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Saturday, April 5, 2025

Hydraulic equations for non newtonian fluids

 Here the dydrualic equations for two knwon non newtonian fluids are presented. These are,

  • the power law fluid and
  • the Bingham plastic fluid.

These equations are to be focus on the flow rate Q, the Reynolds number N_{Re} and the friction factor f_F, for the case of a fluid flowing through a pipe of circular section.

A comment on the friction factors

There are in fluid mechanics two different friction factors:

  • the Darcy friction factor
  • the Fanning friction factor

This is confusing if you are not aware of this fact. The Darcy friction factor (say f_F) and the Fanning's (say f_{FF}) are related as follows,

f_F=4\,f_{FF}

You should pay attention when using Darcy's equation for head loss since it is originally and commonly expressed in terms of f_F. This means that if you are using f_{F} the head loss can be found from:

h_L=2f_{FF}\dfrac{L}{D}\dfrac{V^2}{g}

In this post, the formulas for the newtonian fluid use the Darcy friction factor f_F while those for power law and plastic Bingham fluids use the Fanning friction factor f_{FF}.

Newtonian fluid

The flow rate Q is given by,

Q=\dfrac{\pi\,R^4}{8\mu}\dfrac{P_0-P_L}{L}        Eq. (01)

where R is the pipe internal radius and subscripts 0 and L indicate the end and final of the pipe.

The Reynolds number N_{Re} is given by,

N_{Re}=\dfrac{D\,V}{\nu}        Eq. (02)

The friction factor f_F,for laminar conditions N_{Re}<2000, is given by,

f_{F-L}=\dfrac{64}{N_{Re}}        Eq. (03)

for turbulent flow regime N_{Re}>4000 by,

\dfrac{1}{\sqrt{f_{F-T}}}=-2\log_{[10]}\left( \dfrac{\epsilon}{3.72D}+\dfrac{2.51}{N_{Re}\sqrt{f_{F-T}}} \right)        Eq. (04)

Power law fluid

The flow rate Q is given by,

Q=\dfrac{\pi\,R^3}{(1/n)+3}\left(\dfrac{\left(P_0-P_L\right)R}{2mL}\right)^{1/n}        Eq. (05)

where R is the pipe internal radius and subscripts 0 and L indicate the end and final of the pipe. Formula in Eq. (05) was taken from the familiar book Dynamics of Polymeric Liquids by Bird R. B. et al.

The Reynolds number N_{Re} is given by,

N_{Re}=\dfrac{(4n)^{n}\,D^n\,V^{2-n}\rho}{g_c\,m\,(3n+1)^n8^{n-1}}        Eq. (06)

where g_c=32.17\,lb_m/lb_f\,\cdot \,ft/s^2 is a units correction factor used in the Britsh units system. The density of the fluid \rho must be given in lb_m/ft^3. Equation (06) was taken from the article of Dodge and Metzner [AIChE J 1959 (2)].

The friction factor f_{FF}for laminar conditions N_{Re}<N_{Re-c}, is given by,

f_{FF-L}=\dfrac{16}{N_{Re}}        Eq. (07)

and for turbulent flow 4000<N_{Re}<10^5 regime by,

f_{FF-T}=\dfrac{0.0682\,n^{-1/2}}{N_{Re}^{1/(1.87+2.39\,n)}}        Eq. (08)

and for the transition region N_{Re-c}<N_{Re}<4000 by

f_{FF-Tr}=1.79\times 10^{-4}\exp\left[ -5.24\,n \right]\,N_{Re}^{0.414+0.757\,n}        Eq. (09)

Finally, the critical Reynolds number N_{Re-c} is defined as,

N_{Re-c}=2100+875(1-n)        Eq. (10)

Equations (07-10) were taken from the paper of Darby et al. [Chem. Eng. 1992 99 (9)].

