Occupational Safety amp Health Administration a www osha gov 5 Search GO Advanced Search A Z Index lt lt lt Back to OSHA Technical Manual OTM Table of Contents E Printing Instructions OSHA Technical Manual TABLE OF CONTENTS NEXT CHAPTER SECTION III CHAPTER 6 LASER HAZARDS Contents I Introduction II Nonbeam Laser Hazards III Biological Effects of the Laser Beam IV Laser Hazard Classifications V Investigational Guidelines VI Control Measures and Safety Programs VII Bibliography Appendix III 6 1 _ FDA CDRH Requirements for Laser Products Appendix III 6 2 _ FDA CDRH Federal Laser Product Performance Standard Evaluation Outline Appendix III 6 3 The American National Standards Institute ANSI Appendix ITI 6 4 Warning Signs Appendix III 6 5 Glossary of Laser Terms I INTRODUCTION The term LASER is an acronym for Light Amplification by Stimulated Emission of Radiation Light can be produced by atomic processes which generate laser light A laser consists of an optical cavity a pumping system and an appropriate lasing medium Figure III 6 1 FIGURE ITI 6 1 COMPONENTS OF A LASER PUMP gt PARTIALLY TRANSPARENT MIRROR MIRROR LASER OPTICAL CAVITY A The optical cavity contains the media to be excited with mirrors to red
21. _6 html Source ANSI A 136 1 1993 1 INTRABEAM OPTICAL DENSITY DETERMINATION 1 Based upon these typical exposure conditions the optical density required for suitable filtration can be determined Optical density OD is a logarithmic function defined by EQUATION III 6 1 OPTICAL DENSITY OD logi9 Mij MPE where Ho Anticipated worst case exposure J cm or W cm2 MPE Maximum permissible exposure level expressed in the same units as Hg 2 Based upon the worst case exposure conditions outlined above one can determine the optical density recommended to provide adequate eye protection for this laser For example the minimum optical density at the 0 514 um argon laser wavelength for a 600 second direct intrabeam exposure to the 5 watt maximum laser output can be determined as follows Where f 5 Watts MPE 16 7 W cm using 600 second criterion d 7mm worst case pupil size Computing the worst case exposure Ho Ho Power Area f A 4f pd2 Ho 4 5 0 p 0 7 Hp 12 99 W cm Substitution gives OD logig 12 99 16 7 x 10 OD 5 9 3 The most conservative approach would be to choose an 8 hour occupational exposure In this case the optical density at 0 514 um is increased to OD 7 1 for a 5 0 watt intrabeam exposure because the 8 hour 30 000 MPE is reduced to 1 0 x 10 W cm2 The OD values for various lasers computed for various appropriate exposure times are presented in Table II
22. air to glass Resonator The mirrors or reflectors making up the laser cavity including the laser rod or tube The mirrors reflect light back and forth to build up amplification Ruby The first laser type a crystal of sapphire aluminum oxide containing trace amounts of chromium oxide Scanning Laser A laser having a time varying direction origin or pattern of propagation with respect to a stationary frame of reference Secured Enclosure An enclosure to which casual access is impeded by an appropriate means e g door secured by lock magnetically or electrically operated latch or by screws 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 33 of 33 Semiconductor Laser A type of laser which produces its output from semiconductor materials such as GaAs Service Performance of adjustments repair or procedures on a non routine basis required to return the equipment to its intended state Solid Angle The ratio of the area on the surface of a sphere to the square of the radius of that sphere It is expressed in steradians sr Source The term source means either laser or laser illuminated reflecting surface i e source of light Tunable Laser A laser system that can be tuned to emit laser light over a continuous range of wavelengths or frequencies Tunable Dye Laser A laser whose active medium is a liquid dye pumped by another laser or flash lamps
23. andard does not recognize this repetitive pulse correction factor However some experts envision the possibility of a repetitively pulsed laser which is Class I by the FDA CDRH standard could be rated Class II or even Class IIIB by the ANSI Z 136 standard c The ANSI standard requires that multiple pulse scanning lasers operating from 1 to 15 000 Hz have a correction to the single pulse MPE The correction factor is determined by taking the fourth root of the total number of pulses N in a pulse train Then the correction factor is calculated such that the MPE radiant exposure or integrated radiance of an individual pulse within the train is reduced by a factor N ANSI Z 136 1 Maximum Permissible Exposure Limits a A summary of Maximum Permissible Exposure MPE limits for direct ocular exposures for some of the more common lasers is presented in Table III 6 6 For further information on MPE values refer to the ANSI Z 136 1 Safe Use of Lasers Standard b The information in Table III 6 6 provides the MPE value for different lasers operating for different overall exposure times The times chosen were m 0 25 second The human aversion time for bright light stimuli the blink reflex Thus this becomes the first line of defense for unexpected exposure to some lasers and is the basis of the Class II concept m 10 seconds The time period chosen by the ANSI Z 136 1 committees represents the optimum worst case time period for ocula
24. ational Standard Safety levels with respect to human exposure to radio frequency electromagnetic fields 300 kHz to 100 GHz ANSI C95 1 the appropriate protection guides for exposure to X ray emission is found in the Department of Labor Occupational Safety and Health Standards 29 CFR Part 1910 1096 and the applicable State Codes Lasers and laser systems which by design would be expected to generate appreciable levels of collateral radiation should be monitored ELECTRICAL HAZARDS The intended application of the laser equipment determines the method of electrical installation and connection to the power supply circuit for example conduit versus flexible cord All equipment shall be installed in accordance with the National Electrical Code and the Occupational Safety and Health Act Additional specific recommendations can be found in Section 7 4 of ANSI Z 136 1 1993 FLAMMABILITY OF LASER BEAM ENCLOSURES Enclosure of Class IV laser beams and terminations of some focused Class IIIB lasers can result in potential fire hazards if the enclosure materials are exposed to irradiances exceeding 10 W cm2 Plastic materials are not precluded as an enclosure material but their use and potential for flammability and toxic fume release following 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 4 of 33 direct exposure should be considered Flame resistant materials an
25. ce of all Class IIIA Class IIIB and Class IV lasers The interlocks are typically electrically connected to a beam shutter The removal or displacement of the panel closes the shutter and eliminates the possibility of hazardous exposures b Under the requirements of the ANSI Z 136 Standard for embedded Class IIIB and Class IV lasers only the interlocks are to be fail safe This usually means that dual redundant electrical series connected interlocks are associated with each removable panel c Adjustments or procedures during service on the laser shall not cause the safety interlocks to become inoperative or the laser radiation outside a Class I laser protective housing to exceed the MPE limits unless a temporary laser controlled area is established The interlocking requirements under the FLPPS are detailed and summarized in Appendix ITI 6 2 Remote Interlock Connector All Class IV lasers or laser systems must have a remote interlock connector to allow electrical connections to an emergency master disconnect panic button interlock or to room door or fixture interlocks When open circuited the interlock shall cause the accessible laser radiation to be maintained below the appropriate MPE level The remote interlock connector is also recommended for Class IIIB lasers K LASER USE WITHOUT PROTECTIVE HOUSING ALL CLASSES In some circumstances such as during the manufacture of lasers and during research and development operation of a
