HP-42S Mechanical Engineering - hpcalc.org
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Mechanical Engineering
Step-by-Step Solutionsfor Your HP-42S Calculator
(éfi HEWLETTPACKARD
Edition 1 October 1988
Reorder Number 00042-90022
Notice
This book and any keystroke programs contained herein are provided “as
is” and are subject to change without notice. Hewlett-Packard Company
makes no warranty of any kind with regard to this book or the keystroke
programs contained herein, including, but not limited to, the implied
warranties of merchantability and fitness for a particular purpose.
Hewlett-Packard Company shall not be liable for any errors or for
incidental or consequential damagesin connection with the furnishing,
performance, or use of this book or the keystroke programs contained
herein.
o Hewlett-Packard Company 1988. Allrights reserved. Reproduction,
adaptation, or translation of this book, including any programs, is
prohibited without prior written permission by Hewlett-Packard
Company; except as allowed under the copyright laws. Hewlett-Packard
Company grants you the right to use any program contained in this book
in a Hewlett-Packard calculator.
The programs that control your calculator are copyrighted and all rights
are reserved. Reproduction, adaptation, or translation of those programs
without prior written permission of Hewlett-Packard Company is also
prohibited.
Corvallis Division
1000 N.E. Circle Blvd.
Corvallis, OR 97330, U.S.A.
Printing History
Edition 1 October 1988 Mfg. No. 00042-90024
Contents
5 How To Use This Book
1 7 Forces and Vectors8 Vectors in the HP-4289 Using the "VEC" Program
13 Static Equilibrium at a Point
2 21 Equations of Motion
3 26 Analysis Programs27 Mohr Circle Analysis38 Soderberg’s Equation for Fatigue42 Composite Section Properties58 Spring Constant61 Linear or Angular Deformation
Contents 3
4 65 Thermodynamics66 Equations of State72 Black Body Thermal Radiation
5 78 Fluid Dynamics79 Conduit Flow85 Flow With a Free Surface
6 88 Unit Conversions89 Introduction97 Writing Your Own Unit Conversion Programs99 Dimensionless Units of Angle100 Conversion Factors
4 Contents
How To Use This Book
Please take a momentto familiarize yourself with the formats used in thisbook.
Organization. Each chapter in this book coversa different area ofmechanical engineering. Sections within each chapter highlight the use ofeach program. These sections are organized like this:
Description of the program, including equations and variables used.
m Special remarks and limitations.
m Generalinstructions.
m Keystroke examples.
® Program listings.
About the Examples. Unless otherwise stated, the keystrokes and
displays shown in each section assume the following conditions:
m The required programs have been keyed into your calculator.
m The stack is clear and youw’re starting with the default display format(FIX 4). Generally this does not affect the results of the example,except that your displays may not exactly match the onesin this book.
m The SIZE is set to 25 registers (the default). The number of storageregisters needed (if any) are listed under “Remarks.”
As you work the examples, also rememberthat lowercase letters aredisplayed as uppercase letters when they appear in menu labels.
How To Use This Book 5
If You Have a Printer. Many of the programs in this book will produce
printed output if printing is enabled. Press [J[PRINT) [A] = Fiit to
enable printing.
If you are not using a printer, be sure to disable printing (lJ{PRINT] (4]FOFE) to avoid losing results.
About Program Listings. It is assumed that you understand how to
key programs into yourcalculator. If you’re not sure, review part 2,“Programming,” in the owner’s manual.
If you print your programs, remember that the printer may print somecharactersdifferently than they are displayed. (For example, the +characteris printed as '..) Also note that some printers cannot print the
angle character ().
About the Subject Matter. Discussions on the various topics includedare beyond the scope ofthis book. Refer to basic texts on the subjects ofinterest. Many references are available in university libraries and intechnical and college bookstores. The examples in this book demonstrateapproaches to solving problems, but they do not cover the many waystoapproach general problems in mechanical engineering.
Our thanks to Dex Smith of TwentyEighth Street Publishingfor developing
this book.
6 How To Use This Book
Forces and Vectors
1: Forces and Vectors 7
Vectors in the HP-42S
The HP-42S can represent a vector in two ways: as a complex number or a
1 x n matrix. Of course, you can use matrices for all your work with
vectors. However, when you are working with coplanar vectors, there are
advantages to using complex numbers:
® You can see both parts (coordinates) of cach complex number. (The
contents of a matrix can only be viewed while editing the matrix.)
® You can enter and display complex numbersusing rectangular or
polar coordinates. (Vectorsstored as matrices are always in
rectangular coordinates regardless of the current coordinate mode.)
8 1: Vectors in the HP-42S
Using the “VEC”’ Program
The HP-42S provides most of the tools you will need for working withvectors. This program makes some of those tools easier to use byassigning them to the CUSTOM menu.
Remarks.
® The “VEC” program sets flag 27 to display the CUSTOM menu.
= Registers Rog, Ry;, and Ry, are used for temporary storage of the
matrix elements. Therefore, the SIZE must be set to at least 3 storageregisters (l(MODES] (V] =1ZE 3 [ENTER)).
Program Instructions.
1. Key the “VEC” program (listed on page 11) into your calculator.
2. Press WEGto execute the program.
3. Use the CUSTOM menu key assignments created by “VEC”forvector calculations.
0T calculates the dot product of the vectors in the X- andY-registers.
LROSEcalculates the cross product of the vectorsin the X- andY-registers.
UYELcalculates the unit vector of the vector in the X-register.
£T+[1 combines the coordinates in the X-, Y-, and Z-registers
into a 1 x 3 matrix in the X-register.
L3#5T returns the coordinates in a 1 X 3 matrix to the X-, Y-, and
Z-registers.
.FOL= switches to Rectangular mode. (Press :F.E{#to return toPolar mode.)
1: Using the VEC Program 9
Example. What is the unit vector of 10i —3j +17k?
WEL % 0, 000DI(RWT(WG
To enter the x-, y-, and z-coordinates into the X-, Y-, and Z-registers(respectively), enter the z-coordinate first.
17 [ENTER] 3 [*/] [ENTER] 10
x: 18_ROT)(eG
Put the coordinates into vector (matrix) form.
ST x: [ 1x3 Matrix 1]
oot[orozzfuvEc[ST+01]E35T]POLa
Calculate the unit vector.
HYED L w: 1x3 Matrix ]
Return the coordinates of the unit vector to the stack.
[135T %: B.96813o7JoRozz[uver[2T-0](1+:T]FOLA
The x-coordinate of the unit vector is 0.5013 (to four decimal places).
: -8, 1504[eoTJcross]uved[ST-0j01+2T]POLE |
They-coordinate of the unit vector is —0.1504.
x: 8. 8921I ABTS¥|RO
The z-coordinate of the unit vector is 0.8521.
10 1: Using the VEC Program
“VEC” Program Listing.
Program:
T fin] 126-Bute Fram I
- hox
"LOTY TO @1"CROSSY TO
"LMEST TO
TSTHCIT TO
"LI=+ZT" TO
o bx o
Py
BOODeT
fi
, ficx]
- %oL
S
ToLn
F IR
T [ o
. T00) SF 27
LEL “RECE"FOLARASSIGH "FOLe" TO @6RTH
-W
il
—_3
[y
o
LEL
FECT
HESIGH "RECs" T
FTH
i Fll:”_. i
- pex &
— n
LEL "ST=C31"
STO 848
F
STO @1
R4
=1 570 B2
22 FEe
e=eekT
L
oo
0)
24 EHTER
25 1
26 THDEX
=7 GETH
2 TRAMS
2 ETH
"REGS"
LEL "[J+=T"
IMLES "REGS™
TRAMNS
FLTH
F4
We[
24
Comments:
Makes CUSTOM menu keyassignments.
