Manuals/calci/Examples1
DESCRIPTION
- Basic Engineering examples in z3.
- Reflecting different domains like Engineering, Statistics, Medicine, etc.
- Set of cases that are progressively complex on units are used to show the user how it goes from simple to complex cases.
- Testing how we can make better solutions to the standard problems compared to other software, due to the presence of units.
Examples
ExampleS1: Chemical Engineering
An exhaust pipe is 75mm diameter and it is cooled by surrounding it with a water jacket. The exhaust gas enters at 350C and the water enters at 10C. The surface heat transfer coefficients for the gas and water are 300 and 1500 W/m2K respectively. The wall is thin so the temperature drop due to conduction is negligible. The gasses have a mean specific heat capacity Cp of 1130 J/kgK and they must be cooled to 100C. The specific heat capacity of the water is 4190 J/kgK. The flow rate of the gas and water is 200 and 1400 kg/h respectively. Calculate the required length of pipe for parellel flow and contra flow.
* The following example demonstrates how a problem is solved when units are used. * The units may be SI, Imperial or a mix of both. * Code shows how to assign a unit or convert a unit. * 3 types of calculations are shown: Normal, using Function, using Function1 in Function2.
z3 code: Normal Calculation without using Function
/*Overall Heat transfer coefficient
U = 1/((1/hg)+(1/hw)+(x/k))
//wall very thin. So, x ≈ 0
U = 1</>((1</>hg)+(1</>hw))*/
x = 0 //wall very thin
hg = 300(W/m2.degK) //heat transfer coefficient of water
hw = 1500(W/m2.degK) //heat transfer coefficient of gas
cpg = 1130(J/kg.degK) //mean specific heat capacity of gas (Cp)
cpw = 4190(J/kg.degK) //specific heat capacity of gas
mg = 200(kg/hr) //flow rate of gas
mw = 1400(kg/hr) //flow rate of water
D = 75mm //given exhaust pipe diameter
tg1 = 350degC<>degK //temp. of gas entering
tg2 = 100degC<>degK //temp. of gas to be cooled to
tw1 = 10degC<>degK //temp. of water entering
U = 1</>((1</>hg)<+>(1</>hw))
delt = tg1<->tg2
φ = mg<*>cpg<*>delt
tw2 = tw1<+>(φ</>(mw<*>cpw))
//Parallel flow
delti = tg1<->tw1
delt0 = tg2<->tw2
A = φ<*>(log(delt0</>delti))</>(U<*>(delt0<->delti))
L = A</>(π<*>D)
//answer:1.48m
//Contra Flow
delti = tg1<->tw2
delt0 = tg2<->tw1
A = φ<*>(log(delt0</>delti))</>(U<*>(delt0<->delti))
L = A</>(π<*>D)
//answer:1.44m
z3 code: Using Function
function LengthParallelContraFlow(hg,hw,cpg,cpw,mg,mw,tg1,tg2,tw1,D)
{
//Overall Heat transfer coefficient
//U = 1/((1/hg)+(1/hw)+(x/k))
var x = 0 //wall very thin
//U = 1</>((1</>hg)+(1</>hw))
var U = 1</>((1</>hg)<+>(1</>hw))
var delt = tg1<->tg2
var φ = mg<*>cpg<*>delt
var tw2 = tw1<+>(φ</>(mw<*>cpw))
//Parallel flow
var delti = tg1<->tw1
var delt0 = tg2<->tw2
var A1 = φ<*>(log(delt0</>delti))</>(U<*>(delt0<->delti))
var LParallel = A1</>(π<*>D)
//answer:1.48m
//Contra Flow
delti = tg1<->tw2
delt0 = tg2<->tw1
var A2 = φ<*>(log(delt0</>delti))</>(U<*>(delt0<->delti))
