Module 07

Radiation Protection in Practice

From understanding radiation to working safely with it — the principles, rules, and tools that keep everyone protected.

☢️

You're Being Irradiated Right Now

Every person in the UK receives about 2.7 mSv of radiation dose each year — from the ground, food, and cosmic rays. It's completely natural.

🎯

Protection, Not Elimination

The goal isn't zero radiation — that's impossible. The goal is keeping exposure as low as reasonably practicable while working safely.

📊

What Gets Measured Gets Managed

Every radiation worker in the UK has their dose carefully tracked. Nuclear industry doses are among the lowest of any monitored workforce.

Section 7.1

Contamination vs Irradiation

The most important distinction in radiation protection

Before we go any further, you need to understand the single most important distinction in radiation protection. It's a distinction that determines everything — from how dangerous a situation is, to what protective equipment you need, to whether you can simply walk away from a hazard.

Irradiation

Exposure to radiation from a source

Like standing in sunlight
Energy is hitting you
Move away and it stops
Shielding blocks it
You don't become radioactive

Contamination

Radioactive material in the wrong place

Like getting wet paint on you
Material is on you
Travels with you
Must be physically removed
Continues emitting until removed or decayed

📘 Key Term

Irradiation: Exposure to radiation from an external source. Like being in sunlight — you're receiving energy, but when you move away or put shielding between you and the source, the exposure stops. You don't become radioactive from being irradiated.

📘 Key Term

Contamination: Radioactive material in the wrong place — on your skin, your clothes, a surface, or inside your body. Unlike irradiation, contamination travels with you and continues emitting radiation until it's removed or decays away.

Why This Matters

Scenario	Type	What to Do
Standing near a sealed source	Irradiation	Move away or add shielding — problem solved
Radioactive dust on your clothes	Contamination	Must be physically removed — can't just walk away
X-ray examination	Irradiation	Exposure ends when machine turns off
Inhaled radioactive gas	Internal contamination	Most serious — can't easily remove

The Danger Hierarchy

External irradiation — Least dangerous. Walk away, problem solved.
External contamination — More dangerous. Must be removed before it spreads or gets inside you.
Internal contamination — Most dangerous. Radioactive material inside your body, irradiating your organs continuously from within.

💡 Connecting to Module 3

Remember why alpha radiation is dangerous inside the body but harmless outside? An alpha-emitting particle on your skin is stopped by dead skin cells — harmless. The same particle inhaled into your lungs dumps all its energy into living tissue. This is why internal contamination is so much more serious than external contamination.

Real-World Application

This is why nuclear facilities have two completely different monitoring systems:

Radiation monitors measure dose rates in areas — how much radiation is hitting you per hour in a location. This addresses irradiation.
Contamination monitors check for radioactive particles on surfaces, clothing, and skin. This addresses contamination.

Before leaving a controlled area, workers pass through both types of monitoring. You might have received zero radiation dose but still be contaminated — or vice versa.

Section 7.2

Background Radiation

The radiation dose you're already receiving

You might think radiation exposure only happens to people who work in the nuclear industry. But the reality is that everyone — your family, your neighbours, your pets — receives radiation dose every single day, from completely natural sources.

The average person in the UK receives about 2.7 mSv per year from background radiation. That's not from nuclear power plants or medical procedures — it's just from existing.

📘 Key Term

Sievert (Sv): The unit measuring radiation's potential to cause biological harm. Because one sievert is a large dose, we typically use millisieverts (mSv = one-thousandth) or microsieverts (µSv = one-millionth).

What Does a Sievert Actually Measure?

In Module 3, you learned that radiation damages DNA — breaking the strands, potentially causing mutations or cell death. But not all radiation causes the same amount of DNA damage.

Think of it this way:

Gamma rays are like a spray of small pellets. They pass through tissue, occasionally hitting DNA and causing single-strand breaks. Your cells can usually repair these.

Alpha particles are like a wrecking ball. They're heavy and slow, so they hit everything in a short path — smashing through DNA and causing double-strand breaks that are much harder to repair.

