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MEC232
Human & Equipment Safety

Ehab Abousaif, PhD

Assistant Professor of Electrical
Engineering – Faculty of Engineering

Topic 1
 Course aims
Define human factor analysis,
Recognize equipment safety and occupational safety,
Design the workplace so that they fit the people who use them,
Define the term of Ergonomics,
Describe the materials handling and safety culture,
Recall Occupational Safety and Health Administration (OSHA)
permissible limits,
analyze the risk assessment, hazard identification, and risk
estimation, and
Diagnose accident prevention and Risk control.
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 Grade Distribution
Assessment Measures Weight
Course Grading
Quizzes 20%
Research project 10%

Mid-term Exam 30%
Final Exam 40%
Total 100%

T H E F U T U R E S T A R T S H E R E
Concept of Occupational & Health Safety
Who is responsible for the health and safety?

Everyone is entitled to work in an environment
where risks to their health and safety are properly
controlled.
 The Safety and Health Manager
Everyone wants a safe and healthful workplace, but what each person
is willing to do to achieve this worthwhile objective can vary greatly.
As a result, the management of each firm must decide at what level
along a broad spectrum, the safety and health effort will be aimed.
The worker's behavior is the most important determinant for his/her
safety, but behavior alone can not make a dangerous job safe.
One person, usually designated as safety director or industrial
hygienist, sets the tone of the safety and health program within a firm.
(by posting motivational signs & complying statistics)
 The year 1970 changed the history of worker safety and health in general and the
safety manager’s role in particular.

The landmark change that year was the pasage of the Occupational Safety and
Health Act that created the federal Occupational Safety and Health Adminstratioin
(OSHA).

The field of occupational health has probably benefited even more from OSHA
than has the field of occupational safety.

OSHA designate the new job title of safety & health manager. The term manager
envisions the enlarged scope of responsibility, which includes analysis of
hazarads, compliance with standards, and capital investment planning, in addition
to the conventional functions.
 Information technology has made this task easier, and
today’s safety and health manager can take advantage of
the full test of OSHA standards on the Internet by accessing
the OSHA website.

Until the safety and health manager learns what hazarads a
particular standard is intended to prevent, he/she will have a
difficult time persuading either management or employees
that a given situation needs correction.
 A Reasonable Objective
Any safety & health manager who feels that elimination of workplace
hazards is an indisputable goal is naïve.
In the real world, we must choose among the following:
Ø Hazards that are physically infeasible to correct.
Ø Hazards that are physically feasible, but are economically infeasible
to correct.
Ø Hazards that are both physically and economically feasible to correct.
Hazards that are physically infeasible to correct.
The airplane that took off from LaGuardia airport on January 15, 2009.
During take-off, both engines were disabled by what is thought to have
been birds entering the engine.
This hazarad is currently impossible to eliminate because of the current
mechanics of jet engines.
However, millions of people fly every year, taking the risk.
i.e. exposure of radiation during x-ray procedures. Although precuations
are taken, it is impossible to completely eliminate exposure to undesired
radiation (e.g.carrefour entrance)
Hazards that are physicallly feasible, but are economically
infeasible to correct.

Consider crosswalks on a university campus. There is always the chance
that someone will be struck by an automobile while in the crosswalk.

The hazarad can be eliminated through constuction of elevated walkways,
gates or other mechanisms.

However, owing to the cost, inconvenience, and low probability of
accident, these measures are reserved for the busiest of crosswalks.
 G A L A L A U N I V E R S I T Y THE FUTURE STARTS HERE

Hazarads that are both physically and
economically feasible to correct.

Technology has led to safety innovation in the auto industry, such as
air bags and antilock brake, which are considered indispensable and
included on every automobile.
In reality, every hazarad must fall into one of these categories.
It is unrealistic and naïve strategy to attempt to eliminate all hazards.
To see that consider the following case study.

T H E F U T U R E S T A R T S H E R E
 G A L A L A U N I V E R S I T Y THE FUTURE STARTS HERE

Some managers would accept that the safety and health
rationale as all they need to begin action to correct the
problems listed in the case study. But this would be a naïve
response.
More data are needed to decide what to do.
While busying the plant maintenance department to correct the
foregoing three problems (which may or may not be
consequential), a serious electrocution or respiratory hazard
may be going unchecked or may even unnoticed.
Overreaction may also be deteriorating S&H manager’s
credibility.
The goal of this course, then is to assist
the safety and health manager in:
(1) detecting hazards and
(2) deciding which ones are worth
correcting
Safety Versus It is essential that today’s safety and health
Health manager give sufficient attention not only
to safety hazards, but also to heath
hazards.
There is no question that machine
guarding is a safety consideration, and that
airborne asbestos is a health hazards.

But some hazards- such as those
associated with paint spray areas and
welding operations- are not so easy to
classify.
 An acute effect is a sudden (short term) reaction to
a severe condition; a chronic effect is a long-term
Safety deals deterioration due to prolonged exposure to a milder
with the acute adverse condition. (industrial noise, chemical
exposure)
effects of
Industrial hygienists, those who concentrate on
hazards, health hazards, are known by their sophisticated
whereas instruments and scientific expertise.
health deals
with the Safety specialist, instead of being an expert with
chronic effects precise scientific instruments, usually has more
industrial process experience and practical job
of hazards. knowledge.
 Safety Versus Health
There are probably more occupational health fatalities than safety, but the
statistics will not reflect this difference because health fatalities are delayed and
often are never diagnosed.

Another problem with identifying health hazards is that the signs of occupational
illness are often identical to common symptoms arising from normally occurring
illnesses encountered off the job. For instance, a common cold causes respiratory
congestion, headaches, and perhaps fever. These same symptoms could also be
the result of dangerous exposure to a toxic chemical or other occupational hazard.

The industrial hygienist is tasked with sorting out these symptoms and identifying
occupational hazards to be controlled.
 Role in The Corporate structure
One role of the safety and health manager is as a liaison with
government agencies, a condition brought about by the arrival of
OSHA.
A related field is consumer product safety. The Consumer Product
Safety Commission (CPSC) is a federal agency whose enabling
legislation is obviously patterned after OSHA’s. The laws of the
two are remarkably similar.
CPSC concentrates on the responsibility of the manufacturers of
products, whereas OSHA concentrates on the responsibility of the
employer.
 A CASE STUDY
In 1984, in a shocking disaster in
Bhopal, India, at least 2,500 civilians
were killed in a single industrial
accidental release of deadly methyl
isocyanate gas.

