class notes topic 3
TRANSCRIPT
TOPIC 3 : CHEMICAL HAZARD ASSESSMENT AND PROTECTION
Outline of topic 3:EXPOSURE LIMITS
WORK PLACE AND PERSONAL MONITORING
EXPOSURE TO HAZARDOUS CHEMICALS IN LABORATORIES
PERSONAL PROTECTIVE EQUIPMENTS
EYE, FACE,HEAD,FOOT, HAND AND RESPIRATORY PROTECTION
CHEMICAL PROTECTING CLOTHING
IntroductionWHAT IS YOUR UNDERSTANDING?
• Who are you ?• What is your role?• We have any ISSUES for these?• Are you important for this ISSUES…….?
INTRODUCTION
WHAT IS CHEMICAL HAZARD?
Chemical Hazard is the danger caused by chemicals to the environment and people.
A chemical hazard arises from contamination with harmful or potentially harmful chemicals.
EXAMPLES:
Acetronitrile, Acids,Asbestos,Beryllium,Cadmium,Cyanide compounds,Hydrogen Chloride,Hydrogen Fluoride,Lead,Lithium compounds,Mercury,Methylene Chloride,Nickel,PCBs,Sodium,Uranium.
CONTINUE
Extent to which a person may be safely exposed to a hazardous substance (typically a gas or solvent vapor) without endangering his or her health. These limits are generally discretionary and every country defines its own limits, resulting in a lack of widely accepted standards.
EXPOSURE LIMITS
EXPOSURE
According to the circumstance of the exposure can be :
• Accidental: Unintentional and unexpected exposure. This includes food poisoning.
• Intentional: Exposure with the intention of causing harm. This includes suicide attempts, suicides, and homicides.
• Occupational: Exposure during the industrial processes of manufacture, storage, transportation, application, and final disposal.
OCCUPATIONAL EXPOSURE
• Continuously (for short term) - control strategy where the risk is high
• Intermittently (for long term) - initial determination of hazard - spot measurement in an established process - routine check measurement
MEASUREMENT
• harmful characteristics of the substance, energy or condition involved
• concentration, intensity or level of the exposure to the harmful agent
• time duration of the exposure
EVALUATION
• Elimination-most effective means of hazards control (involves physical removal of hazards)
• Substitution- second effective way to control hazards (removing something that produces hazards and replacing with something that does not produce a hazard)
• Engineering control- third effective controlling hazards (not eliminate hazards, but rather keep people isolated from hazards)
• Administrative control – changes to the way of people work (do not remove hazards, but prevent people exposure to the hazards)
• Personal protective equipment – least effective way to control hazards ( due to high potential of PPE to become ineffective due to damage)
CONTROL
• designed to control the absorption of airbornecontaminants into the body
• measured in:- ppm (parts of vapour/gas per million parts of air)- mg/m3 (milligrams of substance per cubic metre of
air)• expressed as the concentration of an airborne substance
averaged over a reference period -15 minutes short term limit - 8 hours long term limit
OCCUPATIONAL EXPOSURE LIMITS
Maximum Exposure Limit(MEL)
maximum permissible concentration has legal status must not be exceeded reduce exposure to as far below the MEL as possible
Occupational ExposureStandard (OES)
concentration at which no evidence of harm represents good practice if exceeded, take steps to reduce down to OES OES represents adequate control
Two types of occupational exposure limits
* The key difference between this two types of limit is that an OES is set at a level at which there is no indication of risk to health
confirmation
awareness
Long term limits
time-weighted average concentration conc. x exposure time averaged over 8 hours designed to control chronic effects
Short term limits
time-weighted average concentration conc. x exposure time averaged over 15 mins designed to control acute effects
OCCUPATIONAL EXPOSURE LIMITS-DURATION
Toxic effects may depend upon exposure duration:
For chemicals having long-term (chronic effects)-The total dose is the important factor, regardless of duration (what are the health problems at different exposure)
For chemicals having short-term (acute) effects-Shorter exposure durations must be evaluated
Other routes of exposure
Biological Exposure Indices (BEI)- BEI limits are established for chemicals having with significant
skin or ingestion exposures- Exposure are determined using biological specimens i) Blood, urine, exhaled air
ii) Also used to verify the efficacy of workplace controls- BEI limits are intended to correspond to other exposure limits
i) Measurements below the BEI show exposures are below the applicable OEL
WORK PLACE AND PERSONAL MONITORING
WORKPLACE MONITORING
Workplace monitoring is carried out for a number of reasons, they are:
Assessing possible health risks resulting from work activities Assessing the need for and the effectiveness of exposure control measures Determining compliance with permissible exposure levels of toxic substances Assessing the effect of changes in processes, materials or controls Identifying hazardous areas or work tasks that give rise to the most exposure Investigating complaints concerning alleged health effects Reassuring employees who may be exposed to toxic airborne contaminants
*Under the Factories Act Section 59(6), regular workplace monitoring is required in any factory in which toxic chemicals are used or given off.