The same "amount" of radiation (measured in energy) causes very different levels of damage depending on the type. The sievert accounts for this.

Radiation Type	Damage Factor	Why?
Gamma (γ), X-rays, Beta (β)	×1	Causes scattered single-strand breaks — usually repairable
Alpha (α)	×20	Causes concentrated double-strand breaks — harder to repair
Neutrons	×5–20	Knock atoms around, causing indirect damage

So when we say someone received "1 mSv," we're not just counting radiation — we're measuring how much biological harm that radiation could cause, adjusted for how damaging that particular type is.

This is why alpha emitters are so dangerous if inhaled or swallowed. From outside your body, alpha particles can't even penetrate your skin — harmless. But inside your lungs? That ×20 damage factor applies to every cell they hit.

Where Does Background Radiation Come From?

UK Average Annual Background Radiation: ~2.7 mSv

Source	Contribution	Description
Radon gas	~50% (~1.3 mSv)	Seeps from the ground into buildings
Medical	~14% (~0.4 mSv)	X-rays, CT scans, nuclear medicine
Cosmic rays	~12% (~0.3 mSv)	From space, increases with altitude
Food & drink	~12% (~0.3 mSv)	Potassium-40 in food, Carbon-14
Ground & buildings	~11% (~0.3 mSv)	Uranium/thorium in rocks and materials

The Radon Factor

Radon is a colourless, odourless radioactive gas that seeps from the ground. It's produced by the natural decay of uranium in rocks and soil. It accounts for half of our annual radiation dose — more than all other sources combined.

But here's the thing: radon levels vary dramatically depending on where you live.

UK Radon Levels

Click markers to explore regional variation

High (>30% above action)

Elevated (5-30%)

Low (<5%)

UK action level: 200 Bq/m³ — homes above this should consider radon mitigation

🔗 Why Cornwall?

Cornwall sits on granite bedrock, which contains higher levels of uranium than most other rock types. As this uranium decays, it produces radon gas that seeps upward through the soil and into buildings. Some homes in Cornwall have been found with radon levels over 50 times the action level.

Putting Dose in Perspective

Eating one banana

~0.1 µSv

Chest X-ray

~20 µSv

Flight London→New York

~60 µSv

UK annual background

~2,700 µSv

Living in Cornwall (extra)

~5,000 µSv

CT scan (abdomen)

~7,000 µSv

Annual limit for workers

20,000 µSv

A Surprising Comparison

Here's something that surprises most people:

Average annual dose for UK nuclear workers: <1 mSv
Average annual dose for airline crew: 2-3 mSv

That's right — pilots and flight attendants typically receive more radiation dose than nuclear power plant workers. Why? Because at cruising altitude (30,000-40,000 feet), there's less atmosphere shielding you from cosmic rays. Long-haul crews flying polar routes can receive up to 6 mSv per year.

This doesn't mean flying is dangerous — it just shows that radiation exposure is a normal part of life, and that the nuclear industry manages it exceptionally well.

💡 The Key Point

Background radiation isn't something to fear — it's been with us throughout human evolution. The goal of radiation protection isn't to eliminate all exposure (impossible) but to ensure that additional exposure from work activities is kept as low as reasonably practicable, and always within safe limits.

Section 7.3

The ALARP Principle

As Low As Reasonably Practicable — not "as low as possible"

Now we come to the philosophy that underpins all radiation protection in the UK. It's a concept that sounds simple but contains crucial subtlety: ALARP — As Low As Reasonably Practicable.

Notice the word is "practicable," not "possible." This distinction matters enormously.

🔗 ALARP: Not Just for Radiation

ALARP isn't a radiation-specific concept — it's the fundamental principle behind all UK health and safety law. The Health and Safety Executive (HSE) applies ALARP to every workplace hazard: working at height, chemical exposure, machinery guarding, manual handling, electrical safety, confined spaces — everything.

The principle comes from the Health and Safety at Work Act 1974, which requires employers to reduce all risks "so far as is reasonably practicable." Radiation protection simply applies this same established legal framework to ionising radiation.

So when you learn ALARP here, you're learning a concept that applies to your entire working life, not just radiation work.