This incident had an impact on public policy in the US.
Because of its close relationship to worker safety and health,
the responsibility for compliance with Environmental
Protection Agency (EPA) requirements is often made a part of
the duties of the safety and health manager.
 In the first decade of the twenty-first century, an increased
awareness of global warming raised public consciousness of
threats to the environmental in general.

Progressive legislation manadating “green engineering” was
aimed at reducing the use of carbon fuels and their
contribution to the global warming problem.

Competence in these areas is proving to be a point of
differentiation and competitive advantage for companies
excelling in environmental protection.
Resources at Hand
Safety professionals should apply to:
Board of Certified Safety Professionals of America, www.bcsp.org
Health professionals should apply to :
American Board of Industrial Hygiene, www.abih.org
CSP for Certified Safety Profesional and CIH for Certified
Industrial Hygienist.
Professional Societies
Two professional societies are foremost in the career
field of occupational safety and health:
○ American Society of Safety Engineers (ASSE),
www.asse.org
○ American Industrial Hygiene Association (AIHA),
www.aiha.org
Systems Safety
Safety was considered something that could be achieved by being
careful, but it did not require the kind of life-cycle planning and design
that other aspects of the production process required.
In mid-1950s, a movement began in the aerospace industry in
California to consider safety as a system to be planned for and
considered in every step of the process.
System safety is considered essential in fields where an accident can
be catasprophic, such as airlines, aerospace, and hospitals.
Systme safety Society, www.system-safety.org
Standards Institutes
The age of OSHA enforcement has brought increased recognistion of
the national standards-producting organizations. The following are the
most prominet among these organizations:
○ American National Standards Institute (ANSI), www.ansi.org
○ National Fire Protection Association (NFPA), www.ngpa.org
○ American Society of Mechanical Engineers (ASME),
www.asme.org
○ American Society for Testing and Materials, (ASTM)
www.astm.org
Government Agencies
The national institute for Occupational Safety and Health
(NIOSH) has a wealth of research data on the hazards of
specific materials and processes. NIOSH uses these data to
write criteria for recommended new standards. www.niosh.gov
OSHA itself is of value to be the safety and health manger
seeking information.
Thank You

gu.edu.eg
MEC232
Human & Equipment Safety

Ehab Abousaif, PhD

Assistant Professor of Electrical
Engineering – Faculty of Engineering

Topic 2
 Development of the Safety and Health Function
Workers’ Compensation

One of the first questions that arises when one begins to study the field of
industrial safety and health is “Who should be responsible when a
worker is injured?”
- Many would answer, “The employer – because the employer gave
rise to the job and will profit from the production.”

However, the problem is not that simple. The problem of compensation to
injured employees was first addressed as a societal problem in Europe,
and the idea was soon taken up in the United States and Canada.
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 The first laws were introduced in state legislatures in 1909 and
were known as workmen’s compensation laws. Soon, all states in
the United States had such laws.

About 50 years later, the name changed to “workers’
compensation laws” to remove the gender designation for
“workers.”

Gross negligence refers to a person's conduct where an act or
failure to act creates an unreasonable risk of harm to another
because of the person's failure to exercise slight care or diligence.

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4
 Recordkeeping
Forms, reports, and recordkeeping make up no small part of the safety
and health manager’s job.

According to the National Safety Council (NSC), “Just one OSHA data
sheet takes U.S. safety managers a cumulative 54 million hours a year to
complete.

That’s just one of dozens of forms (the safety manager) may be
responsible for” (National Safety Council, 1995).

In addition, the safety manager must keep up with the latest
developments, including changes to rules and procedures.
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 The recording of worker fatalities is more consistent than that of injuries
and illnesses; thus, fatality statistics can be used to observe trends both
before and after federal regulation.

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 Traditional Indexes
Familiar statistical measures are frequency and severity, which
were defined by the old system.

- Frequency measured the number of cases per standard
quantity of work hours.

- Severity measured the total impact of these cases in terms
of “lost workdays” per standard quantity of work hours.

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 Incidence Rates
First aid is not considered medical treatment even if it is
administered by a physician.

Regardless of treatment, the injury is required to be recorded.

To compute the incidence rate, the number of injuries is divided by
the number of hours worked during the period covered by the
study.

The value obtained is then multiplied by a standard factor to make
the rate more understandable.
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 A full-time worker typically works approximately 50 weeks per year at 40
hours per week.

Thus, the number of hours worked per year per worker is approximately

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The term ‘incidence rate’ is really a general term and includes the following:

- Total-Recordable-Cases (TRC): Counts all recordable injury and illness cases,
except fatalities.

- Lost-WorkDay-cases Incidence rate (LWDI): Counts injury (excludes illness) cases
involving “lost workdays,” which includes restricted work activity days. Fatalities
are not included.

- Days Away, Restricted, or Transferred Rate (DART): Counts injury and illness
cases involving days away from work, restricted work activity, and transfer to
another job. Fatalities are not included.

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Cont.

- Number-of-Lost Workdays rate: Counts the number of “lost workdays”,
including restricted work activity days. Fatalities are not included.

- Injury incidence rate: Counts the total number of injury cases.

- Illness incidence rate: Counts total number of illness cases.

- Fatality incidence rate: Counts total number of fatalities.

- Specific-hazard incidence rate: Counts cases in which only a specific hazard
results in injury or illness.

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Recordkeeping
Forms

OSHA’s Form 300

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Recordkeeping
Forms

OSHA’s Form 300A

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Recordkeeping
Forms

OSHA’s Form 301

Within 7 calendar days after
you receive information that
a recordable work-related
injury or illness has occurred,
you must fill out this form or
an equivalent.

According to Public Law 91-
596 and 29 CFR 1904,
OSHA’s recordkeeping rule,
you must keep this form on
file for 5 years following the
year to which it pertains.
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A case study

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To complete OSHA 300, you need to analyze each case as follows:

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Calculation of Incidence Rates

5 X 200,000
TRC = 2_0
250 X 2000
2 X 200,000
DART 1.2
250 X 2000
2 X 200,000
DAFWII 0.8
250 X 2000
2 X 2000,000
LWDI (injuries only) 0.8
250 X 2000
3 X 200,000
Injury incidence rate 1.2
250 X 2000
2 X 200,000
Illness incidence rate = 0_8
250 X 2000
1 X 200,000
Fatality incidence rate 0.4
250 X 2000
36 X 200,000
Number-of-lost-workdays rate 14.4
250 X 2000
1 X 200,000
Specific-hazard incidence rate (eye injuries) 0.4
250 X 2000 27
Thank You

gu.edu.eg
MEC232
Human & Equipment Safety

Ehab Abousaif, PhD

Assistant Professor of Electrical
Engineering – Faculty of Engineering

Topic 3
 Definitions of Ergonomics

‘‘Ergonomics’’ is based on two Greek words: ergos, meaning work,
and nomos, meaning the study of or the principles of. In other words,
ergonomics refers to the study of work. Ergonomics is the discipline
of examining the capabilities and limitations of people.

