1. TESTING GROUNDING SYSTEMS
Originally Developed by:
RONALD J. RENOWDEN - CMSP
Denver Field Office Supervisor, MNM MSHA
Rocky Mountain District
Denver, Colorado
Enhanced by:
Roy W. Milam
Electrical Engineer/Instructor
National Mine Health and Safety Academy
Beckley, West Virginia

2. TESTING GROUNDING SYSTEMS
As required by:
30 CFR §56/

3. 56/ the REG.
“Continuity and resistance of grounding systems shall be tested immediately after installation, repair, and modification; and annually thereafter. A record of the resistance measured during the most recent test shall be made available on request by the Secretary or his duly authorized representative.”

4. WHY DO WE TEST ?
Ensure that continuity & resistance tests are conducted on a specific schedule (at least annually)
Alert mine operators if there is a problem in the grounding system
Problem may not allow the circuit protective devices to quickly operate when faults occur

5. WHY DO WE TEST?
With exception of fixed installations - Numerous fatalities and injuries have occurred due to HIGH resistance or LACK of continuity in equipment grounding systems
Proper testing and maintenance of grounding systems can prevent electrical accidents
This all sounds so good that we made it the policy regarding

6. 56/ the POLICY
The intent of this standard is to ensure that continuity and resistance tests of grounding systems are conducted on a specific schedule. These tests will alert the mine operator if a problem exists in the grounding system which may not allow the circuit protective devices to quickly operate when faults occur. With the exception of fixed installations, numerous fatalities and injuries have occurred due to high resistance or lack of continuity in equipment grounding systems. These accidents could have been prevented by proper testing and maintenance of grounding systems.

7. P O L I C Y Grounding systems typically include the following:
1. equipment grounding conductors - the conductors used to connect the metal frames or enclosures of electrical equipment to the grounding electrode conductor;
2. grounding electrode conductors
- the conductors connecting the grounding electrode to the equipment grounding conductor; and
3. grounding electrodes
- usually driven rods connected to each other by suitable means, buried metal, or other effective methods located at the source, to provide a low resistance earth connection. P O L I C Y

8. P O L I C Y Operators shall conduct the following tests:
1. equipment grounding conductors - continuity and resistance must be tested immediately after installation, repair, or modification, and annually if conductors are subjected to vibration, flexing or corrosive environments;
2. grounding electrode conductors - continuity and resistance must be tested immediately after installation, repair, or modification, and annually if conductors are subjected to vibration, flexing or corrosive environments; and
3. grounding electrodes - resistance must be tested immediately after installation, repair, or modification, and annually thereafter. P O L I C Y

9. 56/ the POLICY
Conductors in fixed installations, such as rigid conduit, armored cable, raceways, cable trays, etc., that are not subjected to vibration, flexing or corrosive environments may be examined annually by visual observation to check for damage in lieu of the annual resistance test. When operators elect to conduct this visual examination as a method of compliance with 30 CFR56/ , MSHA will require that a record be maintained of the most recent annual visual examination.

10. 56/ the POLICY
Grounding conductors in trailing cables, power cables, and cords that supply power to tools and portable or mobile equipment must be tested as prescribed in the regulation. This requirement does not apply to double insulated tools or circuits protected by ground-fault-circuit interrupters that trip at 5 milli-amperes or less.

11. 56/ the POLICY
Testing of equipment grounding conductors and grounding electrode conductors is not required if a fail-safe ground wire monitor is used to continuously monitor the grounding circuit and which will cause the circuit protective devices to operate when the grounding conductor continuity is broken.

12. That’s all the policy! But what does it all mean ?
A record of the most recent resistance tests conducted must be kept and made available to the Secretary or his authorized representative upon request. When a record of testing is required by the standard, MSHA intends that the test results be recorded in resistance value in ohms.
That’s all the policy! But what does it all mean ?