Stores theX-, Y-, and Z-registervaluesinto registers 00-02.
Gets a 3 x 1 submatrix from thestorage register matrix andtransposes it to a 1 x 3 matrix.
Transposes 1 x 3 matrix and puts itinto the storage register matrix.Recalls the vector elements fromregisters 00-02.
1: Using the VEC Program 1
,_..,.,_
Za
sy
1nn
-,-
eT
12 1: Using the VEC Program
Static Equilibrium at a Point
This program calculates the two reaction forces necessary to balancetwo-dimensional resultant force vectors. The direction of the reactionforces must be specified as an angle relative to the arbitrary axis.
ARo
: 0%,Y5)(%4¥4) 22
Rqcosf; + Rycosf, = YF cos¢g
Rysinf; + R, sinf, = YF sing
1: Static Equilibrium at a Point 13
Variables Used.
In Equations Description in Program
XF Sum of forces. EF
6, Angle of first reaction force. Rlg
6, Angle of second reaction force. R2a
Remarks.
® Angles arc entered and displayed using the current angular mode of
the calculator.
Since complex numbersare used for output, angles are normalized to
produce positive magnitudes.
A positive value of force (tension) points away from the origin; a
negative value (compression) points toward the origin.
The program produces an error ifR14 = R2A..
This program sets Polar mode.
Flags 21 and 55 are used to control printer output.
Program Instructions.
1. Key the “CF” program (listed on page 17) into your calculator.
2. Press | ZE 7 to execute the program.
3. Repeatthese stepsfor each force:
14
a. Key in the magnitude of the force; press [ENTER].
b. Key in the angle of the force (measured from the reference
axis).
c. Optional: press M{COMPLEX]. (If you skip this step, the
program automatically converts your inputs into a complex
number.)
d. Press .ZE# . to add the force. The current total force is
displayed after each force is added.
If you enter a force incorrectly, you can delete it by adding an equal
force in the opposite direction. If you notice the mistake
immediately after entering it, press SEEE
1: Static Equilibrium at a Point
4. Store the angles ofthe reaction forces:
a. KeyinR1X and then press "Fis .
b. Keyin R2X and thenpress « FZs .
5. Press ‘R1FEZ to calculate the reaction forces. (Press [¢] to clearthe results from the display.)
6. To work another problem, press CLZFto clear the accumulatedforces and start overat step 3.
Example 1: Balancing a Single Vector. Find the reaction forces inthe following diagram.
Ry
Set Degrees mode and run the “XF” program.
B(MODES] [ES SF=0, 0008 <0.0000
Enter the force vector.
75 135:ZF+ 3F=75.0000 <135.0000ZF+JELEF]Ris[Red [RiR2
1: Static Equilibrium at a Point 15
Enter the angles ofthe reaction forces.
30 Fld
R14=30.0000LZFe [cLZF[Ris(RS ][RiR2]
270 R2a R24£=278. 0008[EF+[CLZF]Ris[RES|RiRE)
Now,calculate the reaction forces.
ElRz
a. 8080S8.YA
Example 2: Forces in a Bridge Truss. Find the reaction forces in
structural members A and C. Assume pin connectionsat the joint.
120 Ib <€—D
Set Degrees mode and thenstart the program. (If you just worked the
previous example, you do not have to restart the program. Press € to
clear the message in the display and then press ELZFto clear the forces
accumulated above.)
BWMODES)
©
GED SF=0, 0000 <0, 0000TF [YPNG
Accumulate the forces.
100 45FF4
ZF=100.0000 £45.0008[ZFsJOLEF[Ris [R3S ][RiR2]
16 1: Static Equilibrium at a Point
120 [ENTER] 180 ZF+
Enter the angles of the reaction forces.
0 Fiz
180 45 [0 R
Calculate the reaction forces.
EiRZ
ZF=86.1942 «£124.8787IWIVIIY
R1<=0.08004LZFs[CLIF]Ris[Rae |—[rRiR2]
IR2&=135 . 0006 |LEF+[CLIF[Ris[Fs]| [RiR2]
=21.4214 «180.06800=1 g
1.421B8. 8008 £-45.0808
R1R2
Notethat for this problem, the reaction forcesare displayed in theopposite direction of the angles entered for R, and R,. This indicates thatthe forces are compressive.
“ZF” Program Listing.
Program:
= ot
1
Ue
03[s
(F L 245-Bute Pram
LEL "ZF*"
CF 21
Fzv? 55
SF 21
CLHMEHNU
FOLAR
—eo
2S0
50I
,...,.S i
= !P OMER B2
"IF+"KEY 1 HER @1"CLEF"KEY 2 MER 82"RlKEY 8 MER 83
AR)
oT
00
2L)
bpeket
L03-
Comments:
Sets or clearsflag 21 to match flag55. Clears the programmable menuand sets Polar mode.
Clears the stack and variables.
Defines the menu keys.
1: Static Equilibrium at a Point 17
et
PlPP
Fao
-7
ob
oo
W0
—
4
DD
oe
eliO
T
oPa0
DO
-iL
T2e
eTN
boo
18
NpEanil
15 EEY 4 WER &4
"RIRZM
KEY & HER BE
EEY = GTO a9
2 LEL 96
MEHL
=STOP
GTO 84
LEL @1REAL?COMPLEXSTO+ "ZF"VIEW "ZF"RTH
LEL 82
CLET
STO "REla™
STO "REZaM
COMPLER
STO O"EFM
WIEM “EF"
ETH
LEL &3
3 CPH?% COMPLEX
STO "R1L"VIEM "Rls"RTH
LEL &4CRH7COMPLEX
L ST “Rz2L
YWIEW "R2L
FTH
Displays the menu and stops.Pressing redisplays the menu.
Addsthe input to XF. If the input isnot already complex, it’s convertedautomatically.
Clears the stack and initializes the
variables.
Stores and displays R14.. (R1X4cannot be complex.)
Stores and displays R2X.. (R2&cannot be complex.)
1: Static Equilibrium at a Point
In LtN otL LEL e
RIL “ZF"21 RECT
G2 COMPLER
52 POLAE
o4 RCL "R2g"
535 SIH
i STox 8T 2
LASTA
cos
STOx ST 2
F+
Fa
ECL "R1aM
SToO= ST T
noo
20=]AN0
[e
0Ln
eTTT
T
¥
T
STO 5T 2
ECL "Riug®
COMPLEXIIF.:1=II
ARCL 5T =
I0o
o=000
00)TOe
02[e
el
L]
— el
- 4
T“fvl
=)gmd
]T
-]
reRCL “EF"RECTCOMPLEX
ow0O
OO0
000
00
00
00]
=)
TLNP
20[e
[ag oLT
+{
Calculates R,.
Calculates R,.
1: Static Equilibrium at a Point 19
=l
TvTR
-
wIona
SO
0D
WWl
g
RCL "R2&
COMPLE=
oT
LNe0PI
o
D6 FULRE="Q¥ ARCL =T A
@2 AYIEM Displays the results.29 RTH
Exits all menus and ends.
b oS
o=5
mr
om
Yet[
— I [ -
20 1: Static Equilibrium at a Point
Equations of Motion
2: Equations of Motion 21
Equations of Motion
This chapter contains three Solver programsfor the following equationsof motion for constant acceleration.
Variables Used.