Ergonomics, as defined by the International Ergonomic Association,
is the scientific discipline concerned with the understanding of
interactions among humans and other elements of a system, and the
profession that applies theory, principles, data, and methods to
design in order to optimize human well-being and overall system
performance.
2
 Ergonomics and safety management
Ergonomics is a multidisciplinary science that studies
human physical and psychological capabilities and
limitations. This body of knowledge can be used to
design or modify the workplace, equipment, products,
or work procedures to improve human performance
and reduce the likelihood of injury and illness.

The branch of engineering science in which biological
science is used to study the relationship between
workers and their environment.

The study of human capability and psychology in
relation to the working environment and the equipment
operated by the worker.
3
 How is Ergonomics Related to Safety?
When the principles of ergonomics are applied in
the context of workplace safety, the concept of
ergonomic safety is born.

Ergonomics safety ensures that the products,
methods, and environment that a worker uses are
appropriate to fit the worker’s job requirements
and personal capabilities.
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 How did Ergonomics Safety develop?

The practice of ergonomics safety principles can be possibly traced
back to the early Egyptian, Greek, and Roman dynasties, where
findings have shown that tools and other manmade devices (e.g.
pulleys, wheels) were created to minimize workload.

Fast forward to the aftermath of the Industrial Revolution, people
began developing factory machinery with some design principles
closer to how we practice modern ergonomics. In 1857, Wojciech
Jastrzebowski, a Polish scholar, then coined the term ‘ergonomics’
– which comes from the Greek words ergon (work or labor) and
nomos (natural laws) – in his publication.
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 The modern principles of ergonomics safety became more
prevalent during World War II as interest in logical human-
machine interaction grew and military equipment, machinery,
and weaponry became more complex. Human factors need to be
taken into account to ensure that these advanced systems are to be
operated safely.

When World War II concluded, research on ergonomics and
safety continued to expand as more and more technological
advancements were introduced. Perhaps the most noteworthy
development in modern ergonomics safety happened in the field
of human-computer interaction, brought on by the explosion of
computer usage in the workplace and, soon after, the home.
6
Why is Ergonomics Important in Workplace Safety?

Ergonomic disorders are the fastest-growing category of work-
related illness. According to the most recent statistics from the U.S.
Bureau of Labor Statistics, they account for 56-63 percent of
illnesses reported to OSHA. Further, around two million work-
related musculoskeletal disorders (MSDs) also occur yearly in the
United States alone.

Many of these are caused by ergonomic work-related injuries like
carpal tunnel syndrome alone, tendinitis, rotator cuff injuries,
muscle strains, and low back injuries due to risk factors like high
task repetition, forceful exertions, and repetitive awkward
postures.
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What are the Benefits of Ergonomics?

The implementation of ergonomics safety as part of the workplace safety program helps
ensure that employees’ capabilities and physical limitations are matched with the right tools
and working spaces to ensure comfortable and safe working conditions for them. The benefits
of an ergonomics safety program can not only make an impact on the lives of employees, but it
can also make a difference in the overall efficiency of the entire organization. Here are some of
the most notable benefits of ergonomic safety in the workplace:

(1) Helps reduce costs: By systematically reducing ergonomic risk factors, you can prevent
costly MSDs. With approximately $1 out of every $3 in workers’ compensation costs attributed
to MSDs, this represents an opportunity for significant cost savings.

(2) Helps prevent other incidents and injuries: Workers who experience discomfort on the
job may find shortcuts or workarounds that could result in incidents and injuries such as slips,
falls, and lacerations. Implementing an ergonomics program and encouraging workers to
report ergonomic issues early helps prevent MSDs as well as other common workplace
incidents.
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(3) Improves overall productivity: Healthy employees are your most valuable
asset; creating and fostering the safety & health culture at your company will lead
to improved productivity for your organization. Effective ergonomic safety
programs can promote good posture at all times, less exertion, fewer motions, and
better heights and reaches, thus helping employees to work more comfortably and
efficiently in their workstations.

(4) Helps foster employee engagement and satisfaction: Employees notice when
the company is putting forth its best efforts to ensure their health and safety. It
shows your company’s commitment to safety and health as a core value. If an
employee does not experience fatigue and discomfort during their workday, it can
reduce turnover, decrease absenteeism, improve morale, and increase employee
involvement.

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 A case study
Employees at a small facility were experiencing a high frequency of back
injuries while manufacturing and finishing air compressor tanks.

Faced with the prospect of losing compensation insurance coverage, it
contacted a Certified Professional Ergonomist (CPE) to conduct an
analysis of the workplace.

Body motion

Activity frequency and duration

Pace issues

Lifting-related risk factors 10
Ergonomics involves knowledge
of sociology, psychology,
anthropology, anatomy,
physiology, chemistry, physics,
mechanics, statistics, industrial
engineering, biomechanics, and
anthropometry.
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What are the objectives of Ergonomists?

The primary objective of ergonomics is the
improvement of human health, safety, and performance
through the application of sound people and workplace
principles. The goal is to help production managers
improve productivity and efficiency.

Ergonomists can best serve as part of a team including
engineers, managers, and medical personnel.

The ergonomics team will systematically analyze the
job requirements from a worker’s capability and
limitation perspective, analyze workplace layout and
design, and recommend improvement of the
production process.

The goal is to eliminate problems before they occur.
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 Applying Ergonomics: An overview

The triad of recognition, evaluation, and control.

Recognition of ergonomic hazards usually involves the search for
symptoms.

Evaluation implies the collection of information to help determine the
extent and location of the problem. (OSHA form 300 &300A)

Engineering controls, such as the design and utilization of ergonomically
correct workstation and workplace layouts. (These include job rotation or
requiring employees to perform several different jobs during a shift to
reduce repetition in a task.)
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Applying Ergonomics
Operator-machine system analysis
examines factors associated with
the people; equipment/machinery,
including the layout of the
workplace; and environment.