26. d by Qualified and Authorized Personnel Training of the individuals in aspects of laser safety is required for Class IIIB and Class IV laser installations 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 19 of 33 3 Transmission from Indoor Controlled Area The beams shall not under any circumstances be transmitted from an indoor laser controlled area unless for specific purposes such as testing In such cases the operator and the LSO must assure that the beam path is limited to controlled air space F CLASS IV LASER CONTROLS GENERAL REQUIREMENTS Those items recommended for Class IIIB but required for Class IV lasers are as follows Supervision directly by an individual knowledgeable in laser safety Entry of any noninvolved personnel requires approval A beam stop of an appropriate material must be used to terminate all potentially hazardous beams Use diffusely reflecting materials near the beam where appropriate Appropriate laser protective eye wear must be provided all personnel within the laser controlled area The beam path of the laser must be located and secured above or below eye level for any standing or seated position in the facility All windows doorways open portals etc of an enclosed facility should be covered or restricted to reduce any escaping laser beams below appropriate ocular MPE level Require storage or disabling of lasers
27. d commercially available products specifically designed for laser enclosures should also be considered II BIOLOGICAL EFFECTS OF THE LASER BEAM A EYE INJURY Because of the high degree of beam collimation a laser serves as an almost ideal point source of intense light A laser beam of sufficient power can theoretically produce retinal intensities at magnitudes that are greater than conventional light sources and even larger than those produced when directly viewing the sun Permanent blindness can be the result B THERMAL INJURY The most common cause of laser induced tissue damage is thermal in nature where the tissue proteins are denatured due to the temperature rise following absorption of laser energy 1 The thermal damage process burns is generally associated with lasers operating at exposure times greater than 10 microseconds and in the wavelength region from the near ultraviolet to the far infrared 0 315 um 103 um Tissue damage may also be caused by thermally induced acoustic waves following exposures to sub microsecond laser exposures 2 With regard to repetitively pulsed or scanning lasers the major mechanism involved in laser induced biological damage is a thermal process wherein the effects of the pulses are additive The principal thermal effects of laser exposure depend upon the following factors m The absorption and scattering coefficients of the tissues at the laser wavelength See Table III 6 1 for a summary of
28. diation within protective housing 6 Warning statement label 7 CAUTION logotype 8 Requires means to measure level of radiation intended to irradiate the body 9 CAUTION if 2 5 mWcm 2 or less DANGER if greater than 2 5 mWcm 2 10 Delay required between indication and emission 11 Variance required for Class IIIB or IV demonstration laser products and light shows 12 DANGER logotype 13 Required after August 20 1986 LASER EMISSIONS DESCRIPTION Type CLASSIFICATION DESIGNATION CLASS I CLASS IIIA CLASS IIA CLASS IIIB CLASS II CLASS IV PERFORMANCE REQUIREMENTS PRESENT YES NO Protective Housing All Classes 1040 10 f 1 Safety Interlocks All Classes 1040 10 f 2 Note requirements are dependent on class of internal radiation Nondefeatable Interlocks 1 Defeatable Interlocks 1 Remote Interlock Connector Classes IIIB amp IV 1040 10 f 3 Key Control Classes IIIB amp IV 1040 10 f 4 Emission Indicator Classes II III amp IV 1040 10 f 5 Class II amp IIIA no delay 1040 10 f 5 i Class IIIB amp IV with delay 1040 10 f 5 ii Indicators on laser and controls if separated by more than 2 meters Note Class IIA is exempt Beam Attenuator Classes II III amp V 1040 10 f 6 Location of Controls Classes IIA II III amp IV 1040 10 f 7 Viewing Optics All C
29. drogen fluoride NIR 2 70 Frequency doubled 0 532 Carbon dioxide FIR 9 6 Nd YAG green Carbon dioxide FIR 10 6 Helium neon green 0 543 Krypton yellow 0 568 Copper vapor yellow 0 570 Key UV ultraviolet 0 200 0 400 um VIS visible 0 400 0 700 um NIR near infrared 0 700 1 400 um 2 of 33 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 3 of 33 TABLE III 6 2 MAJOR CATEGORIES OF LASER USE Alignment Drilling Plasma diagnostics Annealing Entertainment Spectroscopy Balancing Heat treating Velocimetry Biomedical Holography Lidar Cellular research Information handling Special photography Dental Copying Scanning microscopy Diagnostics Displays Military Dermatology Plate making Distance ranging Ophthalmology Printing Rifle simulation Surgery Reading Weaponry Communications Scanning Nondestructive training Construction Typesetting Scanning Alignment Videodisk Sealing Ranging Marking Scribing Surveying Laboratory instruments Soldering Cutting Interferometry Welding Displays Metrology II NONBEAM LASER HAZARDS In some laser operations particularly in the research laboratory general safety and health guidelines should be considered A INDUSTRIAL HYGIENE Potential hazards associated with compressed gases cryogenic materials toxic and carcinogenic materials and noise should be considered Adequate ventilation shall be installed t
30. e At present there are virtually no OFCS s that operate in this wavelength range c Service Group 3A A SG 3A OFCS is not hazardous when viewed with the unaided eye and is hazardous only when viewed with a microscope or an eye loupe d Service Group 3B OFCS that meet none of the above criteria are designated as SG 3B NOTE OFCS s where the total power is at or above 0 5W do not meet the criteria for optical fiber service group designation In this case the OFCS s are treated as a standard laser system V INVESTIGATIONAL GUIDELINES A REQUIREMENTS OF LASER STANDARDS In the United States several organizations concern themselves with laser safety These organizations include the American National Standards Institute ANSI the Center for Devices and Radiological Health CDRH of the Food and Drug Administration FDA the Department of Labor s Occupational Safety and Health Administration OSHA and the Council of Radiation Control Program Directors CRCPD Several state governments and the CRCPD have developed a model state standard for laser safety 1 OSHA Regulatory Practice At the present time OSHA does not have a comprehensive laser standard though 29 CFR 1926 54 is applicable to the construction industry A standard for personal protective equipment Subpart I may apply in some cases The construction standard 29 CFR 1926 102 b 2 for eye and face protection states that employees whose occupation or assignment require
31. e all laser products Protective housing R2 R2 R R2 R2 R2 Safety interlock R34 R34 R34 R34 R34 R34 Location of controls R R _ R R Viewing optics R R R R R R Scanning safeguard R R R R R R Performance laser systems Remote control connector R R Key control R R Emission indicator z R R R10 pio Beam attenuator R R R R Reset RB Performance specific purpose products Medical S S S s8 s8 s8 Surveying leveling alignment S S S S NP NP Demonstration S S S S sll sti Labeling all laser products Certification and identification R R R R R R Protective housing D gt R5 R5 R5 R5 RS Aperture _ _ R R R R Class warning R amp R R Ry RP Information all lasers User information R R R R R R Product literature R R R R R Service information R R R R R R Key R required _ not applicable S same as other products of class NP not permitted D depends on level of interior radiation Notes 1 Based on highest level accessible during operation 2 Required wherever and whenever human access to laser radiation above Class I limits is not needed for product to perform its function 3 Required for protective housings opened during operation or maintenance if human access thus gained is not always necessary when housing is opened 4 Interlock requirements vary according to Class of internal radiation 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION II CHAPTER 6 25 of 33 5 Wording depends on level and wavelength of laser ra
