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Electrical. Introduction An average of one worker is electrocuted on the job every day There are four main types of electrical injuries: –Electrocution.

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Presentation on theme: "Electrical. Introduction An average of one worker is electrocuted on the job every day There are four main types of electrical injuries: –Electrocution."— Presentation transcript:

1 Electrical

2 Introduction An average of one worker is electrocuted on the job every day There are four main types of electrical injuries: –Electrocution (death due to electrical shock) –Electrical shock –Burns –Falls

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4 General Electrical Hazards High-voltage overhead power lines Damaged insulation on wires Digging or trenching near buried lines Broken switches or plugs Overloaded circuits Overheated appliances or tools Static electricity Flammable materials

5 Electrical Terminology Current – the movement of electrical charge Resistance – opposition to current flow Voltage – a measure of electrical force Conductors – substances, such as metals, that have little resistance to electricity Insulators – substances, such as wood, rubber, glass, etc., that have high resistance to electricity Grounding – a conductive connection to the earth which acts as a protective measure

6 Electrical Shock Received when current passes through the body Severity of the shock depends on: Path of current through the body Amount of current flowing through the body Length of time the body is in the circuit LOW VOLTAGE DOES NOT MEAN LOW HAZARD

7 Dangers of Electrical Shock Currents greater than 75 mA* can cause ventricular fibrillation (rapid, ineffective heartbeat) Will cause death in a few minutes unless a defibrillator is used 75 mA is not much current – a small power drill uses 30 times as much *mA=miliampere = 1,1/1000 of an ampere Defibrillator in use

8 Effects on the Human Body 1 mA: Can be felt by the body 2-10 mA: Minor shock, might result in a fall 10-25 mA: Loss of muscle control, may not be able to let go of the current 25-75 mA: Painful, may lead to collapse or death 75-300 mA: Last for 1/4 second, almost always immediately fatal

9 Body’s Resistance Skin offers most of the body’s electrical resistance Increased resistance –Thick and callused skin (foot or hand) –Dry skin Decreased resistance –Thin skin (inner forearm) –Wet or sweaty skin –Broken or abraded skin (scratches)

10 Resistance Varies Different levels of electrical resistance for each person Ranges from 500 ohms to many thousands of ohms The greater the body’s resistance, the less chance of harm A similar voltage shock can be minor to one person and deadly to another.

11 Additional Resistance Gloves Shoes Mats

12 How is an electrical shock received? When two wires have different potential differences (voltages), current will flow if they are connected together –In most household wiring, the black wires are at 110 volts relative to ground –The white wires are at zero volts because they are connected to ground If you come into contact with an energized (live) black wire, and you are also in contact with the white grounded wire, current will pass through your body and YOU WILL RECEIVE A SHOCK

13 How is an electrical shock received? (cont’d) If you are in contact with an energized wire or any energized electrical component, and also with any grounded object, YOU WILL RECEIVE A SHOCK You can even receive a shock when you are not in contact with a ground If you contact both wires of a 240-volt cable, YOU WILL RECEIVE A SHOCK and possibly be electrocuted

14 MCC Panel Video

15 Electrical Burns Most common shock-related, nonfatal injury Occurs when you touch electrical wiring or equipment that is improperly used or maintained Typically occurs on the hands Very serious injury that needs immediate attention

16 Falls Electric shock can also cause indirect or secondary injuries Workers in elevated locations who experience a shock can fall, resulting in serious injury or death

17 Hazards of Inadequate Wiring A hazard exists when a conductor is too small to safely carry the current Example: using a portable tool with an extension cord that has a wire too small for the tool –The tool will draw more current than the cord can handle, causing overheating and a possible fire without tripping the circuit breaker –The circuit breaker could be the right size for the circuit but not for the smaller-wire extension cord Wire Gauge WIRE Wire gauge measures wires ranging in size from number 36 to 0 American wire gauge (AWG)

18 Overload Hazards If too many devices are plugged into a circuit, the current will heat the wires to a very high temperature, which may cause a fire If the wire insulation melts, arcing may occur and cause a fire in the area where the overload exists, even inside a wall

19 Electrical Protective Devices These devices shut off electricity flow in the event of an overload or ground-fault in the circuit Include fuses, circuit breakers, and ground-fault circuit-interrupters (GFCI’s) Fuses and circuit breakers are overcurrent devices When there is too much current: –Fuses melt –Circuit breakers trip open