Monitoring or sampling methodsThe method of sampling will depend on the chemical being monitored. The common air sampling methods are:
a) Sample bag method - used to collect gases and vapors when the concentration is above the
detection limits. - these bag are made of inert plastic film.- air is pumped into the bag and analyzed directly from the bag by
detector tubes, gas chromatography or other instruments.
b) Sorbent tube method - used for sampling of many gases and hydrocarbon vapors. - the tube contains a bed of adsorbent such as charcoal or silica gel. - when air is pulled through the tube, airborne chemicals are trapped by the adsorbent.-After sampling, the sorbent is removed and the trapped chemicals are extracted, identified and quantified using gas chromatography or other analytical methods.
c) Impinger method - used to collect certain inorganic chemicals and some organic chemicals.- a known volume of air is bubbled through the impinger which contains a liquid medium.- the liquid will physically dissolve or chemically react with the chemical of interest.- the liquid is then analyzed by colorimetric, volumetric or other analytical methods to determine the airborne contaminant concentration.
d) Badge method - many gases and hydrocarbon vapors can be sampled passively without a pump, using gas monitoring badges. - badges are available with a variety of collection media including solid adsorbent and reagent-filled tubes. - the air sample comes into contact with the adsorbent by diffusion. - analysis methods vary with the badge type or chemical sampled and include color change and gas chromatography.
e) Filter method - used to collect particulates matters such as dusts, fumes and mists. - air is pulled through a filter of a specific type and pore size. - the collected contaminants can be analyzed by gravimetric, microscopic or atomic absorption technique.
f) Direct reading instruments - such as detector tube, electrochemical sensors and solid state gas detector, photo ionizers and infrared analyzer. - types of direct reading instruments available for measuring gases, vapours and particulates in air using different principles. - most direct reading instruments allow for continuous monitoring of the contaminant level, some have data logging features and alarm settings to warn users of hazardous conditions.
Selection of measurement techniques/equipmentA number of factors need to be considered prior to selecting an air monitoring
technique / equipment for any particular application are:
Specificity – ability to detect one compound in presence of other contaminants Accuracy – closeness of result to actual concentration present Sensitivity – amount of substance that must be present to give a response Calibration – verify that an instrument is performing acceptably at the concentration of interest Interference – reaction of other substances other than the compound of interest Warning alarm – signals to alert personnel that higher than acceptable average concentration are present Data logging features – ability to store monitoring data for time-weighted average concentration determination Cost – expense associated with purchase of equipment or supplies Intrinsic safe – characteristic of equipment required so that it can be used in certain area
Sampling strategies
Location of sampling- depends on the objective of sampling or the type of information required
Personal sampling- to maximize the effectiveness of monitoring for assessing exposure hazard
Duration and volume of sampling- total volume of sampled depends on duration of sampling
Frequency- frequency of monitoring depends on the exposure level
What to sample- type of chemicals to sample will depend on basically two factors:i) The risk to the workers- depending on chemical are likely to be liberated into workplace atmosphereii) The toxic effects of the chemicals
Permissible exposure levels (PEL)
Assessing risks of exposure to contaminants in working environment, the result of concentration measurements are compare with their PELs. Two types of PELs are specified in the Factories (Permissible Exposure Levels of Toxic Substances) Order:
PEL (Long Term) is the maximum time-weighted average (TWA) concentration of a toxic substance to which persons may be exposed over 8-hour workday or a 40-hour workweek
PEL (Short Term) is the maximum TWA concentration to which persons may be exposed over a period of 15 minutes during the workday.
TYPES OF HAZARDOUS CHEMICALS PRESENT IN LABORATORIES
Hazardous chemicals present physical or health threats to workers in clinical, industrial and academic laboratories such as:
Carcinogens Toxins Irritants Corrosives Sensitizers HepatotoxinsNephrotoxins Neurotoxins
TOXIC CHEMICALS
The potential that a chemical can cause harmful health effects depends on two factors:
i) The toxicity of the chemical - the toxicity of a chemical is an inherent property. However, a chemical will produce injury or disease only if a worker is actually exposed to it.
ii) The degree of exposure- the degree of exposure of workers to a chemical will depend on how it is used and the availability and effectiveness of the control measures in the workplace.
