FLOW OF HEAT

 

Syllabus:

Classification of heat flow processes :

Conduction:     Fourier’s law, Heat flow through a cylinder

Convection:      Natural convection, forced convection, surface coefficients, overall heat                                                 transfer coefficient. Heat transfer through boiling liquids, and condensing                                                 vapors.

Radiation:         Black body, Emissivity, Angle of vision in radiant heat flow, Radiation errors                            in thermometry.

Sources of heat energy

 

Classification of heat flow process

            When two objects at different temperatures are brought into thermal contact, heat flows from the object at higher temperature to the object at lower temperature. The mechanisms by which the heat may flow are three: conduction, convection and radiation.

Conduction

            When heat flow through a body without any observable motion of matter, the type of heat flow is called conduction.

Mechanism :

            In metallic solids, thermal conduction results from the unbound electrons (which is similar to the electrical conductivity).

            In solids that are poor conductor of heat and in liquids the heat is conducted by the transport of momentum of the individual  molecules along the temperature gradient.

            In gases the conduction occurs by the random motion of the molecules, so that heat is “diffused” from hotter regions to the colder ones.

Examples:

            Heat flow through the brick wall of a furnace or the metal wall of a tube.

Convection

            When heat flows by the transfer of matter, the type of heat flow is called convection.

In this case the heat flows by actual mixing of warmer portions with the cooler portions of the same material. Convection is restricted to the flow of heat in fluids. Heat flows through fluid by both conduction and convection and its is difficult to separate the two methods because of the eddies set up by the change of density with temperature.

Examples

            Transfer of heat by the eddies of turbulent flow and by the current of warm air from a room heater flowing across the room.

Natural and forced convection

            The forces used to create convection currents in fluids are two types.

Natural convection:

            When a fluid is heated the warmer part becomes lighter than the cooler part. Due to this difference in density the cooler (higher density) fluid moves down wards and the warmer (lighter density) move upwards and thus forming  a convection current. Thus heat is transferred with mass. This method of heat transfer is called natural convection.

Forced convection:

            If the current (or movement of fluid) is caused not by the density difference but by some agitator or by some mechanical devices then the type of heat flow associated with it is called forced convection.

Radiation

            When heat is transferred through the space by electromagnetic waves the type of flow of heat is called radiation heat flow.

When radiation is passing through empty space, it is not transformed into heat or any other form of energy nor it is diverted from its path.  If the radiation falls on a matter the radiation energy will be transmitted (i.e. pass through the matter), reflected or absorbed. Only the energy that is absorbed is converted into heat energy.

CONDUCTION

The basic law of heat transfer by conduction can be written in the form of the rate equation:

The driving force is the temperature gradient.

Fourier’s law

Fourier’s law states that the rate of heat flow through a uniform material is proportional to the area perpendicular to the heat flow (A), the temperature drop (dt) and inversely proportional to the length of the path of flow.

Consider an area A of a wall of thickness L. Let the temperature be uniform over the area A on one face of the wall. Both sides of the wall has a temperature gradient.  If a thin thickness dL, parallel to the area A, be taken at some intermediate point in the wall, with a temperature difference of dt across such a layer, then Fourier’s law may be represented by he equation:

                                           eqn 1

Where k = proportionality constant

If the temperature gradient dt/dL does not vary with time (this case is observed at steady state of heat flow) then the rate of heat flow is constant with time and

             eqn. 2

Since normally we know only the temperature at the two faces of the wall hence integrating the Fourier’s equation:                                                                      eqn. 3

On integration, if t₁ is the higher temperature than t₂.

                    eqn. 4

If A does not vary with L (i.e. the case of a flat wall) then equation 4 integrates to

             

or, by rearranging  we get                            or,    eqn. 5

In equation 5   Dt is the driving force and the resistance is  L / k A..

Thermal conductivity

            The proportionality in constant k in equation  is called the thermal conductivity (also called the coefficient of thermal conductivity) of the material of which the wall is made.

If          q          is expressed in Btu

            q          in hr

            A         in ft².

            t           in ⁰F and

            L          in ft

the unit of k will be :

The numerical value of the thermal conductivity depends upon

            (i) The material of which the body is made of

                        The thermal conductivities of liquids and gases are smaller compared to solids. For                         example at 212⁰F the thermal conductivity of

                                                            silver is 240 (Btu)(ft) / (hr)(ft²)(⁰F)

                                                            water is 0.35 (Btu)(ft) / (hr)(ft²)(⁰F) and

                                                            air is 0.017 (Btu)(ft) / (hr)(ft²)(⁰F)

            (ii) and upon its temperature.