var LContra = A2</>(π<*>D)
//answer:1.44m
return [LParallel,LContra]
}
hg = 300(W/m2.degK) //heat transfer coefficient of water
hw = 1500(W/m2.degK) //heat transfer coefficient of gas
cpg = 1130(J/kg.degK) //mean specific heat capacity of gas (Cp)
cpw = 4190(J/kg.degK) //specific heat capacity of gas
mg = 200(kg/hr) //flow rate of gas
mw = 1400(kg/hr) //flow rate of water
D = 75mm //given exhaust pipe diameter
tg1 = 350degC<>degK //temp. of gas entering
tg2 = 100degC<>degK //temp. of gas to be cooled to
tw1 = 10degC<>degK //temp. of water entering
LengthParallelContraFlow(hg,hw,cpg,cpw,mg,mw,tg1,tg2,tw1,D)
z3 code: USING EXAMPLE1 function SOLUTION IN EXAMPLE2 function
function HeatTransferCoefficient(hg,hw)
{
//Overall Heat transfer coefficient
//U = 1/((1/hg)+(1/hw)+(x/k))
var x = 0 //wall very thin
//U = 1</>((1</>hg)+(1</>hw))
var U = 1</>((1</>hg)<+>(1</>hw))
return [U]
}
hg = 300(W/m2.degK)
hw = 1500(W/m2.degK)
HeatTransferCoefficient(hg,hw)
function LengthParallelContraFlow(tw1,mg,mw,cpg,cpw,tg1,tg2)
{
var delt = tg1<->tg2
var φ = mg<*>cpg<*>delt
var tw2 = tw1<+>(φ</>(mw<*>cpw))
//Parallel flow
var delti = tg1<->tw1
var delt0 = tg2<->tw2
var A1 = φ<*>(log(delt0</>delti))</>(HeatTransferCoefficient(hg,hw)<*>(delt0<->delti))
var LParallel = A1</>(π<*>D)
//answer:1.48m
//Contra Flow
delti = tg1<->tw2
delt0 = tg2<->tw1
var A2 = φ<*>(log(delt0</>delti))</>(HeatTransferCoefficient(hg,hw)<*>(delt0<->delti))
var LContra = A2</>(π<*>D)
//answer:1.44m
return [LParallel,LContra]
}
cpg = 1130(J/kg.degK)
cpw = 4190(J/kg.degK)
mg = 200(kg/hr)
mw = 1400(kg/hr)
tw1 = 10degC<>degK
tg1 = 350degC<>degK
tg2 = 100degC<>degK
LengthParallelContraFlow(tw1,mg,mw,cpg,cpw,tg1,tg2)
ExampleS2: Civil Engineering
A steel pipe 5 ft (1.5 m) in diameter and 3/5 in. (9.53 mm) thick sustains a fluid pressure of
180 lb/sq.in. (1241.1 kPa). Determine the hoop stress, the longitudinal stress, and the increase
in diameter of this pipe. Use 0.25 for Poisson’s ratio.
z3 code: Using Function
function HoopStress(p,D,t,E,v){
/*hoop stress
s = pD/2t
longitudinal stress
s'= pD/4t
increase in cyl diameter
delD = D(s-vs')/E */
var s = p<*>D</>(2<*>t)
var sdash = p<*>D</>(4<*>t)
var delD = D<*>(s<->v<*>sdash)</>E
return [s,sdash,delD<>inch]
}
p = 180(lb/sqin) // radial pressure
D = 5(ft) // internal diameter
t = (3/8)<>(inch) // wall thickness
E = 30e+6(lb/sqin) // modulus of elasticity for steel
v = 0.25 //poison's ratio
HoopStress(p,D,t,E,v)
ExampleS3: Civil Engineering
A 1/2-in. (12.7-mm) diameter Copperweld bar consists of a steel core 3/8 in. (9.53 mm) indiameter and a copper skin 1/16 in. (1.6 mm) thick. What is the elongation of a 1-ft (0.3-m) length of this bar, and what is the internal force between the steel and copper arising from a temperature rise of 80°F (44.4°C)? Use the following values for thermal expansion coefficients: cs = 6.5*106 and cc = 9.0*106 , where the subscripts s and c refer to steel and copper, respectively. Also, Ec = 15*106 lb/sq.in. (1.03*108 kPa).