ROUTES OF ENTRY INTO THE BODY
A chemical may enter into the body through three routes:
i) Inhalation- the main route of entry of chemicals into the body.- excessive exposure may cause direct irritation or local damage to the respiratory system or injury to tissues within the body.
ii) Skin absorption- direct contact of the skin with certain chemical may result in primary irritation or a sensitization reaction similar to an allergic type of response.- some can penetrate through skin and enter the bloodstream .
iii) Ingestion- may occur as a result of poor personal hygiene (eating with contaminated hands)- ingested materials may be absorbed into the blood from the intestine.
TOXIC EFFECTS OF CHEMICALSThe effects of exposure to chemicals may be classified in the following ways:
Acute effect- a short-term exposure to usually very high concentration of toxic chemicals resulting in immediate illness, irritation and even death.
Chronic effect- prolonged or repeated exposure to low concentrations of noxious substances resulting in certain diseases which may take some time to develop.
Reversible (temporary) effect- an effect that disappears if exposure to the chemical ceases.
Irreversible (permanent) effect- an effect that has a lasting, damaging effect on the body, even if exposure to the chemical ceases.
Local effect- the chemical causes harm at the point of contact or entry. Systemic effect- the chemical enters the body, is absorbed and transported to
the various organs of the body where harm is effected.
CONTROL MEASURES
Where the risk of exposure to chemicals is found not acceptable, suitable control measures must be implemented to minimize the exposure so as to safeguard the safety and health of the workers.
Point of Control Control measure
At the source Substituting with a less toxic/harmful substanceChanging to a less hazardous processInstalling effective local exhaust ventilation
Along the path Applying dilution ventilationIncreasing the distance between the source and receiverPracticing good housekeeping
At the receiver Rotation of workersTraining and education of workersWearing suitable personal protective equipment
Engineering Control
• Substitution/Elimination• Changing of processes• Enclosure• Isolation / Segregation• Local exhaust ventilation• Housekeeping• Personal protective equipment• Administrative measures• Education and training
Some examples of material substitution and their applications are listed in the following table:
PREVENTING EXPOSURE TO HAZARDOUS CHEMICALS IN LABORATORIES
Chemical-hygiene planEmployee information and trainingMedical examinations and consultationMethods of control and personal protective
equipmentSafeguards for particularly hazardous substancesHazard identificationRecordkeeping
PPE- INTRODUCTION
What is PPE………?
Personal Protective Equipment (PPE)
PPE means the equipment that is worn to limit exposure to potentially harmful substances or conditions.
DEFINITIONS OF PERSONAL PROTECTIVE EQUIPMENT (PPE)
Equipment (devicesor clothing) worn to help isolate a worker
from direct exposure to hazardous material / condition / environment
Clothing, equipment and or substance which, when worn or used
by people as a barrier between themselves and the hazard correctly, it
may protect part or all of the body from foreseeable risks of injury or
disease at work or in a workplace
Note: The success of this control is dependent on the protective equipment being chosen correctly,
as well as fitted correctly and worn at all times when required
PRINCIPLES OF PPE PROTECTION
“Prevent contact between the hazards and the internal or external parts of the body to be protected”.
PPE - INTRODUCTION
The significant of PPE
To protect an employee against hazards including impact, heat or cold, harmful chemicals, dust and others.
Mr safety…the figure is too blur…I can understand it!
Don’t worry….Later, I will explain one by one….Now I want you to Know……PPE can protect you from head to Toe!
PPE - TYPES
Hard hat
Safety glasses, goggles
Gloves
Earplugs, earmuffs
Safetyand
shoes boots
Face shield
Respirators
PPE-Typical Hazards
May causes for head injuries if:-Objects falling from above such as tools.Bumping head against objects such as pipe or beam. Direct contact with exposed electrical wiring or components
May causes for eye injuries if:- Dust and other flying particles such as metal shavings or sawdust. Corrosive gasses, vapors and liquids. Molten metal that may splash. Intense light from welding and lasers.
May causes for body injuries if: Intense heat. Impact from radiation, hazardious chemical, etc.
Types of control – Last Resort Approach
Other methods not feasible or practicable.
Its use cannot be substituted by any other means. i. Emergency situation or rescue work. ii. Close or direct contact is necessary to carry out work. iii. During cleaning or maintenance operations.
Temporary measure.
As a back-up or complement.
