NEW RADIATION LEGISLATION M M TREVOR RADIATION Aims to: Produce - - PowerPoint PPT Presentation

NEW RADIATION LEGISLATION

M M TREVOR

RADIATION

Aims to:

• Produce a working definition for the

term Radiation

• Consider what types of radiation are

present in the workplace

• Look at risk assessment of artificial
• ptical radiation and electromagnetic

radiation

• Discuss possible implications of the

draft IRR 2018

WHAT IS RADIATION?

RADIATION

Tasks set in audience’s PowerPoint

• Please list what types of energy sources

you think we need to consider.

• For each energy source you identified

please give its method of energy transfer.

• Please identify if you would consider

potential energy transfer to be radiation.

• Have a stab at a definition.

RADIATION

Radiation – the transfer of energy from a source This is far too simple a definition we need to consider:

• Types of energy
• Types of transfer

Radiation radiates:

• Obeys the Invers Square Law (ISL) rule

RADIATION

Energy

• We have an energy source such as a hot
• bject (heat), a loud speaker (sound) or

a candle (light)

• This energy is transferred from the

source to another point usually as a wave

– Note for heat we consider radiation transfer not conduction or convection

RADIATION

Energy

• We have an energy source such as an

unstable nucleus

• E = mc2
• This radiation is in the form of charged

particles (alpha and beta) and un- charged particles (neutrons)

• Energy emitted is sufficiently large to

ionize an atom

RADIATION

Energy transfer

• Energy travels from the source in

straight lines – rectilinear propagation

• It continues to do this until acted upon

by an external factor

– For example alpha particles are quickly acted upon by the earths gravitational field – this would not happen in outer space

RADIATION

Potential Energy

– Potential energy being the energy of a body as a result of its position

• For example an electric, magnetic or

gravitational potential energy

– Force is a method to transfer energy – Energy is transferred to the object which the force is acted upon [gives motion KE]

RADIATION

Concept of a Field

• The field due to a ‘body’ (mass, charge
• r magnet) is the region of space

surrounding the ‘body’ where other ‘bodies’ will feel a force due to it’s presence

– Movement in a field changes the potential energy of a body – So energy has been transferred

RADIATION

Field lines

– We can try to model the field using field lines or lines of force – Gives the direction another body will move under the influence of the force – Field lines have three possible arrangements (as seen with gravitational, electric and magnetic fields)

RADIATION

http://hyperphysics.phy-astr.gsu.edu/hbase/Forces/isq.html

RADIATION

We do not have magnetic dipoles however the strength of the force does

• bey the invers square law

RADIATION

Definition: Radiation is the transfer of energy (including potential energy) from a (point) source outward such that it obeys the inverse square law (until an interaction takes place), where the energy is transferred as a wave, a particle or the repositioning of a ‘body’ within a field

–When energy is radiated from the source, energy is transferred from the source to another point

RADIATION IN THE WORKPLACE

• Gravitational field (working at heights)
• Sound (noise)
• Electric and magnetic fields 2016
• Electromagnetic radiation

– Radio waves – Micro waves – Visible radiation 2010 – Ionizing radiation draft for 2018

THE ICNIRP

ICNIRP

International Commission on Non-ionizing Radiation Protection. An independent organization, providing scientific advice and guidance on the health and environmental effects of non-ionizing radiation (NIR) to protect people and the environment from detrimental NIR

• Investigate the effect of non-ionizing radiation on

the body for the different frequencies at

http://www.icnirp.org/

CONTROL OF AOR AT WORK REGULATIONS 2010

OPTICAL RADIATION

Light is an everyday example of optical radiation (artificial optical radiation, if it is emitted by a lamp and not the sun).

• The term ‘optical radiation’ is used

because light is a form of electromagnetic radiation, and because it has effects on the eye — i.e. it enters the eye, is focused and then detected.

OPTICAL RADIATION

Task set in audience’s PowerPoint

• Please try and calculate the power

disposition to the eye.