32. e engineering features limiting accessible emission Emission Act of giving off radiant energy by an atom or molecule Enclosed Laser Device Any laser or laser system located within an enclosure which does not permit hazardous optical radiation emission from the enclosure The laser inside is termed an embedded laser Energy Q The capacity for doing work Energy is commonly used to express the output from pulsed lasers and it is generally measured in Joules J The product of power watts and duration seconds One watt second one Joule Excimer Excited Dimer A gas mixture used as the active medium in a family of lasers emitting ultraviolet light Fail safe Interlock An interlock where the failure of a single mechanical or electrical component of the interlock will cause the system to go into or remain in a safe mode Gas Discharge Laser A laser containing a gaseous lasing medium in a glass tube in which a constant flow of gas replenishes the molecules depleted by the electricity or chemicals used for excitation Gas Laser A type of laser in which the laser action takes place in a gas medium Helium Neon HeNe Laser A laser in which the active medium is a mixture of helium and neon Its wavelength is usually in the visible range Used widely for alignment recording printing and 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 31 of 33 measuring
33. eam E LASER CONTROLLED AREA When the entire beam path from a Class IIIB or Class IV laser is not sufficiently enclosed and or baffled to ensure that radiation exposures will not exceed the MPE a laser controlled area is required During periods of service a controlled area may be established on a temporary basis The controlled area will encompass the NHZ Those controls required for both Class IIIB and Class IV installations are as follows 1 Posting with Appropriate Laser Warning Signs a Class IIIA beam irradiance 2 5 mW cm2 Class IIIB and Class IV lasers Require the ANSI DANGER sign format white back ground red laser symbol with black outline and black lettering see Appendix III 6 4 Note that under ANSI Z 136 1 criteria area posting is required only for Class IIIB and Class IV lasers b Class II or Class IIIA areas if area warning is deemed unnecessary by the LSO All signs and labels associated with these lasers when beam irradiance for Class IIIA does not exceed 2 5 mW cm2 use the ANSI CAUTION format yellow background black symbol and letters c During times of service and other times when a temporary laser controlled area is established an ANSI NOTICE sign format is required white background red laser symbol with blue field and black lettering This sign is posted only during the time when service is in progress Examples of area warning signs and logotype designs are given in Appendix III 6 4 2 Operate
34. ect for exposures to visible light between 10 and 10 4 seconds 2 8 hours The standard accepts that a cumulative radiant energy exposure of 3 85 millijoules mJ will not cause a biological effect Hence a 10 second total accumulated exposure corresponds to an average power entering a 7 mm aperture of 385 microwatts uW For an exposure of 10 4 seconds the average power would be 0 385 UW In the FLPPS the power level of 0 385 pW is referred to as the Class I Accessible Emission Limit AEL for a visible CW laser ANSI Z 136 1 Long Term Exposure Limits a The ANSI Z 136 1 1993 standard is a user standard and therefore provides maximum permissible exposure MPE limits These were derived by normalizing the power or pulse energy data derived from biological research studies relative to a defined limiting aperture For example in the visible and near infrared spectra the limiting aperture is based upon the diameter of a fully dilated pupil of the human eye 7 mm The area of a 7 mm pupil is 0 385 cm2 Hence the irradiance limit for long term ocular exposure is computed by dividing the AEL value of 0 385 pW by the area of the limiting aperture of 0 385 cm2 This yields the worst case MPE value of 1 0 pW cm2 for long term exposure in the wavelength range of 0 400 to 0 550 mm b The ANSI Z 136 and FDA CDRH allowable exposure limits for CW lasers Class I limits are essentially identical for wavelengths between 0 400 and 0 550 um The ANSI
35. een prepared and approved by the CDRH the manufacturer may then actively market the laser for that specific medical or surgical procedure c The FDA CDRH Federal Laser Product Performance Standard FLPPS regulates the manufacturer of commercial laser products not the user The standard does not contain specific design specifications but is a conceptual performance standard which the designer of laser products must consider The intent is to insure laser product safety d FLPSS is applicable to lasers or laser systems sold by a company within or imported into the U S In some cases it can also apply when a laser or laser system is transferred within a company for internal use within the U S The compliance procedure requires implementation of the procedures and requirements as set forth in the U S Federal Laser Product Performance Standard 21 CFR Part 1000 parts 1040 10 and 1040 11 e Under the requirements of the FLPPS the manufacturer is first required to classify the laser as either a Class I Class II Class I A Class IIIA Class IIIB or Class IV laser product and then to certify by means of a label on the product as well as submit a report demonstrating that all requirements performance features of the compliance standard are met Specific performance features include m protective housing m protective housing warning labels and logotype labels 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www o
36. en there is a possibility that the system may become energized The immediate area shall be considered a temporary laser controlled area d Staring into the end of any broken severed or unterminated optical fiber or cable shall be avoided 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 23 of 33 e The end of any broken severed or unterminated optical fiber shall not be viewed with unfiltered optical instruments microscopes telescopes etc An exception to this is the use of indirect image converters such as an infrared image converter or closed circuit television system for verification that a fiber is not energized f During a splicing operation either installation or service if it is required that the ends of the fiber be examined with an eye loupe for a satisfactory cut only an eye loupe containing an appropriate filter shall be used If a fusion splicer is used the appropriate operating safety procedures shall be rigidly adhered to VII BIBLIOGRAPHY American National Standards Institute American National Standard for the Safe Use of Lasers ANSI Z 136 1 1993 Laser Institute of America New York NY 1993 American National Standards Institute American National Standard for the Safe Use of Optical Fiber Communication Systems Utilizing Laser Diode and LED Sources ANSI Z 136 2 1988 Laser Institute of America Orlando Florida 1988 Amer
37. engineering controls are inadequate to eliminate the possibility of potentially hazardous eye exposure i e whenever levels of accessible emission exceed the appropriate MPE levels This generally applies only to Class IIIB and Class IV lasers All laser eye wear shall be clearly labeled with OD values and wavelengths for which protection is afforded m Skin protection can best be achieved through engineering controls If the potential exists for damaging skin exposure particularly for ultraviolet lasers 0 200 0 400 m then skin covers and or sun screen creams are recommended For the hands gloves will provide some protection against laser radiation Tightly woven fabrics and opaque gloves provide the best protection A laboratory jacket or coat can provide protection for the arms For Class IV lasers flame resistant materials may be best 20 of 33 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 21 of 33 m In general other controls should serve as primary protection rather than depending on employees to use protective eye wear Many accidents have occurred when eye wear was available but not worn This may be because laser protective eye wear is often dark uncomfortable to wear and limits vision b Laser Barriers and Protective Curtains m Area control can be effected in some cases using special barriers specifically designed to withstand either direct or diffu