Correct usage of PPE
Suitability (Fitting, size)ConsistentCompatibility of PPEErgonomic and other factorsMaintenanceAs a final line of defense
“ PPE should not be the first option of control”
Limitation May not provide the degree of protection obtained
during laboratory testing May not be comfortable May create a new hazard in itself Protection offered is difficult to measure Effectiveness often depends on `good fit’ with
workers
If PPE is used as the first option without reducing hazard at source:
Risk to workers if PPE fails and failure not detected. Cause employees to believe they are "safe“ and may take
higher risks. Result in worse consequences if people fail or forget to wear
equipment. Will shift the responsibility for safe working condition from
the employer to the employee.
2 Main reasons why employees are required to be provided with and to use PPE on a certain task;
Hazard and risk control
Legal requirement
REGULATORY REQUIREMENTSOCCUPATIONAL SAFETY AND HEALTH ACT, 1994(Act 139)Part IV –General duties of employee & self-employed personSection 15 (1) –it
shall be the duty of employer & every self-employed person to ensure, so far as practicable, the safety, health & welfare at work of all his employees
OCCUPATIONAL SAFETY AND HEALTH ACT, 1994(Act 139)Part VI –General duties of employees24. (1) It shall be the duty of every employee while at work-(c) to wear or use at all times any protective equipment or clothing provided by the employer for the purpose of preventing risks to his safety and health; and
OCCUPATIONAL SAFETY AND HEALTH ACT, 1994(Act 139)Occupational Safety and Health (Use and Standard of Exposure of Chemicals Hazardous to Health) Regulations 2000 or (USECHH 2000).
TYPES OF PPE
Classification of personal protective equipment
a. Based on protection of body parts/system-e.g: head, eye and face, hearing
b. Based on type of hazards- Protection against hazards -chemical, biological,
heat & cold- Protection against accidents - falls (safety belt);
splash protection (goggles)
Classification of PPE
Head protection Eye protection Hearing protection Foot protectionBody protection Respiratory protection
PPE SELECTION CRITERIA
Selection of PPE is dependent on: i. the hazard identification, ii. risk assessment, and iii. control measures
implemented PPE is used to: i. complement/combination of other control measure
PPE selected must be carried out under a PPE program PPE must be certified products to ensure acceptable level of
protection from hazards Limitations of PPE must be identified and adhered to
THE ELEMENTS OF PPE PROGRAM
Training on PPE Hazard recognition in the work environment What control measures can be taken The type of PPE suitable for use The limitations of PPE Demonstration of correct use Practicing using the PPE Cleaning, storing and maintaining PPE Use of PPE in dealing with emergencies
Cont..PPE-Typical Hazards
May causes for hear injuries if:- Too expose with noise enviroment.
May causes for foot injuries if:- Slippery surfaces. Hot or wet surface. Sharp object such as nails that might be pierce ordinary shoes.
May causes for hand injuries if:- Chemical exposers. Burning activities. Punctures, cutting activities, etc
PPE-General Control Measures
At early stage, the identification to assess the workplace to determine if hazards are present, or are likely to be present, which necessitate the use of PPE.
WHY?..............................
This determination need to define because to avoid any wastage.
Cont…PPE-General Control Measures
After selecting PPE, providing the training to the employees who are required to used it. THEN, PLEASE MAKE SURE what kind of training that might help them.
…..Why it necessary to our work activities….
….How it will protect us…..
….What are the limitations….
…How to clean and disinfect…
…What is its useful life & how is it disposed….
Implementation during work progress
During the construction daily work, employee need to wear suitable PPE and have to properly maintained and store it after used.
Cont…PPE-General Control Measures
PPE - SUMMARY Before selecting appropriate PPE, a careful hazard assessment should be performed to ensure that the PPE selected will protect against all relevant hazards.
When worn properly, PPE effectively reduces risk of injury or death due to exposure to workplace hazards.
Good implementations of PPE give a good effect to construction site safety…..
Eye, face, head, foot, hand and respiratory protection
Eye or face protection must be worn when exposed to hazards from flying particles, liquid chemicals,dusts, fumes or vapors.
Note that specialized eye protection is required for protection against hazards such as laser beams and welding
EYE AND FACE PROTECTION
Safety glasses Safety goggles Full-face shields
HEAD PROTECTION Hard hats are made of rigid, impact-resistant, non-flammable materials
such as fiberglass and thermoplastics. Protective helmets designed to reduce electrical shock hazard should be
worn if you are working near exposed electrical conductors. Thermal liners may be required if you work in extremely cold
temperatures. To keep your protective headwear in top condition, check it before and
after each use to make sure there are no cracks, signs of wear or discoloration.