Remarks. These Solver programs can also be used for angular motion.
s = vyt + 1/2at?
v =v, +at
v? =v2+ 2as
In Equations Description In Programs
t Time. 1
a Acceleration. a
Vo Initial velocity. Wi
v Final velocity. U
s Displacement. =
Usea,v,,v,ands to represent o, w,, w, and 6, respectively.
Program Instructions.
1. Key the appropriate program (“MO1”, “M0O2”, or “MO3”) intoyour calculator. (The programs are listed on pages 24 and 25.)
Press lSOLVER).Select “MO1”, “MO2”, or “MO3” by pressing the correspondingmenu key.
2.
3.
4.
22 2: Equations of Motion
Use the variable menu to store the known values. Key in each valueand then press the corresponding menu key.
5. Optional: Store guesses into the unknown variable to direct theSolver to a particular solution (there might be more than one).
6. Press the menu key for the unknown value. The Solver immediatelybegins to search for a solution.
Example. If a rock dropped off a bridge hits the water 1.6 seconds later,how high is the bridge? What is the velocity of the rock when it strikes thewater?
Since each of the equations only uses four of the five variables, manyproblems with two unknowns can be solved by carefully choosing theprograms you use. In this case, s and v are unknown. First solve for s usingthe equation that does not require v (“MO1”). Then use one of the othertwo equationsto find v. (Key “MO1” and “MO2”into yourcalculatorbefore you begin this example.)
B(SOLVER] 't x: B.8600ATTN
Store the known values: t = 1.6 seconds, a = —9.8 m/s? (for free fallingobjects), and vy = 0.
6. F t=1.60003]Jwe5]]|
a=-9.8000LTevs1]
0:wm vP=0. B804LTowo§[|
s=-12,5440NTNN
2: Equations of Motion 23
The bridge is about 12.5 meters above the water. Now find v. Since s isnow known, you can use “MQ2” or “MO3”.
EXIT] HMOZ x: =12.5448L7bwev||
When you first select a Solver program (as you just have), the first menukey you press executes a store to that variable, even if you don’t key in anumberfirst. Therefore, you'll have to press ©¥twice to start the
Solver.
W v=-12.5440IITI
by v=-15.6300L1nwe&[|
The rock is traveling at almost 15.7 meters per second when it hits thewater.
““MO1” Program Listing.
83 { 48-Bute Fram o B9 RCLx "a"
&1 LeL "MOL" 18 2
B2 MYRR "tY 11 =+
Bz MYAR "a" 12 Wik
a4 MYAR "oat 13 RECLx “.oa
83 MvAR "= 14 +
He RCLO" 15 RCL- "g"
&7 EMTER 16 EHD
g2 ®trZ
24 2: Equations of Motion
‘““MO2” Program Listing.
.,..
fex= fax] RCL "t
RCLx "a"RCL+ "w@"RCL- "utEHD
1TL 3Z-Bgte Pram
LEL "mOZ"
fvAR "Lr.1 l“‘l H F: 1n 'a kN
MWHERE @t
FIWHRE Mot
e o
.,_.
,.Tye
oLRN
W
fua]
o0D
1%
Nof
00T
-
N Lot
““MO3” Program Listing.
- =-=
3=
Tw0o{ 29-Bute Pram
LEL "MOz
YRR "a"
MYAR "Bt
MYAR "at
MYAR "="
S RCL et
RCL "w@"M2
- 150a1
2
RCLx g
ECLx ="
EHD
=Fo3
03
W+X
DoyI
on
--
Jaog3
[|
T[a
x]-1
e o
2: Equations of Motion 25
Analysis Programs
26 3: Analysis Programs
Mohr Circle Analysis
This program calculates the 2-D Mohr’s circle for stress using strain gagedata (equiangular or rectangular) or using known stresses.
Configuration 1 2
Code
Type of Rosette Rectangular Delta (Equiangular)
c Principle Principlestress b stress
/ /
a a
Principal Strains 1 [ex + € 12 0 Flatete
€1, €
v £ V20e, — ) + 2— ¢)7 |FVAa— @ T 2o — oH2Ae— ) ]
Center of
Mohr Circle E(e, + ¢€2) E(e, + ¢ + €)
) 2(1 —v) 3(1 —v)2
Maximum Lt EShear Stress 2(1+v) 3(1+v)
Tmax X \V2(e; — €)* + 2(ep — €)% X VAa— &)+2=+ 2ec— )
Orientation _
of Principal 1a [Zéb& 66] 1o [ V3 (e @) }Stresses ¢ 2 € — € 2 (2¢, — & — ¢€.)
3: Mohr Circle Analysis 27
Variables Used.
in Equations Description in Program
E Young’s modulus. E
v Poisson’sratio. ¥
€, Strain . el
& Strain g5 OF¢ ez
&, Strain gy OF£ ek
o Normal stress on the x-face. "
oy, Normal stress on the y-face. Y
o1 Minimum principal stress. Smin
oy Maximum principal stress. Srman
Toy Shearstress. THU:wY
Tmax Maximum shearstress. TAUMma:
¢ Counterclockwise angle from ¢, to &the maximum principal stress.
g Counterclockwise angle from the x- £axis to the maximum principal axis.*
i Arbitrary angle counter- clockwise ARELfrom the x-axis.*
S Normal stress.*
T Shearstress.*
*Refer to the equations on page 32.
28 3: Mohr Circle Analysis
Remarks.
m Shearing stress on any element is positive if it tends to rotate theelement clockwise. Tensile forces are considered positive;compressive forces are considered negative.
m Angles are entered and displayed using the current angular mode ofthe calculator.
m The program calculates the principal stresses for a two-dimensionalstress state only. However, a knowledge of the stresses in the z-direction is necessary to determine the overall maximum andminimum stresses.
m This program uses storage register Rgg to store intermediate results.Before running this program be sure the SIZEis set to at least 1
(MMODES] (Y] =1ZE 1 [ENTER)).
m The program sets flag 21, which causes the program to stop each time
a result is displayed if printing is disabled.
Program Instructions.
1. Key the “MOHR” program (listed on page 34) into your calculator.
2. Press ‘MOHE to execute the program.
3. When the program displays Tups of Input?, pressone of thefollowing:
Eas if equiangular strain gage readings are known.
FET if rectangular strain gage readings are known.
STRESif stresses are known directly.
4. The program then displays Store Yaluesi [R-S]andavariable menu containing the variables to be entered. Store eachvariable by keying in the value and then pressing the correspondingmenu key. Afterall of the values have been stored, press (R/S]. Theprogram then calculates and displays the results. If you are notusing a printer, press after each result.
3: Mohr Circle Analysis 29
5. Optional: To calculate the normal stress and the shearstress, do thefollowing:
a. When you see AREZ7, key in the arbitrary angle of rotation.
b. Press [R/S]. If you are not using a printer, press aftereach result.
Example 1: Equiangular Strain Gage. An equiangular rosettestrain gage measures the following strains:
£o=180p
[ 200[‘
€10 = —290
Find the principal stresses and their orientation. The material properties
are E = 30 x 10° psi and v = 0.3.
B(MODES] HER Tupe of Input?
HITHR TITIN
Efg Store Yalues; [R-51]
30[E)6E E=30, 383, BB0. bRaMO.
i V=0. 2000ITI
180 (B) 6 F/A) El =1=0, POD2ITI.