z3 code: Normal Calculation without using Function
dc = 12.7(mm) // diameter of copperweld
ds = (3/8)<>(inch) // diameter of steel core
dcs = (1/16)<>(inch) // diameter of copper skin
Es = 30e+6(lbf/in2) // modulus of elasticity for steel
Ec = 1.03e+11(Pa) // modulus of elasticity for copper
cs = 6.5e-6(diffF-1) // coefficient of thermal expansion steel
cc = 9e-6(diffF-1) // coefficient of thermal expansion copper
L = 1(ft) // original length
delT = 44.4(diffC) // increase in temperature
//cross-sectional area
A = π<*>(dc)^2</>4
As = π<*>(ds)^2</>4
Ac = A<->As
//coeff of expansion
//c = ((As<*>Es<*>cs)<+>(Ac<*>Ec<*>cc))</>(As<*>Es<+>Ac<*>Ec)
a = (As<*>Es<*>cs)
b = (Ac<*>Ec<*>cc)<>(lbf.diffF-1)
d = (As<*>Es<+>Ac<*>Ec)
c = (a<+>b)</>d
//thermal expansion
delL = c<*>L<*>delT
//expansion w.o restraint
delLc = cc<*>L<*>delT
delLcs = delLc<->delL
delLs= cs<*>L<*>delT
delLsc = delL<->delLs
//restraining force
P1 = Ac<*>Ec<*>delLcs</>L
P2 = As<*>Es<*>delLsc</>L
z3 code: Using Function
function InternalForce(dc,ds,dcs,L,Es,Ec,cs,cc,delT){
//cross-sectional area
var A = π<*>(dc)^2</>4
var As = π<*>(ds)^2</>4
var Ac = A<->As
//coeff of expansion
//c = ((As<*>Es<*>cs)<+>(Ac<*>Ec<*>cc))</>(As<*>Es<+>Ac<*>Ec)
var a = (As<*>Es<*>cs)
var b = (Ac<*>Ec<*>cc)<>(lbf.diffF-1)
var d = (As<*>Es<+>Ac<*>Ec)
var c = (a<+>b)</>d
//thermal expansion
var delL = c<*>L<*>delT
//expansion w.o restraint
var delLc = cc<*>L<*>delT
var delLcs = delLc<->delL
var delLs= cs<*>L<*>delT
var delLsc = delL<->delLs
//restraining force
var P1 = Ac<*>Ec<*>delLcs</>L
var P2 = As<*>Es<*>delLsc</>L
return[P1,P2]
}
dc = 12.7(mm) // diameter of copperweld
ds = (3/8)<>(inch) // diameter of steel core
dcs = (1/16)<>(inch) // diameter of copper skin
Es = 30e+6(lbf/in2) // modulus of elasticity for steel
Ec = 1.03e+11(Pa) // modulus of elasticity for copper
cs = 6.5e-6(diffF-1) // coefficient of thermal expansion steel
cc = 9e-6(diffF-1) // coefficient of thermal expansion copper
L = 1(ft) // original length
delT = 44.4(diffC) // increase in temperature
InternalForce(dc,ds,dcs,L,Es,Ec,cs,cc,delT)
z3 code: USING EXAMPLE1 function SOLUTION IN EXAMPLE2 function
function CoefficientOfExpansion(dc,ds,dcs,Es,Ec,cs,cc){
//cross-sectional area
var A = π<*>(dc)^2</>4
var As = π<*>(ds)^2</>4
var Ac = A<->As
//coeff of expansion
//c = ((As<*>Es<*>cs)<+>(Ac<*>Ec<*>cc))</>(As<*>Es<+>Ac<*>Ec)
var a = (As<*>Es<*>cs)
var b = (Ac<*>Ec<*>cc)<>(lbf.diffF-1)
var d = (As<*>Es<+>Ac<*>Ec)
var c = (a<+>b)</>d
return[As,Ac,c]
}
dc = 12.7(mm)
ds = (3/8)<>(inch)
dcs = (1/16)<>(inch)
Es = 30e+6(lbf/in2)
Ec = 1.03e+11(Pa)
cs = 6.5e-6(diffF-1)
cc = 9e-6(diffF-1)
CoefficientOfExpansion(dc,ds,dcs,Es,Ec,cs,cc)
function InternalForce(L,delT,Es,Ec,cs,cc){
//thermal expansion
var delL = CoefficientOfExpansion(dc,ds,dcs,Es,Ec,cs,cc)[2]<*>L<*>delT
//expansion w.o restraint
var delLc = cc<*>L<*>delT
var delLcs = delLc<->delL
var delLs= cs<*>L<*>delT
var delLsc = delL<->delLs
//restraining force
var P1 = CoefficientOfExpansion(dc,ds,dcs,Es,Ec,cs,cc)[1]<*>Ec<*>delLcs</>L
var P2 = CoefficientOfExpansion(dc,ds,dcs,Es,Ec,cs,cc)[0]<*>Es<*>delLsc</>L
return [P1,P2]
}
L = 1(ft)
delT = 44.4(diffC)
Es = 30e+6(lbf/in2)
Ec = 1.03e+11(Pa)
cs = 6.5e-6(diffF-1)
cc = 9e-6(diffF-1)
InternalForce(L,delT,Es,Ec,cs,cc)
ExampleS4: Civil Engineering
M1 is a 4x4, F = 5500 lb (24,464 N), and Phi = 30°. The allowable compressive
stresses are P = 1200 lb/sq.in. (8274 kPa) and Q = 390 lb/sq.in. (2689.1 kPa). The
projection of M1 into M2 is restricted to a vertical distance of 2.5 in. (63.5 mm).