                        The variation of thermal conductivity with temperature is meager (very small) but it is                  assumed that the variation is linear; that is:

k  =  a   +  b t

                        where a and b are constants and t is the temperature.

Compound resistances in series

Consider a flat wall constructed of a series of layers.

·        L₁, L₂, L₃ are the thickness of the layers.

·        K₁, K₂, K₃ are the thermal conductivities of the layers

·        Let the area of the compound wall, at right angles to the heat flow be A.

            Let t₀, t₁, t₂ and t₃ be the temperatures at the surfaces of the wall and at each junction according to the figure where t₀> t₁> t₂ > t₃ .

Therefore,        

            where, Dt₁ =  t₃  –  t₀.

                        Dt₁ =  t₁  –  t₀.

                        Dt₁ =  t₂  –  t₁.

                        Dt₁ =  t₃  –  t₂.

Again from Fourier’s law

Since all the heat passing through the first resistance must pass through the second and in turn, pass through the third, so q₁, q₂ and q₃ must be equal and all of them can be represented by q. From equation (1–4):

      = q R₁ + qR₂  +  qR₃.

      = q (R₁ + R₂ + R₃)

\        

If the equivalent resistance of the compound wall is R then

\         R = R1 + R₂  +  R₃.

HEAT FLOW THROUGH A CYLINDER

Let us consider the hollow cylinder represented by the figure.

r₁ = inside radius

r₂ = outside radius

t₁ = inside temperature

t₂ = outside temperature

N = length of the cylinder

km = mean thermal conductivity of the material of the cylinder

            It is desired to calculate the rate of heat flow through the wall.

Let us consider a very thin cylinder, concentric with the main cylinder with

            a radius r where            r₁ < r < r₂.

            the thickness of the wall of that cylinder is dr

            temperature difference across dr is dt

Then applying Fourier’s law over the thin wall will give:

                where A = total area of the thin wall

           

\        

or,       

or,       

or,       

or,                            

PRINCIPLES OF HEAT FLOW  IN FLUIDS

            Heat transfer from a warmer fluid to a cooler fluid, usually through a solid wall separating the two fluids, is found in different heat transfer equipment like heat exchangers, evaporators etc.

The heat transferred may be in the following forms:

(i)         latent heat accompanying a phase change such as condensation , vaporization

(ii)        sensible heat without any phase change.

Mechanisms of heat transfer through a fluid : Both by conduction and convection.

Heat flow from one fluid to another fluid separated by a solid wall

            For example a liquid is flowing through a pipe and that liquid is heated by a steam from outside the pipe. In this case heat will be transferred from steam to the liquid. Both steam and the liquid are having  Reynolds number above 4000 i.e. they are flowing in turbulent motion. In this case steam will produce a thin film on the outside surface of the pipe and the liquid will form another film at the inside surface of the pipe wall [because the flow is very slow near the solid wall hence in the film viscous flow will prevail]. Beyond these films the steam and the liquid are remaining in turbulent motion i.e. complete mixing is going on.

            Heat is transferred through this stagnant films by conduction and when it reaches the bulk of the fluid heat is mixed by forced convection. Since the bulk of the fluids are in great motion hence the heat transfer within the bulk is very rapid. Since the thermal conductivities of the fluids are low hence, although the films are very thin, the resistance offered by it to the flow of heat is very large.

Temperature gradients in forced convection

            Let us consider that heat is flowing from a hot fluid through a metal wall to a cold fluid.

·        The dotted lines F₁F₁ and F₂F₂ on each side of the solid wall is representing the boundaries of the films in viscous flow; all parts of the fluids to the right of F₁F₁ and to the left of F₂F₂ are in turbulent flow.

·        The temperature gradient from the bulk of the hot fluid to the metal wall is represented by the curved line t_at_bt_c.

The temperature t_a is the maximum temperature in the hot fluid (i.e. in the bulk of the fluid).

The temperature t_b is the temperature at the boundary between the viscous and turbulent flow.

The temperature t_c is the temperature at the actual interface between the fluid and the solid wall.

Similarly for fluid 2 the curved line is t_dt_et_f.

·        When a thermometer (or any heat sensing instrument) is inserted into the bulk of the fluid it will show a temperature t₁ and t₂ respectively for the two fluids. This t₁ is neither t_a nor t_b but this will be an average temperature and t_a < t₁ < t_b .  t₁ is shown as a straight line MM.

The same remarks will apply for fluid 2 also whose average temperature t₂ is represented by the line NN.

·        The temperature gradient t_dt_c is caused by the flow of heat in pure conduction through the solid wall and this (t_c – t_d) smaller than (t₁ – t₂).

