4 Essential Ground Testing Methods - Fluke Corporation

What is ground resistance testing? It is a test done to measure the resistance between a grounding electrode and earth. Specialized earth testers, like the Fluke -2 FC Earth Ground Clamp and the Fluke -2 GEO Earth Ground Tester, are the troubleshooting tools built to make earth ground tests a lot easier. How do you perform ground testing? Depending on the situation you’re in and what kind of ground setup you’re looking at, there are four different methods of testing earth ground resistance available.

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• Stakeless testing
• Selective testing
• Soil resistivity testing
• Fall-of-potential testing

1. Stakeless earth ground testing

Stakeless testing uses only two clamps, one as a signal generator and one as a receiver, or one clamp like the -2 FC, to make the measurements . It entirely eliminates the need for temporary ground stakes and is very useful when stakes can’t be driven into the ground. It also eliminates the dangerous and time-consuming process of disconnecting parallel grounds and finding a safe place to drive the stakes.

The stakeless method is the preferred method when parallel grounds are present and temporary ground stakes would be difficult to be driven in the ground. The stakeless method can be done with just one tool: the -2 Earth Ground Clamp. Just clamp in on and measure away. You can use it both as a voltage generator and an amp clamp in one jaw. Plus, you can measure for low leakage current in a building at the same time.

You can also use this method with two clamps attached to a -2. The first clamp is placed around the ground conductor and generates a voltage. The second clamp measures the current flowing due to the voltage generated from the first clamp.

2. Selective earth ground testing

The selective testing method uses one clamp and two stakes. It allows you to measure the ground resistance at specific parts of an installation, isolating the system to check or reference what’s in place.

The selective testing method uses a current clamp while the electrode of interest is still under test. The clamp meter, like a Fluke -2, is used to isolate the test current injected into the electrode under test.

Two earth stakes are placed in the soil in a direct line away from the electrode of interest, usually spacing of 20 meters is sufficient. The clamp meter is connected to the electrode and the Earth Ground Clamp meter is placed around the electrode to eliminate the effects of parallel resistances in a ground system. This allows only the earth electrode of interest to be measured.

3. Soil resistivity earth ground test

The soil resistivity measurement method uses four stakes and is typically used before installing an earthing arrangement. The soil composition, moisture content, and temperature all impact the resistance measurements you’ll see, so this testing is necessary to determine the design when installing a new grounding system. Taking these steps to check out the site before figuring out the layout or building begins. Ideally, you’d want to find a location with the lowest possible resistance to work with. This is also used to reassess an environment after, for example, a drought.

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To test soil resistivity, connect the Fluke -2 to four stakes in the ground. The earth ground tester will generate a known current through the outer two stakes and the inner two will measure any drop in voltage potential. The tester then automatically calculates soil resistance using Ohms law.

4. Fall of Potential earth ground test

Fall of potential measurement uses two stakes and the electrode under test to prove the correct installation of a system, check the grounding system that’s already in place before building, or this type of test can be used as part of a continued maintenance program.

To run a test with this method, you first have to make sure the ground electrode of interest is disconnected from the site. Once that’s done you place two earth stakes in the soil in a direct line–line them up away from the earth electrode of interest, usually 20 meters apart is sufficient.

The -2 will generate a known current between the outer stake and the ground electrode while the inner stake measures for any drop in voltage potential.

Ground testing requirements

Ideally, the ground resistance of a system is zero ohms, but in reality, this isn’t always achievable. Both the National Fire Protection Association (NFPA) and IEEE recommend a ground resistance value of 5.0 ohms or less. But, when you dive further into the National Electric Code (NEC), section 250.56 says that you want to make sure the system to ground is 25.0 ohms or less. In facilities with sensitive equipment, it should be 5.0 ohms or less. It all boils down to a goal of achieving the lowest ground resistance possible that makes sense economically and physically.