📘 Key Term

ALARP (As Low As Reasonably Practicable): The legal principle requiring that radiation exposures be reduced as far as is reasonably practicable. This means balancing the cost, time, and effort of reducing dose against the benefit gained — not simply minimising dose at any cost.

Why Not "As Low As Possible"?

Because "as low as possible" would be impractical and counterproductive.

If your only goal was minimising radiation dose absolutely, you'd:

Never have medical X-rays (even when they'd save your life)
Never fly anywhere
Never live in Cornwall
Spend unlimited money on shielding even when doses are already negligible

"As low as possible" ignores context. "As low as reasonably practicable" embraces it.

The Legal Basis

ALARP isn't just good practice — it's law in the UK, and has been since 1974.

The Health and Safety at Work Act 1974 requires employers to ensure the health and safety of employees "so far as is reasonably practicable." This applies to all hazards — from scaffolding to solvents to radiation.

For radiation work specifically, the Ionising Radiations Regulations 2017 (IRR17) require employers to:

"...take all necessary steps to restrict as far as is reasonably practicable the extent to which employees and other persons are exposed to ionising radiation."

The key legal test comes from a 1949 court case (Edwards v National Coal Board), which established that a measure is "reasonably practicable" unless the cost of implementing it is grossly disproportionate to the benefit gained.

Note: not just "disproportionate" — grossly disproportionate. The law is weighted in favour of safety.

The ALARP Triangle

Click each zone to explore

Tolerable if ALARP

This is where most workplace activities fall. The risk is neither negligible nor unacceptable — it sits in the middle ground where work can proceed, but only if the risk is reduced as far as reasonably practicable.

In this zone, you must demonstrate that you've done everything reasonable to reduce the risk. The burden of proof is on you to show that any remaining risk is justified because further reduction would require grossly disproportionate sacrifice.

This is the zone where the ALARP assessment really matters — weighing the cost and effort of risk reduction against the benefit gained.

Examples across HSE domains

Radiation: Industrial radiography, medical X-rays, nuclear maintenance
Height: Scaffolding work with harnesses and guardrails
Chemicals: Using solvents with local exhaust ventilation (LEV) and PPE
Driving: Heavy goods vehicle (HGV) operations with training and safety systems

The ALARP Question

When considering whether to implement a safety measure, ask:

"Is the sacrifice (in cost, time, or effort) grossly disproportionate to the risk reduction achieved?"

If YES → The measure is not reasonably practicable
If NO → The measure should be implemented

ALARP in Action: An Example

Scenario: A routine maintenance task requires workers to enter an area with a dose rate of 2 µSv/hour. The task takes 4 hours.

Without any additional measures:
Dose = 2 µSv/h × 4 hours = 8 µSv per worker

Option A: Temporary Shielding

Cost: £500, 2 hours setup
Reduces dose rate to 0.5 µSv/h
New dose: 2 µSv (saves 6 µSv per worker)

Option B: Permanent Redesign

Cost: £500,000, 6 months work
Reduces dose rate to 0.1 µSv/h
New dose: 0.4 µSv (saves 7.6 µSv per worker)

ALARP Analysis:
Option A is clearly reasonably practicable — modest cost, significant dose reduction.
Option B is likely grossly disproportionate — huge cost for minimal additional benefit when doses are already very low.

The ALARP solution: Implement Option A.

Important Clarification

ALARP does NOT mean:

❌ Reducing dose to zero
❌ Spending unlimited money on protection
❌ Using the cheapest option
❌ A simple cost-benefit calculation

ALARP DOES mean:

✅ Reducing dose until further reduction would require grossly disproportionate effort
✅ Always prioritising safety (the "gross disproportion" test favours safety)
✅ Considering all options, not just the obvious ones
✅ Documenting your reasoning

💡 Connection to Dose Limits

Dose limits (which we'll cover next) are legal maximums that must never be exceeded. But ALARP means you shouldn't aim for the limit — you should aim as far below it as is reasonably practicable.

Think of it like a speed limit: the limit might be 70 mph, but that doesn't mean you should always drive at 70. In fog, 40 mph might be the responsible choice.