Surface coefficients

            Since the thickness of the film is not known, the simple equation of conduction cannot be applied in this case. The difficulty is circumvented by the use of surface coefficient.

The surface coefficient on the hot side is defined by the relation

where,  h₁  = surface coefficient of the fluid on the hot side  [Btu/(ft^{2 0}F s)]

            q   =  amount of heat flowing from hot to cold fluid. [Btu / s]

            A₁ = area of the metal wall on the hot side in a plane at right angle to the heat flow.[ft²]

            (t₁ – t_C) = temperature gradient. [⁰F]

If we compare  equation with  then  it is evident that

h₁ is analogous to (k / L) and (1/h₁A₁ ) is the resistance term same as that of (L / kA) and h1 contains the effect of both the viscous film and of the thermal resistance of the turbulent  core that causes the temperature difference (t₁ – t_C).

In the same way h₂ may be defined as  

So the resistance imparted by the hot side = 1 / h₁A₁.

Resistance imparted by the metallic wall = L / kA_m.

Resistance imparted by the cold side =  1 / h₂A₂.

Overall heat transfer coefficient

If this resistances are substituted in the equation for compound resistance in series

then  

If the numerator and denominator are multiplied with A₁ then

So the overall heat transfer coefficient U₁ is defined by the equation

Therefore          q  =  U₁A₁Dt     states that the rate of heat transfer is the product of three factors: overall heat transfer coefficient (U₁), temperature drop (Dt), and area of heating surface(A₁).

For a tubular pipe A₁ = pD₁ l     where D₁ and l are the inner diameter and length of the pipe respectively. Similarly A₂ = pD₂ l and A_m = pD_m l .

So another form of overall heat transfer coefficient :

Analogous equation can be written for U_m and U₂.

Fluids in natural convection

            If a fluid is in contact with a heated surface. The fluid immediately adjacent to the tube will tend to rise because of its decreased density and to be replace by colder fluid. This fluid circulation caused by density differences due to the temperature differences in the fluid is termed natural convection.

The velocity of circulation of the fluid is dependent

            on the density differences

            on the geometry of the system, i.e. to the size, shape, arrangement of the heating surface

            and the shape of the heating vessel in which the fluid is enclosed.

For the simple case of a fluid outside a single horizontal cylinder with a large extent of fluid surrounding the cylinder, the heat-transfer coefficient for natural convection has been correlated by an equation containing three dimensionless groups the Nusselt number (Nu), the Prandtl number (Pr) and the Grashof number (Gr):

            Nu  =  y (Gr, Pr)

where ,       ,                    

where   h = average heat transfer coefficient, based on the entire pipe surface

            k_f = thermal conductivity of fluid

            c_p = specific heat of fluid at constant pressure

            r_f = density of fluid

            b = coefficient of thermal expansion of fluid

            g = acceleration of gravity

            DT_o = average difference in temperature between outside of pipe and fluid distant from wall

            m_f = viscosity of fluid

When hot bodies lose heat to their surroundings they do so both by radiation and convection. In the lower temperature range convection is more important, in higher temperature range radiation is more important.

Heat transfer through boiling liquids

            Consider a horizontal tube or a group of horizontal tube immersed in a pool of pure liquid with steam or other source of heat inside the tubes. DT is the difference in temperature between the tube wall temperature and the temperature of the liquid (under the pressure of the vapour space above the liquid).

·        When the DT is very small the rate of heat transfer is nearly similar to that of a non-boiling liquid.

·        As the DT is increased, the coefficient of heat transfer is increased rapidly because the stirring effect of the increasing number of bubbles released produces currents in the liquid that accelerates the heat transfer. This increasing coefficient multiplied with the increasing DT, results in an even more rapid increase in the total heat transferred per unit area.

·        However, if the temperature of the surface is continually increased, a point is found where the heat-transfer coefficient reaches a maximum.

·        At higher DT beyond the maximum value the heat transfer rate is sharply lowered. Actually the bubbles of vapour formed on the heating surface are discharged rapidly to rise through the liquid. This type of boiling is called nucleate boiling. At critical DT, these bubble coalesce into a continuous film of vapour that insulates the tube, and this reduces the heat transfer rate with increasing DT.

With polished horizontal tube in reasonably pure water, this critical point is reached at relatively modest value of DT, possibly 45 to 50⁰F. With rougher commercial steel tubes the critical DT is much higher.

            In case of nucleate boiling how easily the bubbles will leave the surface depends on the following factors:

·        roughness of the tube and the type of roughness: For instance a rough surface with small sharp projections makes it possible to detach bubbles from points more easily than from a smooth surface.