It provides safety professionals
with a systematic procedure to
study the three categories of causes
resulting in ergonomic hazards in
the occupational setting: people,
machines, and the environment. 14
 People Variables
The people or operator variables associated with a system are
composed of the human factors contributing to the ergonomic
problem. (physiological dimensions, capabilities, and limitations)

Examination of mental and physical job demands is done to
determine whether job demands exceed human capabilities.

Knowledge of human physiological dimensions (anthropometry)
and movement (biomechanics) is a critical component.

A quantitative evaluation of motions, forces, or other contributing
factors can then be performed.
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 How to Spot and Correct Ergonomic Hazards
Here are some general ergonomic safety tips to help prevent the most prevalent
ergonomic hazards:

(1) When transporting and handling:
Be knowledgeable about body limitations.
Provide carts for transporting materials to eliminate lifting.
Require all loads to be labeled with their weight.
When lifting, keep your back straight and lift with your legs.
Assign two or more staff to lift heavy objects depending on weight.
Lift slowly and carefully.
Don’t twist or turn your spine while carrying the load.
Use shoulder pads to cushion loads carried on the shoulder.
Use knee pads for kneeling tasks.
Store materials at waist height to minimize reaching.
Design containers with handles for easy gripping.
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(2) Workstation improvements:

Redesign workstations to eliminate awkward postures.
Provide adjustable equipment that can be used by workers to allow neutral
postures.
Maintain good body posture

(3) Staff scheduling and training:

Rotate workers among different tasks to avoid repetitive motions.
Improve the work schedule to minimize excessive overtime that causes fatigue.
Increase staff to reduce individual workloads.
Provide sufficient employee breaks.
Adequate recovery time can reduce fatigue.
Provide workers with training on ergonomics policies and procedures.

17
Thank You

gu.edu.eg
MEC232
Human & Equipment Safety

Ehab Abousaif, PhD

Assistant Professor of Electrical
Engineering – Faculty of Engineering

Topic 4
 Personal protective equipment (PPE)
The need for personal protection implies that hazards
have not been eliminated or controlled.

The need for first aid implies something even worse!

When feasible, engineering control of the hazard is
preferred over the use of personal protective equipment
(PPE).

We realize that some risks will always remain; our goal is
to eliminate unreasonable risks, not all risks.

The job of improving safety and health in the workplace
will never be completely finished; so we must concern
ourselves with the need to provide personal protection
against hazards that have not been completely eliminated
and to provide first aid when an accident does occur.
Hierarchy of controls
Personal protective equipment (PPE)

- The basic premise of enforcement authorities is that if personal protective
equipment (PPE) is needed, then the employees must be trained to use it
properly.

- Employees need to know when PPE is necessary, what kinds of PPE are
required, and how to wear it effectively, to avoid developing a false sense of
security.

- If either the workplace changes or the PPE changes, the employer must take a
responsible position and retrain the employee if necessary.

- Both the initial training and the retraining must be documented with a
certificate that identifies the names of employees trained, the dates, and the
subject for which the employee is certified.
 Protecting employees from workplace hazards

Employers must protect employees from
workplace hazards and dangerous work
procedures that can cause injury, illness,
and fatalities.

Employers must:

- Use all feasible engineering and work
practice controls to eliminate and
reduce hazards.
- Then use appropriate PPE if these
controls do not eliminate hazards.
- Remember: PPE is the last control.
 Hearing Protection
The most important factor in selecting a type of noise protection is probably
effectiveness in reducing the decibel level of noise exposure. However, this
is by no means the only important factor, and selection can be somewhat
complicated.

Economics is always a factor, and if limited effectiveness is all that is
necessary in a given situation, cheaper devices can be selected. Employee
comfort is probably at least as important a factor as economics.

The worker comfort factor goes beyond the simple goal of promoting
worker satisfaction; it affects the amount of protection the worker will
receive. If workers find a type of ear protection uncomfortable or awkward
to wear, they will use every excuse not to wear it, which results in loss of
protection.
Sound levels and their relevance
Cotton Balls: Ordinary cotton balls, without the
addition of a sealing material, are virtually
worthless as a means of personal protection from
noise.

Swedish Wool:
Similar in feel to cotton, Swedish wool is a mineral fiber that has much better
attenuation values than cotton. Swedish wool is somewhat effective, but is
much more effective when impregnated with wax to make a better seal.

One problem with Swedish wool is that it can tear when it is pulled out. To
alleviate this problem, Swedish wool sometimes comes in a small plastic
wrapper that is inserted with the wool. Swedish wool can be considered only
fairly reusable; reuse will depend on personal hygiene, quantity of earwax, and
worker preference.
Earplugs

The most popular type of personal protection for hearing is
the inexpensive rubber, plastic, or foam earplug. Earplugs are
practical from the standpoint of being
easily cleaned and reusable.

Workers often prefer earplugs because they are not as
visible as muffs or other devices worn external to the ear.
However, within this advantage lies a pitfall: Workers may be
more complacent about using the earplugs when it is not
immediately obvious to the supervisor whether the earplugs
are being worn.

The noise attenuation for properly fitted earplugs is fairly
good, falling somewhere between that of Swedish wool and
the more effective earmuffs.
Molded Ear Caps

Some ear protectors form the seal on the
external portion of the ear by means of a mold to
conform to the external ear and a small plug.
Since human ear shapes vary so widely, fit is a
problem.

Molded ear caps are more visible than
earplugs, which has both advantages and
disadvantages, as discussed earlier. Molded ear
caps may be more comfortable to the wearer, but
are more expensive than earplugs.
Earmuffs

Earmuffs are larger, generally more expensive, and
more conspicuous than Swedish wool, plugs, or caps,
but they can have considerably better attenuation
properties.

The attenuation capability depends on design, and
more variety in design is possible with earmuffs.
Although some workers object to wearing
conspicuous earmuffs, some workers prefer them,
stating that they are more comfortable than earplugs.
Helmets
The most severe noise-exposure problems may force the
safety and health manager to consider helmets for personal
protection against noise. Helmets are capable not only of
sealing the ear from noise, but also of shielding the skull
bone structure from sound vibrations that can be transmitted
to the ear as noise. Helmets are the most expensive form of
hearing protection but have the potential to offer protection
from a combination of hazards. Properly designed, the
helmet can act as a hard hat and a hearing protector at the
same time.