OPTICAL RADIATION

Consider a 10 W laser (mid-day sun is 10 W cm-2) — The beam is 1 mm in diameter — With a power disposition of 1000 W cm-2 — This is sufficient to ignite paper or cause skin burns — If the beam enters the eye it will be focused by the lens to give a power disposition 100 000 times greater or 108 W cm-2 — Even if the laser operates at 900 nm (beyond the visible range) it still penetrates the eye and can cause damage.

OPTICAL RADIATION

Heat – black body radiation

• KE of the atom (charge in motion) gives

an electromagnetic wave

T emperature in K Colour emitted

1,000 Red 1,500 Reddish orange 2,000 Yellowish

• range

2,800 Yellow 3,500 Yellowish white 4,500 Warm white 5,500 White

OPTICAL RADIATION

Some of the invisible portions of the electromagnetic spectrum are included in the term ‘optical radiation’. These are the ultraviolet and infrared spectral regions. Although they cannot be seen (the retina doesn’t have detectors for these wavelengths) portions of these spectral regions can penetrate the eye, to a greater or lesser degree.

• UVA is transmitted to the retina less efficiently

than green light

OPTICAL RADIATION

Exposure limits exist for the spectral region 180 nm to 3,000 nm for non- coherent optical radiation and from 180 nm to 1 mm for laser radiation.

• Ultraviolet ‘C’ (UVC) 100–280 nm
• UVB 280–315 nm
• UVA 315–400 nm
• Visible 380–780 nm
• Infrared ‘A’ (IRA) 780–1,400 nm
• IRB 1 400–3,000 nm
• IRC 3,000–1,000,000 nm (3 μm to 1 mm)

OPTICAL RADIATION

Unit of measure

• “irradiance” means the radiant power incident

per unit area upon a surface expressed in watts per square metre (W m-2 )

• “radiance” means the radiant flux or power
• utput per unit solid angle per unit area

expressed in watts per square metre per steradian ( W m-2 sr-1)

• “radiant exposure” means the time integral of

the irradiance, expressed in joules per square metre (J m-2)

OPTICAL RADIATION

You can access the free download of the Non-binding guide to good practice for implementing Directive 2006/25/EC from the following:

http://www.uni- heidelberg.de/md/zentral/universitaet/beschaeftigte/service/s icherheit/leitfaden_eu_optische_strahlung_engl.pdf

• Laser classification and safety are in section eight from

page 27

• AOR biological effects are in appendix B page 46 onwards
• Exposure limits (Annex I and II) from page 123

OPTICAL RADIATION

As required by our membership of the EU the British Government produced new legislation on Artificial Optical Radiation (AOR).

http://www.legislation.gov.uk/uksi/2010/1140/pdfs/uksi_ 20101140_en.pdf

To assist employers in implementing this new legislation the government has produced a useful guide at the web site below:

http://www.hse.gov.uk/radiation/nonionising/optical.htm

OPTICAL RADIATION

Hazard Whenever electromagnetic radiation interacts with a material, it is likely to deposit some energy at the point of interaction (possible damage mechanism).

• We must also consider AOR effects on the skin

(requires health surveillance of workers)

The most serious long-term effect of UV radiation is the induction of skin cancer. The non-melanoma skin cancers (NMSCs) are basal cell carcinomas and squamous cell. Malignant melanoma is the main cause of skin cancer death, although its incidence is less than NMSC.

OPTICAL RADIATION

Where should you be? As an employer with only safe sources

• Have a list of all the sources in your

workplace (see list in guide page three)

• Not on the list?
• Let your employees know you only have

safe sources

– Have a list of workers that have issues with AOR (migraine sufferers)

• Review with new equipment

OPTICAL RADIATION

As an employer with normally safe sources that could be inappropriately used

• Have a list of all these sources in your

workplace

• Identify what needs to be done to keep

your employees safe

– Let your employees know what actions they need to take to keep the sources safe when in use

• Record and review

OPTICAL RADIATION

For one from the following list indicate what instructions you would give to keep your employee safe.