13. TYPICAL GROUNDING SYSTEM has three parts
EQUIPMENT GROUNDING CONDUCTORS
(the most important part!!!)
Grounding Electrode Conductors
Grounding Electrodes

14. EQUIPMENT GROUNDING CONDUCTOR
The conductors used to connect the metal frames or enclosures of electrical equipment to the grounding electrode conductor
Life Wire; Life Line
Most important electrical safety item in the electrical system
People protector

15. GROUNDING BUS maybe in MCC
Equipment Grounding Conductors
GROUNDING BUS maybe in MCC
Motor 1
Motor 4
Motor 2
Motor 3

16. GROUNDING ELECTRODE CONDUCTOR
Conductor that connects the grounding electrode and the transformer to the equipment grounding conductor
TRANSFORMER
Main Ground Bus
maybe in the MCC
Earth
Grounding
Electrode

17. GROUNDING ELECTRODES
Usually driven rods connected to each other by suitable means, buried metal plates, or any other effective methods located at the power source to provide a low resistance earth connection.
What is actually in contact with Earth.
Grid
Rod

18. EQUIPMENT GROUNDING CONDUCTORS Test for Continuity and Resistance
Immediately after -
INSTALLATION,
REPAIR, OR
MODIFICATION, AND
ANNUALLY, IF conductors are subjected to
VIBRATION
FLEXING
CORROSIVE ENVIRONMENTS

19. GROUNDING ELECTRODE CONDUCTOR Test for Continuity and Resistance
Immediately after -
INSTALLATION,
REPAIR, OR
MODIFICATION, AND
ANNUALLY, IF conductors are subjected to
VIBRATION
FLEXING
CORROSIVE ENVIRONMENTS

20. GROUNDING ELECTRODES Testing
Test for Resistance (Earth)
Immediately after -
INSTALLATION,
REPAIR, OR
MODIFICATION, AND
ANNUALLY thereafter.

21. Are there EXCEPTIONS ? YES !!!
In lieu of doing annual resistance tests, the Grounds may be examined annually by visual observation to check for damage…..
BUT ONLY IF:
The conductors are in fixed locations such as;
RIGID CONDUIT
ARMORED CABLE
RACEWAYS
CABLE TRAYS, ETC (there’s more)

22. MORE EXCEPTIONS These FIXED LOCATIONS Vibration FLEXING CORROSIVES
MUST NOT be SUBJECTED TO:
Vibration
FLEXING
CORROSIVES

23. HOW MUCH IS TOO MUCH ?
FLEXING
VIBRATION
CORROSIVES

24. HOW MUCH IS TOO MUCH ?
The inspector makes the final determination concerning areas acceptable to visual examinations

25. IF VISUAL EXAMS ARE CONDUCTED
MSHA policy requires that a WRITTEN RECORD be maintained of the most recent ANNUAL VISUAL EXAMINATION, can be electronic

26. EQUIPMENT GROUNDING CONDUCTORS IN:
Trailing cables
Power cables
Cords supplying power to tools
Cords and cables supplying power to portable or mobile equipment
MUST BE TESTED AS PRESCRIBED IN THE REGULATION

27. When Is Testing NOT Required?
IF a fail-safe ground wire monitor is used. The monitor will cause the circuit protective device to open when the grounding conductor continuity is broken. It continuously monitors the continuity of the grounding conductor.
Double insulated tools are used. There is no grounding conductor to test.
If the circuit used incorporates a GFCI that trips at 5 milli-amps or LESS. There are 110v and 220v devices now available.

28. RECORDS RESISTANCE VALUES IN OHMS Most recent tests
Must be available for review by MSHA upon request
No specific format required
Be legible
Visual exam records

29. A little ADVICE ? Should have electrical knowledge
Know how to test and use the instrument/PPE
Know what kind of electrical system
Check circuit protective device vs. Ohms test
Check with power off
Proper size ground wire
Never let metal framework or earth be the primary grounding conductor
Never use peg grounding

30. NATIONAL ELECTRICAL CODE
Section EFFECTIVE GROUNDING PATH: The path to ground from circuits, equipment, and metal enclosures for conductors shall:
Be permanent and electrically continuous
Have capacity to conduct safely any fault current likely to be imposed on it, and
Have sufficient low impedance to limit the voltage to ground and to facilitate the operation of the circuit protective devices.
The earth SHALL NOT be used as the sole equipment grounding conductor

31. OK, now that the operator has tested his grounding circuit and recorded the results, what do we do with them?
In other words……

32. How do you know if the ground wire resistance is okay?
Can apply good old OHM’S LAW:
E = IR E = VOLTS I = AMPS (current) R = RESISTANCE (ohms) E I = R E I R

33. BUT …..FIRST ! Remember OHM’S LAW ! ( E = IR )
Circuits are protected by fuses/breakers against SHORT CIRCUITS AND GROUND FAULTS
IF GF occurs, we want the fuse/breaker to clear ASAP!
Question? Where does the current go when a ground fault occurs?
GROUNDING CONDUCTOR carries the fault current back to the SOURCE (current does not return to earth, but sometimes travels thru it).
FAULT CURRENT takes path of LEAST resistance?

