Occupational exposure limits-noise

Occupational Health
By
Dr. Ashraf Hussain
MSc. Community Medicine
Occupational Exposure Limits
In general, the occupational exposure limit (OEL) represents the maximum airborne concentration of a toxic substance to which a worker can be exposed over a period of time without suffering any harmful consequences.
These limits are set out by many professional organizations.
Such as the American Conference of Governmental Industrial Hygienists (ACGIH), and the National Institute for Occupational Safety and Health (NIOSH) in the United States.
They are established based on the chemical properties of the substance, experimental studies on animals and humans, toxicological and epidemiological data.
Different organizations may use different terminology for the OEL. For example, the ACGIH term for OEL is "Threshold Limit Value" (TLV)® while the NIOSH term is "recommended exposure limits" (REL).
A legal limit or guideline (such as an occupational exposure limit) should never be viewed as a line between "safe" and "unsafe".
The best approach is to always keep exposures or the risk of a hazard as low as possible.
As an example, carcinogens are not usually defined by an exposure limit.
With many carcinogens, it is difficult to say for certainty that if exposure is below a set point, the agent is not likely to cause harm.
For this reason, for carcinogens and other specific agents (such as allergens), the "As Low as Reasonably Practicable" (ALARA) principle should be applied.
ALARA, in practical terms, means that exposure should be eliminated or reduced as much as possible.
Types of Exposure Limits
ACGIH defines three categories of threshold limit values:
Threshold Limit Value – Time-Weighted Average (TLV-TWA): The concentration of a hazardous substance in the air averaged over an 8-hour workday and a 40-hour workweek to which it is believed that workers may be repeatedly exposed, day after day, for a working lifetime without adverse effects.
Threshold Limit Value – Short-term exposure (TLV-STEL):
A 15-minute time weighted average exposure that should not be exceeded at any time during a workday, even if the overall 8-hour TLV-TWA is below the TLV-TWA.
Workers should not be exposed more than four times per day to concentrations between TLV-TWA and TLV-STEL.
There should be at least a 60 minute interval between exposures.
Threshold Limit Value – Ceiling (TLV-C): This is the concentration that should not be exceeded during any part of the working exposure.
Three-times the value of the TLV-TWA for no more than 15 minutes, no more than four times per workday. Exposures must be at least 1 hour apart during the workday.
Five times the TLV-TWA under any circumstances.

Noise
Noise is an unwanted, unpleasant or undesirable sound
It is one of the most common occupational hazards.
SOUND MEASURES
Intensity or Loudness
Intensity is the loudness of the sound measured in decibels (dB).
The scale runs from the faintest sound the human ear can detect, which is labeled 0 dB, to over 180 dB, the noise at a rocket pad during launch.
The decibel scale is a logarithmic scale, not a linear scale, small numbers represent enormous changes. Sound energy that is twice the level of 83 dB is not 166 dB, rather 86 dB.
Frequency or Pitch of the sound
measure the frequency of sound vibrations per second, called Hertz (Hz).
? Frequency is measured in cycles per second, or Hertz (Hz).
? A low pitch such as a deep voice or
a tuba makes fewer vibrations per
second than a high voice or violin.
Exposure limits
Exposure limits in noise exposure are a trade-off between sound level (measured in decibels) and duration of exposure (time).
For an 8-hour exposure, for example, the maximum permissible sound level is 90 dB.
Anything beyond 8 hours at this noise level is not allowed.
For greater exposure levels, such as 95 dB, the maximum allowed exposure time is only 4 hours.
In a time-weighted average (TWA), greater noise levels require shorter exposure times, and lower noise levels allow longer exposure times.
Occupational Hazards of Noise
A. Acoustic effect of the noise
1. Conductive hearing loss: explosive sound that damage the eardrum or the middle ear. This type is reversible.
2. Sensory neural hearing loss
Temporary threshold shift: temporary rise of auditory threshold which results from noise induced fatigue of the nerve sensitivity.
It usually recovers within 16 hours.
If noise continue then it will be permanent.
permanent threshold shift then is the noise induced hearing loss.
Noise induced hearing loss is a permanent hearing impairment resulting from prolonged exposure to high levels of noise.
When noise is too loud, it begins to kill cells in the inner ear.
As the exposure time to loud noise increases, more and more hair cells are destroyed.
As the number of hair cells decreases, so does hearing.
Currently, there is no way to restore life to dead hair cells; so the damage is permanent.


Noise-Induced Hearing Loss
Causes no pain
Causes no visible trauma
Leaves no visible scars
Is unnoticeable in its earliest stages
Accumulates with each overexposure
Takes years to notice a change
Sensori-neural hearing loss can be caused by several factors other than noise as aging, some diseases, but noise-induced hearing loss is different in one important way – it can be reduced or prevented all together.
Non-auditory health and physiological effects of noise
1. Nervousness, fatigue and annoyance
2. Interference in communication by speech
3. Raises the blood pressure, heart rate and the stress hormone levels.
4. Disrupt healthy sleep patterns.
5. Increase the risk of accidents.
Non-auditory effects of the Noise
Non-auditory effects can be divided into two categories - physiological effects and performance effects.
The response to noise may depend on characteristics of the sound including intensity, frequency, predictability, complexity of sound, duration (length of exposure), and the meaning of the noise.

Physiological effects
The muscle tension response, where muscles tend to contract in the presence of loud noise.
The respiratory reflexes, where the respiratory rhythm tends to change when noise is present.
Changes in the heart beat pattern.
Changes in the diameter of the blood vessels, particularly in the skin
performance effects
Speech intelligibility
Annoyance
Fatigue due to distorted sleep pattern
Job interference
A conversation nearby will distract a person and affect their concentration, hence reducing the employee s efficiency.
A noisy environment could create an additional hazard, since audible alarms might not be heard.
Diagnosis of noise induced hearing loss
At first no signs or symptoms
Recognition of hearing impairment occurs when the loss reaches the human speech frequencies (500-2000) Hz
First symptom is tinnitus (ringing) or sensation of blocked ear .
Close talk in a crowed become difficult to understood.
Then the words become distorted or unpleasant to hear
Audiometric Testing
Audiometric testing is the aid test of whether a Hearing Conservation Program is effective or not.
Monitors employee’s hearing over time
Baseline audiogram must be performed within first 6 months of work exposure ( 8 hour TWA ? 85 dBA)
Annual audiograms are required each year after baseline audiogram
Annual audiograms are compared back to each employee’s baseline audiogram to determine if a significant shift in hearing has occurred (a 10 dB average shift at 2000-4000 Hz in either ear).
If a shift occurs, and is found to be due to noise exposure, the employee must be retrained/refit with hearing protectors.
Prevention and control of noise and hearing loss
Hierarchy of Controls
Controlling risks of noise exposure
Implementing one or more of the following hierarchy of control measures can manage excessive noise levels, in order of effectiveness:
1. Eliminating the noise source.
2. Substituting noisy machinery with quieter machinery or buying quiet - this is a cost-effective way to control workplace noise at the source.
3. Engineering controls by treating the noise at the source or in its transmission path e.g. using sound dampeners or silencers, noise barriers and isolation.
4. Introducing administrative noise control measures e.g. training and education, job rotation, job redesign or designing rosters to reduce the number of workers exposed to noise.
5. Providing Personal Protective Equipment (PPE) e.g. earmuffs, earplugs. However, if workers are frequently required to wear PPE to reduce the risk of hearing loss from a noise exposure that exceeds the exposure standard, then an audiometric testing regime must be implemented.