30 3: Mohr Circle Analysis
200(E)6(*/<) E=z
290 [*/] E) 6 /)
R/S
R/S
e3=-0. 6003NTRN
Smax*856?51358
SMin=—6,103.707218] X: =651 7072
TRUmax=7, 389, 4215x: =6, 1083.7072
£=31.8333%: -6, 10 3.7672
Example 2: Known Stresses. The stresscs acting on an element areshown below (all stresses are in MPa).
. 'rxy=30
»O’x=75
3: Mohr Circle Analysis 31
N=
2
Sz + SyS1=—‘2—+Tmax
S, + SS, = 32 ! ~ Tmax
1 - 21y= —tan~! |——22" [s,—sy]
_51+S22 + Trax c052[0’ - 0]
T = Tmax sin2[0’ - ]
Find the principal stresses and their orientation, and the stresses on the
face of the element oriented 45° counterclockwise from the x-axis.
B(MODES]
|
DEG Tupe of Input?
MOHRE (EnaTReCJotresl[[
STRES Store Valuesj [RsS]ETTETIWDWB
30 THUAEY TAUxY=30. 0000IRITIN
75 H ®=rS.8880
ol&v11|
32 3: Mobhr Circle Analysis
20 [*/]
R/S
R/S
45 [R/S)
Y=-20,80800 TRETINR.
Smax=83. 6885x: 83. 6885
Smin=-28.68856805%: —28.
TAUmax=56. 1885x: —28.6805
Y: -28. 6800RRB<L70. BBBG
Norm=-2. 5880% = 8ea
Shear=47, 5004X 880
3: Mohr Circle Analysis 33
“MOHR” Program Listing.
Program:
BE £ 412-Bute Pram
@1 LEL “MOHRE"
Az SF 21
H3 CLMENU
B MEQLM
85 KEY 1 XKEQ @i
@e "RECH
87 EEY Z RKER @82
gHg “STRES®B3 EEY 3 WEQ 83
18 KEY 9 GTO @9
11 LEL H
12 "Tupe of Input?"
= MEHU
14 FPROMFT
15 GTO A
LEL "M1"MYAR "E"r,1 |I'.I H E: 1 l'lll i
MYAR "el"MYAR:MYAR:[
[bb
ets ¥
es
00)
22 LBEL "MZ"23 MYAR TRy24 MYAR M25 MYAR T
LEL @8
VARMEHL "E1"
2 WEQ B2
o1T
RCL "E™
1RCL— "m
oo00[
o
34 3: Mohr Circle Analysis
Comments:
Sets flag 21 to control output anddefines the menu for selecting thetype of analysis.
Displays the menu and promptsforthe type of input. Pressing
redisplays the menu.
Declares the menu variables for the
first variable menu.
Declares the menu variables for the
second variable menu.
Selects the first variable menu for input.
Calculates r,,,, for strain gage data.
Tl
e1
4 =
S8
wnoonAO
gLR
03P
onon
1T
=Ltoen
g00
To
Fuo0o
IJa
TWT
TLN
T iiO
Jr
w0o
=]
ST0 88
RCL TEM
1
RCL+ "y
“THUmMa""E‘l"
" E-I:__l n
i ~
1Y = J
GTO B84
LEL &
WER A
GTO 84
LEL @z
WARMEML "Mzt
#ER @z
Calculates results using equiangularstrain gage readings.
Calculates results using rectangularstrain gage readings.
Selects the second variable menu for
input.
3: Mohr Circle Analysis 35
Lo0O
5=poedodol)
i[35)
-1
oQ0
oD
00
00
Q%D
0D0D
o0
912za3a4a52E97g
=b
LT
- %) =l kA
=TT
TSogg&
eke
ekek
5 X Jo
L0[e
50
q
1
STO 8g
STO "THUMmEx"
RCL T-
RCL "y
RCL "t
LEL &4
2T "Smin
f+
STO "g
RECL "TAUmax"
RCL+ 28
STO "Smas
VIEM "Smax"
RCL @i
RCL- "TAUmax"
STO "Smin®
VIEW "Smin”
WIEW "TAUma:"WIEM "g"
IHMFPUT "HREBL"
ROL- "a"—
SIH
3: Mohr Circle Analysis
Calculates results using knownstresses.
Calculates 1, and 6.
Calculates S, and Spin.
Displays 74y and 6.
Optional routine calculates normaland shearstress at an arbitraryangle.
k] [
.e,o2
WAg
2!
bkb
ekek
N N L
* "TAUma:"
RCL+ &
"Morp="
ARCL 5T =
2 AVIENW
R
RCLx "TAUMax""Shear="ARCL 5TAYIENFTH
LEL @23"Erore Malues;
FUIRE-31
22 FROMFT'3 LEL &3
EXITALL
EMD
Promptsfor input using the selectedvariable menu. Pressing clearsthe menu and continues.
3: Mohr Circle Analysis
Soderberg’s Equation for Fatigue
This program is used with the Solverto calculate any one ofthe sixvariables in Soderberg’s equation for fatigue when the otherfive areknown. Soderberg’s equation is shown graphically in the following figure.
Experimental Failure Line
AN /Failure PointN
h Working Stress Line
. for FS =1
w o
Design Line
with FS >1
FS
<« Syp
S S
%_ 2 Smax+sm1n+K[sy:][smax smm]
38 3: Soderberg’s Equation for Fatigue
Variables Used.
In Equation Description in Program
Syp Yield point stress. Sup
S, Endurance stress. Se
5 max Maximum applied stress. Smax
S min Minimum applied stress. Zmin
K Stress concentration factor. K
FS Factor of safety. Fs
Remarks.
u Soderberg’s equation is valid for ductile materials only.
m Fatigue effects arec magnified in corrosive environments.
Program instructions.
1. Key the “SODER?”program (listed on page 41) into your calculator.
2. Press l[SOLVER] =0LEFto select the Solver equation.
3. Store each of the known variables by keying in the value and thenpressing the corresponding menu key.
4, Press the menu key for the unknown variable.
Example. Given the following values, what is the maximum allowableapplied stress if the minimum applied stress is 15,000 psi?
Sy = 80,000 psi
5. = 30,000 psi
K=15
E§S =20
3: Soderberg’s Equation for Fatigue 39
B(SOLVER] =0LEF
80000=4'E
30000 E
15000 =M IH
40 3: Soderberg’s Equation for Fatigue
Sup=808, BBd. BRAVP|SE_[SMAR[SMINGB]Fo|
Se=30, B00. BOEABETNTTRTNI
Smin=15, B0B. PAEAL2P§SEJSHAi[SMINGK|FS]
K=1.5008STWFETTA
FS=2.8600[sVP|SE{IMAH[SMINGK|Fs|
Smax=25, 000. 0684[P|€JEMisHiNGb|Fs]
“SODER” Program Listing.
,_ px]
p— ot
[}
Jo
03
oDe
T L BZ-Bute Fram o 11 RCL- "Smin"
LEL “SODER" 12 RCL= "E"MYAR "Suyp® 13 RCLx "Sup"MYAR "Se" 14 RCL+ "Sa
MYHRE "Smax" 13 +
MYAE "ZSmin” 16 2
% MVAR TR 17 =+
MYAR "FS" ig2 RCL "Sup"
ECL "ZSmax" 17 ECL+ "F3"
ECL+ "Smin" 28 -
LAST: 21 EMD
—AlG
15
OT
OI
oL
5 vo0
0D
=)
-I
e
3: Soderberg’s Equation for Fatigue 41
Composite Section Properties
The mathematical properties of a cross section composed ofa finitenumber of rectangular elements can be computed by adding thecontribution of each rectangular region individually. This program usesthis principle to calculate the area of a section, the momentsof inertiaaboutthe specified set of axes, the momentsof inertia about an axistranslated to the centroid, the momentsof inertia of the principalaxes,and the angle of rotation between thetranslated axes and the principal
axis.