It must be remembered that fit is very important for all
types of hearing protectors. As in noise enclosures or sound
barriers, the material itself might have excellent sound-
attenuation properties, but if there is a leak or crack, most of
the effectiveness of the device is lost.
Eye and face protection
The use of safety glasses has become so widespread and
so many different styles are now available that many
safety and health managers have established a rule that
the safety glasses must be worn throughout the plant. A
general custom in industry is to require visitors to wear
safety glasses during plant tours.

There is a difference between street safety glasses and
industrial safety glasses. Visitors or employees who claim
that their prescription glasses are “safety glasses”
probably mean that they have street safety lenses.
Industrial safety lenses must pass much more severe tests
to meet the American National Standards Institute
(ANSI) standards.
 Machining operations that produce chips or
sparks are almost universally conceded to
necessitate the use of eye protection.

Notable among these operations are those of
grinding machines, drill presses, and lathes.
Both metal and wood materials can produce
dangerous eye hazards when machined.

Corrosive liquids or other dangerous
chemicals also represent eye hazards when
poured, brushed, or otherwise handled in the
open. When working with such materials,
face protection may be needed in addition to
eye protection.
 Workers must wear personal protective equipment
over the eyes or face, when the job requires it,
regardless of whether they are wearing contact lenses.

In OSHA’s early years rules were observed that
prohibited the use of contact lenses in certain jobs.
Later research led OSHA to remove these prohibitions
and permit contact lens users to wear them on the job,
provided appropriate personal protective equipment is
used as required for nonusers of contact lenses as well.

Contact lenses have some advantages over
conventional glasses (with frames). The frames of
conventional glasses may partially restrict the field of
view and may interfere with the seal required for full-
face respirators.
 Is it Easy or Just an Illusion ?
The problem of providing personal protective equipment seems straightforward and easy
enough to understand.

However, the simplicity of the problem is an illusion, and many industrial safety and
health managers fall into its trap.

For instance, it would seem that if the noise level in the production area is too high, the
solution to the problem would be to provide ear protection for the workers.

However, anyone who has actually confronted this problem knows that the solution is not
that simple.

For a variety of reasons, many people do not want to wear ear protection. They may be shy
about the appearance of ear protection equipment, they may feel discomfort or perhaps even
pain, they may feel it interferes with their necessary hearing or efficiency, or they may feel
that the use of personal protective equipment is their own business, not their employer’s.
 The matter of personal protective equipment becomes very delicate when
employees bring their own equipment to work.

If the equipment is not properly maintained, who is responsible—employer or
employee?
- OSHA’s position is that the employer is responsible.

As a safety and health manager, consider the following logic: If employees bring
their own personal protective equipment to work, is it not possible that the
equipment itself could represent a hazard?

Personal protective equipment must be properly selected to match the hazard, and
employees bringing their own equipment might falsely think they are safe when
their equipment could actually be malfunctioning or inappropriate.
 Respiratory protection
Of even more vital importance than eye and hearing protection is the
need for respiratory protection from airborne contaminants.

Particularly hazardous atmospheres may be referred to as IDL, which
stands for “immediately dangerous to life” or IDLH, which stands for
“immediately dangerous to life or health.”

Recently, the acronym IDLH has become more widely used. If a single
acute exposure is expected to result in death, the atmosphere is said to be
IDL. If a single acute exposure is expected to result in irreversible damage
to health, the atmosphere is said to be IDLH.

Some materials (e.g., hydrogen fluoride gas and cadmium vapor), for
example, may produce immediate transient effects that, even if severe,
may pass without medical attention but are followed by sudden, possibly
fatal collapse 12 to 72 hours after exposure.

The victim “feels normal” after recovery from transient effects until
collapse.
A classification of the various devices is in order. The
two major classifications are:

(1) Air-purifying
devices versus
(2) Atmosphere-supplying devices
Atmosphere-supplying respirators provide clean breathing air from a source separate from the work
area. These respirators protect wearers from many types of contaminants (particles, gases, and
vapors). In some cases, they can also supply breathable air in places that do not have enough oxygen.
Fit testing is required for respirators with a tight-fitting facepiece.
Respirator Plan

OSHA standard 1910.134(c) sets forth these necessary steps, summarized here
as follows:

1. Procedures for respirator selection
2. Medical evaluations for respirator users—Personnel Screening
3. Respirator fit testing
4. Procedures for proper use of respirators
5. Procedures for respirator maintenance
6. Provision of adequate supplied breathing air for air-supplying respirators
7. Employee training for when respirators are needed
8. Employee training for proper wearing, use, and maintenance of respirators
9. Procedures for continuing evaluation of the respirator program
 Head protection
Hard-hat rules should be carefully formulated with ample
consideration for the consequences both ways. Once it has been
decided that a hard hat rule is necessary, the safety and health
manager should take steps to ensure its implementation.
The evidence that was used to prove the need for the hard-hat rule should be compiled into an
organized training package to convince workers.

After the training and launching of the implementation phase, follow-up checks should be used
to ensure that the rule is being followed. Corrective steps should be taken to overcome
individual violations of the rule, including disciplinary actions if necessary.

Hard hats seem to have won wider acceptance than hearing protection.

Besides being a symbol for occupational safety and health, the hard hat has become a symbol
for rugged, physical jobs.

This image has appealed to males for centuries and is becoming an increasingly appealing
image for female workers as well.
 Safety shoes (steel-toe shoes)
Safety shoes are a more expensive undertaking than hard hats
because safety shoes get worn out faster and are more expensive
per item. Employees may buy their own shoes at attractive
discounts in some arrangements, and this encourages actual use.
Safety shoes come in a wide variety of appealing styles, and
employee resistance to wearing safety shoes is largely a thing of
the past.

The safety and health manager is usually saddled with the
decision as to which jobs require safety shoes and which do not.
Although applicable national standards are explicit about the
design and construction of safety shoes, as with almost all personal
protective equipment, the decision of where such shoes must be
worn is left up to either the user or management.

One place where safety shoes are clearly needed is on shipping
and receiving docks. This should be obvious, but there has been
some legal controversy over this issue.
 Protective Clothing and Skin Hazards
Occupational skin disease, especially contact
dermatitis from irritants to the skin, represents
a significant number of all occupational
diseases reported. The safety and health
manager should be alert to several skin hazard
sources, such as welding, special chemicals,
open-surface tanks, cutting oils, and solvents.