OPTICAL RADIATION

Inappropriately used (placed close to eye) safe sources can cause harm.

• Ceiling-mounted and task lights without

diffusers or filters

• Desktop projectors and vehicle headlights
• Non-laser medical lights
• Multiple photographic flash lamps and art &

entertainment lights

• UV insect traps
• Group 2 lamp systems [see British Standard BS

EN 62471: 2008] and class 1M, 2 or 2M lasers

OPTICAL RADIATION

As an employer with hazardous sources

• Have a list of all these sources in your

workplace

• Undertake a risk assessment
• Identify what control measures are

needed to keep your employees safe

– see next set of slides

• Implement controls and check outcome

(Take action if employees are exposed to AOR in excess of the exposure limits)

• Record and review

OPTICAL RADIATION

H T T P : / / W W W . H S E . G O V . U K / R A D I A T I O N / N O N I O N I S I N G / O P T I C A L . H T M

Hazardous light source (see Table 1)

• Metal working: welding (arc and oxy-fuel) and plasma

cutting

• Pharmaceutical and research: UV fluorescence and

sterilisation systems

• Hot industries: furnaces
• Printing: UV curing of inks/Motor vehicle repairs: UV curing
• f paints and welding
• Medical and cosmetic treatments: laser surgery, blue light

and UV therapies, Intense Pulsed Light sources (IPLs)

• Industry, research and education: use of Class 3B and Class

4 lasers (laser safety advisor)

• Any Risk Group 3 lamp or lamp system (including LEDs), for

example search lights, professional projections systems

OPTICAL RADIATION

General control measures to consider

• Use an alternative, safer light source that can achieve the

same result

• Use filters, screens, remote viewing, curtains, safety

interlocks, clamping of work pieces, dedicated rooms, remote controls and time delays

• Train workers in best-practice and give them appropriate

information

• Organise the work to reduce exposure to workers and

restrict access to hazardous areas

• Issue personal protective equipment (PPE), e.g. clothing,

goggles or face shields.

• Use relevant safety signs

OPTICAL RADIATION

Risk Assessment

• Use manufactures data
• To measure or calculate the levels of

exposure - follow the following standards or recommendations where they apply; or follow national or international science- based guidelines

(a) for laser radiation, the standards of the International Electrotechnical Commission (IEC); or (b) for non-coherent radiation, the standards of the IEC and the recommendations of the International Commission for Illumination (CIE) and the European Committee for Standards (CEN).

OPTICAL RADIATION

You need to record

• the level, wavelength and duration of exposure (with the

exposure limit values)

• the effects of exposure on employees or groups of

employees whose health is at particular risk from exposure

• any possible effects on the health and safety of employees

resulting from interactions between AOR and photosensitising chemical substances

• any indirect effects of exposure on the health and safety
• f employees such as temporary blinding, explosion or fire
• the availability of alternative equipment designed to

reduce levels of exposure

OPTICAL RADIATION

• appropriate information obtained from health surveillance,

including where possible published information

• multiple sources of exposure
• any class 3B or 4 laser that is classified in accordance with

the relevant IEC standard that is in use by the employer and any artificial optical radiation source that is capable of presenting the same level of hazard

• information provided by the manufacturers of artificial
• ptical radiation sources and associated work equipment

in accordance with the relevant European Union Directives.

ELECTRIC & MAGNETIC FIELDS

E & M RADIATION

Note: The information presented is obtained from the government archive of the Health Protection Agency site. This archive was created 01-04-2014 and its maintenance cannot be guaranteed. (32 slides)

http://webarchive.nationalarchives.gov.uk/20140714084352/http:// www.hpa.org.uk/Topics/Radiation/UnderstandingRadiation/AtAGla nce/Flash_ElectricAndMagneticFields/

E & M RADIATION

Electric fields are generated where a voltage exists but current does not necessarily flow Even when an appliance is unplugged or switched off the field exists around the ring main

E & M RADIATION

Magnetic fields are created only when the electric current flows Magnetic field at 90o to electric field

