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Electrical Troubleshooting
Diagnosing Voltage Drop
One of the most rampant electrical maladies showing up
in automotive service bays today is the phenomenon known
as voltage drop. Left unchecked, voltage drop causes countless
unsolved electrical mysteries, especially when it infects
the ground side of a circuit. It can also trick you into
replacing parts that are not bad.
The more connections and wiring a vehicle has, the more
vulnerable the electrical system is to voltage drop.
To contain electrical voltage drop, practice safe electrical
service. This means measuring voltage drop before reaching
any conclusions. "Voltage dropping" a circuit tell you when
the circuit is too restricted to operate a component (motor,
relay, light bulb, etc.) or operate it correctly. If the
circuit is restricted, repair it and retest. If there is
no restriction and the component still does not run or run
correctly, then replace the component.
In this example, if the water pipe completely collapses,
water stops flowing, pressure drops to zero and the water
wheel stops turning. Electrically, the same thing happens
when a wire falls off or a connection breaks. Current stops
flowing, voltage drops to zero. A starter motor would quit
or a headlight would go out.
Symptoms of voltage drop
Often confusing and contradictory, electrical voltage drop
symptoms vary according to the circuit's job and the severity
of the voltage drop.
- inoperative electrical parts
- sluggish, lazy electrical devices
- erratic, intermittent devices
- devices that work sluggishly or erratically during periods
of high electrical loads
- excessive radio interference or noises in the radio
- damaged throttle or transmission cables or linkage
- repeated throttle or transmission cable failures
- damaged drivetrain parts
- engine or transmission performance complaints
- no-starts or hard starts
- high sensor or computer voltages
- erratic engine or transmission computer performance
- false trouble codes in the memory of any on-board computer
- premature or repeated A/C compressor clutch failure.
This symptom list brings up several points.
- Visual inspections miss most cases of electrical voltage
drop. You usually can't see the corrosion inside a connection
or the damaged wire that is causing the problem.
- Ground-side voltage drop, a commonly overlooked cause
of electrical trouble, can cause most of these symptoms.
Any circuit or component is only as good as its ground.
- The more sophisticated electrical systems become, the
more important their grounds are. The number of electrical
components has increased rapidly and most do not have
separate ground wires. Instead, these devices are grounded
to the engine or body. Rust, grease, vibration and/or
careless repairs often restrict the circuit from the engine/body
back to the battery.
- Many components such as engine sensors share a common
ground. Therefore, a bad ground complicates diagnosis
because it affects several components at once.
- Some shop manuals and diagnostic charts or fault trees
recommend checking grounds last. In reality, it is much
quicker to check ground circuits before you climb that
fault tree.
- It's quicker and smarter to routinely check a circuit's
voltage drop than it is to memorize long lists of symptoms.
If experience has taught us nothing else, it's that chasing
symptoms is no substitute for routine and thorough voltage
drop testing.
Experience has taught us other reasons to check voltage
drop first. Voltage drop, usually on the ground side, causes
inaccurate or bizarre voltmeter readings and oscilloscope
patterns. Moreover, when you connect a voltmeter or scope
to a system with bad grounds, the test equipment itself
can create a good substitute ground. This can be frustrating:
as long as your equipment is connected, the circuit works
and you can't find anything wrong!
Basic procedures
Whenever an electrical problem gives you fits, take a deep
breath and think of the basic electrical building block,
the series circuit. Drawings 1 through 7 show basic series
circuits. No matter how complicated a system is you can
always simplify it into mini-series circuits. Then, inspect
each circuit for voltage drop.
Also, relate electricity to water flowing through a water
circuit. Water pressure inside the reservoir pushes gallons
of water through the pipe. The water turns the water wheel
and then flows back into the reservoir. In an electrical
circuit, electrical pressure (voltage or volts) pushes electrical
volume (current or amps) through the circuit, operating
a load. The load may be a computer, a motor, a lamp, a relay,
or other device. In the water circuit, the water uses up
most of its energy turning the water wheel. Water continues
flowing toward the reservoir, but it flows at a lower pressure.
Likewise, electrical pressure (voltage) is used up operating
the load. Therefore, voltage falls to about zero on the
ground side, but current keeps flowing toward the battery.
Because the voltage in a healthy ground circuit should be
about zero, some technicians call it ground zero.
A kinked return pipe restricts water flow back to the reservoir,
slowing down the water wheel and causing a pressure reading
on the return side of the wheel. Likewise, ground side voltage
drop hurts load performance and causes a voltage reading
at the ground side of the load.
Resistance—Restriction
When you think of excessive resistance, imagine a dent or
kink that is restricting water flow through a pipe. Common
sense should tell you that a kink anywhere in the water
circuit (supply side or return side) restricts water flow,
causing the water wheel to slow down or stop turning.
Excessive resistance has the same effect on an electrical
circuit. Bad connections and broken or under size wires
act like a pipe with a kink, restricting current flow. Like
the water circuit, restricting current flow anywhere — hot
side or ground side — hurts the performance of the load.
The effect on the load is hard to predict because it varies
with the severity of the restriction. For example, the motor
in a restricted circuit may stop working or just run slower
than normal.
A restricted circuit can cause an A/C compressor clutch
to slip and prematurely burn out. A computer on a restricted
circuit may shut off or else work erratically. When corrosion,
loose connections or other types of resistance restrict
a circuit, volts and amps both drop. If volts drop, amps
drop too. That is why when you find a voltage drop in a
connection or cable, you know the connection or cable is
restricted.
Look at the water circuits in our drawings and remember
two critical points. First, a free-flowing ground side is
as important as a free-flowing hot side. Second, a ground
side restriction is the only thing that causes voltage readings
greater than 0–0.1V in any ground circuit.