z3 code: Using Function
function NotchDesign(b,φ,P,Q,F,A){
//lengths
var AB = b</>DSIN(φ)
var AC = (b<*>DSIN(φ/2))</>DSIN(φ)
var BC = (b<*>DCOS(φ/2))</>DSIN(φ)
//stresses f1 and f2
var f1 = (F<*>DSIN(φ))</>(A<*>DTAN(φ/2))
var f2 = (F<*>DSIN(φ)<*>DTAN(φ/2))</>(A)
//allowable stresses
var N1 = P<*>Q</>((P<*>(DSIN(φ/2))^2)<+>Q<*>(DCOS(φ/2))^2)
var N2 = P<*>Q</>((P<*>(DCOS(φ/2))^2)<+>Q<*>(DSIN(φ/2))^2)
return[AC;BC;f1<>(lbf/sqin);f2<>(lbf/sqin);N1<>Pa;N2<>Pa]
}
b = 3.625(inch) // length
φ = 30(deg) // angle
P = 1200(lbf/sqin) // allowable compressive stress
Q = 2689.1e+3(Pa) // allowable compressive stress
F = 24464(N) // force
A = 13.1(sqin) // area
NotchDesign(b,φ,P,Q,F,A)
ExampleS5: Engineering Economics
The QRS Corp. purchased capital equipment for use in a 5-year venture. The equipment
cost $240,000 and had zero salvage value. If the income tax rate was 52 percent and the
annual income from the investment was $83,000 before taxes and depreciation, what was
the average rate of earnings if the profits after taxes were invested in tax-free bonds yielding 3 percent? Compare the results obtained when depreciation is computed by the straight-line method.
z3 code: Using Function
function RateOfEarnings(EC,n,GI,r,i){
//taxable income
var DC = EC</>n
var TI = GI<->DC
//annual tax payment
var TP = r<*>TI
//net income
var NI = GI<->TP
//S = R(USCA)
//SPCA = (1<+>i)^n
var s = NI<*>(5.309)
var sp = s</>EC
var i = [(sp^0.2)<->1]<*>100
return i
}
EC = 240000 // equipment cost
n = 5 // no. of years
GI = 83000 // gross income
r = 0.52 // income tax rate
i = 0.03 // tax free bonds yeild
RateOfEarnings(EC,n,GI,r,i)
ExampleS6: Fluid Mechanics
A steel pipe is discharging 10 ft3/s (283.1 L/s) of water. At section 1, the pipe diameter is 12 in. (304.8 mm), the pressure is 18 lb/sq.in. (124.11 kPa), and the elevation is 140 ft(42.67 m). At section 2, farther downstream, the pipe diameter is 8 in. (203.2 mm), and the elevation is 106 ft (32.31 m). If there is a head loss of 9 ft (2.74 m) between these sections due to pipe friction, what is the pressure at section 2?
z3 code: Using Function
function BernoullisPressure(d1,d2,p1,z1,z2,q1,q2,hf,w,g){
var a1 = π<*>(d1)^2</>4
var a2 = π<*>(d2)^2</>4
var v1 = q1</>a1
var v2 = q2</>a2
var p2 = (((v1^2<->v2^2)</>(2<*>g)<+>z1<->z2<->hf)<*>w)<+>p1
return p2<>(lbf/in2)
}
d1 = 12(inch)
d2 = 203.2(mm)
p1 = 124.11e+3(Pa)
z1 = 140(ft)
z2 = 32.31(m)
q1 = 283.1(L/s)
q2 = 10(ft3/s)
hf = 9(ft)
w = (62.4/(144*12))<>(lbf/inch3)
g = 32.2(ft/s2)
BernoullisPressure(d1,d2,p1,z1,z2,q1,q2,hf,w,g)