E & M RADIATION

Units Electric field in volts per metre (V m-1) or in kilovolts per metre (kV m-1) Magnetic field in tesla (T) or its subdivisions (mT, µT and nT)

Field strength at 50 cm from appliance Microwave oven 1.7 µT Washing machine 1.0 µT Vacuum cleaner 0.8 µT Dish washer 0.8 µT Food mixer 0.7 µT Hair dryer 0.12 µT

E & M RADIATION

CONTROL OF EMF AT WORK REGULATIONS 2016

E & M RADIATION

You can access the free download of the Non-binding guide to good practice for implementing Directive 2013/35/EC for SMEs from the following:

https://publications.europa.eu/en/publication-detail/- /publication/c5fb1d53-8775-11e5-b8b7- 01aa75ed71a1/language-en/format-PDF/source-47229864

• Health effects are given on pages eight and nine
• Type of equipment or workplace that put employees at

risk with and without active implants are given on pages (14 to 17)

E & M RADIATION

As required by our membership of the EU the British Government produced new legislation on EMF

http://www.legislation.gov.uk/uksi/2010/1140/pdfs/uksi_ 20101140_en.pdf

To assist employers in implementing this new legislation the government has produced a useful guide at the web site below:

http://www.hse.gov.uk/radiation/nonionising/optical.htm

E & M RADIATION

Questions set in audience’s PowerPoint

• Dose this type of radiation cause

cancer?

• Are the effects of this radiation

cumulative?

E & M RADIATION

Hazard Note this legislation does not cover suggested long-term health effects.

Direct effects are separated into:

• non-thermal effects, such as the stimulation of

nerves, muscles and sensory organs

• thermal effects, such as tissue heating

See pages (5 to 7) HSE CEMFAW guide

E & M RADIATION

All these effects show a threshold below which there is no risk, and exposures below the threshold are not cumulative in any way. The effects caused by exposure are transient being limited to the duration

• f exposure.

E & M RADIATION

Indirect effects

Where the presence of an object may become the cause of a safety or health hazard

• Interference with electronic equipment and
• ther devices (active and passive implants)
• Electric shocks or burns from contact currents

E & M RADIATION

Employees working close to equipment

• perating at high currents or high

voltages may be in regions of strong electromagnetic fields. This is also likely to be the case for equipment designed to deliberately transmit electromagnetic radiation at high power. These strong fields may exceed the ALs or ELVs

• AL – Action Level and ELV – Exposure Limit Value
• See schedule Part 2 and Part 3 of the legislation

E & M RADIATION

E & M RADIATION

Industrial sources of EMF which may exceed the ELVs and/or the indirect- effect ALs

Light industry – Heating (Dielectric, Induction & Microwave), welding (Resistance, Manual & Steam), magnetic particle inspection, Industrial magnetiser and demagnetisers, RF plasma devices including vacuum deposition and sputtering Heavy industry - Industrial electrolysis, Furnaces, arc and induction melting (Microwave drying in the construction industry) Transport - Electrically-powered trains and trams, Radar (air traffic control & weather)

E & M RADIATION

Exemption

Regulations allow the sensory-effect ELVs to be exceeded when certain safety conditions are met.

• Armed forces
• MRI - development, testing, installation, use

and maintenance of, or research related to,

MRI equipment for patients in the health sector, where:

– the exposure of employees above the ELV is at the lowest level reasonably practicable – employees are protected against the health effects and safety risks arising from their exposure to EMFs

E & M RADIATION

Where should you be? As an employer with only safe sources

• Have a list of all the sources in your

workplace (see list in guide pages (9-10))

• Let your employees know you only have

safe sources

– Have a list of workers that have issues with EMF (see next slide)

• Review with new equipment

E & M RADIATION

Tasks set in audience’s PowerPoint

• Please identify some implanted and

body-worn devices.