Most welders know the value of heavy-duty
protective aprons and flameproof gauntlet
gloves. Leather or woolen clothing is more
protective than cotton from a burn ability
standpoint. Nomex™ is a treated flame-
retardant fabric.
 Another concern for protective clothing is
chemical exposures from open-surface
tanks. Gloves must be impervious to and
unaffected by the liquid being handled
and long enough to prevent the liquid
from getting inside.

If the gloves are not long enough, they
can be more hazardous than beneficial.
Many workers’ hands have become more
irritated than their unprotected arms
simply because the gloves they were
wearing permitted liquids to get inside,
turning the gloves themselves into dip
tanks for the hands!
 First aid
The safety and health manager will frequently be responsible for the
first-aid station and may supervise a plant nurse. The first-aid station may
satisfy several additional functions besides providing immediate care for
the injured. The first-aid station is often used for medical tests, screening
examinations, and monitoring of acute and chronic effects of health
hazards.

Also, the plant nurse or other first-aid personnel may be responsible for
performing some of the recordkeeping and reporting functions discussed
in previous lectures.
One adequately trained first-aid person is required in the absence of an infirmary, clinic, or hospital
“in near proximity” to the workplace.

The interpretation has sometimes depended on whether the route to the hospital crosses a railroad
track

If the workplace is not itself a hospital or clinic or is not directly adjacent to one, the safety and
health manager is advised to be sure that at least one, preferably more than one, employee is
adequately trained in first aid.
 A first-aid kit or first-aid supplies should be on hand, and the
safety and health manager should seek a physician’s advice
regarding the selection of these materials.

Unfortunately, medical doctors are hesitant to give such advice,
probably because they fear subsequent involvement in litigation
should an accident occur for which adequate materials are not
available. Safety and health managers should do their best to obtain
such advice and then document what was done to obtain
information.

Another first-aid consideration is the provision of emergency
showers and emergency eyewash stations on job sites where
injurious corrosive material exposure is a possibility.

Almost everyone has seen the deluge-type shower, which is
activated by grabbing and pulling a large ring attached to a chain
that activates the valve. Eyewash facilities are similar to a drinking
water fountain in which two jets are provided, one for each eye.
Thank You

gu.edu.eg
MEC232
Human & Equipment Safety

Ehab Abousaif, PhD

Assistant Professor of Electrical
Engineering – Faculty of Engineering

Topic 5
Fire Protection
It is easy to oversimplify fire protection as meaning only
fire extinguishment, but it encompasses three fields:
- Fire prevention,
- Fire suppression,
- Personal protection (escape).

The fire itself has three ingredients: oxygen, heat, and
fuel, as shown in the familiar fire triangle.

By keeping in mind these three essential physical
ingredients of fire, strategies for prevention and
suppression can be developed for various industrial
circumstances.
1
 Fire Prevention
Effective fire prevention requires anticipation of fire sources. Each facility is
different and requires an individual analysis of potential fire sources.

A principal cause of industrial fires is overheated bearings or hot machinery
and processes. Another cause is clogged or dirty ventilation filters or ducts,
especially when the clogging material is a flammable or combustible air
contaminant.

Another component in a fire prevention plan is a strategy
for housekeeping. Accumulation of combustible dusts in
grain elevators and paint residues in spray painting
operations are good examples of how poor housekeeping
can contribute to fire hazards. 2
 Emergency Evacuation
Using the escape strategy for dealing with fires or other
emergencies, the employer must prepare a written emergency action
plan.

The emergency action plan concept has been around for many years
for hospitals, schools, and institutions, and more recently, has been
extended to industries in general.

It is crucial to an emergency action plan is an employee alarm
system. However, alarm systems are not as simple as they may
seem. There are searching questions that must be asked:

- Will persons recognize the signal as a fire alarm?
- What about deaf or blind employees?

Audible, visual, and tactile systems must be considered, or perhaps
combinations of these systems.
3
 Employee Fitness
Volunteering to join the fire brigade is not sufficient to qualify the
worker to fight fires.

Conditions that may be hazardous include heart disease, epilepsy, or
emphysema.

Other conditions, such as ruptured eardrums or the wearing of a beard,
may make the use of respiratory equipment ill advised. The safety and
health manager should be sure that the fire brigade volunteers are
screened, and a physician’s certificate may be necessary for
questionable cases. Volunteers unfit for interior structural firefighting
may be used in other tasks.
4
 Firefighter Training

Many places have fire training academies, and safety and health managers
should find out what schools and academies are available for their fire
brigade members.

Interior structural firefighting is more demanding, and fire brigade
members assigned to such tasks should be trained at least quarterly. Other
fire brigade members should be trained at least annually. Also, firefighting
equipment to be used by the fire brigade should be inspected annually, and
fire extinguishers should be inspected monthly.
5
6
 Fire extinguishers

Fire extinguishers are still the most effective method of
immediately controlling a very local fire before disastrous
consequences ensue.

The safety and health manager needs to understand the
various fire classes and the type of extinguishers
appropriate for each class.

A fire extinguisher is a handheld active fire protection device usually filled with a
dry or wet chemical used to extinguish or control small fires, often in emergencies.

Typically, a fire extinguisher consists of a hand-held cylindrical pressure vessel
containing an agent that can be discharged to extinguish a fire. Fire extinguishers
manufactured with non-cylindrical pressure vessels also exist but are less
common. 7
Fire Classes

8
 Inspection, Testing, and Mounting
In addition to the monthly and annual inspections, fire extinguishers must
receive a hydrostatic test according to a prescribed test schedule.

Fire extinguisher shells deteriorate from mechanical damage or corrosion
and may be unsafe for containing pressures inside. The hydrostatic test
places the extinguisher under a test pressure to determine whether it can
safely contain the pressures to which it will be subjected in use.

The test has technical specifications and must be done by a trained person
using suitable equipment and facilities. The safety and health manager
invariably leaves the hydrostatic tests for the professional fire extinguisher
service to perform.
9
 Training and Education

A facility looks well equipped and protected when fire extinguishers
are placed about the workplace, readily accessible for use in an
emergency.

However, the appalling reality is that few employees know how to use
a fire extinguisher effectively, and some would even be afraid to use
the extinguishers if they knew how.

This is especially true of fire extinguishers or hose systems located
behind glass doors. For most people, there is a great reluctance to break
glass even in an emergency.
10
Automatic Sprinkler System

Automatic sprinkler systems present a paradox because
they affect employee safety, but are usually installed
principally to protect property and to lower insurance
rates.