38. er with no additional controls for the operator c It should be noted that during periods of service or maintenance controls appropriate to the class of the embedded laser may be required perhaps on a temporary basis when the beam enclosures are removed and beam access is possible Beam access during maintenance or 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 18 of 33 service procedures will not alter the Class I status of the laser during operation 2 Limited Open Beam Path a It is becoming an accepted work practice particularly with industrial materials processing lasers to build an enclosure that completely surrounds the laser focusing optics and the immediate area of the workstation Often a computer controlled positioning table is located within this enclosure The design often allows a gap of less than one quarter of an inch between the bottom of the enclosure and the top of the material to be laser processed Such a design enables the part to be laser cut or welded to move while the laser delivery optics remain stationary b Such a system might not meet the stringent human access requirements of the FLPPS for a Class I laser but the real laser hazards are well confined Such a design provides what can be called a limited open beam path In this situation the ANSI Z 136 1 standard recommends that the LSO shall conduct a laser hazard analysis and e
39. he laser still need eye protection even for diffuse reflections Other calculations are also presented in Table III 6 7 for a 500 Watt CO and a 5 Watt argon laser Note that the NHZ s do not vary for the CO laser because the MPE values are nearly identical for 10 second and 8 hour criteria Also note that the diffuse reflection NHZ s are very small except for the 8 hour criterion for the argon laser In most cases 0 25 second can be used with visible lasers unless intentional staring is required or intended TABLE III 6 7 NHZ DISTANCE VALUES FOR VARIOUS LASERS Exposure Hazard range meters Laser type criteria Diffuse Lens on laser Direct Nd YAG 100 Watt 8 hours 1 4 11 3 1410 1 064 um 10 seconds 0 8 6 3 792 co 500 Watt 8 hours 0 4 5 3 309 10 6 um 10 seconds 0 4 5 3 390 Argon 25 2 x 5 0 Watt 8 hours 12 6 1 7 x 103 103 0 488 um 0 25 seconds 0 25 33 3 240 Laser criteria used for NHZ distance calculations Laser parameter Nd YAG co Argon Wavelength um 1 064 10 6 0 488 Beam power Watts 100 0 500 0 5 0 Beam divergence mrad 2 0 2 0 1 0 Beam size at aperture mm 2 0 20 0 2 0 Beam size at lens mm 6 3 30 0 3 0 Lens focal length mm 25 4 200 0 200 0 MPE for 8 hours w cm 1 6 x 103 1 0 x 105 1 0 MPE for 10 seconds w cm2 5 1x 103 1 0 x 10 MPE for 0 25 second w cm2 ag 2 5 x 103 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti
40. he safety procedures required for such beam access during service functions should be clearly delineated in the laser product s service manual B LASER SAFETY OFFICER LSO 1 The LSO has the authority to monitor and enforce the control of laser hazards and effect the knowledgeable evaluation and control of laser hazards The LSO administers the overall laser safety program where the duties include but are not limited to items such as confirming the classification of lasers doing the NHZ evaluation assuring that the proper control measures are in place and approving substitute controls approving standard operating procedures SOP s recommending and or approving eye wear and other protective equipment specifying appropriate signs and labels approving overall facility controls providing the proper laser safety training as needed conducting medical surveillance and designating the laser and incidental personnel categories 2 The LSO should receive detailed training including laser fundamentals laser bioeffects exposure limits classifications NHZ computations control measures including area controls eye wear barriers etc and medical surveillance requirements 3 In many industrial situations the LSO functions will be a part time activity depending on the number of lasers and general laser activity The individual is often in the corporate industrial hygiene department or may be a laser engineer with safety responsibility Some
41. hen the interlocks are defeated I ADMINISTRATIVE AND PROCEDURAL CONTROLS 1 Standard Operating Procedures One of the more important of the administrative and procedural controls is the written Standard Operating Procedure SOP The ANSI Z 136 1 standard requires an SOP for a Class IV laser and recommends SOP s for Class IIIB lasers The key to developing an effective SOP is the involvement of those individuals who operate maintain and service the equipment under guidance of the LSO Most laser equipment comes with instructions for safe operation by the manufacturers however sometimes the instructions are not well suited to a specific application due to special use conditions 2 Alignment Procedures Many laser eye accidents occur during alignment The procedures require extreme caution A written SOP is recommended for all recurring alignment tasks 3 Limitations on Spectators Persons unnecessary to the laser operation should be kept away For those who do enter a laser area with unenclosed Class IIIB or Class IV beam paths appropriate eye protection and instruction is required 4 Protective Equipment Protective equipment for laser safety generally means eye protection in the form of goggles or spectacles clothing and barriers and other devices designed for laser protection a Laser Protective Eyewear and Clothing m Eye protection devices designed to protect against radiation from a specific laser system shall be used when
42. ican National Standards Institute American National Standard for the Safe Use Lasers in the Health Care Environment ANSI Z 136 3 1988 Laser Institute of America Orlando Florida 1988 Food and Drug Administration Regulations for the Administration and Enforcement of the Radiation Control for Health and Safety Act of 1968 Lasers Center for Devices and Radiological Health Food and Drug Administration DHHS 21 CFR Chapter 1 1968 Food and Drug Administration Performance Standard for Laser Products Center for Devices and Radiological Health Food and Drug Administration DHHS 50 CFR 161 33682 33702 1985 Food and Drug Administration Compliance Guide for Laser Products Center for Devices and Radiological Health Food and Drug Administration DHHS FDA 86 8260 Doyle Daryl and Kokasa John Laser Processing of Kevlar Hazardous Chemical By products Proceedings of ICALEO Laser Institute of America Toledo Ohio 1986 Rockwell R James Jr Ed Laser Safety Training Manual Sixth Edition Rockwell Associates Inc Cincinnati Ohio 1989 Sliney David H and Wolbarsh Myron L Safety With Lasers and Other Optical Sources New York Plenum 1980 Rockwell R James Jr Ensuring safety in laser robotics Lasers and Applications 3 11 65 69 November 1984 Rockwell R James Jr Fundamentals of Industrial Laser Safety In Industrial Laser Annual Handbook M Levitt and D Belforte Eds Penn Well Books Tulsa
43. ined 4 Entryway Warning Systems In order to safely operate a Class IV laser or laser system a laser warning system shall be installed as described m A laser activation warning light assembly shall be installed outside the entrance to each laser room facility containing a Class IV laser or laser system In lieu of a blinking entryway warning the entryway light assembly may alternatively be interfaced to the laser in such a manner that a light will indicate when the laser is not operational high voltage off and by an additional light when the laser is powered up high voltage applied but not operating and by an additional flashing light when the laser is operating A laser warning sign shall be posted both inside and outside the laser controlled area H TEMPORARY LASER CONTROLLED AREA Should overriding interlocks become necessary during periods of special training service or maintenance and access to Class IIIB or Class IV lasers is required a temporary laser controlled area shall be devised following specific procedures approved by the LSO These procedures shall outline all safety requirements necessary during such operation Such temporary laser controlled areas which by nature will not have the built in protective features as defined for a laser controlled area shall nevertheless provide all of the safety requirements for all personnel both within and without the temporary laser controlled area during periods of operation w