·        the tendency of the liquid to wet the tube: A liquid that wets the tube strongly tends to pinch off the bubbles of gas and liberate them more quickly than a liquid that does not wet the surface easily.

·        the difference in density between the bubble and the liquid

·        the physical arrangement of the surface: For instance, a vertical tube with bubbles rising inside it, will always show a much higher critical DT than a horizontal tube, with bubbles formed on the outside.

Heat flow through condensing vapours

            When a saturated vapour, such as steam, transmits its heat to a metal surface  and is condensed, the condensation  may take place in either of two entirely distinct forms. One is film type condensation and the other is drop-wise condensation.

Film-type condensation:

            In this case the condensed liquid wets the surface on which it is condensing and forms a continuous film of condensate. If the condensate is occurring on the outside of the tube then this film of condensate drops off the underside of the tube. If the tube is vertical then the condensate runs down the whole length of the tube.

For the case of a horizontal tube in true-film type condensation on which there is condensing a saturated vapour, free from any non-condensed gas and moving at low velocities, Nusselt has derived the following equation:

           

where   l = latent heat of vaporisation of vapor, Btu/lb

            r = density of condensate, lb/ft³.

            k = thermal conductivity of condensed vapor

            g = acceleration due to gravity (ft/hr²)

            m = viscosity of condensate film, (ft-lb-hr) units

            D = outside pipe diameter, ft

            DT  =temperature difference between vapor and metal, ⁰F.

For the case of a vertical tube with all other conditions same as above Nusselt has given the equation:

                         where L = the length of the tube.

·        The film coefficient between condensing vapors and metal walls increases with increasing temperature of the vapor, because of decreased viscosity of the film condensate.

·        Coefficient (h) decreases with increasing temperature drop, because increasing temperature drops cause faster condensation and hence thicker liquid films.

·        The presence of non-condensable gas accumulate near the heating surface and add to their resistance to that of the liquid film.

Drop-wise condensation

            In this case the condensed liquid does not wet the surface, but collects in drops that may range from microscopic size up to drops easily seen with naked eye. This drops grow for a while and then fall of the surface, leaving an apparently bare area in which new drops form again.

            These two types of condensation give widely different film coefficients of heat transfer. Coefficients in the case of drop-wise condensation is much more greater than those obtained in the film type condensation provided all other characteristics of the surface is the same.

RADIATION

            Any solid body at any temperature above absolute zero radiates energy. This radiation is an electromagnetic phenomenon and takes place without the necessity of any medium.

            The approximate range of wavelengths for infra-red radiation (or heat rays) is 0.8 to 400 mm.

            In industries, most of the cases, the thermal radiation corresponds to wavelengths from 0.8 to         25 mm.

The Black Body

            Not all substances radiate heat at same rate at a given temperature. So a theoretical hot body is defined, which is called ‘black body’.

Definition:        A ‘black body is defined as that body which radiates maximum possible amount of                         energy at a given temperature.

Example:          It has been shown that the inside of an enclosed space, at a constant temperature                                     throughout, viewed through an opening so small that the amount of energy escaping                       through the opening is negligible, corresponds to a black body.

Practical e.g.    In practice, a convenient black body is made from a tube of carbon plugged at both                         ends with a small observation hole in the center of one end.

Industrial e.g.   The inside of furnace at completely uniform temperatures, viewed through a small                                     opening, is a black body. The interior of the furnace and all the objects within the                                furnace can also be considered black bodies.

Rates of radiation

            If the radiation energy emitted by a hot body is plotted against the wave lengths emitted then graphs of the nature shown in the fig will be obtained.

            The total amount of radiation emitted by a black body would be given by integrating the curves of the figure (Effect of temperature on amount and distribution of black-body radiation) The result is the Stefan-Boltzmann law

                        q  =  b A T⁴.

where  

q = energy radiated per hour (BTU/hr)

A = area of radiating surface (sqft)

T = absolute temperature of the radiating surface ⁰R (Rankine) = t ⁰F + 460

For black bodies the value of b = 0.174 x 10 ^–8 Btu / (hr sqft ⁰F⁴)

No actual body radiates quite as much as the black body. The radiation by any actual body can be expressed as

                        q  = e b A T⁴.

where e is the emissivity of the body.

·        The emissivity is a fraction less than 1 and is the ratio of the energy emitted by the body in question to that emitted by a black body at the same temperature.

·        When a radiant energy falls on a cooler body either the energy is reflected or  transmitted or absorbed. The fraction of the radiation energy falling on a body that is absorbed is represented by a, the absorptivity, which is always less than 1. If the reflected energy can be neglected then the energy absorbed by any body is equal to the radiation falling on it.