E & M RADIATION

Workforce employees at particular risk:

• Employees wearing active/passive

implanted medical devices (AIMDs and PIMDs ), or body-worn medical devices (BWMDs)

• Employees who are pregnant
• Employees who work in close proximity

to electro-explosive devices, explosive materials or flammable atmospheres

E & M RADIATION

As an employer with hazardous sources

• Assess the levels of EMFs and ensure that

exposure is below a set of ELVs.

If the AL is not exceeded, exposure cannot exceed the corresponding ELV. If the AL is exceeded it is still possible, and it is often the case, that the corresponding ELV will not be exceeded.

• When appropriate, devise and implement an

action plan to ensure compliance with the exposure limits.

• When appropriate, assess the risks of

employees’ exposure and eliminate or minimise those risks.

E & M RADIATION

You must make sure you take employees at particular risk into account.

• Provide information and training on the

particular risks (if any) posed to employees and details of any action you are taking to remove or control them.

• Take action if employees are exposed to EMFs

in excess of the ELVs

• Provide health surveillance or medical

examination, as appropriate.

(You should follow the “general control measures to consider” as with AOR)

IONIZING RADIATION

IONIZING RADIATION

• X-rays (100 keV ~ 108 K) Note 100 s

after the Big Bang temperature 109 K and one month after temperature 107 K

IONIZING RADIATION

Propose to transpose the BSSD on 1st January 2018 five weeks before the transposition deadline.

IRR 1999 - exposure to ionising radiation is calculated and assessed on a calendar year basis.

Dose Limit for exposure to the lens of the eye

• Reduction of equivalent dose from 150 mSv to

20 mSv in a year

• Authorisation of 5 year averaging for dose limit

to lens of the eye: Dutyholders can make use of this flexibility but this will be subject to conditions specified by HSE.

IONIZING RADIATION

Graded Approach

• Three tiered risk-based system of regulatory
• control. The BSSD refers to these levels as

notification, registration, and licensing and the higher the radiation protection risk associated with the work, the greater the requirements.

• It requires the Competent Authority (HSE) to

have in place a positive system of authorisation whereby they grant permission to dutyholders for higher risk activities through registration and

• licensing. Online System was expected to be up

and running by now. You need to contact your RPA.

IONIZING RADIATION

• HSE propose periodically renewing licenses and
• registrations. They also propose extending

licensing requirements to a small number of further practices where the risks are considered to be the same, if not higher, than those the Directive requires to be licensed.

• Remove seven days notice of every instance of

site radiography. Restrictions could be placed on site radiography practices within specific conditions in any licence documentation issued

IONIZING RADIATION

Other new key requirements

• Weighting factors: Introduction of new

weighting factors for dosimetry.

• Record retention: Change from 50 years to

not less than 30 years retention after the last day of work.

• Notification and recording of significant

events: HSE have interpreted ‘significant event’ as an event which results in an accident. HSE propose to link this to the IRR requirement for contingency plans.

IONIZING RADIATION

• Outside workers: the definition of outside

workers in the regulations to be amended to include all those who work with radiation to ensure outside workers are afforded the same protection as those workers employed by the employer responsible for the work.

• Public dose estimation: Procedures are

required that estimate the does to members of the public. Although environmental regulations cover most practices, IRR will be amended to cover those that do not.

IONIZING RADIATION

• Appointed doctor: HSE intend to remove the

requirement for a registered medical practitioner to be appointed ‘in writing’ for the purposes of these Regulations.

• Authorisation of the whole body dose limit

in special cases: HSE will authorise the application of an effective dose limit of 100 mSv

• ver five years (with no more than 50 mSv in a

single year) rather than dutyholders only giving prior notification.

IONIZING RADIATION

• Dosimetry services: The BSSD requires the

recognition of the ability of dosimetry services to perform certain dosimetry functions by the competent authority. HSE is to adopt the BSSD terminology of “recognition” in place of “approval” as part of revising the current dosimetry service regime.

• Radon: IRR expresses the radon reference level
• ver a 24 hour period, while the BSSD

expressed the reference level on an annual

• basis. Calculations show the current IRR

requirement is equivalent to the annual average in BSSD. HSE will therefore adopt the value in the BSSD.

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