44. ing light as waves which are in phase in both time and space Monochromaticity and low divergence are two properties of coherent light Collimated Light Light rays that are parallel Collimated light is emitted by many lasers Diverging light may be collimated by a lens or other device Collimation Ability of the laser beam to not spread significantly low divergence with distance Continuous Mode The duration of laser exposure is controlled by the user by foot or hand switch Continuous Wave CW Constant steady state delivery of laser power Controlled Area Any locale where the activity of those within are subject to control and supervision for the purpose of laser radiation hazard protection Diffuse Reflection Takes place when different parts of a beam incident on a surface are reflected over a wide range of angles in accordance with Lambert s Law The intensity will fall off as the inverse of the square of the distance away from the surface and also obey a Cosine Law of reflection Divergence The increase in the diameter of the laser beam with distance from the exit aperture The value gives the full angle at the point where the laser radiant exposure or irradiance is e or e2 of the maximum value depending upon which criteria is used Embedded Laser A laser with an assigned class number higher than the inherent capability of the laser system in which it is incorporated where the system s lower classification is appropriate to th
45. irect the produced photons back along the same general path B The pumping system uses photons from another source as a xenon gas flash tube optical pumping to transfer energy to the media electrical discharge within the pure gas or gas mixture media collision pumping or relies upon the binding energy released in chemical reactions to raise 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html the media to the metastable or lasing state C The laser medium can be a solid state gas dye in liquid or semiconductor Lasers are commonly designated by the type of lasing material employed 1 Solid state lasers have lasing material distributed in a solid matrix e g the ruby or neodymium YAG yttrium aluminum garnet lasers The neodymium YAG laser emits infrared light at 1 064 micrometers Gas lasers helium and helium neon HeNe are the most common gas lasers have a primary output of a visible red light CO lasers emit energy in the far infrared 10 6 micrometers and are used for cutting hard materials Excimer lasers the name is derived from the terms excited and dimers use reactive gases such as chlorine and fluorine mixed with inert gases such as argon krypton or xenon When electrically stimulated a pseudomolecule or dimer is produced and when lased produces light in the ultraviolet range Dye lasers use complex organic dyes like rhodamine
46. is ANSI standard is included in this listing mainly because a high percentage of industrial facilities require that the eye protection used in their plants meet the ANSI Z 87 requirements In the past this basically referred to the drop ball test in which a 1 inch diameter ball weighing 2 4 ounces and dropped 50 inches must not fracture the protective lens The new Z 87 1 1989 requires a high velocity impact test wherein small 1 4 in diameter steel balls weighing 0 04 ounces are projected at high velocity at the protective filter In addition there is a high mass impact test in which a 1 inch diameter pointed heat treated steel projectile 30 degree cone that weighs 17 6 ounces is dropped at specified distances These new requirements place far more stringent performance requirements on safety eye wear APPENDIX ITI 6 4 WARNING SIGNS FIGURE III 6 2 CAUTION 27 of 33 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iii_6 html YELLOW BLACK FIGURE III 6 3 DANGER WHITE BLACK POSITION1 BOLD BLACK LETTERING POSITION BOLD BLACK LETTERING RED SYMBOL POSITIONS BLACK LETTERING FIGURE ITII 6 4 LASER REPAIR NOTICE 28 of 33 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 29 of 33 WHITE BLUE OTICE LASER REPAIR IN PROGRESS BOLD BLACK LETTERING Do not Enter When Light is
47. lasses 1040 10 f 8 Scanning Safeguard All Classes 1040 10 f 9 Manual Reset Mechanism Class IV 1040 10 f 10 4 http www osha gov dts osta otm otm_iii otm_iti_6 html APPENDIX III 6 2 FDA CDRH FEDERAL PRODUCT PERFORMANCE STANDARD EVALUATION OUTLINE 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION II CHAPTER 6 26 of 33 LABEL REQUIREMENTS Certification Label All Classes 1010 2 Identification Label All Classes 1010 3 Class Designation and Warning Label All Classes except Class I 1040 10 g 1 2 amp 3 Radiation Output Information Position 2 on label Classes II III amp IV 1040 10 g 4 Note Class ITA is exempt Aperture Label Classes II III amp IV 1040 10 g 5 Note Class IIA is exempt Noninterlocked Protective Housing Labels i e service panels All Classes 1040 10 g 6 Defeatably Interlocked Protective Housing Labels 1040 10 g 7 Warning for Invisible Radiation wherever applicable all labels 1040 10 g 8 Positioning of Labels 1040 10 g 9 Label Specifications 1040 10 g 10 INFORMATION REQUIREMENTS User Information 1040 10 h 1 Operator amp Maintenance Instructions h 1 i Statement of Parameters h 1 ii Label Reproductions h 1 iii Listing of Controls Adjustments and Procedures including Warnings h 1 iv Service Information 1040 10 h 2 ii PRESENT YES N
48. m Yttrium Aluminum Garnet A synthetic crystal used as a laser medium to produce 1064 nm light Neodymium Nd The rare earth element that is the active element in Nd YAG laser and Nd Glass lasers Nominal Hazard Zone NHZ The nominal hazard zone describes the space within which the level of the direct reflected or scattered radiation during normal operation exceeds the applicable 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 32 of 33 MPE Exposure levels beyond the boundary of the NHZ are below the appropriate MPE level Optical Cavity Resonator Space between the laser mirrors where lasing action occurs Optical Density A logarithmic expression for the attenuation produced by an attenuating medium such as an eye protection filter Optical Fiber A filament of quartz or other optical material capable of transmitting light along its length by multiple internal reflection and emitting it at the end Optical Pumping The excitation of the lasing medium by the application of light rather than electrical discharge Optical Radiation Ultraviolet visible and infrared radiation 0 35 1 4 um that falls in the region of transmittance of the human eye Output Power The energy per second measured in watts emitted from the laser in the form of coherent light Power The rate of energy delivery expressed in watts Joules per second Thus 1 Watt 1 Joule x 18g P
49. more common laser types and wavelengths m Irradiance or radiant exposure of the laser beam Duration of the exposure and pulse repetition characteristics where applicable m Extent of the local vascular flow m Size of the area irradiated C OTHER 1 Other damage mechanisms have also been demonstrated for other specific wavelength ranges and or exposure times For example photochemical reactions are the principal cause of threshold level tissue damage following exposures to either actinic ultraviolet radiation 0 200 ym 0 315 um for any exposure time or blue light visible radiation 0 400 ym 0 550 um when exposures are greater than 10 seconds To the skin UV A 0 315 um 0 400 um can cause hyperpigmentation and erythema Exposure in the UV B range is most injurious to skin In addition to thermal injury caused by ultraviolet energy there is the possibility of radiation carcinogenesis from UV B 0 280 mm 0 315 mm either directly on DNA or from effects on potential carcinogenic intracellular viruses Exposure in the shorter UV C 0 200 ym 0 280 um and the longer UV A ranges seems less harmful to human skin The shorter wavelengths are absorbed in the outer dead layers of the epidermis stratum corneum and the longer wavelengths have an initial pigment darkening effect followed by erythema if there is exposure to excessive levels These biological effects are summarized in Table III 6 3 The hazards associated with skin expo