34. CONTINUED
IF ground wire is missing or high resistance, current will flow in dangerous places to return to the source.
TOUCH AND STEP POTENTIALS MAY EXIST ON THE FRAMES OF EQUIPMENT AND ON THE EARTH
HAZARDOUS!!!!! : SHOCK, BURNS, ELECTROCUTION……..DEATH

35. EXAMPLE:
The operator’s record of resistance testing (in OHMS) shows the following:
Crusher motor = 1 ohm
Screen Deck = .5 ohm
Stacker main motor = 1.5 ohm
Conveyor = 1 ohm

36. Need: Circuit/System VOLTAGE:
Example:What’s Next ?
Need: Circuit/System VOLTAGE:
Motors supplied with 3 phase, 460 volt AC
Grounded WYE Service; Ø-Ø=460v; Ø-grd=265v
Need: Fuse/Circuit Breaker Size (for each)
100hp, 125amps, 300amps each (crusher motor)
40hp, 52amps, 100amps each (screen)
25hp, 34amps, 70 amp breaker (stacker)
10hp, 14amps, 30 amp breaker (conveyor 1)

37. GROUNDED WYE
Grounded WYE Service; 460 V, 3-PHASE ØA-ØB=460v; ØA-grd=265V ØA-ØC=460v; ØB-grd=265V ØB-ØC=460v; ØC-grd=265V
O A B A
O B C
O C
Ground
Ground

38. How good is the equipment grounding?
CONVEYOR 1: 1ohm, Ø-grd=265v.
How much FC will flow if GF at motor frame?
To find current (ohms law) I= E/R v I = =265 amp FC; On 30 amp 1ohm breaker
265a.(FC)/30a(bkr) = What’s this mean?
Breaker will TRIP almost instantaneous level ASAP
GOOD GROUNDING!

39. LET’S CHECK ANOTHER !
SCREEN: .5 ohms, Ø-grd=265v v I = =530 amp FC; On 100 amp ohm fuses
530a.(FC)/100a.(fu) = What’s this mean?
Fuse will not TRIP near instantaneous level (ASAP)
GOOD GROUNDING ? Questionable! Review trip curve chart for fuse to find trip time….
ADVICE: Check connections; loose, dirty, wire size? CORRECT/ REPAIR! Screens- flexing and vibration!

40. LET’S CHECK ANOTHER !
CRUSHER: 1 ohm, Ø-grd=265v v I = =265 amp FC; 300 amp fuses ohm
265a.(FC)/300a.(fu) = What’s this mean?
Fuse will not BLOW (must see at least 125% to begin)
DANGEROUS GROUNDING UNACCEPTABLE!
ADVICE: Check connections; loose, dirty, wire size? CORRECT & REPAIR! Crushers - flexing and vibration

41. Let’s make a small change!!!
CRUSHER: 1 ohm, Ø-grd=265v, but this time we’re going to use a 100 Amp, Magnetic Trip Circuit Breaker with a trip range of amps, set on LOW, as protection.
265v
I = =265 amp FC; CB set 150 Amps
1ohm
265a.(FC)/150a.(Inst.) = What’s this mean?
Breaker will TRIP instantaneously.
GOOD GROUNDING!

42. Corner Grounded Delta
Corner Grounded Delta Service; 460 V, 3-PHASE ØA-ØB=460v; ØA-grd=0V ØA-ØC=460v; ØB-grd=460V ØB-ØC=460v; ØC-grd=460V
O A B
O B C
O C A
Ground

43. Corner Grounded Delta CONVEYOR 1: 1ohm, Ø-grd=480v.
How much FC will flow if GF at motor frame?
To find current (ohms law) I= E/R v I = =480 amp FC; On 30 amp breaker ohm
480a.(FC)/30a(bkr) = What’s this mean?
Breaker will TRIP at instantaneous level ASAP
GOOD GROUNDING !

