Ergonomics: Back Injuries

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Ergonomics Back Injuries
Dana Root, MS, PT, CPE OSHA Region V, Ergonomics
Coordinator dana.root_at_dol.gov 414-297-3315
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Comparison of Total Injury and Illness Cases
Involving Days Away from Work to MSD Cases
Involving Days Away from Work, 1999-2004
Injuries and Illnesses (Thousands)

• Median Days Away
• 1999 7 days
• 2000 7 days
• 2001 8 days
• 2002 9 days
• 2003 10 days
• 2004 10 days

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Source Bureau of Labor Statistics U.S.
Department of Labor Survey of Occupational
Injuries and Illnesses
Percentage of Total Cases that are MSD cases
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Direct Costs of Ergonomic Injuries

• 2005 Liberty Mutual Workplace Safety Index
• Top 10 workplace injuries
• 1. Overexertion
• 26.4 of all injuries
• 13.4 BILLION nation-wide
• 6. Repetitive motion injuries
• 5.9 of all injuries
• 3.0 BILLION nation-wide

Source Liberty Mutual Research Institute Annual
Workplace Safety Index 2005
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Direct Costs of Injuries

• Top cause of serious workplace injuries
• Overexertion 34
• Excessive exertion
• Lifting, lowering, pushing, pulling,
• holding, carrying, throwing
• Repetitive motion 13.5

Source Liberty Mutual Research Institute Annual
Workplace Safety Index 2005
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Overexertion Injuries

• Preferred safety intervention
• Better training 16.6
• Better equipment and workspace 7.4

Source Liberty Mutual Research Institute Annual
Workplace Safety Index 2005
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Overexertion and Low Back Pain

• Overexertion is the most common cause of back
  injuries
• Muscle strains and sprains
• Force is the most important risk factor
• Job physical factors
• Non-occupational risk factors may increase risk
• Individual issues
• Psychosocial issues

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Overexertion Injury Claims Low Back Pain

• 67 involve lifting
• 20 involve pushing/pulling
• 87 are related to materials handling

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Point You in the Right Direction
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So, why is this important?
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Third Class Lever Elbow
AFm
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MAm 2
MAw 14
AFm
MAm
W
MAw



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• AFm 20 14 / 2
• 140 pounds

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Human Body is at a Mechanical Disadvantage

• Gains
• ? range of motion
• ? speed of movement
• Compressive force at the elbow
• 20 pounds 140 pounds 120 pounds

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Third Class Lever Low Back
MAm 2
MAw 25
20
AFm
AFm MAm W MAw
AFm 20 25 / 2
250
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Example

• Weight 50 pounds
• MAw 12 inches
• Body wt. 100 pounds
• MAbw 8 inches
• AFm ?
• MAm 2 inches

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AFm MAm W MAw BW MAbw
Example
AFm (50 12) (100 8) / 2
1400/2 700 pounds
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With Body Weight Without Body Weight

• Compressive Force
• 700 100 50 850pounds
• 300 50 350 pounds

• Applied Force
• 700 pounds
• 300 pounds

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Body Weight is Primary Compressive Force

• NIOSH recommended limit is Fc ? 770
• Back muscles generate force ? if too much can
  cause injury
• Most of compressive force comes from body weight
• If load ?
• Muscles create ? compressive forces on the spine

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Human Body is at a Mechanical Disadvantage

• Gains
• ? range of motion
• ? speed of movement
• Compressive force at the elbow
• 20 pounds 140 pounds 120 pounds

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6 Task Variables

• Horizontal Distance
• Vertical Location
• Vertical Travel Distance
• Asymmetrical Angle
• Coupling
• Frequency

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6 Task Variables

• Horizontal Position of Load
• Most significant influencing factor
• Affects compressive forces on the L5S1 disc
• Distance the hands are away form the mid-point
  between the ankles

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RWL Recommended Weight Limit

• Load constant 51 pounds
• RWL LC HM VM DM AM FM CM

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Lifting Index

• Relative estimate of the level of physical stress
  associated with the lifting task
• LI Load weight / RWL
• Lifting is the same as lowering

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Lifting Lowering Control Options

• Body mechanics options
• If lift correctly can lift just about anything gt
  NO
• Compression
• Strength
• Energy expenditure
• Assumption can bring load close to the body
• Strongest position with hands between knees
• Moment arm small when hands by crotch

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Lifting Lowering Control Options

• Engineering options
• Weight of object
• Knuckle and shoulder height
• Distance away from body horizontal location
• Origin/destination of lift
• Slid, push, pull

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Pushing versus Pulling

• Force exerted by the body
• Type of wheels
• Types of bearings
• Type of surface
• Slope of surface
• Handle height

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Pushing versus Pulling

• Force exerted by the body
• Pulling force
• Flex spine
• Back muscles contracting gt ? compressive forces

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Pushing versus Pulling

• Force exerted by the body
• Pushing force
• Abdominal muscles are more active
• Less compressive force

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Pushing versus Pulling

• Control options
• Keep forces low
• Initial and peak
• Handle height between hip and shoulder
• Large wheels
• To ? friction
• Slip resistant shoes
• Good housekeeping
• Good steering mechanism
• Incline surfaces lt 2?

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Energy Expenditure

• Aerobic activities
• Produce whole body fatigue
• Fast paced lifting, lowering, walking, climbing
• Repetitive lifting gt overexertion injury
• Factors affecting aerobic capacity
• Gender
• Age
• Physical fitness
• Nature of work
• Whole body

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Energy Expenditure Control Options

• Effect of the workload
• Lifts versus trips
• Fatigue versus spinal compression
• Lifting technique
• Efficiency
• Amount of work
• Endurance

• Work pace
• Heavier object
• Heavier body weight
• Lift versus lower
• Lower less energy
• Carrying location
• Center of gravity

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Have We Accomplished Our Goal?

• What Is the Goal?
• Send Every Worker Home at the End of the Day
  in the Same Condition As When They Came to Work

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Ergonomics Free Resources

• www.osha.gov
• www.cdc.gov/niosh
• www.nsc.org
• www.hfes.org
• www.ergoweb.com
• www.dir.ca.gov
• www.lni.wa.gov

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Ergonomics More Free Resources

• NIOSH Elements of Ergonomics Programs, 97-117
• Easy Ergonomics A Practical Approach for
  Improving the Workplace
• Phone 800-963-9424

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ALWAYS THINK SAFETY BEFORE LIFTING A HEAVY LOAD
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