Ay = Dx;Ay;
A=Ag+A,,+ A+ 0 + Ay
n
Yx0id,ix_= t=1
A
Yyoides—_ =1
y A
n — —
Iy = YX0iYoiAei Ly=1y -AXxYy=1
n Ay? —L-fhase men-ayi1
n AX'Z .
Iy=2[x(%l+1—2‘] 81 IF=I!I-Ax2t1=1
J=1+1,
42 3: Composite Section Properties
Ly = L-cos’$ + Iisin2¢ + Isin 2%
Ly = L;cos’p + Esin’p + I-sin24
J¢= I?¢+I'y_¢
Variables and Storage Registers Used.
In Equations Description In Program
Ax; Width of a rectangular element. i
Ay; Height of a rectangular element. H
Ay Area of an element. Ry,
A Total area of the section. Ro1
x x-coordinate of the centroid (total). Rgs + Ry
y y-coordinate of the centroid (total). Ry + Ry
Xog x-coordinate of the centroid of an Heelement.
Yo y-coordinate of the centroid of an Yoelement.
I, Moment of inertia about the x-axis. Ry
1, Momentof inertia about the y-axis. Ro7
J Pole}r moment of inertia about the Rosorigin.
1, Product of inertia about the origin. Rgo
3: Composite Section Properties 43
In Equations Description In Program
L Moment of inertia about the x-axis Rostranslated to the centroid.
I Moment of inertia about the y-axis Ryytranslated to the centroid.
I Product of inertia about the Rootranslated axis.
¢ Angle between the translated axis Rosand the principal axis.
Iy Moment of inertia about the principalX-axis.
Iy Moment of inertia about the principaly-axis.
Jy Polar moment of inertia about the Rosprincipal axis.
Remarks.
44
Angles are entered and displayed using the current angular mode ofthe calculator.
For a given origin, the polar moment of inertia is constant regardlessof the angular rotation. Therefore, I- is equal to J4
It is possible to obtain a negative value for the product of inertia.
Before using “SECTION”be sure to set the SIZE to at least 11registers (l(MODES] (V] £1ZE 11 [ENTER)). The table above showsthat some ofthe registers are used more than once. Storage registersnot listed in the table are used for other intermediate results.
This program clears all of the storage registers.
Results are labeled and displayed in the same order as in the tableabove. The program uses variables only for the four section inputs.
This program uses flags 21 and 55 to control printer output.
3: Composite Section Properties
Program Instructions.
1.
2.
3.
4.
5.
Key the “SECTION”program (listed on page 53) into yourcalculator.
Press SEC T I to execute the program.
When you see MHumbetr of Sect ions?, key in the number ofcomposite sections and then press [R/S].
Enter the data for each section:
a. Key in the x-coordinate of the centroid and then pressWi
b. Key in the y-coordinate of the centroid and then pressR
¢. Key in the width of the section and then press M
d. Keyin the height of the section and then press H
e. Press to continue.
If you store an incorrect value, simply repeat the step to store thecorrect value. If you notice that you’ve made a mistake afterpressing , start over at step 2.
After the data for each section has been entered, the programcalculates the results. If you are not using a printer, press after
each result is displayed.
3: Composite Section Properties 45
Example 1: Rectangular Section. Calculate the section properties
of the following cross section.
yA
Table of Inputs
X Ye AX|AY
21151} 4 3
B(MODES] [EG Number of Sections?E;ECTI %: B. 0000
1 [R/S] Input Section 13 LR/S)EETATYTA
2 spwe RC=2 . P00ITTIOI
15 %0 Yc=1. 5000TTTT
46 3: Composite Section Properties
4 W W=4. 0000ITTTN
3. H H=3. 8060Le [v §W]W]
[R/S] Rrea=x: 12. 0000
R/S Xc=%: 2. 00009
x: 1.56800
R/S Ix=x: 36. 0000
R/S Iy=x: 64,0000
- J=
x: 100.0000
- Ixy=x:36, DOOO
3: Composite Section Properties 47
R/S Ixc=
x: 9. 88608
R/S Iuc=x: 16,0000
R/S Ixgc=%: ¥, 80680
R/S Lphi=x: 0. 8060
Ixc phi=x: 9, 8888
R/S Iyc phi=w16,BBOD
R/S Jephi=x: 29. 0000
48 3: Composite Section Properties
Example 2: Composite Section. Calculate the section properties ofthe following section.
Table of Inputs
X Yo |OX|Ay
1156 |15
211 6 2 112
7 1 10| 2
@MODES] «DEG Number of Sections?SEETL x: 25,0000
3 [R/S] Tnput Section 1;LR-51]TIITS
5 sy ®c=5.80P0
IETSATITN
115 Ko Yc=11.5600IETATSYIIN
3: Composite Section Properties 49
R/S
50
b
3: Composite Section Properties
W=6. 8604IT7OI
H=1.0000IETSTYTN
Input Section 23 [R~S]EDTYBA
®c=1.0600TRTNTNSI
Yc=6. BbbaLot]vo]W]B[]
IN=2.BBBB lIETTOTI
H=12.08008ITDTTI
Input Section 33[R-S]Lo[ve[W[w][]
KC=7. 604(8|v|W]H|
— V=1, 0000IB7TO
10 W W=10.08000LacvW]Bl|
2 H H=2.088680INETTWTRB
[R/S] Area=x: 50, 6008
R/S Y=% 3.8800
R/S Yc=w: 4. 6608
R/S Ix=% 15972, 6667
[R/S] Iu=w1, 346. 6667
R/S] J=% 3,319.3333
3: Composite Section Properties 51
ng=X: 629, 8090
R/S] Ixc=w: 886.8867¢
R/s Igc=
x: 593.9467
R/S Ixyc=X: 279. 8400
R/S £phi=x: 38.9814
R/S Ixc phi=x: 1,0852.0261
R/S Iuyc phi=x: 42 86?2
R/S Jrhi=%: 1,4808.8333
52 3: Composite Section Properties
“SECTION” Program Listing.
Program:
.,.
fx]™ lx] £ 295-Bute Fram
LEL "SECTION"
MYAR
MYAR
MYAR
MYAR
-~ lex]
ok
n lv'j n
B H n
) ]=
Oe)
Pde
— Lo
LEL B
"Humber of
F'oections?"FROMFT
HES
IF
T
oo
1T
ooot0o
by 21
Pk
ek
ek
ek
1
1o=
Lo
m—
oy
A3
g
01
4+=
ee)
- [L
bbb
ek
ek
ks
eN
wioga)
FU5LR-S1
CF Z1
AVIEM
CLH
SF 21
STOF
ALEMG
o
o0o]
Q03
PlIIy
—
Comments:
Defines the menu variables.
Prompts for the number of sections;rejects a zero input,
Clears the storage registers andstores a loop counter in Re,.
Selects the variable menu.
Builds the promptstring using theloop counter.
Displays the prompt and stops.Pressing continues the
program.