Section 7.4

Dose Limits

The legal boundaries — but not the targets

While ALARP provides the philosophy, dose limits provide the hard legal boundaries set by the Ionising Radiations Regulations 2017 (IRR17). But remember: dose limits are ceilings, not targets.

👷

Workers

Trained, monitored, informed

20mSv/year

Whole body effective dose

Eye lens 20 mSv

Skin / Extremities 500 mSv

👥

Public

Not trained, not monitored

1mSv/year

Whole body effective dose

Eye lens 15 mSv

Skin 50 mSv

🛡️

Protected Groups

Stricter limits for vulnerable individuals

1mSv

Fetus (for the remainder of pregnancy, once the worker formally declares)

Young workers (trainees aged 16-18 in radiation work) 6 mSv

Putting Limits in Perspective

How do real-world doses compare to the 20 mSv legal limit?

👷

Nuclear worker

Typical annual occupational dose

0.5 mSv (2.5%)

🏠

UK background

Annual dose just from living

2.7 mSv (13.5%)

✈️

Airline pilot

Annual dose from cosmic rays

3.0 mSv (15%)

Legal limit for workers

⚠️

Legal limit

Maximum permitted for workers

20 mSv (100%)

💡 Nuclear workers typically receive less dose than airline pilots — and far less than the legal limit allows

⚠️ Limits Are Not Targets

A worker receiving 19 mSv is "within limits" — but something has likely gone wrong. Many organisations set investigation levels at 1-2 mSv, far below the legal limit, to ensure ALARP is being achieved.

🔗 What Happens If Exceeded?

Exceeding a dose limit triggers immediate investigation, HSE notification, medical review, and potential prosecution. It happens extremely rarely because the industry maintains doses far below limits through ALARP.

Section 7.5

Time, Distance, Shielding

Your three practical levers for reducing dose

So far we've covered the philosophy (ALARP) and the rules (dose limits). Now let's get practical. When you're working in an area with radiation, you have three fundamental tools to reduce your dose:

⏱️

TIME

Less time = Less dose

½ time = ½ dose

📏

DISTANCE

Further = Much safer

2× dist = ¼ dose

🛡️

SHIELDING

Material blocks rays

1 Half-Value Layer = ½ dose

1. Time — The Simple One

Radiation dose accumulates like rain filling a bucket. The longer you stand in the rain, the wetter you get. The maths is straightforward:

                        Dose = Dose Rate × Time
                    

Practical applications:

Pre-plan work — rehearse complex tasks in non-radiation areas first
Rotate workers — share the dose across a team
Prepare everything — have all tools ready before entering the area

2. Distance — The Powerful One

This is where physics gives you a massive advantage. The Inverse Square Law means that doubling your distance doesn't halve your dose — it quarters it.

🔬 Inverse Square Law — Drag the Worker

100 75 50 25 0

Dose Rate (µSv/h)

Dose Rate

25.0 µSv/h

1m 2m 3m 4m 5m 6m 7m 8m 9m 10m

☢️

2.0 m

← drag me →

Distance

2.0 m

Dose Rate

25.0 µSv/h

Reduction

4×

Dose Rate = 100 µSv/h ÷ distance² — The power of the inverse square!

3. Shielding — The Material One

Put material between you and the source. But here's the critical part: different radiation types need different shielding.

Radiation	Stopped By	Key Point
Alpha (α)	Paper, skin, air	Contamination control, not shielding
Beta (β)	Plastic, aluminium	Avoid lead — causes Bremsstrahlung
Gamma (γ)	Lead, concrete, steel	Attenuates but never fully stops
Neutron (n)	Water, polyethylene	Hydrogen-rich materials slow them

⚠️ Why Avoid Lead for Beta Shielding?

When fast-moving beta particles hit heavy atoms like lead, they decelerate rapidly. This deceleration produces Bremsstrahlung radiation (German for "braking radiation") — essentially X-rays.

