Power and Grounding - Best Practices

Presenter
• Tom Kehr, CTS-D, CTS-I, ISF-C, LEED Green
Associate, Network+
• Since 1986, Tom has been involved in either designing,
installing, operating or purchasing audiovisual systems.
• Tom has also been heavily involved in church audio,
leading ministry teams and training volunteers in both
permanent and portable venues. In addition, he owned
a regional sound reinforcement company for over 16
years.
• Prior to joining InfoComm, Tom was a senior designer
for a large Washington, D.C. area firm. He is a member
of Syn-Aud-Con and AES and is a licensed amateur
radio operator.

Agenda
• To recognize best practices for power
and grounding systems for AV
systems
• To be able to discuss why these are
best practices

Outline
• Current pathways
• System Grounding
• Equipment Grounding
• Ground Faults
• Rack Grounding
• What to specify
• Ground Loops
• Noise Defense

Authority Having Jurisdiction
• Enforces codes and
regulations (Required)
• We can also apply:
– Standards
• Industry
• Client
– Best Practices

Avoid Ambiguous Terms
• Dedicated power
• Dedicated ground
• Clean power
• Dirty power
• Quiet ground
• Low or high voltage
• Technical power
• Technical ground

Use Electrician (NEC) Terms
• Panelboard
• Individual branch circuit
• Auxiliary Ground
• Isolated Ground

Panelboard
• Main service
panelboard
• Sub-panelboard

Circuit Theory
• Electricity seeks to go to ground

Circuit Theory
• “Electrical current is the unseen
movement of electrons that flow from
the power source through the electrical
circuit of the appliance or equipment and
then return to the power source. The
complete path the electrons take is
called the electrical circuit.” – Mike Holt,
“Basic Electrical Theory”

Circuit Theory
• All of the
electrons leaving
the source of
power go through
each component
in the circuit and
return to the
source

Electricity Goes To Ground?
• Let’s explore

Complete The Circuit
• Why have ground?

Circuit Theory
• Electricity always takes the path of
least resistance

Circuit Theory
• While more current
will flow through
the path of lesser
resistance, current
will take any and
all available
pathways
• Path could be an
unintentional path
– Safety
100,000Ω
1,000Ω
10Ω
I = V / R
1.2 mA = 120 / 100,000
120 mA = 120 / 1,000
12 A = 120 / 10

System Grounding
• The Grounded Conductor is frequently the Neutral and it is
the return path back to the electrical source

Lightning/Surges On Power Line

System Grounding
• Lightning, line surges and
unintentional contact with
higher voltage lines
• Reduce fires
• Protects the electrical
system

Equipment Grounding
• NEC: Non-current-carrying conductive materials … shall be
connected to earth

Ground Fault
• Current path during a ground-fault
• Connection to earth is not involved

Ground Fault
• Interruption of
Ground-Fault
Current Path
– Improper use of
Grounding
Adapter
• Not a “Ground
Lift Adapter”
– Not to be used
to solve hum and
buzz problems

Circuit Theory
• While the majority
of the current will
flow through the
path of lesser
resistance, current
will take any and
all available
pathways
• Path could be an
unintentional path
– Safety
100,000Ω
1,000Ω
10Ω
I = V / R
1.2 mA = 120 / 100,000
120 mA = 120 / 1,000
12 A = 120 / 10

• Common ground stud for all gear
Grounding Racks

Review -
• Current seeks to return to the source
• It will take any and all pathways
– One of the current carrying conductors
– Non-current carrying conductive materials
• Current pathway for a Ground Fault
– Do not use Grounding Adapters
• Proper Rack Grounding

Auxiliary Ground
• Auxiliary
Equipment
Grounding
Conductor
– Insures low
impedance
equipment ground
– Avoids depending
upon conduit
installation

Specify -
• Branch circuits
for “Audiovisual
Use Only” with
auxiliary
equipment
grounding
conductor

Ground Loops
• A ground loop is a continuous conductive loop
– Formed by using the Equipment Grounding (safety)
Conductors of any two electronic devices and the
cable shield connecting those two devices
– Formed by the shields of two interconnecting cables
between any two electronic devices
– Normal, common
– Not always problematic

Noise Defense - Shielding
• Shield
–Metallic partition
–Works bidirectionally
• Contains
• Keeps out
–50 / 60 Hz
–Nearfield

• Magnetic Fields
– Uses any magnetically permeable material to absorb
and conduct magnetic lines of flux
• Magnetically permeable materials include:
– Iron, steel, nickel alloys
• Iron, steel, nickel alloys vary in their
permeability
– “Permeability” – Ability to conduct magnetic
fields

• Electric Fields
– Uses any electrically conductive material to absorb and
conduct electrical lines of force
• Electrically conductive materials include:
– Gold, silver, copper, aluminum, etc.
• Gold, silver, copper, aluminum, etc. vary in their
conductivity
– “Conductivity” – Ability to conduct an electrical
current
– Conductivity is the opposite of resistance

Noise Defense
• Balanced Interfaces
• CMR Specifications
– Lab measurement vs. “real world”
– Component tolerances create slight impedance
imbalances
– CMR specifications should be in accordance with
IEC Standard 60268-3

Noise Defense
Differential-Mode Signal Common-Mode Noise Common-Mode Noise with
Differential-Mode Signal

Review -
• Specify
– Individual branch circuits with auxiliary equipment
grounding conductors
• Ground loops
– Normal, expected
– Not all are problematic
• Noise Defense
– Shielding - What works and what doesn’t at 60 Hz
– Specify steel conduit
– Use balanced interfaces with quantifiable CMRR
specifications

What We Have Covered:
• Current pathways
• Ground Faults
• Rack Grounding
• What to specify
• Ground Loops
• Noise Defense

Power and Grounding - Best Practices

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