50. n unenclosed laser or laser system may become necessary In such cases the LSO shall determine the hazard and ensure that controls are instituted appropriate to the class of maximum accessible emission to ensure safe operation Such controls may include but are not limited to access restriction eye protection area controls barriers shrouds beam stops etc administrative and procedural controls and education and training L OPTICAL FIBER LIGHT WAVE COMMUNICATION SYSTEMS OFCS 1 Under normal operation such systems are completely enclosed Class I with the optical fiber and optical connectors forming the enclosure During installation or servicing or when an accidental break in the cable occurs the system can no longer be considered enclosed If engineering controls limit the accessible emission to levels below the applicable MPE irradiance no controls are necessary If the accessible emission is above the MPE the following requirements shall apply a Only authorized trained personnel shall be permitted to perform service on light wave transmission systems if access to laser emission is required b Only authorized trained personnel shall be permitted to use the laser test equipment Optical Loss Test Set Optical Time Domain Reflectometer etc during installation and or service c All unauthorized personnel shall be excluded from the immediate area of access to laser radiation during service and installation wh
51. nd labeled protective enclosure In some cases the enclosure may be a room walk in protective housing which requires a means to prevent operation when operators are inside the room b Class I A a special designation that is based upon a 1000 second exposure and applies only to lasers that are not intended for viewing such as a supermarket laser scanner The upper power limit of Class I A is 4 0 mW The emission from a Class I A laser is defined such that the emission does not exceed the Class I limit for an emission duration of 1000 seconds c Class II low power visible lasers that emit above Class I levels but at a radiant power not above 1 mW The concept is that the human aversion reaction to bright light will protect a person Only limited controls are specified d Class IIIA intermediate power lasers cw 1 5 mW Only hazardous for intrabeam viewing Some limited controls are usually recommended NOTE There are different logotype labeling requirements for Class IIIA lasers with a beam irradiance that does not exceed 2 5 mW cm2 Caution logotype and those where the beam irradiance does exceed 2 5 mW cm2 Danger logotype e Class IIIB moderate power lasers cw 5 500 mW pulsed 10 J cm or the diffuse reflection limit whichever is lower In general Class IIIB lasers will not be a fire hazard nor are they generally capable of producing a hazardous diffuse reflection Specific controls are recommended f Class IV High
52. o has authority to monitor and enforce measures to control laser hazards and effect the knowledgeable evaluation and control of laser hazards Laser System An assembly of electrical mechanical and optical components which includes a laser Under the Federal Standard a laser in combination with its power supply energy source Lens A curved piece of optically transparent material which depending on its shape is used to either converge or diverge light Light The range of electromagnetic radiation frequencies detected by the eye or the wavelength range from about 400 to 760 nm The term is sometimes used loosely to include radiation beyond visible limits Limiting Aperture The maximum circular area over which radiance and radiant exposure can be averaged when determining safety hazards Maintenance Performance of those adjustments or procedures specified in user information provided by the manufacturer with the laser or laser system which are to be performed by the user to ensure the intended performance of the product It does not include operation or service as defined in this glossary Maximum Permissible Exposure MPE The level of laser radiation to which a person may be exposed without hazardous effect or adverse biological changes in the eye or skin Nd Glass Laser A solid state laser of neodymium glass offering high power in short pulses A Nd doped glass rod used as a laser medium to produce 1064 nm light Nd YAG Laser Neodymiu
53. o reduce noxious or potentially hazardous fumes and vapors produced by laser welding cutting and other target interactions to levels below the appropriate threshold limit values e g American Conference of Governmental Industrial Hygienists ACGIH threshold limit values TLV s or Occupational Safety and Health Administration s OSHA permissible exposure limits PEL s EXPLOSION HAZARDS High pressure arc lamps and filament lamps or laser welding equipment shall be enclosed in housings which can withstand the maximum pressures resulting from lamp explosion or disintegration The laser target and elements of the optical train which may shatter during laser operation shall also be enclosed NONBEAM OPTICAL RADIATION HAZARDS This relates to optical beam hazards other than laser beam hazards Ultraviolet radiation emitted from laser discharge tubes pumping lamps and laser welding plasmas shall be suitably shielded to reduce exposure to levels below the ANSI Z 136 1 extended source OSHA PEL s and or ACGIH TLV s COLLATERAL RADIATION Radiation other than laser radiation associated with the operation of a laser or laser system e g radio frequency RF energy associated with some plasma tubes x ray emission associated with the high voltage power supplies used with excimer lasers shall be maintained below the applicable protection guides The appropriate protection guide for RF and microwave energy is that given in the American N
54. on Title 18 Article 7 Arizona Radiation Regulatory Agency Arkansas Division of Radiation Control amp Emergency Management Act 460 Florida Department of Health amp Rehabilitative Services Non Ionizing Chapter 10D 89 Georgia Department of Public Health Chapter 290 5 27 Illinois Department of Nuclear Safety Chapter 111 12 Massachusetts Department of Public Health 105 CMR 21 Montana Health amp Environmental Services 92 003 New York Department of Labor Code Rule 50 Pennsylvania Environmental Resources Chapter 203 Title 25 Texas Department of Health Radiation Control Act Parts 50 60 70 Washington Labor amp Industry Chapter 296 62 WAC Using CRCPD Model State laser standard as basis 3 FDA Center for Devices and Radiological Health Performance Requirements a The CDRH of the Department of Health and Human Services was chartered by Congress to standardize the manufacture of lasers in interstate commerce after August 2 1976 CDRH also has the responsibility for enforcing compliance with the medical devices legislation All manufacturers of surgical lasers must obtain premarket approval of their devices through the CDRH b FDA sanctions the exploratory use of lasers for specific procedures through a process known as an Investigational Device Exemption IDE Approval of an IDE permits the limited use of a laser expressly for the purpose of conducting an investigation of the laser s safety and effectiveness Once an IDE has b
55. power lasers cw 500 mW pulsed 10 J cm or the diffuse reflection limit are hazardous to view under any condition directly or diffusely scattered and are a potential fire hazard and a skin hazard Significant controls are required of Class IV laser facilities 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html TABLE III 6 4 LASER CLASSIFICATIONS SUMMARY OF HAZARDS Applies to wavelength ranges ee Hazards Class UV VIS NIR IR Direct ocular Diffuse ocular Fire I X X X X No No No IA Ez xX SS Only after No No 1000 sec II F X Fs Only after No No 0 25 sec TIA Xx X X X Yes No No IIB X X X X Yes Only when laser No output is near Class IIIB limit of 0 5 Watt IV X X X X Yes Yes Yes Key X Indicates class applies in wavelength range z Class IA applicable to lasers not intended for viewing ONLY CDRH Standard assigns Class IIIA to visible wavelengths ONLY ANSI Z 136 1 assigns Class IIIA to all wavelength ranges C HOW TO DETERMINE THE CLASS OF LASERS DURING INSPECTION 1 The classification of a laser or laser product is in some instances a rather detailed process It can involve determination of the AEL measurement of the laser emission measurement determination of the emission pulse characteristics if applicable evaluation of various performance requirements protective housing interlocks etc as specified by the F