So using lead to shield beta particles can actually increase your dose by converting relatively harmless beta (stopped by skin) into penetrating X-rays. Use low-Z (low atomic number) materials like plastic or aluminium instead — the beta stops without generating X-rays.

Half-Value Layer (HVL)

Unlike alpha and beta, gamma radiation doesn't just stop — it attenuates. Each layer of shielding reduces the intensity, but some always gets through.

📘 Key Term

Half-Value Layer (HVL): The thickness of a specific material needed to reduce gamma radiation intensity by half. Add one HVL, and 50% of the radiation is blocked. Add another HVL, and you block half of what's left (leaving 25%), and so on.

The HVL depends on the material:

Lead: ~6 mm — dense, very effective, but heavy and toxic
Steel: ~21 mm — common in construction, structural
Concrete: ~49 mm — cheap, good for permanent installations

The maths is simple: after n half-value layers, intensity = 100% ÷ 2ⁿ

So: 1 HVL = 50% | 2 HVL = 25% | 3 HVL = 12.5% | 7 HVL = less than 1%

🧱 Half-Value Layers — Build Your Shield

1 Choose a material below

2 Click the numbered bars to add layers

Each layer blocks 50% of gamma rays. The material changes thickness, not blocking power.

☢️

100 µSv/h

1

2

3

4

5

6

7

👆 Click to add

100 µSv/h

Layers

0 HVL

Total Thickness

0 mm

Dose to Worker

100 µSv/h

🔗 Connecting to Module 3

This is where your understanding of radiation types becomes practical. Knowing that alpha particles are stopped by paper tells you that contamination control (preventing inhalation/ingestion) matters more than external shielding for alpha emitters.

Section 7.6

Dosimetry and Monitoring

What gets measured gets managed

How do we know if ALARP is being achieved? How do we verify workers stay within dose limits? The answer is monitoring — both individuals (dosimetry) and areas.

You can't manage what you don't measure.

📘 Key Term

Dosimeter: A device worn by a radiation worker that records accumulated radiation dose. Modern dosimeters are small badges worn on the body, usually at chest height. Typically exchanged monthly or quarterly for analysis.

Types of Personal Dosimeters

TLD (Thermoluminescent Dosimeter)

Contains crystals that absorb radiation energy. When heated, they release this energy as light — the amount of light equals the dose received. Accurate, reusable, tissue-equivalent.

OSL (Optically Stimulated Luminescence)

Similar to TLD but uses light instead of heat. Can be re-read, very accurate at low doses.

Electronic Personal Dosimeter (EPD)

Electronic detector with digital display. Provides real-time dose reading and alarms for high dose rates. Workers know their dose during the shift.

📊 How a Dosimeter Works

Adjust the source activity to see how the dosimeter responds. Higher activity = higher dose rate.

☢️

10 MBq

5.0 µSv/h

DOSE RATE METER

Low Activity Source Activity High Activity

Source 10 MBq

Dose Rate 5.0 µSv/h

Status SAFE

Dose Records

Every radiation worker's dose history is recorded and kept:

By the employer
By an Approved Dosimetry Service (ADS)
In the Central Index of Dose Information (CIDI) maintained by HSE

Records kept for at least 50 years. Workers can request their own dose history at any time.

Area Monitoring

It's not just people who are monitored — areas are too:

Fixed Area Monitors — Permanently installed, continuous display, alarm capability
Portable Survey Meters — Handheld instruments for checking dose rates
Contamination Monitors — Detect radioactive material on surfaces or skin

Dosimetry equipment including TLD badge, electronic dosimeter, and survey meter

Investigation Levels

Level	Typical Value	Action
Recording level	>0.1 mSv/month	Dose recorded
Investigation level	>1-2 mSv/month	Review why dose was higher than expected
Legal limit	20 mSv/year	Must never be exceeded

This tiered approach catches problems early, long before limits are approached.

Section 7.7

Practical Controls

Controlled areas, supervised areas, and working safely

All the principles we've covered — ALARP, dose limits, Time/Distance/Shielding, monitoring — come together in the practical organisation of radiation workplaces. The UK uses a system of designated areas to ensure the right level of control is applied in the right places.

