Ravi Singh choudhary said:
View attachment 101776
Left side is copper bar and right side is steel. Neglecting the effect of thermal contact reisistance; If you consider this then diagram should be like below;
View attachment 101777
Above diagram is not an equilibrium diagram; equilibrium diagram would be simply horizontal line of 1000K.
As thermal conductivity of both the bars are different that means slope of temperature profile would be different inside bars.
Please correct me if I am wrong, #Mentors
Assuming a radially insulated bar - no heat flow in the y or z direction - heat flow only along the x-axis.
Assuming heat conduction of copper > heat conduction of steel.
assuming heat capacity of copper is < heat capacity of steel.
You do not give any time frame for your diagrams.
Nor a pick for the starting temperature of the bar(s).
If we take the top diagram, and have the initial temperature, T
0, of the bar(s) at time t
0.
If we assume T
0 at the bottom of the graph, then the temperature profile is what it would be 3/4 ( approxiametely, could be 7/8, but more than half way through to equilibrium ) of the time it would take the bar(s) to reach 1000 C throughout.
And NOT at t
o when the bars have the 1000 C applied to their ends.
The line from the left to the right, should have one slope for the copper, and a different slope for the steel, as the thermal conductivity and the thermal diffusivity for each are not the same.
The one correct thing is that the two lines left to right, and right to left, I would agree, should meet at the same temperature somewhere in the steel.
The bottom graph should have the temperatures profiles from the left and from the right meeting somewhere also in the steel. What you have is the heat flow abruptly stopping at the copper-steel junction. Not sure why - Did you put for some reason a perfect insulator there? Or a good choice you made that the contact resistance >> conductivity resistance?
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You should take note that there is such as thing as heat capacity as well as heat conduction. Both are properties of material. If we slice our hypothetical bar into sections, then before at any section of a material can conduct heat to the next section, it has to absorb heat. By absorbing heat, the temperature of the section will rise and only then can heat be sent along to the next section. Of course this does not happen in discrete steps but is a continious process, with the sections of width dx, and temperature between sections of dT.
At the start of applying the 1000 C, there is a large temperature difference from that to the first section, the slope dT/dx should be very steep. As time progresses, the slope should become more and more horizontal, until as you say, at equilibrium, the whole bar is at one temperature of 1000 C.
Having said that, at no time though, as time passes, is the temperature profile an exactly completely straight line from the 1000 C through to the sections of bar that have already been heated up to the particular section of the bar that is just beginning to heat up, ( at a lower dT/dx than precious sections ) , wherever that particular section be may be.
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Problem:
What if we assume:
heat conduction of copper > heat conduction of steel
but
heat capacity of copper > heat capacity of steel
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At the interview you may get a similar but not the same question.
- if the copper length is twice the length of the steel.
Your answer at the interview has to be flexible yet brief enough to show your knowledge on the subject matter at hand.
related terms:
heat conduction
heat capacity
thermal diffusivity.
general heat conduction equation
http://booksite.elsevier.com/samplechapters/9780123735881/9780123735881.pdf section 1.3 Page 6, Equation 1.12 page 7, Eq 1.29 Page 2
( Note that the equation is parabolic and not straight line )
see graph Fg 1.6 Note the logrithmic scaling of temperature
Good luck reinforcing your familiarity with the subject matter.