44. Corner Grounded Delta I = .5ohm =960 amp FC; On 100 amp fuses
SCREEN: .5 ohms, Ø-grd=480v v
I = .5ohm =960 amp FC; On 100 amp fuses
960a.(FC)/100a.(fu) = What’s this mean?
Fuse will TRIP near instantaneous level (ASAP)
GOOD GROUNDING !

45. Corner Grounded Delta
CRUSHER: 1 ohm, Ø-grd=480v v I = =480 amp FC; 300 amp fuses ohm
480a.(FC)/300a.(fu) = What’s this mean?
Fuse will start heating up. (must see at least 125% to begin) Will blow on very long delay.
DANGEROUS GROUNDING UNACCEPTABLE!
ADVICE: Check connections; loose, dirty, wire size? CORRECT & REPAIR! Crushers - flexing and vibration

46. FLOATING or UNGROUNDED SYSTEMS
BE AWARE!
HAZARDOUS- IF NOT MONITORED FOR GROUNDS AND MAINTAINED
ELECTRICAL SHOCK
THERMAL ARC FLASH BURNS
ELECTROCUTION
FIRES

47. Now let’s look at some of the test instruments that can be used to test the grounding system

48. Instruments used to test the grounding electrode

49. This is a Biddle Earth Tester that is battery powered
This is a Biddle Earth Tester that is battery powered. It uses 6 “C” cells. It is used to test the grounding electrode resistance.

50. This a type of Biddle Earth Tester that is battery powered
This a type of Biddle Earth Tester that is battery powered. It is powered by 4 “C” cells. It is used to test the grounding electrode resistance.
Measuring the resistance of the equipment grounding conductor for this piece of equipment.

51. This is a Biddle Earth Tester that is used to test the resistance of the grounding electrode. It is powered by the use of the hand crank on the side of the device.

52. This is the Field Kit that is used with an Earth Tester to measure the resistance of the grounding electrode. It contains 2 metal stakes, and 3 conductors of various lengths.

53. Set-Up for Testing Grounding Electrode Resistance
C1 P1 G P2 C2
Earth
Test Rods
Grounding Electrode

54. This person is driving a test rod to be used while testing the grounding electrode resistance.

55. This is the method used when testing the grounding electrode resistance with a Biddle Earth Tester.

56. The results obtained during the testing of the grounding electrode resistance are plotted on a graph. The actual resistance of the electrode is the flat part of the graph.

57. Another method of testing the resistance of the grounding electrode is using a voltage source, such as a vehicle battery, a voltmeter and an ammeter. We do not recommend this method as it can be extremely dangerous.

58. This is one possible set-up for testing the grounding electrode resistance.

59. This is the method used when testing the grounding electrode resistance with a Biddle Earth Tester.

60. Use OHM’S LAW to calculate the resistance values your tests found.
R=E/I

61. The results obtained during the testing of the grounding electrode resistance are plotted on a graph. The actual resistance of the electrode is the flat part of the graph.

62. This is the ECOS Pow-R-Mate Tester
This is the ECOS Pow-R-Mate Tester. It is used to test the resistance and impedance of the grounding electrode. It is both battery powered and plug-and-cord connected.

63. This is a Biddle Insulation Tester that is used to test the insulation value of conductors, motors, transformers, and cables. It is powered by the hand crank on the side of the device. This device should not be used to test the grounding electrode nor the equipment grounding conductors.

64. Instruments used to test the grounding electrode conductor and the equipment grounding conductors

65. This is a Fluke Graphics Multi-Meter which can be used to measure the resistance of the equipment grounding conductors.

66. This is a Fluke Multi-Meter which can be used to measure the resistance of the equipment grounding conductors.

67. This is a Simpson Multi-Meter which can be used to measure the resistance of the equipment grounding conductors. It is reading an open conductor now.

68. This is a Simpson Multi-Meter, with test leads attached, which can be used to measure the resistance of the equipment grounding conductors. It is reading an open conductor now.

69. This is a Simpson Multi-Meter, with test leads attached, which can be used to measure the resistance of the equipment grounding conductors. It is reading Zero ohms resistance as the test leads are contacting each other. The meter is being zeroed.