20 Ground-Fault Circuit Interrupter This device protects you from dangerous shock The GFCI detects a difference in current between the black and white circuit wires (This could happen when electrical equipment is not working correctly, causing current “leakage” – known as a ground fault.) If a ground fault is detected, the GFCI can shut off electricity flow in as little as 1/40 of a second, protecting you from a dangerous shock

21 Grounding Hazards Some of the most frequently violated OSHA standards Metal parts of an electrical wiring system that we touch (switch plates, ceiling light fixtures, conduit, etc.) should be at zero volts relative to ground Housings of motors, appliances or tools that are plugged into improperly grounded circuits may become energized If you come into contact with an improperly grounded electrical device, YOU WILL BE SHOCKED

22 Most people don’t realize that overhead powerlines are usually not insulated Powerline workers need special training and personal protective equipment (PPE) to work safely Do not use metal ladders – instead, use fiberglass ladders Beware of powerlines when you work with ladders and scaffolding 29 CFR 1910.333(c)(3) – Overhead Powerline Hazards

23 Some Examples of OSHA Electrical Requirements....

24 The path to ground from circuits, equipment, and enclosures must be permanent and continuous Violation shown here is an extension cord with a missing grounding prong 1910.304(g)(4) – Grounding Path

25 Hand-held electric tools pose a potential danger because they make continuous good contact with the hand To protect you from shock, burns, and electrocution, tools must: –Have a three-wire cord with ground and be plugged into a grounded receptacle, or –Be double insulated, or –Be powered by a low-voltage isolation transformer 1910.304(g)(1) – Hand Held Electric Tools

26 Installation and use. Listed or labeled equipment shall be used or installed in accordance with any instructions included in the listing or labeling. 1910.303(b)(2)(i) – General Requirements

27 Installation and use. Listed or labeled equipment shall be used or installed in accordance with any instructions included in the listing or labeling. 1910.303(b)(6) – General Requirements

28 Installation and use. Listed or labeled equipment shall be used or installed in accordance with any instructions included in the listing or labeling. 1910.303(b)(6) – General Requirements

29 Internal parts of electrical equipment, including busbars, wiring terminals, insulators, and other surfaces, may not be damaged or contaminated by foreign materials such as paint, plaster, cleaners, abrasives, or corrosive residues. 1910.303(b)(7)(iii) – General Requirements

30 There shall be no damaged parts that may adversely affect safe operation or mechanical strength of the equipment, such as parts are broken, bent, cut or deteriorated by corrosion, chemical action, or overheating. *Note frequently cited. 1910.303(b)(7)(iv) – General Requirements

31 Marking – Other markings giving voltage, current, wattage, or other rating as necessary. 1910.303(e)(1)(ii) – General Requirements

32 The width of working space in front of the electric equipment shall be the width of the equipment of 762mm (30in.), whichever is greater. In all cases, the working space shall permit at least a 90 ̊ opening or equipment doors or hinged panels; 1910.303(g)(1)(i)(B) – General Requirements

33 Except as elsewhere required or permitted by this standard, live parts of electric equipment operating at 50 volts or more shall be guarded against accidental contact by use of approved cabinets or other forms of approved enclosures or by any of the following: 1910.303(g)(2)(i) – General Requirements

34 Must guard live parts of electric equipment operating at 50 volts or more against accidental contact by: –Approved cabinets/enclosures, or –Location or permanent partitions making them accessible only to qualified persons, or –Elevation of 8 ft. or more above the floor or working surface Mark entrances to guarded locations with conspicuous warning signs 1910.303(g)(2)(i);1910.303(g)(2)(iii) – Guarding of Live Parts

35 In locations where electric equipment is likely to be exposed to physical damage, enclosures or guards shall be so arranged and of such strength as to prevent such damage. 1910.303(g)(2)(ii) – Guarding of Live Parts

36 Grounding Path – the path to ground from circuits, equipment, and enclosures shall be permanent, continuous, and effective. 1910.304(g)(5) – General Requirements

37 For a period not to exceed 90 days for Christmas decorative lighting, carnivals, and similar purposes; 1910.305(a)(2)(i)(B) – Temporary Wiring

38 Junction boxes, pull boxes and fittings must have approved covers Unused openings in cabinets, boxes and fittings must be closed (no missing knockouts) Photo shows violations of these two requirements 1910.305(b)(1) and (2) – Cabinets, Boxes and Fittings