56. publication includes an extensive appendix that details suggested practice in fourteen medical subspecialty areas Although the appendix is not technically a part of the standard Major emphasis is included on the associated hazard topics of airborne contaminants plume and electrical and fire hazards The information in the base of the standard has been kept less mathematical and refers the reader frequently to the ANSI Z 136 1 Standard if such detail is needed Summary charts provide information on MPE and NHZ values Control measures are identical in most cases to the master standards with items special to medical laser systems foot pedals output calibration QC and safety audits etc given additional coverage ANSI NFPA 70 1990 THE NATIONAL ELECTRICAL CODE 1990 HANDBOOK The fifth edition of the National Electrical Code Handbook is based on the new edition of The National Fire Protection Association s NFPA 70 The National Electrical Code This document authored by the NFPA s Electrical Code Committee is unquestionably the most authoritative and comprehensive document on electrical safety and addresses the topic from both a fire and electrocution point of view The Handbook includes the complete text of the Code provisions along with explanations It provides a basis for safety procedures for all electrical hazards associated with lasers ANSI Z 87 1 1989 PRACTICE FOR OCCUPATIONAL AND EDUCATIONAL EYE AND FACE PROTECTION Th
57. r exposures to infrared principally near infrared laser sources It was argued that natural eye motions dominate for periods longer than 10 seconds m 600 seconds The time period chosen by the ANSI Z 136 1 committees represents a typical worst case period for viewing visible diffuse reflections during tasks such as alignment 30 000 seconds The time period that represents a full 1 day 8 hour occupational exposure This results from computing the number of seconds in 8 hours e g 8 hours x 60 minutes hour x 60 seconds minute 28 800 seconds Rounded off it becomes 30 000 seconds c The safety exposure limits MPE s in Table III 6 6 are expressed in irradiance terms W cm2 that would be measured at the cornea Note that they vary by wavelength and exposure time 6 17 08 10 41 AM http www osha gov dts osta otm otm_iii otm_iti_6 html OSHA TECHNICAL MANUAL SECTION II CHAPTER 6 12 of 33 http www osha gov dts osta otm otm_iii otm_iti_6 html TABLE III 6 6 SUMMARY MAXIMUM PERMISSIBLE EXPOSURE LIMITS Wave length MPE level W cm Laser type yum 0 25 sec 10 sec 600 sec 30 000 sec CO2 CW 10 6 aoe 100 0 x 103 F 100 0 x 103 Nd YAG 1 33 a 5 1 x 103 Se 1 6 x 103 CW Nd YAG 1 064 sie 5 1 x 103 zaa 1 6 x 103 CW Nd YAG Q switched 1 064 ash 17 0 x 10 ese 2 3 x 106 GaAs Diode CW 0 840 1 9 x 103 wes 610 0 x 10 HeNe CW 0 633 2 5 x 103 293 0 x 106 17 6 x 106 K
58. rea can be considered as the protective housing for an open beam laser Such a walk in enclosure can also be a FDA CDRH Class I provided that controls preclude operation with personnel within the room viz pressure sensitive floor mat switches IR sensors door interlocks etc Master Switch Control All Class IV lasers and laser systems require a master switch control The switch can be operated by a key or computer code When disabled key or code removed the laser cannot be operated Only authorized system operators are to be permitted access to the key or code Inclusion of the master switch control on Class IIIB lasers and laser systems is also recommended but not required Optical Viewing System Safety Interlocks filters or attenuators are to be incorporated in conjunction with beam shutters when optical viewing systems such as telescopes microscopes viewing ports or screens are used to view the beam or beam reflection area For example an electrical interlock could prevent laser system operation when a beam shutter is removed from the optical system viewing path Such optical filter interlocks are required for all except Class I lasers Beam Stop or Attenuator Class IV lasers require a permanently attached beam stop or attenuator which can reduce the output emission to a level at or below the appropriate MPE level when the laser system is on standby Such a beam stop or attenuator is also recommended for Class IIIA and Class
59. rnational standards divide lasers into four major hazard categories called the laser hazard classifications The classes are based upon a scheme of graded risk They are based upon the ability of a beam to cause biological damage to the eye or skin In the FLPPS the classes are established relative to the Accessible Emission Limits AEL provided in tables in the standard In the ANSI Z 136 1 standard the AEL is defined as the product of the Maximum Permissible Exposure MPE level and the area of the limiting aperture For visible and near infrared lasers the limiting aperture is based upon the worst case pupil opening and is a 7 mm circular opening 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION III CHAPTER 6 http www osha gov dts osta otm otm_iii otm_iti_6 html 6 of 33 2 Lasers and laser systems are assigned one of four broad Classes I to IV depending on the potential for causing biological damage The biological basis of the hazard classes are summarized in Table III 6 4 a Class I cannot emit laser radiation at known hazard levels typically continuous wave cw 0 4 uW at visible wavelengths Users of Class I laser products are generally exempt from radiation hazard controls during operation and maintenance but not necessarily during service Since lasers are not classified on beam access during service most Class I industrial lasers will consist of a higher class high power laser enclosed in a properly interlocked a
60. rotective Housing A protective housing is a device designed to prevent access to radiant power or energy Pulse A discontinuous burst of laser light or energy as opposed to a continuous beam A true pulse achieves higher peak powers than that attainable in a CW output Pulse Duration The on time of a pulsed laser it may be measured in terms of milliseconds microseconds or nanoseconds as defined by half peak power points on the leading and trailing edges of the pulse Pulsed Laser Laser which delivers energy in the form of a single or train of pulses Pump To excite the lasing medium See Optical Pumping or Pumping Pumped Medium Energized laser medium Pumping Addition of energy thermal electrical or optical into the atomic population of the laser medium necessary to produce a state of population inversion Radiant Energy Q Energy in the form of electromagnetic waves usually expressed in units of Joules watt seconds Radiant Exposure H The total energy per unit area incident upon a given surface It is used to express exposure to pulsed laser radiation in units of J cm2 Reflection The return of radiant energy incident light by a surface with no change in wavelength Refraction The change of direction of propagation of any wave such as an electromagnetic wave when it passes from one medium to another in which the wave velocity is different The bending of incident rays as they pass from one medium to another e g
61. rypton 0 647 25x 103 ooo 364 0 x 106 28 5 x 10 CW o 31 0 x 106 oe 25x103 18 6 x 10 16 7 x 106 2 5 x 103 1 0 x 1068 Argon CW 0 514 2 5 x 103 pa 16 7 x 10 1 0 x 10 XeFl Excimer cw 0 351 n 33 3 x 10 XeCl Excimer cw 0 308 ee zem sis 1 3 x 10 Source ANSI Z 136 1 1993 C LASER HAZARD COMPUTATIONS 1 NHZ Definition Use and Values a The Nominal Hazard Zone NHZ describes the space within which the level of direct reflected or scattered radiation during normal operation exceeds the MPE The NHZ associated with open beam Class IIIB and Class IV laser installations can be useful in assessing area hazards and implementing controls b It is often necessary in some applications where open beams are required e g industrial processing laser robotics surgical uses to define the area where the possibility exists for potentially hazardous exposure This is done by determining the NHZ Consequently persons outside the NHZ boundary would be exposed below the MPE level and are considered to be in a non hazardous location c The NHZ boundary may be defined for example by direct beams intrabeam and diffusely scattered laser beams as well as beams transmitted from fiber optics and or through lens arrays The NHZ perimeter is the envelope of MPE exposure levels from any specific laser installation geometry d The purpose of an NHZ evaluation is to define that space where control measures are required