Plastic Bingham fluid

The flow rate Q is given by,

Q=\dfrac{\pi\,R^3\tau_w}{4\mu_\infty}\left[  1 - \dfrac{4}{3}\left( \dfrac{\tau_0}{\tau_w}\right)+ \dfrac{1}{3}\left( \dfrac{\tau_0}{\tau_w} \right)^4 \right]        Eq. (11)

where R is the pipe internal radius, \mu_\infty is called the limiting viscosity and \tau_0 is the yield stress. Also, \tau_w

\tau_w=\dfrac{\left(\mathbb{P}_0-\mathbb{P}_L\right)R}{2L}        Eq. (12)

In Eq. (12) pressures \mathbb{P}_0 and \mathbb{P}_L include the hydrostatic contribution in an inclined pipe. Formulas in Eqs. (11-12) were taken from the familiar book Dynamics of Polymeric Liquids by Bird R. B. et alSubscripts 0 and L indicate the end and final of the pipe.

The Reynolds N_{Re} and Hedstrom N_{He} numbers are given by,

N_{Re}=\dfrac{D\,V\, \rho}{\mu_\infty}        Eq. (13)

N_{He}=\dfrac{D^2\,\rho\,\tau_0 }{\mu_\infty^2}        Eq. (14)

In this case the friction factor f_{FF} is given for all flow regimes as,

f_{FF}=\left( f_{FF-L}^m+f_{FF-T}^m \right)^{1/m}        Eq. (15)

where,

m=1.7+\dfrac{40000}{N_{Re}}        Eq. (16)

and the friction factors for laminar f_{FF-L} and turbulent f_{FF-T} regimes are:

f_{FF-L}=\dfrac{16}{N_{Re}}\left[ 1+\dfrac{1}{6}\dfrac{N_{He}}{N_{Re}}-\dfrac{1}{3}\dfrac{N_{He}^4}{f_F^3N_{Re}^7} \right]        Eq. (17)

f_{FF-T}=\dfrac{10^a}{N_{Re}^{0.193}}        Eq. (18)

a=-1.47\left[ 1+0.146\exp\left( -2.9\times 10^{-5}N_{He} \right) \right]        Eq. (19)

Notice that for plastic Bingham fluids there is no laminar-transition-turbulent regions reported, so that in order to find f_F you must solve numerically Eq. (15). However, you may read the manuscript of Swamee and Aggarwal [J. Pet. Sci. Eng. 2011 76] if you would like to know about an effort to give a critical N_{Re} for these fluids. Equations (13-19) were taken from the paper of Darby et al. [Chem. Eng. 1992 99 (9)].

Wednesday, March 26, 2025

On the vapor pressure data for different NaCl dilutions at different temperatures

 The data presented in this post were extracted from the International Critical Tables.

As is usual in evaporation operations the boiling temperature elevation (BPE) is a key data for engineering calculations. Then, the vapor pressure for different combinations of solute concentration and temperatures are to be combined with the Duhring approximation (Duhring's lines).

The data was just rewritten from the source previously mentioned.


Vapor pressure, mm Hg
Wt % 0.0 2.5 5.0 7.5 10.0 12.5 15.0 17.5 20.0 22.5 25.0 27.5
t °C
0 4.579 4.5 4.4 4.4 4.3 4.2 4.1 4.0 3.8 3.7 3.5
10 9.21 9.1 8.9 8.8 8.6 8.4 8.2 8.0 7.7 7.4 7.1
20 17.54 17.3 17.0 16.7 16.4 16.1 15.7 15.3 14.8 14.2 13.6
30 31.83 3.4 30.9 30.4 29.8 29.2 28.5 27.7 26.8 25.8 24.7
40 55..34 54.5 53.6 52.7 51.7 50.7 49.5 48.1 46.6 44.9 43.0
50 92.54 91.2 89.7 88.1 86.4 84.7 82.8 80.5 78.1 75.3 72.2
60 149.46 147.2 144.8 142.3 139.7 136.8 133.7 130.0 126.0 121.7 116.8
70 233.79 230.2 226.4 222.4 218.3 213.9 208.9 203.5 197.5 190.7 183.1
80 355.47 350 344 338 332 325 318 309.5 300.5 290.2 278.9 266
90 526 517 509 500 491 481 470 458 445.1 430 414 395
100 760 748 736 723 710 695 680 665 643 622 599 572
110 1075.4 1057 1040 1022 1003 983 961 936 911 881 849 810
B. P., °C 100 100.44 100.9 101.4 101.93 102.51 103.16 103.89 104.72 105.68 106.78 108.12