3: Composite Section Properties 53
E=ITHLL
RCL "H®RCL% "lSTD @2
H1
RCLx "yo"STO+ @4
RECL "HE
ECL=
43 STO+
44 RCL "%
45 H1Z
Ns
T-
==
oo
-o
-o
o
efa
faL
bt0
L{2
o
1oL[
M
IIHH
1 [ [+43
43SEo+
on
L]—
.o +
X
IT
2
oon
ooOoo
L3 D)
(N
o T2
55 RCL "KM
SE HeE
ar 12
iloo
=oO
i [ax] RCL= )
AN
[xx)-1[
61 5T0+B2 +53 STO+ 82
4 ROL "Hco65 ROLx “yo"
RCL=
STO+ 1T a2
=
]T
= oo[
T1T
=TT L
T o0
o0
T= 5
1
- 12 =TG=
Accumulates the inputs into theappropriate storage registers. (Referto the table starting on page 43.)
Repeats loop for each section.
54 3: Composite Section Properties
a3
[oI
mdg
=g=)))
iT
=)=y
WD
)5 [x]
ote
nT
000D
00
00O
=1wO
oL
00
00
Wg
Fo
003o
Tw0
00
WO
no
Ow00e
o LS|
=tg
0
-2L Lo
bet
et
oM
0o
23[
Calculates L.
o03
w0
—i
=
RCL a1 Displays the area.
+ Calculates and displays.
Calculates and displaysx
o10
Displays I, and calculatesI
R+ DisplaysI,,.
+-
RCL &71 I IJ 1
HER 82
V[xalRCL Y1 Displays J .
BER B3
3: Composite Section Properties 55
T
bt
peke
el
oM
o=
--s
-5
b3T
WD
112 RCL 85 DisplaysI11=
TOl
==
=
25==== o
=
56
e DisplaysI, .
F Calculates L.
Displays ;.
Displays L.
5T 642 RCL 16 Mg
AER 83
Calculates ¢.
3: Composite Section Properties
Iz z Calculates and displays L,
nn
Joo
00[
i
be..
i nonT
[P
io]
i
e n iT
o0(T
[24)
Jao3Do
)T
fodbb
ekb
ek
(1))
in
RCL: 18
+.=
RCL B85
SIHL
RCL~ @3 Calculates and displaysL+o=
"Iuc phi"
EE @2
RCL 8% Displays J;.n IF“—l 1 "
GTO 94 Returns to the initial prompt.
LEL &= Displays a result. If results are beingFr=n printed (flag 55 set), the label andF&7? 55 value are printed on a single line.ARCL ST =
AYIEM
EHE
3: Composite Section Properties 57
Spring Constant
This Solver program calculates the value of any of the five variables in thefollowing spring equation, given the other four.
F,~Fk=1 "2
X2 - Xl
Variables Used.
In Equations Description In Program
X, First spring length. “1
F, Force required to retain spring at F1length X;.
X, Second spring length. 2
F, Force required to retain spring at Fzlength X,.
k Spring constant. k Remarks. The “SPRING” Solver program can also be used to solve anygenerallinear equation of the formy — yy = m(x — xg).
Program Instructions.
1.
58
Key the “SPRING” program (listed on page 60) into yourcalculator.
Press I{SOLVER] SFRIH.
Usethe variable menu to store each of the known values by keyingin the value and then pressing the corresponding menu key.
Press the menu key for the unknown.
3: Spring Constant
Example. A compression spring is 4.0 cm long under no compressiveforces. A force of 27 Newtons compresses the spring to a length of 2.8 cm.Find the spring constant, k, if the solid (fully compressed) height of thespring is 2.5 cm. Also find the force required to fully compress the spring.
BSOLVER) SFEIH
4 1
0 FIL
28
The spring constant is 22.5.
25
x: B. 8800SWTTI
X1=4.0800SNTTT.
F1=8.0000itF1jRaFa&|
®2=2.8000#tF1weFaK|
F2=27.0bo8#1F1w2FaK|
k=22.5600TNTTA.
K2=2.5008#1F1RFaK|
F2=33. /o009#1F2H2F@K|
3: Spring Constant 59
A force of 33.75 Newtons would completely compress the spring(to 2.5 cm).
“SPRING” Program Listing.
B8 £ 49-Bute From I @7 RCL "F1"B1 LEL "SFRIMG" @% RCL- “F2"B2 MYAR K1Y @3 RCL "®2"B2 MYAR "F1" 18 RCL- "#1"a4 MYAR “H2" 11 =85 MYAR "F2" 12 RCL- k"BE MVAR Uk 13 EMD
60 3: Spring Constant
Linear or Angular Deformation
This program solves for linear deflection under tensile load, or theanalogous angular deflection under torque. Given four ofthe fivevariables, the unknown is calculated. '
8T \
P ¥
p or \
}
T 17-!
€ / —>| |— €« / —>
_P<s Az g -TZAC=RE =G
3: Linear or Angular Deformation 61
Variables Used. Since the form of the two equations is identical, eithertype of deformation problem can be solved using this program. Use thefollowing table to relate the variables used in the equations to thevariables used in the program.
In Equations Description In Program
Al Change in length. Delta
P Applied load. P
l Length. L
A Cross-sectional area. A
E Modulus of elasticity. E
6 Deflection angle (in radians). Delta
T Applied torque. F
J Polar moment of the section. A
G Modulus ofelasticity in shear. E
Remarks.
m This program is not applicable for non-elastic media or elastic mediawhere stress exceeds the elastic limit. Materials must be isotropic.The equation for angular deflection is not valid in the neighborhoodof the applied torque.
m Even though the polar moment must be expressed in radians,it is notnecessary to set Radians mode because no trigonometric functionsare used in the program.
Program Instruction.
1. Key the “DEFORM” program (listed on page 64) into yourcalculator.
2. Press [SOLVER] KEFEto select the program.
3. Store each of the known values by keying in the value and thenpressing the corresponding menu key.
62 3: Linear or Angular Deformation
4. Solve for the unknown value by pressing the corresponding menukey.
Example. Steel bars (each 10 meters long) affixed to a roof are to beused to support the end of a cantilever balcony. The load on each bar willbe 50,000 N.If the maximum allowable deflection is 0.001 meters, whatshould the area of the bars be? The modulus of elasticity is given as2.068 x 10" N/m?.
B(SOLVER] LiEF (TR x: 8. BbA[SOLVER) WELTA]P
|
L
|
w
|
€
|
|
.001 BELTH IDelta=8.8@18 I[NTWIA
50000 F ¢ P=50, 606. 080CELTRLP |L |% |E [|
10 [=10. 0000|-:--r-n-|
2068[E] 11 E E=2086, 860, 808, 00A.weetslP ]L ]w [€ ||
R A=0. 0024(YITNY
3: Linear or Angular Deformation 63
“DEFORM” Program Listing.
@8 £ 45-Bute Prom 3 @7 RCL "P"@1 LEL "DEFORM" @g RCLx LB2 MYAR "Delta" @3 RCL+ “A"@3 MYAR P 1@ RCL+ “E"@4 MYAR "L 11 RCL- "Delta"a5 MYAR "A" 12 END@5 MYAR "E"
64 3: Linear or Angular Deformation
Thermodynamics
4: Thermodynamics 65
Equations of State
This section contains programs for both ideal gas and Redlich-Kwongequations ofstate.