If a spray area is protected by an automatic sprinkler system, a good way to protect
the sprinkler heads is to cover them with paper bags. If a fire does occur, the paper
bags will either burn away or be washed away by the water spray so that they do
not interfere with the fire suppression action of the sprinklers.

Another error with automatic sprinklers is to stack material too close to the ceiling.
This interferes with the distribution of spray from the sprinkler head. 11
 Dry Chemical Systems

Dry chemicals used for extinguishing agents are usually not dangerous to
the health or safety of personnel. However, the actual distribution of the
chemical powder during an emergency may obscure vision, preventing
escape.

The biggest problem with dry chemical systems is the caking or lumping of
the agent. Humid climates or moisture-producing processes subject the
system to a greater risk of caking. Caking can render a dry chemical useless,
so the chemical should be sampled annually to be certain that moisture is not
causing caking.

12
 Electrocution Hazards
The first step toward safety from electrocution is to overcome the myth that “ordinary 110-volt
circuits are safe.”

The truth is that ordinary 110-volt circuits can easily kill, and actually do kill, many more people than
do 220- or 440-volt circuits, which nearly everyone respects.

However, the myth about 110 volts persists because almost everyone has sustained an electrical
shock around the home or on the job without serious injury.

It is true that some persons are more resistant to electrocution hazards than others, but a far more
important factor is the set of conditions surrounding the accident. Wet or damp locations are known
to be hazardous, but even body perspiration can provide the dampness that can make electrical
contact fatal.

Another important condition is the point of contact. If current flow enters the body through the
fingers and passes out through a contact at the elbow, no vital organs receive direct exposure.
However, if the flow is from a hand through the body to the feet, vital organs such as the heart, chest
muscles, and diaphragm are affected, with possibly fatal results.
13
Ohm’s law

15
 Human skin, if it is dry enough, is a good insulator and may have a
resistance of 100,000 ohms or more. By using Ohm’s law, a 110-volt
exposure would result in only a tiny current:

It can be seen that such a tiny current will probably not even be
noticed.

However, add perspiration or any other moisture to the skin, and
the resistance drops sharply. Owing to perspiration alone, the skin
resistance can be reduced 200 times, to a level of about 500 ohms,
with good contact with the electrical conductor. Once inside the
body, the electrical resistance is very low and the current flows. If
the total resistance in the circuit is only 500 ohms, the current is
calculated as:

From Figure 17.1 it can be seen that an alternating current at this level
passing through the body, including the heart, will most likely be
fatal.
16
Grounding
A requirement for
electrical current to
flow is that its path
makes a complete
loop from the source
of electrical power
through the circuit
and back again to the
power source.
17
Wiring
A typical 110-volt circuit has three wires: hot,
neutral, and ground. Sometimes the neutral is
called the “grounded” conductor, in which case
the ground is called the “grounding” conductor.

The purpose of the hot wire (usually a black
insulated wire) is to provide contact between the
power source and the device (load) that uses it.
The neutral (usually a white insulated wire)
completes the circuit by connecting the load with
ground. Both the hot and the neutral normally
carry the same amount of current, but the hot is at
an effective voltage of 110 volts with respect to
ground, whereas the neutral is at a voltage of
nearly zero with respect to the ground.

The third wire is the ground wire and is usually
either green or is simply a bare wire. The purpose
of the ground wire is safety.
 Fire Hazards
Most people think of electrocution when they think of electrical
safety, but electrical codes have as much to do with fire hazards
as they do with electrocution.

Many systems, such as fuses or circuit breakers, protect against
both fire and electrocution, but their primary function is fire
prevention.

19
Wire fires
One of the most common causes of
electrical fires is wires that become
overheated because they conduct too
much current.

Wire diameters (gauges) must be
properly sized to handle the
expected current load, and
overcurrent protection (fuses or
breakers) must ensure that these
loads are not exceeded.
Arc & sparks

Whenever two conductors make a
physical contact to complete a
circuit, a tiny (or not so tiny)
electric arc jumps the air gap just
prior to contact.

This arc may be so small as to be
undetectable, but it is usually hot
enough to ignite explosive vapors
or dusts within their dangerous
concentration ranges. 21
Electrical Sockets & plugs

22
Thank You

gu.edu.eg
MEC232
Human & Equipment Safety

Ehab Abousaif, PhD

Assistant Professor of Electrical
Engineering – Faculty of Engineering

Topic 6
 X-ray radiation
X-ray is a high-energy electromagnetic radiation. In many languages, it is
referred to as Röntgen radiation, after the German scientist Wilhelm
Conrad Röntgen, who discovered it in 1895 and named it X-radiation to
signify an unknown type of radiation.

X-ray wavelengths are shorter than those of UV rays and longer than those of gamma rays.
There is no universally accepted, strict definition of the bounds of the X-ray band. Roughly,
X-rays have a wavelength ranging from 10 nanometers to 10 picometers, corresponding to
frequencies in the range 30 petahertz to 30 exahertz (3×1016 Hz to 3×1019 Hz) and energies in
the range 100 eV to 100 keV, respectively.

X-rays are widely used in medical diagnostics (e.g., checking for broken bones) and material
science (e.g., identification of some chemical elements and detecting weak points in
construction materials).
1
Radiation shielding

2
 Radiation protection in diagnostic interventional radiology
Employers must ensure for all workers that:

Occupational dose limits are not exceeded,
Protection and safety are optimized,
Suitable and adequate facilities, equipment, and services for protection
are provided,
Appropriate monitoring equipment and personal protective
equipment are provided and properly used,
Appropriate training is provided as well as periodic retraining and
updating,
Adequate records are maintained, and
A safety culture is provided 3
Workers must:

follow any applicable rules for protection,
Use properly the monitoring devices and personal protective
equipment, and
co-operate with the employer with respect to protection and safety.

4
 Dose limits for occupational exposure
Dose limits are set to protect workers and members of the public from the effects
of ionizing radiation.

They are set at a level that reduces the risk of serious effects occurring, such as
cancer, and are in place to protect the eyes, skin, and extremities against other
forms of damage, from exposure with the benefits of using ionizing radiation.

The sievert is a unit of radiation exposure
dose that a person receives and is used with
regard to what is exposed to radiation, i.e. the
human body. It is a derived unit of ionizing
radiation dose in the (international system of
units) and is a measure of the health effect of
low levels of ionizing radiation on the human
body
5
 Dose limits and optimization of protection
ALARA stands for “as low as
reasonably achievable”. This
principle means that even if it is
a small dose, if receiving that
dose has no direct benefit, you
should try to avoid it.