62. s exposure to laser beams shall be furnished suitable laser safety goggles which will protect for the specific wavelength of the laser and be of optical density O D adequate for the energy involved OSHA citations are issued by invoking the general duty clause or in some cases Subpart I In such cases the employers are required to revise their reportedly unsafe work place using the recommendations and requirements of such industry consensus standards as the ANSI Z 136 1 Standard See also Table III 6 8 2 Specific and Model State Laser Regulations A few states currently have laser regulations Requirements are generally concerned with the registration of lasers and the licensing of operators and institutions Physician used and other medical lasers are generally exempt from state requirements The complexity of state laser regulations may change in the future pending adoption of the 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION II CHAPTER 6 9 of 33 http www osha gov dts osta otm otm_iii otm_iti_6 html Suggested State Regulation for Lasers promulgated through the Conference of Radiation Control Program Directors This model state standard has been adopted in part for example by Arizona and Florida Several other states have enacted some form of regulation Table III 6 5 summarizes state regulations TABLE III 6 5 SUMMARY OF CURRENT STATE LASER REGULATIONS State Department Regulation Alaska Environmental Conservati
63. sely scattered beams The barrier will be described with a barrier threshold limit BTL the beam will penetrate the barrier only after some specified exposure time typically 60 seconds The barrier is located at a distance from the laser source so that the BTL is not exceeded in the worst case exposure scenario a Currently available laser barriers exhibit BTL s ranging from 10 to 350 W cm for different laser wavelengths and power levels An analysis conducted in a manner similar to the NHZ evaluations described previously can establish the recommended barrier type and installation distances for a given laser It is essential that the barrier also not support combustion or be itself consumed by flames during or following a laser exposure J ENGINEERING CONTROLS Engineering controls are normally designed and built into the laser equipment to provide for safety In most instances these will be included on the equipment provided by the laser manufacturer as part of the performance requirements mandated by the FLPPS Specifics on some of the more important engineering controls recommended in the ANSI Z 136 1 standard are detailed as follows 1 Protective Housing A laser shall have an enclosure around it that limits access to the laser beam or radiation at or below the applicable MPE level A protective housing is required for all classes of lasers except of course at the beam aperture In some cases the walls of a properly enclosed room a
64. sha gov dts osta otm otm_iii otm_iti_6 html 10 of 33 product identification label and certification statement safety interlocks emission indicator remote interlock connector key control beam attenuator specification of control locations viewing optic limitations scanning beam safeguards and manual reset of beam cutoff f FDA CDRH performance requirements are tabulated in Appendix III 6 1 An outline to assist in evaluating FLPPS laser system performance requirements is included in Appendix III 6 2 The American National Standard Institute ANSI An American National Standard implies a consensus of those substantially concerned with its scope and provisions These standards are intended as a guide for manufacturers consumers and the general public However there is no inherent requirement for any person or company to adhere to an ANSI standard Compliance is voluntary unless specifically required by an organization For example the U S Department of Energy requires adherence to the ANSI Z 136 1 by their staff as well as by all contractor organizations Appendix III 6 3 summarizes ANSI Standards applicable to laser safety B LASER EXPOSURE LIMITS At present either the FDA criteria for medical lasers or the following ANSI standards can be useful in evaluating laser safety 1 FDA Long Term Exposure Limits The FDA CDRH Federal Laser Product Performance Standard FLPPS assumes a linearly additive biological eff
65. stablish the extent of the NHZ c In many system designs such as described above the NHZ will be extremely limited and procedural controls rather than elaborate engineering controls will be sufficient to ensure safe use In many cases the laser units may be reclassified by the LSO as Class I under the specifications of the ANSI Z 136 standard d Such an installation will require a detailed standard operating procedure SOP Training is also needed for the system operator commensurate with the class of the embedded laser e Protective equipment eye protection temporary barriers clothing and or gloves respirators etc would be recommended for example only if the hazard analysis indicated a need or if the SOP required periods of beam access such as during setup or infrequent maintenance activities Temporary protective measures for service can be handled in a manner similar to the service of any embedded Class IV laser 3 Totally Unenclosed Beam Path There are several specific application areas where high power Class IIIB and Class IV lasers are used in an unenclosed beam condition This would include for example open industrial processing systems often incorporating robotic delivery laser research laboratory installations surgical installations etc Such laser uses will require that the LSO conduct a hazard analysis and NHZ assessment Controls are chosen to reflect the magnitude of hazards associated with the accessible b
66. sure are of less importance than eye hazards however with the expanding use of higher power laser systems particularly ultraviolet lasers the unprotected skin of personnel may be exposed to extremely hazardous levels of the beam power if used in an unenclosed system design NOTE The primary purpose of an exiting laser beam e g cutting or welding of hard materials must not be forgotten Some laser beams designed for material alteration may be effective some distance from their intended impact point 6 17 08 10 41 AM OSHA TECHNICAL MANUAL SECTION II CHAPTER 6 5 of 33 http www osha gov dts osta otm otm_iii otm_iti_6 html TABLE III 6 3 SUMMARY OF BASIC BIOLOGICAL EFFECTS OF LIGHT Photobiological spectral domain Ultraviolet C 0 200 0 280 um Ultraviolet B 0 280 315 um Ultraviolet A 0 315 0 400 um Visible 0 400 0 780 um Infrared A 0 780 1 400 um Infrared B 1 400 3 00 um Infrared C 3 00 1000 um Eye effects Photokeratitis Photokeratitis Photochemical UV cataract Photochemical and thermal retinal injury Cataract retinal burns Corneal burn Aqueous flare IR cataract Corneal burn only Skin effects Erythema sunburn Skin cancer Accelerated skin aging Increased pigmentation Pigment darkening Skin burn Photosensitive reactions Skin burn Skin burn Skin burn Skin burn IV LASER HAZARD CLASSIFICATIONS A INTRODUCTION 1 The intent of laser ha
67. zard classification is to provide warning to users by identifying the hazards associated with the corresponding levels of accessible laser radiation through the use of labels and instruction It also serves as a basis for defining control measures and medical surveillance 2 Lasers and laser systems received from manufacturers are required by federal law 21 CFR Part 1000 to be classified and appropriately labeled by the manufacturer It should be stressed however that the classification may change whenever the laser or laser system is modified to accomplish a given task 3 It should also be stressed that an agency such as the Food and Drug Administration s Center for Devices and Radiological Health FDA CDRH does not approve laser systems for medical use The manufacturer of the laser system first classifies the laser and then certifies that it meets all performance requirements of the Federal Laser Product Performance Standard FLPPS The forms submitted by the manufacturer to FDA CDRH are reviewed for technical accuracy omissions and errors If none are found the manufacturer is notified only that the submission appears to be complete Therefore all lasers and laser systems that are manufactured by a company or purchased by a company and relabeled and placed into commerce or incorporated into a system and placed into commerce shall be classified B LASER HAZARD CLASSES 1 Virtually all of the U S domestic as well as all inte

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