The ideal gas equation is
PV = nRT
The Redlich-Kwong equation is
P= nRT a
(V-b) TWYV2V(V+b)
where:
= 4934 b nRT}!S
b = 00867 2ole¢
Variables Used.
in Equations Description in Program
P Absolute pressure. F
v Volume. W
n Number of moles present. r
R Universal gas constant. F
T Absolute temperature. T
T, Critical temperature. T
P, Critical pressure. Pz
66 4: Equations of State
Values of the Universal Gas Constant
Value Units Unitsof R Units of R of P
|
UnitsofV
|
of T
8.314 N-m/g mole-K N/m?
|
m3/g mole K83.14
|
cm’-bar/gmole-K
|
bar |[cmi/gmole| K82.05
|
cm’-atm/gmole-K
|
atm
|
cm®/gmole
|
K0.7302
|
atm-ft*/Ib mole-°R
|
atm
|
fi}/lbmole
|
°R10.73
|
psi-ft3/Ib mole-°R psi
|
ft*/lbmole
|
°R1545
|
psf-ft’/lbmole-R
|
psf
|
ft3/lbmole
|
°R Critical Temperatures and Pressures
Substance T..K T.,°R
|
P,, atm
Ammonia 405.6 730.1 112.5Argon 151 272 48.0Carbon dioxide 304.2 547.6 72.9Carbon monoxide 133 239 34.5Chlorine 417 751 76.1Helium 5.3 9.5 2.26Hydrogen 33.3 59.9 12.8Nitrogen 126.2 227.2 33.5Oxygen 154.8 278.6 50.1Water 647.3 1165.1 218.2Dichlorodifluoromethane 384.7 6925 39.6Dichlorofluoromethane 451.7 813.1 51.0Ethane 305.5 549.9 48.2Ethanol 516.3 929.3 63Methanol 513.2 923.8 785n-Butane 425.2 765.4 375n-Hexane 507.9 914.2 29.9n-Pentane 469.5 845.1 33.3n-Octane 568.6 1023.5 |24.6Trichlorofluoromethane 471.2 848.1 43.2
4: Equations of State 67
Remarks.
m P,V,n,and T must have units compatible with R .
m At low temperatures or high pressures, the ideal gas law does notrepresent the behavior ofreal gases.
m No equation ofstate is valid for all substances over an infinite rangeof conditions. The Redlich-Kwong equation gives moderate to goodaccuracy for a variety of substances over a wide range of conditions.Results should be used with caution and tempered by experience.
Program Instructions.
1. Key the “IDEAL” program (listed on page 70) or the “RK”program (listed on page 71) into your calculator.
2. Press B(SOLVER] ILEAL (for an ideal gas) or IB(SOLVER]RE (for Redlich-Kwong).
3. Use the variable menu to store each of the known values: key in thevalue and then press the corresponding menu key. Notice that thereare seven menu variables. Therefore, you must use [4] or [¥] to
enter or solve for P, .
4. Solve for the unknown by pressing the corresponding menu key.
Example 1: An Ideal Gas. Whatis the pressure (in bars) when 0.63 gmoles of air is enclosed in a 25,000 cm? space at 1200K? Assume an idealgas. From the table on page 67, R is given as 83.14. (Key the “IDEAL”program into your calculator.)
BEOLVER) ILERL % 8, D000ITTI
25000 4 V=25, 000, 0000ITTA
B3 'H n=8.6300IITOA
68 4: Equations of State
83.14 R R=83, 1400ITOON
1200 s 5122 T=1, 260, 0600LFvN1k1]|
F P=2.5142IIO0OA
Example 2: Using Redlich-Kwong’s Equation. Thespecificvolume of a gas in a container is 800 cm3/g mole. The temperature willreach 400K. Given the following constants, what will the pressure beusing the Redlich-Kwong relation?
T, = 305.5K
P, = 482 atm
R = 82,05 cm® atm/g mole K
B(SOLVER] |R X: 2. D142|nnmnml
800 W V=800, 0000PvWBT]1c]
1 H n=1.B8000ITIOAT
8205 E R=82. 08560Le [v IN[R TT]TC]
4: Equations of State 69
400 T T=408. 0008P¢NR7[TC]
3055 T Tc=305. 5000[P 1¢[NTR [T[TC]
(V)482 Fi Pc=48. 2000|lnnulllll-|llmllnlll4
a = P=36.2669L¢ |v [N [R ]7|TC]
“IDEAL” Program Listing.
86 £ 48-Bute Fram 2 @7 RCL "n"@1 LEL "IDEAL" B2 RCLx "RB2 MYAR P @9 RCLx "T"B3 MYAR "y 18 RCL "P"a4 HYAR "R 11 ROLx "y85 MYAR "R" 1z -e MYAR T 13 EMD
70 4: Equations of State
“RK” Program Listing.
] 113-Bute From @ 23 WER a1LEL “RK" 24 RCL "WMYAR “E 25 +MYRR 26 LASTHMYAR R 27 %
RCL “T*
ooMM
ST
oNe
D0Oe
53
85 MYAR “R" 28BE MYAR "T" 23 SORT67 MYAR "Tc 3@ x88 MYAR "Pc 31 +@3 RCL T 32 -16 HEQ @ 3% RCL- "P"11 RCL "y 34 RTH12 HER @1 35 LEL @8z - 26 RCLx "n"
14 = 27 RCL» "R
15 HER 81 38 RTH16 4.934 39 LEL @117 46 B, B36718 RCL "Tc® 41 RCLx "Tc1% 1.5 42 HEQ G@2@ 43 RCL+ "Pc"
$a Ja EHL
4: Equations of State 71
Black Body Thermal Radiation
All bodies emit thermalradiation according to their temperature. Thehigher the temperature, the more thermal radiation emitted. A black bodyis one that emits the maximum possible amount of energy at everywavelength for a specified temperature. The figure below represents theblack body thermal emission as a function of wavelength.
This program can be used to calculate the following:
m The wavelength of maximum emissive power for a given temperature.
m The temperature corresponding to a particular wavelength of
maximum emissive power.
m The total emissive power for all wavelengths at a particular
temperature.
m The emissive powerat a particular wavelength and temperature.
A max
Black body
monochromatic
emissive power
1 2 3 4 5 6 7 8
Wavelength, #m
72 4: Black Body Thermal Radiation
AmaxT =C3
Eb(O ) = O"I‘4
2nc 1
Epx=——p7X (T - 1)
Variables Used.
In Equations Description in Program
Amax Wavelength of maximum emissivity Min microns.
T Absolute temperature in °R or K. T
Epo -y Total emissive power in Btu/hr-ft? or Ewatts/m?.
E,, Emissive powerat A in Btu/hr-ft2-um For watts/m?-um.
Remarks.
m This program usesflag 00 to determine which set of units to use forthe following constants:
(Flag 00 Clear)S1 Units English Units
(Flag 00 Set)
cy |5.9544x 1078 W-m?
¢, 1.4388 % 10% um-K
cs 2.8978 x 10° um-K
o |5.6697 x 1078 W/m?-K? 1.8887982 x 107 Btu-um*/hr-ft
2.58984 x 10* um-°R
5.216 x 10° um-°R
1.713 x 107 Btu/hr-ft>-°R* ® This program uses flags 21 and 55 to control printer output.
4: Black Body Thermal Radiation 73
Program Instructions.
1. Key the “BBODY” program (listed on page 76) into yourcalculator.
2. Clear flag 00 to select SI units (l[FLAGS] CF 00) or set flag00 to select English units (l[FLAGS] = SF 00).
3. Press EEODRYto execute the program.
4. Use the variable menu to store each of the known values (key in thevalue and then press the corresponding menu key). Then calculatethe desired unknown by pressing its menu key. Be sure to use valueswith consistent units.
To Calculate You Must Provide
w T
T w
E T
P WandT
Example. If sunlight has a maximum wavelength of 0.550 xm, what isthe sun’s temperature in K? Assumethe sun is a black body. Whatis thetotal emissive power and the emissive power at A,,,? What is the emissivepower at A = 0.400 pm (ultraviolet limit) and 0.700 ym (infrared limit)?(Clearflag 00 for SI units.)
x: B. 0008L7epr||
55 H W=0, 5560[TONOIS
74 4: Black Body Thermal Radiation
T T=5,268.7273TNOOI
The sun’s temperature is 5,269K.