CONTROLLED AREA

>7.5 µSv/h

Special procedures required. Entry restricted to trained, authorised personnel only.

🔒 Restricted entry

📛 Personal dosimetry

📋 Local rules apply

SUPERVISED AREA

1-6 mSv/year possible

Conditions kept under review. Less restrictive than controlled areas.

👁️ Monitoring recommended

⚠️ Warning signs

📊 Periodic review

UNDESIGNATED

<1 mSv/year

Background levels. No specific radiation controls needed.

✓ Normal access

✓ No special PPE

✓ Standard procedures

Requirements for Controlled Areas

Physical Controls

Clear demarcation & warning signs

Physical barriers to restrict entry

Radiation trefoil symbol displayed

Interlocks where appropriate

Procedural Controls

Written Local Rules

Named Radiation Protection Supervisor

Entry permits & authorisation

Training requirements

Monitoring

Personal dosimetry for all workers

Area monitoring equipment

Contamination checks

Dose record keeping

📋

Local Rules

Every controlled area must have written Local Rules covering:

1 Area boundaries & demarcation

2 Key radiation hazards present

3 Specific working instructions

4 Names of Radiation Protection Supervisor (RPS) personnel

5 Dose investigation levels

6 Emergency procedures

7 Contamination control (if relevant)

8 PPE requirements

Radiation Protection Supervisor (RPS)

A person appointed by the employer to supervise radiation work and ensure compliance with local rules and IRR17. They're the first point of contact for radiation protection matters, providing practical, on-the-ground supervision.

Supervise work Enforce local rules First point of contact Report issues to RPA (Radiation Protection Adviser)

🔗 Connecting to Module 4

Remember the three barriers from Module 4 — cladding, pressure vessel, containment building? Designated areas work on the same principle: multiple layers of control, each providing protection even if another fails. Physical barriers, procedural controls, and monitoring all work together.

Knowledge Check

Test your understanding of radiation protection

Question 1 of 5

A worker discovers radioactive dust on their clothing after working in an area. Why is this potentially more serious than simply being near a radiation source?

A Dust emits more radiation than sealed sources

B Contamination travels with you and can be inhaled or ingested, continuing exposure; irradiation stops when you move away

C Clothing provides no shielding against radiation

D There is no practical difference in risk

Key Takeaways

The essential concepts from Module 7

☢️

Contamination vs Irradiation

Irradiation = exposure from an external source — move away and it stops. Contamination = radioactive material in the wrong place — it travels with you. Internal contamination (inhaled/ingested) is the most serious hazard.

⚖️

ALARP: The Philosophy

As Low As Reasonably Practicable — not "as low as possible." Reduce dose until further reduction would require grossly disproportionate sacrifice. It's UK law, weighted in favour of safety.

📏

Inverse Square Law

Dose rate ∝ 1/distance². Double your distance = quarter the dose. This is why distance is often the most effective protection tool — and it's free.

🧱

Half-Value Layer

Each HVL halves gamma intensity. 3 HVLs = 12.5% remaining. 7 HVLs = less than 1%. Material matters: Lead (6mm), Steel (21mm), Concrete (49mm) per HVL.

⏱️

Time, Distance, Shielding

Your practical toolkit. Minimise time near sources. Maximise distance (inverse square). Use appropriate shielding. Often the simplest measures are most effective.

🚧

Controlled Areas

Not radiation-free — radiation-managed. Entry restricted, dosimetry required, local rules apply. The designation ensures proper controls are in place where radiation is present.

UK Dose Limits to Remember

20 mSv/year

Workers

1 mSv/year

Public

6 mSv

Lens of eye (annual)

500 mSv

Extremities (annual)

Coming Up in Module 8

Regulation & the UK Framework

Now that you understand how radiation protection works in practice, Module 8 examines who oversees it all. You'll learn about the Office for Nuclear Regulation (ONR), the 36 licence conditions, how sites are licensed and inspected, the role of the Safety Case, and WANO's Ten Traits of healthy nuclear safety culture.

From personal protection to organisational governance — the regulatory framework that keeps the UK nuclear industry safe.