k0ua
Epic Contributor
Ah, the old "when is a wire not a wire" thing. When a wire is not a wire is when a wire is a resistor. And resistors oppose the flow of currents.
Here is an example. buy beg borrow or steal a 1000 ohm resistor. Place one end of it on a 12 volt battery. measure with your voltmeter neg to the neg of the battery, and positive to the positive of the battery and note the voltage. Somewhere around 12 volts right? Usually about 12.6 to 12.7 for a charged battery. But now measure the positive thru the 1000 ohm resistor. What will the voltage reading be? Will it be lower? nope still around that 12 volts thru that resistor. Change out that resistor for a 10, 000 ohm resistor, what will be the voltage? Still the same. How much current are we trying to pull thru those resistors? Very Very Very little. The current depends on the internal resistance of the meter itself.
Think about this, could we start our tractors thru that 1000 ohm resistor? No of course not, because we want to pull large amount of current from out battery and those resistors will resist the flow of large currents. So resistors don't seem to resist the voltage, they just resist the current. And when they resist the current, when we actually try to pull some current thru the circuit, we then see a huge voltage drop. This is explained very well by the equation E=IR. This equation was defined by a fella named Ohm. back in the 1700's. And it is called Ohm's law. Yeah, it is not just a good idea, it is the law!
So why do we try to start our tractors thru cables with high resistance? Wires are supposed to be wires right? Yeah, they were engineered to be the proper size, and to have low resistance by the tractor engineers, and they work really really well. Right up to the point they don't work like wires anymore and now they start working like resistors.
Why do they do that? Well it usually has to do with a thing called corrosion. A breakdown of the metallic connections in the wires with the terminals on the ends and sometimes even a total destruction of the metal in the cables by turning this metal into metallic salts. These are compounds that do not conduct currents worth a darn. They start to act just like those resistors we discussed earlier.
Corrosion is caused by exposure to the acid in the batteries themselves and water and oxygen in the air. This is a naturally occurring process that is going on all the time. If we can prevent these elements from getting to our battery terminals/clamps/wires, by liberal coatings of something like a grease we can greatly prolong the life of our battery cables.
As an example to the original poster , If he had coated his cable ends/terminals/battery posts with No-Ox-Id battery grease he would have never had the problem to begin with. His cables would have been as good as they day they were made. I have been telling people about this for years, about how I coat the battery cable ends, the terminals and the posts of the batteries with this grease of every new vehicle I get. I never have problems with corrosion. And I never will. And if you were to follow my example you never will either.
I learned the hard way in the telephony industry with our battery plants what that little jar of grease that was sent with every set of batteries we installed was for! Yep they actually included it. With instructions!.
Well, enough about my pontification of my vast knowledge of battery plants, and the old "ounce of prevention worth a pound of cure" thing. But I would advise you this:. Get a jar of NO-Ox-Id. and coat every battery post, every battery terminal, every battery cable and their crimped on ends, and the surface of the ground on the chassis, and the ground bolt and anything else metallic you want to never rust/rot/corrode and to stay like new. Ring! Ring!. Class is out!
Here is an example. buy beg borrow or steal a 1000 ohm resistor. Place one end of it on a 12 volt battery. measure with your voltmeter neg to the neg of the battery, and positive to the positive of the battery and note the voltage. Somewhere around 12 volts right? Usually about 12.6 to 12.7 for a charged battery. But now measure the positive thru the 1000 ohm resistor. What will the voltage reading be? Will it be lower? nope still around that 12 volts thru that resistor. Change out that resistor for a 10, 000 ohm resistor, what will be the voltage? Still the same. How much current are we trying to pull thru those resistors? Very Very Very little. The current depends on the internal resistance of the meter itself.
Think about this, could we start our tractors thru that 1000 ohm resistor? No of course not, because we want to pull large amount of current from out battery and those resistors will resist the flow of large currents. So resistors don't seem to resist the voltage, they just resist the current. And when they resist the current, when we actually try to pull some current thru the circuit, we then see a huge voltage drop. This is explained very well by the equation E=IR. This equation was defined by a fella named Ohm. back in the 1700's. And it is called Ohm's law. Yeah, it is not just a good idea, it is the law!
So why do we try to start our tractors thru cables with high resistance? Wires are supposed to be wires right? Yeah, they were engineered to be the proper size, and to have low resistance by the tractor engineers, and they work really really well. Right up to the point they don't work like wires anymore and now they start working like resistors.
Why do they do that? Well it usually has to do with a thing called corrosion. A breakdown of the metallic connections in the wires with the terminals on the ends and sometimes even a total destruction of the metal in the cables by turning this metal into metallic salts. These are compounds that do not conduct currents worth a darn. They start to act just like those resistors we discussed earlier.
Corrosion is caused by exposure to the acid in the batteries themselves and water and oxygen in the air. This is a naturally occurring process that is going on all the time. If we can prevent these elements from getting to our battery terminals/clamps/wires, by liberal coatings of something like a grease we can greatly prolong the life of our battery cables.
As an example to the original poster , If he had coated his cable ends/terminals/battery posts with No-Ox-Id battery grease he would have never had the problem to begin with. His cables would have been as good as they day they were made. I have been telling people about this for years, about how I coat the battery cable ends, the terminals and the posts of the batteries with this grease of every new vehicle I get. I never have problems with corrosion. And I never will. And if you were to follow my example you never will either.
I learned the hard way in the telephony industry with our battery plants what that little jar of grease that was sent with every set of batteries we installed was for!
Yep they actually included it. With instructions!. Well, enough about my pontification of my vast knowledge of battery plants, and the old "ounce of prevention worth a pound of cure" thing. But I would advise you this:. Get a jar of NO-Ox-Id. and coat every battery post, every battery terminal, every battery cable and their crimped on ends, and the surface of the ground on the chassis, and the ground bolt and anything else metallic you want to never rust/rot/corrode and to stay like new. Ring! Ring!. Class is out!
