Re: Cable length

agarson · ‎Dec 10, 2015

Hi

How would I solve the following problem on cable length

Thanks

Two cables, both with cross sectional area 5 mm², are connected in parallel across a common DC voltage of E = 36 V.

The resistivity of Cable 1 is ρ = 17 x 10^-9 Ω.m at 20 °C, while the resistivity of Cable 2 is ρ = 28 x 10^-9 Ω.m at 20 °C.

Cable 1 is 1641 mm in length.

If 44.9 % of the current passes through Cable 1, determine the length of Cable 2.

Assume the ambient temperature is 20°C.

Fred_Kohlhepp · ‎Dec 10, 2015

You can use the current sharing ratio and Ohm's law to determine the relative resistance of the two cables. They're both the same area. Resistance is made up of resistivity cross-section area (the same) and length.

-MFra- · ‎Dec 14, 2015

LucMeekes · ‎Dec 14, 2015

I tend need to disagree.

Note that 44.9% and 50.1% do NOT add up to 100%...You're violating Kirchoff's law.

Also note that the resistivity is (correctly) given in nΩ.m, not in nΩ/m.

Luc

-MFra- · ‎Dec 15, 2015

Fred_Kohlhepp · ‎Dec 15, 2015

Check your math!

-MFra- · ‎Jul 23, 2016

The drawbacks of on-line haste ....

-MFra- · ‎Dec 15, 2015

Commonly the cables are made of copper.

I made the calculations based on this hypothesis.

it is obvious that if a cable is copper and the other is silver, resistivity and specific resistances are different.

Bye

LucMeekes · ‎Dec 15, 2015

I do not think the material name (i.e. copper) does matter in this case. The specific resistivity is given for each of the two cables, and they're different. If one is copper, the other isn't.

Your (now encircled) equation cannot be correct. If one cable carries 44.9% of the current, the other MUST carry the remainder, that is 1- 44.9 %= 55.1 %.

You draw a Z.L1 in your circuit. That is not given in the assignment; and it wouldn't matter if it were.

Luc

-MFra- · ‎Dec 15, 2015

Considering my hypothesis, (both cables copper), the calculations are correct. (Sorry, in the calculations I wrote 0.499 and not 0.449).

I believed that the applicant was referring to the specific resistance of each cable (and that he had made a mess) and not to the resistivity of each.

In the latter case, you're right.

LucMeekes · ‎Dec 15, 2015

OK.

I still have a problem with your definitions of rho.c1 and rho.c2.

The (specific) resistivity is a material property, commonly denoted by the greek letter rho, and it has the dimension Ohm * m, or sometimes Ohm * mm^2 /m to indicate that the resistance of a wire increases with length (in m) and is inversely proportional to the crossectional area (in mm^2). So never Ohm/m !

I've found one place (of many) where such resistivities of materials are given: Table of Resistivity.

With rho.copper given as 1.68*10-8 Ohm*m, it could be that cable 1 is of copper. Then cable 2's rho closely matches that of aluminum (2.65 *10^-8 Ohm * m.

Luc

-MFra- · ‎Dec 15, 2015

I'm a bit precipitous, which leads me into error. I'm sorry.

I rewrite the calculations, as had to be done. (the results are the same, though)

greetings Franc

LucMeekes · ‎Dec 15, 2015

OK.

Luc

agarson · ‎Dec 15, 2015

Hi

I have tried to copy what you have done but end up with undefined variable.What am I doing worng

Thanks

-MFra- · ‎Dec 15, 2015

Good evening Aaron Garson!

Do not worry, I am attaching the file

Greetings f. M.

LucMeekes · ‎Dec 15, 2015

It's because the variable (gamma2) you are trying to evaluate is actually not defined. It is only used in writing up equations involving a 'hard' equals sign "=", which means "is equal to". For definitions you must use an assignment symbol ":=", which you normally get by just typing the colon.

But besides that, you're not looking for that variable, gamma2 should be defined as 1-gamma1, where gamma1 in turn should be defined as 44.9%.

In the solve you're trying to get at x, and that variable should be available once you have defined gamma1 and gamma2 and L1 properly (define them just like you did nOhm, rho1 and rho2.

Success!
Luc

ppal · ‎Jul 21, 2016

Relevance of the copper - silver argument? Just use the data given - no need to infer the material.

ppal · ‎Jul 21, 2016

The 0.449 and 0.551 is the current split ratio.

All other numbers are self evident from your initial question.

You can spruce it up with a better labels and definitions.

AlvaroDíaz · ‎Jul 21, 2016

There are also a some cheat which can be do with this set of equations.

Actually, the "hide" is only for show the equations, but it not necessary.

Best regards.

Alvaro.

ppal · ‎Jul 21, 2016

Cable length is 1641mm not 1640mm

AlvaroDíaz · ‎Jul 22, 2016

I loose a milimeter attaching the wire to the battery 🙂

ppal · ‎Jul 22, 2016

There is also a physical impossibility problem with the way this question is drafted. The cables are NOT "connected in parallel across a common DC voltage of E = 36 V." They would have to be connected across a much lesser voltage. While not mentioned in the question the sketch shown in the replies show a Zl1 where most of the voltage would be dropped (which would be a real world connection). If the cables were connected across 36V they would have to carry approximately 2.87 million Amperes. Good luck with that.

AlvaroDíaz · ‎Jul 22, 2016

Hi. That's what mean a shortciruit. But still have some applications. For example, as lamp, with power about 250 kW for each wire, or to use the wires to cut something by heating them.

Also, a good time to remember that Ohm law isn't a true "law", it is a rule, which sometimes hold, but not always. If the wire explode, them Ohm law don't apply.

Best regards.

Alvaro.

ValeryOchkov · ‎Jul 22, 2016

A little remark from Mathcad Server - not ohm*m but ohm*m^2/m:

And second - do not use two different metals in one circle

-MFra- · ‎Jul 23, 2016

It seems that .... with these two cables .... we put "meat to cook" ...

Fred_Kohlhepp · ‎Jul 26, 2016

Don't need 36 Vdc, don't really need temperature.