On the heat capacity for NaCl solutions

 This post is based on the results published by James C. S. Chou and Allen M. Rowe Jr. in their paper Desalination, 6(1969) 105-115.

For enthalply calculations the heat capacity is key. However, this last parameter depends on temperature and pressure, and in the case of dilutions on the concentration of solute.

From the thermodynamical point of view the formal relationship between enthalpy and heat capacity is expressed as,

h=h_0+\int_{T_0}^Tc_P\,dT+\int_{P_0}^P\left[ v-T\left( \dfrac{\partial v}{\partial T} \right)_P \right]dT    Eq. (01)

where the subscript 0 indicates a reference data or condition that must be known in order to estimate the data at another set of conditions (without subscripts). c_P and v are the heat capacity at constant pressure and the specific volume, respectively. Chou and Rowe provide math expressions for these two parameters (fortunately):

c_P=1.3041791 - 8.1519942x + 16.203997x^2 -\left( 0.19159475\times 10^{-2}\right.

\left. -0.029952864x+0.0037589577x^2\right)T+\left( 0.29944976\times 10^{-5} \right.

\left. -0.498581\times 10^{-4}x-0.89329066\times 10^{-6}x^2 \right)T^2        Eq. (02)

where x is the mole fraction and the temperature is given in K. The units of c_P are cal/g\,C. The specific volume is:


v=A(T)-P\, B(T)-P^2\, C(T)+w\, D(T)+w^2\, E(T)-wP\,F(T)

-w^2P\, G(T)-\dfrac{1}{2}wP^2\, H(T)        Eq. (03)

where w is the salt weight fraction in the solution and the remperature T must be given in K. The A through H temperature functions are defined as,

A(T)=5.916365-0.010357941T+0.92700482\times 10^{-5}T^2
-\dfrac{1127.5221}{T}+\dfrac{100674.1}{T^2}

B(T)=0.52049144\times 10^{-2}-0.10482101\times 10^{-4}T+0.83285321\times 10^{-8}T^2
-\dfrac{1.1702939}{T}+\dfrac{102.27831}{T^2}

C(T)=0.11854697\times 10^{-7}-0.65991434\times 10^{-10}T

D(T)=2.5166005+0.011176552T-0.17055209\times 10^{-4}T^2

E(T)=2.8485101-0.015430471T+0.22398153\times 10^{-4}T^2

F(T)=-0.0013949422+0.77922822\times 10^{-5}T-0.17736045\times 10^{-7}T^2

G(T)=0.0024223209-0.13698670\times 10^{-4}T+0.20303356\times 10^{-7}T^2

H(T)=0.55541298\times 10^{-6}-0.36241535\times 10^{-8}T+0.60444040\times 10^{-11}T^2

Finally, for the purpose of a reference situation we may take the data of enthalpy at 25\,C and pressure of 1\,atm. Again, Chou and Rowe provide an expression for it in the range of salt weight fraction w28.8524\% to 0.0006\%. This is,

h_0=24.953(1-w)+30.805561w^{1.5}-161.50632w^2

+79.059598w^{2.5}+114.83149w^3        Eq. (04)

where the enthalpy h_0 is given in cal/g\,solution.