39 Unused opening in cabinets, boxes, and fittings shall be effectively closed. 1910.305(b)(1)(ii) – Cabinets, Boxes and Fittings

40 All lamps for general illumination shall be protected from accidental contact or breakage by a suitable fixture or lampholder with a guard. Brass shell, paper-lined sockets, or other metal-cased sockets may not be used unless the shell is grounded. 1910.305(a)(2)(ix) – Wiring methods, components and equipment for general use

41 All pull boxes, junction boxes, and fittings shall be provided with covers identified for the purpose. Each outlet box shall have a cover, faceplate, or fixture canopy. Covers of outlet boxes having holes…shall have smooth, well rounded surfaces for the cords. 1910.305(b)(2)(i) – Covers and Canopies

42 Where a fixture canopy or pan is used, any combustible wall or ceiling finish exposed between the edge of the canopy or pan and the outlet box shall be covered with noncombustible material 1910.305(b)(2)(ii) – Covers and Canopies

43 1910.305(g) – Flex Cords and Cables More vulnerable than fixed wiring Do not use if one of the recognized wiring methods can be used instead Flexible cords can be damaged by: –Aging –Door or window edges –Staples or fastenings –Abrasion from adjacent materials –Activities in the area Improper use of flexible cords can cause shocks, burns or fire

44 Unless specifically permitted flexible cords and cables may not be used: As a substitute for the fixed wiring of a structure Where run through holes in walls, ceiling, or floors Where run through doorways, windows, or similar openings Where attached to building superfaces Where concealed behind building wall, ceiling, or floors Where installed in raceways, except as otherwise permitted. 1910.305(g)(1)(iv) – Flex Cords and Cables

45 Flexible cords and cables shall be connected to devices and fittings so that strain relief is provided that will prevent pull from being directly transmitted to joints or terminal screws. 1910.305(g)(2)(iii) – Flex Cords and Cables

46 Permissible Uses of Flexible Cords Examples Pendant, or Fixture Wiring Portable lamps, tools or appliances Stationary equipment-to facilitate interchange

47 Prohibited Uses of Flexible Cords Examples Substitute for fixed wiring Run through walls, ceilings, floors, doors, or windows Concealed behind or attached to building surfaces

48 Deenergizing electric equipment before inspecting or making repairs Using electric tools that are in good repair Using good judgment when working near energized lines Using appropriate protective equipment 29 CFR 1910.331-.335 Training employees working with electricity in safey work practices including:

49 Portable cord and plug connected equipment and flexible cord sets shall be visually inspected before use on any shift for external defects. Cord and plug connected equipment and flexible cord which remain connected with no damage need not be visually inspected until relocated. 29 CFR 1910.334 – Visual Inspection, Extension Cords

50 Hazard Control Electrical systems are inherently safe Injuries typically occur when: –Procedures are inappropriate –Procedures are not followed or ignored –Safety systems are circumvented

51 Arc Flash An explosive release of energy caused by an electrical arc.

52 Causes of Arc Flash Dust, impurities, and corrosion at contact surfaces –Produces heat, loosening contact and creating sparks –Sparks start arcs Sparks produced during –Racking of breaks –Replacement of fuses –Breakers/fuses closing into faulted lines Failure of insulating materials Snapping of leads at connection due to human, rodent or birds Accident touching/dropping of tools, nuts-bolts, or metal parts

53 Approach Distances and Flash Protection Boundary for Qualified Employees from Alternating Current Voltage (Phase to Phase) Minimum Approach Distance Flash Protection 300 Volts and less Avoid Contact0 ft. 10 in 480 Volts1 ft. 0 in.5 ft. 600 Volts1 ft. 0 in.5 ft

54 Labeling of Arc Flash

55 Arc Blast Protection Insulating gloves Rubber matting Insulating blankets Insulating hoods Insulating line hose Insulating sleeves FR clothing

56 Summary Hazards Inadequate wiring Exposed electrical parts Wires with bad insulation Ungrounded electrical systems and tools Overloaded circuits Damaged power tools and equipment Using the wrong PPE and tools Overhead powerlines All hazards are made worse in wet conditions Protective Measures Proper grounding Using GFCI’s Using fuses and circuit breakers Guarding live parts Proper use of flexible cords Training


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