A completely collapsed return pipe stops water flow, stalling
the water wheel and causing a system pressure reading at
the return side of the wheel. Likewise, a broken ground
wire totally blocks current flow, shuts off the load and
causes the ground side of the load to read system voltage.
Voltage drop tests
Electrical voltage drop varies according to current flow.
Unless you operate the circuit so current flows through
it, you can't measure voltage drop. Because an ohmmeter's
battery can't supply the current that normally flows through
most circuits, ohmmeter tests usually can't detect restrictions
as accurately as a voltage drop test.
Open-circuit problems such as broken or disconnected wires
or connections stop current flow. After you fix an open
circuit, switch the circuit on again and check for lingering
voltage drop. Until you get current flowing and check the
circuit again, you can't know if the entire circuit is healthy.
Although resistance-free connections, wires and cables
would be ideal, most of them will contain at least some
voltage drop. If your manuals do not list voltage drop values,
use the following as maximum limits:
- 0.00V across a connection
- 0.20V across a wire or cable
- 0.30V across a switch
- 0.10V at a ground
Because most computer circuits operate way down in the milliamp
range, they don't tolerate voltage drop as well as other circuits
do. Note that a milliamp is one-thousandth (0.001) amp. The
recommended working limit is 0.10V-drop across low-current
wires and switches. Testing low-current circuits also requires
a high-impedance (10-megohm) voltmeter. A low-impedance voltmeter
may load a low-current circuit so much that it gives an incorrect
reading or no reading whatsoever! Most professional-grade
digital multimeters (DMMs) have 10-megohm input impedance.
Using a DMM is the fastest way to accurately measure voltage
drops. If the DMM you own does not have autoranging capability,
use a low-voltage (0-1 V) scale for voltage drop testing.
Remember that test lights are not accurate enough to diagnose
electrical voltage drop.
Quick ground tests
Because ground circuit voltage drop can cause most of the
symptoms listed earlier, consider adopting this new work
habit: test grounds first! Before you do a tune-up, check
out electrical problems, or test a starting, charging, ABS
or air conditioning system, routinely test the engine and
body grounds. Connect your DMM between the engine and negative
battery terminal. Safely disarm the ignition and crank the
engine for a few seconds.
If the voltage drop is excessive, repair the engine ground
circuit and retest. Note that on some distributorless ignition
systems, the simplest way to prevent the engine from starting
during the ground test is to pull the fuel pump fuse. Next,
connect the DMM between the negative battery terminal and
the vehicle's firewall. Then start the engine and switch
on all the major electrical accessories. Too much voltage
drop? Then fix the body ground and retest.
Once engine and body grounds are within limits, proceed
with your diagnosis. Do not be surprised if fixing these
grounds solves the car's problems. The fact that a vehicle
passes the body ground test does not mean you can safely
ground your voltmeter wherever you want. Some technicians
have run themselves in circles for hours because their voltmeters
were not well grounded. For safe electrical service, make
yourself a 20- or 30- foot jumper wire with an alligator
clip on each end. When you have to test an electric fuel
pump, lighting system or ABS computer in the rear of the
vehicle, ground your DMM to the battery with the jumper
wire.
Computer ground kinks
Because computer circuits operate on such low current, the
standard ground tests may not reveal a marginal ground on
an on-board computer. Before you condemn any on-board computer,
check its grounds first. Operate the computer system and
backprobe each computer ground terminal. If you measure
anything greater than 0.10V, trace that ground circuit and
locate the problem.
Sometimes, computer grounds are connected to a spot where
they are easily disturbed or prone to corrosion, such as
a thermostat-housing bolt. Computer connector terminals
also can corrode. Removing the connector and spraying the
terminals with electrical cleaner may be all it takes to
eliminate the voltage drop.
Experience shows that as little as 0.30V on a computer
ground terminal can cause trouble. Try pinpointing that
with a test light! Poor computer and/or sensor grounds can
cause higher-than-normal sensor voltages and false trouble
codes. In many cases, the bad ground prevents the computer
or sensor from pulling a voltage signal down to or near
ground zero. Sure, accessing the computer to check grounds
may be a hassle. Nevertheless, mistakenly replacing expensive
sensors and computers is a bigger hassle.
Connect a DMM across part of a circuit and it directly reads
the voltage drop across that wire, cable, switch, or connection.
Here, one DMM would display the voltage loss between the
battery and the load. The other would show the voltage loss
from the ground side of the load to the battery.
Body ground gremlins
Keep your eyes peeled for missing body grounds. If someone
else worked on the vehicle, he may have forgotten to reconnect
body ground wires or cables. Remember that when the body
ground is restricted, current tries to find another route
back to the battery. The easiest alternate route may he
through the transmission shift cable or the throttle cable.
Not only can this current weld the cable together, it also
can pit or erode bushings and bearings inside the transmission.
If you find the insulation on the body ground wire is burnt
or blistered, you can bet that starter current overheated
the wire. When the engine ground is restricted, starter
current tries to return to the battery through the body
ground circuit. Experience shows that if the body ground
circuit can handle the current load, the customer may not
notice the problem right away.
Under periods of heavy current flow, a restricted body
ground may hamper or shut off a component. For example,
turn signals have been known to stop blinking when the driver
steps on the brake pedal. Testing confirmed that a restricted
body ground choked off the turn signals. The ground could
not handle current from the turn signals and brake lights
at the same time.
Safe service
Practicing safe electrical service helps you solve electrical
problems quicker and more profitably than guessing and swapping
parts. Put your DMM to work wiping out electrical voltage
drop today. It is the responsible thing to do.
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