Wednesday, February 19, 2025

Mechanical energy added to a fluid - A pump

 An important component of the general mechanical energy equation

\dfrac{p_1}{\gamma}+z_1+h_A-h_R-h_L+\dfrac{v_1^2}{2g}=\dfrac{p_2}{\gamma}+z_2+\dfrac{v_2^2}{2g}        Eq. (01)

is h_A since it represents the mechanical energy added to the fluid so that it can continue its trip through the pipe. At this point, two cases are visualized,

  • the energy h_A is one the system requires in order to the pipe system to do its work, and
  • the energy h_A is brought from the technical features of a real life pump, for example, so that the conditions of the pipe system are changed in turn.

Of course, in most technical problems both cases presented above are part of the solution in an iterative procedure.

What is the relationsip between h_A and a pump

Since the pump takes electrical energy and transforms it into mechanical energy to be later transferred into the fluid, these  two parameters should be related. This is done through the effeciency of the motor,

\mathbf{e_M}=\dfrac{Power\, output\, from \, the\, motor}{Power\, delivered\, by\, fluid}=\dfrac{P_O}{P_R}    Eq. (02)

where P_O is the mechanical power the motor so that the impeller may turn at certain speed with certain force and P_R is the power the fluid actually receives. Since part of the power P_O is wasted as heat or lost due to wearing of mechanical parts, P_O>P_R and as a consequence \mathbf{e_M}<1. If \mathbf{e_M}=1 you would have an impossible thermodynamical machine. P_O is a parameter measured and supplied, in the name plate, by pump manufacturers so that this data is easy to get.

Notice that Eq. (02) is the same if instead of a pump the case were that of a turbine (actioned by a mechanical energy of the fluid). We would be talking about h_R instead of h_A too.

For a centrifugal pump the power transferred into the fluid and the energy added h_A are related as follows,

P_R=h_A\gamma Q        Eq. (03)

where Q is the volumetric flow rate and \gamma a property of the fluid. Also, from Eq. (03) it is obvious that P_R would be very hard to measured. Therefore, it is more common to speak of the efficiency of a pump which we know is smaller than 1 but with present technological advances could be in the range of 0.8 - 0.9 for new equipments. Then, the usual case would be that P_R is unknown, so that,

P_R=\mathbf{e_M}P_O        Eq. (04)

and consequently, Eq. (01) becomes,

\mathbf{e_M}P_O=h_A\gamma Q        Eq (05)

From Eq. (05), h_A is isolated to be,

h_A=\dfrac{\mathbf{e_M}P_O}{\gamma Q}        Eq. (06)

In this way h_A can only be estimated if the efficiency of the pump \mathbf{e_M} and power of the motor of the pump P_O are known.

Friday, February 14, 2025

Fitting data to a power law equation

 This is a common task for experimentalists looking for relationship among data sets and groups of these.

The common feature of data behaving according to a power law equation,

y=\alpha\,x^\beta        Eq. (01) 

where \alpha and \beta are free parameters or parameters for adjustment is that once \ln y vs \ln x is plotted, a straight line is obtained.

Schematic representation of data behaving as power law Eq. (01) (left) and data producing a straight line in log log plot (right).

For short, rather than having to use logarithms to get data from a log-log plot, \alpha and \beta can be determined so that all data can be easily represented by Eq. (01).

How to determine the free parameters

Vey easy. Since in the log-log plot the curve becomes a straight line, it should have an equation like,

\ln y=m\, \ln x + b        Eq. (02)

where m is the slope and b is the ordinate at which the line cuts the axis. On the other hand, if operate with \ln on Eq. (01) we obtain,

\ln y=\ln\left| \alpha \, x^\beta \right|

\ln y = \ln \alpha + \beta\ln x        Eq. (03)

Next, comparison of Eqs. (02-03) leads to,

m=\beta and b=\alpha        Eq. (04)

Well, this is not all because the real question is not being answered, how can we estimate \alpha and \beta? Equation (4) is just a partial answered. A reliable way of finding m and b is by a linear regression using the minimum squares method so that the reader is then referred to,

Minimum squares method

I hope you can find this useful.

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