Figure shows in cros section a wall consisting of four layers with thermal conductivities `K_(1)=0.06W//mK`
`K_(3)=0.04W//mK` and `K_(4)=0.10W//mK`. The layer thicknesses are `L_(1)=1.5cm,L_(3)=2.8` cm and `L_(4)=3.5cm` the temperature of interfaces is as shown in figure. energy transfer through the wall is in steady state.
Q. The temperature of the interface between layers 3 and 4 is

Figure shows in cros section a wall consisting of four layers with thermal conductivities K_(1)=0.06W//mK K_(3)=0.04W//mK and K_(4)=0.10W//mK . The layer thicknesses are L_(1)=1.5cm,L_(3)=2.8 cm and L_(4)=3.5cm the temperature of interfaces is as shown in figure. energy transfer through the wall is in steady state. Q. The temperature of the inteface between layers 2 and 3 is

Figure shows in cross section a wall consisting of four layers with thermal conductivities K_(1) = 0.06 W // mK, K_(3) = 0.04 W// mK and K_(4) = 0.10 W// mK . The layer thickness are L_(1) = 1.5 cm, L_(3) = 2.8 cm and L_(4) = 3.5 cm . The temperature of interfaces is as shown in figure. energy transfer through the wall is in steady state. the temperature of the interface between layer 3 and 4 is:

Figure shows in cross section a wall consisting of four layers with thermal conductivities K_(1) = 0.06 W // mK, K_(3) = 0.04 W// mK and K_(4) = 0.10 W// mK . The layer thickness are L_(1) = 1.5 cm, L_(3) = 2.8 cm and L_(4) = 3.5 cm . The temperature of interfaces is as shown in figure. energy transfer through the wall is in steady state. the temperature of the interface between layer 3 and 4 is:

Two bars of thermal conductivities K and 3K and lengths 1 cm and 2 cm respectively have equal cross-sectional area, they are joined lengths wise as shown in the figure. If the temperature at the ends of this composite br is 0^(@)C and 100^(@)C respectively (see figure), then the temperature phi of the interface is

A slab consists of two parallel layers of iron and brass 10 cm and 10.9 cm thick and of thermal conductivities 500 "Wm"^(-1) "K"^(-1) and 109 "Wm"^(-1) "K"^(-1) respectively. The area of opposite faces are 2m^(2) each and are at temperatures 373 K and 273 K. Find heat conducted per second across the slab and also the temperature of the interface.

Two parallel plates A and B are joined together to form a compound plate . The thicknesses of the plate are 4.0cm and 2.5cm respectively and the area of cross section is 100cm^(2) for each plate. The thermal conductivities are K_(A)=200Wm^(-1) C^(-1) for plate A and K_(B)=400Wm^(-1) C^(-1) for the plate B. The outer surface of the plate A is maintained at 100^(@)C and the outer surface of the plate B is maintained at 0^(@)C . Find (a) the rate of heat flow through any cross section, (b) the temperature at the interface and (c) the equivalent thermal conductivity of the compound plate.

Two materials having coefficients of thermal conductivity '3k' and 'k' and thickness 'd' and '3d' respectively, are joined to form a slab as shown in the figures. The temperatures of the outer surfaces are theta_(2) and theta_(1) respectively (theta_(2) gt theta_(2)) . The temperature at the interface is :

A slab consists of two parallel layers of copper and brass of the same thichness and having thermal conductivities in the ratio 1:4 If the free face of brass is at 100^(@)C anf that of copper at 0^(@)C the temperature of interface is .

A rod AB of uniform cross-section consists of 4 sections AC, CD, DE and EB of different metal with thermal conductivities K, 0.8,1.2K and 1.5 respectively. Their lengths are respectively L,1.2L, 1.5L and 0.6L . They are jointed rigidly in Succession at C, D and E to from the rod AB The end A is mainained at 100^(@)C and the end B is the maintained at 0^(@)C . The steady state temperatures p the joints C, D and E are respectively T_(C),T_(D) and T_(E) Match the following two columns

Five rods of same dimensions are arranged as shown in the figure. They have thermal conductivities K _(1) , K_(2) , K _(3) , K_( 4) and K_( 5) . When points A and B are maintained at different temperatures, no heat flows through the central rod if