The NEC also requires a minimum electrode length of 2.5 meters (8 feet) to be in contact with the soil in order to have a ground resistance system. But there are also four variables that affect ground resistance in a ground system:

• Length / Depth of the ground electrode: double the length, reduce ground resistance by up to 40%
• Diameter of the ground electrode: double the diameter, lower ground resistance by only 10%
• Number of ground electrodes: for increased effectiveness, space additional electrodes at least equal to the depth of the ground electrodes
• Ground system design: single ground rod to ground plate

Each electrode must also be the proper spacing between them to reduce or eliminate their spheres of influence. This will vary depending on the size and shape of the conducting material. The proper distance apart ensures the test stakes are not influenced by one another, or a ground system under test.

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Sir,

I would like to know what is the acceptable Insulation resistance of Neutral to Earth in a 3 Phase 380 VAC 4 wire ... where we get a 220 VAC supply from neutral to ground... 220 VAC is supplying computer, Lighting, water cooler and some CCTV loads

Are there any website that have this information?

Thank You very much The absolute minimum for a 220Vac system is 220Kohm. (the netherlands)
Afcourse you have to disconnect all equipment first when you start meassuring. The resistance can only be meassured with a megger (same as multimeter but meassures with 500Vdc) and this voltage kills a lot of equipment.

When you ask me you have a problem when the system gets down to 220Kohms. It's bether to find out where the low resistance value comes from. You will find something faulty in a system with 220Kohm.

Jurgen first of all, your question can be answered by reading the description details of your systems.Normally there is STANDARD color coding arrangements where you can get the ground base of what country you are..for I know Good Earth Ground must be High resistance,there are so many testers to test good ground it depends to the soil.if you are standing in the Poor resistance Ground.Just ask anybody here knows SOIL TREATMENT for good Grounding.The ground must be 0 Voltage!

diony_com
PHILIPPINES Resistance to ground

Unregistered said: Sir,

I would like to know what is the acceptable Insulation resistance of Neutral to Earth in a 3 Phase 380 VAC 4 wire ... where we get a 220 VAC supply from neutral to ground... 220 VAC is supplying computer, Lighting, water cooler and some CCTV loads

Are there any website that have this information?

Thank You very much

I think the question refers to what is acceptible resistance to ground of the "grounding electrode(s) system".

In USA the NEC (Nat'l Elecric Code) requires a second means (ie drive a second ground stake) of grounding if resistance from one means (metal water pipe or ground stake) is more than 25 ohm.

SO this leads me to interpret this as the resistance to ground must be 25 ohm or less.

Dan Bentler Insulation testing requires there be a certain amount of resistance per feet/meter. It is not as simple a process as connecting a megger and getting a zero volt reading.

This application guide from Fluke offers details of doing resistance testing.
http://www.fluke.com/Application_Notes/ElectricalPower/InsulTestAppNote2.pdf

Testing wiring and cable installations
​When testing wires or cables, they should be disconnected from panels and machinery to keep them isolated. The wires and cables should be tested against each other and against ground (see Figure 4 on page​4). The Insulated Power Cable Engineers Association (IPCEA)provides the following formula that suggests minimum insulation resistance values.​R = K x Log10 (D/d)​R​​- MΩs per feet (305 meters) of cable. Based on dc test potential of 500 volts, applied for one minute at 15.6ｰC (60ｰF)temperature)​K - Insulation material constant.(For example: Impregnated Paper-, Varnished Cambric-, Thermoplastic Polyethlene-, Composite Polyethylene-)​D - Outside diameter of conductor insulation for single conductor wire and cable D = d + 2c + 2b diameter of single conductor cable​d - Diameter of conductor​c - Thickness of conductor insulation​b - Thickness of jacket insulation​For example, one thousand feet of number 6 A.W.G. Heat Resistant Natural Rubber insulation type stranded conductor with 0.125 insulation thickness will have K = 10,560 and Log10 (D/d) = 0.373 inches. According to the formula (R = K x Log10 (D/d), R = 10,560 x 0.373 = 3,939 MΩ per feet) the expected minimum insulation resistance for single conductor per thousand feet at temperature of 60ｰF will be 3,939 MΩ​

The ICEA (formerly IPCEA) offers information concerning wire standards.
http://www.icea.net/Public_Pages/Documents/documents.html

In many cases the wire/cable data sheet may offer the expected insulation resistance.