To do this, you can use three
basic protective measures in
radiation safety: time, distance,
and shielding.
6
 Special arrangements
Pregnant workers
A female worker should, on becoming aware that she is pregnant,
notify the employer.
The notification of pregnancy must not be considered a reason to
exclude a female worker from work.
The employer then must adapt the working conditions in respect of
occupational exposure.
To ensure that the embryo or fetus is afforded the same broad level
of protection as a member of the public (Embryo dose < 1 mSv)

7
Classification areas in a radiology facility:

Controlled areas
All X-ray rooms (radiography, fluoroscopy, CT, mammography, interventional, etc.),
including control rooms
Physically delineated
Warning signage
Restricted access – physically & administratively

Supervised areas
A supervised area is defined as any area not designated as a controlled area, but in which
occupational exposure conditions are kept under review even though specific protective
measures and safety provisions are not normally needed. The areas will be designated with
the careful evaluation of the dose rate in the particular areas. Areas where mobile radiography
takes place.

Public (uncontrolled) areas (public dose limits)
Waiting rooms, toilets, corridors, stairwells, etc
8
Who can enter a controlled area?

Entrance into controlled areas is strictly controlled by the
employer. Employees designated as 'classified persons' and outside
workers can enter the area where they have been authorized to do
so by the employer and have received appropriate training.

If an assessment of the potential exposure shows that work in a
controlled area could be done by employees who are not classified
persons, suitable written arrangements and monitoring would be
required to ensure exposures are kept as low as possible. Other
workers should only be allowed conditional access and only in
accordance with prior written arrangements.
9
What is a classified person?

An employer must classify an employee where they consider that their employee is likely to receive:

- an effective dose greater than 6 mSv per year or
- an equivalent dose greater than 15mSv per year for the lens of the eye or
- a dose greater than 150mSv per year for the skin or the extremities (hands, forearms, feet or ankles)
- Employees can only be classified if they are aged 18 years or over.

What happens if I am 'classified’?

As a classified person, your employer is required to:

- inform you that you are classified
- assess and record your radiation dose
- ensure that you are certified fit to work with ionizing radiation by an appointed doctor or
employment medical adviser (medical surveillance)
- Your employer should periodically review if there is a continuing need for classification.

10
 Primary Beam and Scatter Radiation
Primary Beam
The primary beam is a significant hazard,
even very short exposure times can result in
severe radiation burns.

Scatter radiation
It is produced when the primary beam
interacts with samples and structures in the x-
ray enclosure. Scatter radiation is a hazard
near the sample.
Leakage radiation from the X-ray tube is very
low and not hazardous when the tube housing
is intact. 11
 Working with x-rays

Primary beam
the x-ray tube

Scatter
the patient

When working with X-rays:
Avoid the primary beam
Minimize exposure to scatter

12
Scatter - distance

Scatter decreases
approximately by the inverse
square law

Stand as far away from the
patient when x-rays are being
produced

13
Scatter – time

Minimize the time spent in areas where scatter is present
Only be in the X-ray room if required to be

Minimize the “beam on” time in fluoroscopy & interventional
procedures

14
Scatter – shielding

Shielding in walls, doors, windows, ceilings, floors

Permanent operator barriers

Personal protective equipment

Movable barriers

15
 Biological effects of radiation exposure
Radiation is one of the best-investigated hazardous agents. Radiation levels can be
readily controlled and monitored so work may continue at a level of risk that is much
less than with many other technologies.

The following slides present topics essential for working safely with radiation:

Radiation dose units
Acute vs. chronic radiation exposure
Effects of radiation exposure
–radiation burns
–radiation sickness
–long-term effects of exposure to radiation
Radiation Dose Limits
General Radiation Safety
16
Why are different units used to measure exposure to radiation?

17
Acute vs. chronic radiation exposure

18
Radiation burns

Occur as a result of an acute localized exposure.

Radiation burns can occur from a wide range of exposures and
usually result from direct exposure to the primary beam. High-
energy X-rays readily penetrate the outer layer of skin that
contains most of the nerve endings, so you may not feel an X-ray
burn until the damage has been done. Extreme cases involve skin
grafts or amputation of fingers.

The hands, fingers, and eyes are the parts of the body most
commonly at risk.

The severity of the burn will depend on the dose received, the
length of the exposure, the energy of the X-rays, and the sensitivity
of the individual.

Burns can be caused with exposures of 300 rem, but normally do
not become apparent below exposures of at least 600 rem. 19
Radiation sickness

20
 Long-term Effect
Long-term effects resulting from chronic exposure to ionizing radiation include
carcinogenesis, life span shortening, and cataract formation. The principal delayed
effect of chronic radiation exposure is an increased incidence of cancer.

Long-term effects of acute exposure to radiation are often classified as leukemia
and other cancers, radiation-induced life-shortening, genetic effects, and
embryonic effects.

Genetic defects are less likely than cancer, and not as serious, therefore, the risk of
developing cancer from radiation exposure is more significant.

Radiation exposure in utero can result in spontaneous abortions, congenital
abnormalities, impairment of growth and mental functions, and increased
incidences of leukemia.
21
22
Analytical Unit Safety Features

23
24
 Regulations & Safety Practices

NEVER bypass a safety device, such as interlocks and failsafe features,
shutters, etc., without approval from the Radiation Safety Officer, since these
devices are meant to protect you from serious harm and injury..
DO NOT operate a unit in any manner other than specified in the procedures
and the conditions listed on your Radiation Use Authorization.

LEARN the Standard Operating Procedures for each X-ray unit you operate.

DO NOT allow anyone other than trained and certified personnel to operate
the unit.

ALWAYS follow the ALARA principles (Time, Distance, and Shielding)
25
 DO NOT remove covers, shielding material, or tube housing or perform
modifications to shutters, collimators or beam stops without verifying the x-ray tube
is off and will remain off until safe conditions have been restored. The main switch,
rather than interlocks, shall be used for routine shutdown.

NEVER place any part of your body in the primary beam.

DO NOT attempt to operate if the X-ray unit is not mechanically intact and sound.

ALWAYS control access to radiation-producing equipment during use to avoid
unintentional exposures.

ALWAYS know the location and presence of the primary and diffracted/scattered
X-ray beams
26
Health and Safety in a Radiology Facility

27
Thank You

gu.edu.eg