Ensure that the straps are secure and working properly and that the hard hat fits your head securely.
FOOT PROTECTION
Reinforced Safety-Toe Shoes Reinforced Safety Boots Neoprene or Nitrile Boots Electrical Hazard Boots
HAND PROTECTION
Always wear gloves that are made of material that is resistant to the hazards in your workplace.
Before using gloves inspect for holes, tears signs of wear or other defects and replace if necessary.
You should also replace gloves periodically, depending on the frequency of use and in accordance with manufacturer’s recommendations.
After use, be sure to remove gloves before handling objects such as doorknobs, telephones, etc.
Disposable glove Fabric glove Laminate glove
RESPIRATORY PROTECTION
If you need respiratory protection to prevent overexposure to inhalation hazards you need to:
Select an appropriate respirator based on the specific chemical(s) you may be exposed to and the conditions under which that exposure occurs.
Have a medical evaluation to ensure that you are capable of wearing respiratory protection safely.
Attend training in the use, maintenance and limitations of the particular respirator that you will be using.
Have a fit test to ensure that the respirator fits properly.
Chemical protective clothing
INTRODUCTION
The purpose of chemical protective clothing and equipment is to shield or isolate individuals from the chemical, physical and biological hazards that may be encountered during hazardous material operations.
During chemical operations, it is not always apparent when exposure occurs.
Many chemicals pose invisible hazards and offer no warning properties
PROTECTIVE CLOTHING APPLICATIONS
Protective clothing must be worn whenever the wearer faces potential hazards
arising from chemical exposure, such as:
Emergency response
Chemical manufacturing and
process industries
Hazardous waste site cleanup
and disposal
Asbestos removal and other
particulate operations
Agricultural application of pesticides
“Within each application, there are several operations which require chemical protective clothing”. . .
Emergency response Rescue: entering a hazardous materials area for the purpose of removing
an exposure victim(special consideration on selected protective clothing may affect the ability of the wearer to carry out the rescue )
Spill mitigation: entering a hazardous material area to prevent a potential spill or to reduce the hazards from existing spill(protective clothing must accommodate the required tasks without sacrificing adequate protection)
Decontamination: applying decontamination procedures to personnel or equipment leaving the site(a lower level of protective clothing is used by personnel involved in decontamination)
THE CLOTHING ENSEMBLE
Checklist of components that may form the chemical protective ensemble:
Protective clothing (suit, coveralls, hoods, gloves, boots) Respiratory equipment (SCBA, combination SCBA/SAR, air purifying
respirators) Cooling system (ice vest, air circulation, water circulation) Communications device Head protection Eye protection Ear protection Inner garment Outer protection (overgloves, overboots, flashcover).
Factors that affect the selection of ensemble components include:
How each item accommodates the integration of other ensemble components. Some ensemble components may be incompatible due to how they are worn (e.g., some SCBA's may not fit within a particular chemical protective suit or allow acceptable mobility when worn).
The ease of interfacing ensemble components without sacrificing required performance (e.g. a poorly fitting over glove that greatly reduces wearer dexterity).
Limiting the number of equipment items to reduce donning time and complexity (e.g. some communications devices are built into SCBA's which as a unit are NIOSH certified).
CLASSIFICATION OF PROTECTIVE CLOTHING
Personal protective clothing includes the following:
Fully encapsulating suits (protects against splashes, dust, gases, vapors) Non-encapsulating suits (protects against splashes, dust and other
materials but not against gases and vapors) Gloves, boots, and hoods (protects against heat, hot water some
particles) Firefighter's protective clothing Proximity garment, or approach clothing (protects against splashes,
dust, gases and vapors) Blast or fragmentation suits (provides protection against very small
detonations) Radiation-protective suits (protects against alpha and beta particles but
not against gamma radiation)
RISKS
Heat stress - full body chemical protective clothing puts the wearer at considerable risk of developing heat stress. This can result in health effects ranging from transient heat fatigue to serious illness or death.
Heart rate - Count the radial pulse during a 30-second period as early as possible in any rest period. If the heart rate exceeds 110 beats per minute at the beginning of the rest period, the next work cycle should be shortened by one-third.
Oral temperature - Do not permit an end user to wear protective clothing and engage in work when his or her oral temperature exceeds 100.6°F (38.1°C).
Body water loss- The body water loss should not exceed 1.5% of the total body weight loss from a response.
DISCUSSION
summary- explanation for each part in a group-
submit report during class