·        It can be shown that the absorptivity of a given substance at a given temperature and its emissivity at the same temperature must be equal.

That is,                         e =  a

Since the e of a black body is 1 hence the a of the black body will also be equal to 1. Therefore the black body absorbs all the radiation falling on it – an important property of black body.

·        The value of a for a given surface at a given temperature varies some what with the wavelength of the radiation involved. To avoid complication due to this the concept of gray body has been introduced. The absorptivity of a gray body at a given temperature is constant for all wavelengths of radiation.

·        When a small black body of area A and temperature T₂ is completely surrounded by a hotter black body of temperature T₁, the net amount of heat transferred from the hotter body to the colder body is, therefore the algebraic sum of the radiation from the two bodies, so that Stefan’s law may be written for this case as

q  =  b A (T₁⁴– T₂⁴)

ANGLE OF VISION

            Let us consider a hot plate of indefinitely large extent is radiating heat. An element on this hot plate having an area of A  is radiating heat at the rate of  q  Btu/hr in every direction. In order to intercept all this radiation, a cooler body would need to subtend an angle of approximately 180 spherical degree (or 2p steradians), i.e. an hemisphere with the hot element as the centre.

So angle of vision is the solid angle subtended by a finite surface at the radiating element.

            The solid angle subtended by a hemisphere is 2p steradians. This is the maximum angle of vision that can be subtended at any area element by a plane surface in sight of the element. If the angle of vision is less than 2p steradians, only a fraction of the radiation from the area element will be intercepted by the receiving area and the remainder will pass on to be absorbed by other surfaces in sight of the remaining solid angle.

Figure shows several typical radiating surfaces:

(Fig. a) Two large parallel planes, one is a hot surface and the other is a cold surface. An area element on either plane is subtended by a solid angle of 2p steradians by the other. The radiation from either plane is intercepted by the other completely.

(Fig. b) A point on the hot body  sees only the cold surface, and the angle of vision (of the element on hot body) is again 2p steradians for the cold surface. Elements of cold surface can see the hot body and at the same time other portions of the cold body hence the angle of vision (of the element on cold body) is smaller for the hot body.

(Fig. c) A point on the hot surface can see the cold body as well as portions of the hot body, hence the angle of vision (of the element of hot body) is smaller than 2p steradians for the cold surface.

(Fig. d) The cold surface subtends a small angle at the hot surface, and the bulk of the radiation from the hot surface passes on to some undetermined objects situated at the background.

Square of the distance effect

The heat flow can be measured in two terms:    (1) Total heat flow (Btu/hr) and

                                                                        (2) Heat flow per unit area (Btu/hr/sqft)

The energy from a small surface that is intercepted by a large surface depends only upon the angle of vision.  In the above figure the cold surface may remain in any of the positions (I, II, III). The total amount of heat (Btu/hr) received by cold surface I will be equal to the cold surfaces II and III, since the angle of vision is same (2p steradians) in all the cases. But the amount of heat received per unit area of cold surface (Btu/hr/sqft) will differ and will decrease as the cold surface goes far away from the hot element.

Practical example

When a kettle (cold surface) is placed over a hot plate (hot surface) the angle of vision (of an element on the hot plate) will decrease with the distance of the two surfaces.

i.e f > q  So the amount of heat received per unit area of the kettle will be greater in the first case than that of the 2nd case and hence the temperature of the kettle in first case will be much more than the 2nd one.

            Projecting fins or ribs that tend to increase the cold surface do not absorb an increased amount of heat by radiation unless they increase the angle of vision of the cold surface.

Radiation error in thermometry

            Ordinary gases, free from smoke or visible flames, are practically transparent to radiation. When such gases are flowing through any pipe (or conduit) the temperature of the wall of the pipe is usually much cooler than the average gas stream.

            Now if any type of temperature measuring instrument is inserted into the gas stream , as the temperature of the instrument approaches the temperature of the gas it (temp. of the instrument) becomes higher than the temperature of the wall of the pipe. The instrument, therefore, immediately starts radiating heat.

            The instrument is heated by convection, and loses heat by radiation. At higher temperature, rate of heat loss by radiation is much more greater than that of convection. Hence, the instrument always shows a temperature less than the actual average gas temperature.

Remedy             Various means are available to reduce this loss by radiation though it never can be eliminated completely.

·        Radiation to the wall can be reduced by using polished metal for the wall of the pipe.

·        The measuring instrument itself, the bulb of the thermometer, the junction of the thermocouple, or other devices should be made of bright metal to make the device deviate as far as possible from a black body.

DOWN LOAD-----ORIGINALL-----FLOW OF HEAT

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