E=43, 698,091, 4860(W7€P||
Thetotal emissive power is approximately 43,690,000 W/m?.
B P=5.2229e-8L7EP||
The power at 0.550 pm is 5.2229 x 108 W/m?-um.
4 W W=0.46800TITT
Y F=3.9649E-8TII
The power at 0.400 pm is 3.9649 x 10~8 W/m?-um.
T W=8. 7000ATAOR
B F=4,5934E-5TOTTNN
The power at 0.700 um is 4.5934 x 10~8 W/m?-um.
“BBODY”’ Program Listing. This program uses a variable menu forinput. When you select a variable that you wantto calculate, the programuses the character number (ASCII value) ofthe variable nameto causethe program to branch to the appropriate subroutine (lines 13 through15). For example, when you press to calculate T, the programbranches to LBL 84 because the character number of “T”is 84.
4: Black Body Thermal Radiation 75
Program:
.,.2 - L
$ao
00e
3 2 LEL “EEODY"MYAR WYMYAR “TMYAR "E"MYAR PCF 21F57 55SF 21
TTo
To5
0oo
=)T
Lf
XN,
i,bb
1T
L0
LEL ©&
WARMEHU "EBEODY™
LA
i1z STOF
12 ATOR
14 ==H7
15 wE@ IHD S
1e GTO B0
ol-]
LELHER @1ROL+ "T"STO "WII.II I El-'«! I l-'-l "
RTH
-- o0
5ooo]
TS 12,8
Wee
M -[l
fol
a0e
v00LEL &4
SER 81
RL+ "L& STD "T"
||I.IIEH IITII
FTH
Frl
Lk
tN
¢
[P
:
==
2% LEL &9G RCL T
i ZEZ-Bute Fraom O
Comments:
Declares the menu variables and setsor clears flag 21 to match flag 55.
Displays the variable menu andstops. Pressing redisplays themenu. If a menu key is pressed tocalculate an unknown, the character
code of the variable nameis used tobranch to the appropriate routine.
Calculates W.
Calculates T.
Calculates E. Flag 00 is tested todetermine which value to use for the
constant, o.
76 4: Black Body Thermal Radiation
-o o
n
ST“E®H
o "-’IIEH IIEII
oo
bB
choan
dn
0e
03
[0eT300
no
TL
Cnoon
eT
Oe
LNe
033o
Sol00—T
TT
ooF
oL0
=]
=g=g=
Fid
FTH
5295, 4RCL+ WYROL: THEti1
RCL "k5
i
STO P
I..,I I EL.J n F: 1
FETH
[} |
-=
w> ol
eyO
e
Calculates P. Flag 00 is tested toenter the appropriate values for theconstants ¢, and c,.
Tests flag 00 and enters theappropriate value for the constant c .
4: Black Body Thermal Radiation
Fluid Dynamics
78 5: Fluid Dynamics
Conduit Flow
This program solves foreither the average velocity or the pressure dropfor viscous, incompressible flow in conduits.
K5)For laminar flow (Re < 2300)
f =16/Re
Forturbulentflow (Re >2300)
;- 0.0772 :69 . Y
8 pe * [ 3.713]
I# Results calculated when 2300 < Re < 4000 aremeaningless. To determine if results are valid, examine the
Note calculated Reynolds numberafter the calculation (step 5inthe program instructions).
5: Conduit Flow 79
Variables Used.
In Equations Description in Program
Vv Average velocity. W
AP Pressure drop. F
L Conduit length. L
D Conduit diameter. If the conduit [:-is not circular, use anequivalent diameter defined by:
D,, = 4x Cross Section.al Area
Wetted Perimeter
€ Surface irregularity. E
Re Reynolds number; Re = DV/v. F
v Fluid kinematic viscosity. B
Fluid density. 5
f Fanning friction factor.* F
Kr Sum of fitting coefficients. K
*The Fanning friction factor is one-forth the Dareyfriction factor. Thatis, f = fp + 4.
80 5: Conduit Flow
Fitting Coefficients
Fitting K
Globe valve, wide open 75t0 10
Angle valve, wide open 3.8
Gate valve, wide open 0.15100.19
Gate valve, 3/4 open 0.85
Gate valve, 1/, open 44
Gate valve, 1/4 open 20
90° elbow 04to 0.9
Standard 45° elbow 0.35t00.42
Tee, through side outlet 1.5
Tee, straight through 0.4
180° bend 1.6
Entrance to circular pipe 0.25 10 0.50
Sudden expansion
Accelerationfrom V' = 0t0V = V.yunce (1 -Aup/Adn )2*
1.0 *A 4p is the upstream area andA, is the downstream area.
5: Conduit Flow 81
Surface Irregularities
Material e (Feet) e (Meters)
Drawn or smooth tubing 5.0x107¢ 1.5x 107
Commercial steel or wrought iron 1.5x 1074 46x107°Asphalted cast iron 40x10°* 1.2x107*
Galvanized iron 50x107* 1.5x1074
Cast iron 83x107* 25x1074
Wood stave 6.0x107%to [1.8x107* to3.0x1073 9.1x1074
Concrete 1.0x1073to |[3.0x107*to1.0x1072 3.0x1073
Riveted steel 3.0x103to |9.1x107*to3.0x 1072 9.1x1073
Program Instructions.
1. Key the “FLOW?”program (listed on page 84) into your calculator.
2. Press [SOLVER] FLiill to select the program.
3. Use the variable menuto store the known values. Key in each valueand then press the corresponding menu key. Since there are morethan six variables, use the [¥] and [&] keys to display the alternaterows of the variable menu.
4. Solve for the unknown value by pressing the corresponding menukey.
5. View the Reynolds number by pressing [J[PGM.FCN] YIEN
R [ENTER]. If the Reynolds number is greater than 2300 andless than 4000, the results calculated are meaningless.
6. Optional: To view the Fanning friction factor, press ll[PGM.FCN“1EH (ENTER] F [ENTER).
82 5: Conduit Flow
Example. A 60-meter pipe has three 180° bends (Ky = 3 x 1.6). Thefluid is water (v = 9.3 x 107" m?/s, p = 1000 kg/m>). The pipe diameteris0.030 m and the surface roughness is 3 x 10~* m. If the average velocity is3.20 m/s, what is the pressure drop in Pascals? Whatis the Reynoldsnumber? What is the Fanning friction factor?
M(SOLVER
3E 4[4
.03 b
3.2 5
93 [E 7 [*A]
60 L
3[ENTER]16([x] E
B3
FLTH
E
g
E=8.08003E&v&tK
D=0.08380€ov&LK]
V=3. 2000ITU
B=9. 3PPDE-7ITT
L=66.8000Le 1o [v |& |L [K |
K=4.8000LE 1o |v |E |t |K |
S=1, BBB. BBBOsp1[1|
5: Conduit Flow 83
F P=418,351.25598[¢1p1111
Check the Reynolds number and the Fanning friction factor.
BPGMFCN] Y I1EH [ENTER] R [ENTER] [R=183,225.8865Ls1¢I11[|
BPGMFCN] 'IE{l (ENTER] F (ENTER] [F=8.B896(s1e[|§1|
“FLOW” Program Listing.
#E L 128-Bute Fram 2 LoG
B1 LEL "FLOW" 9 OEEK]MYAR ME"
YRR MDYYRRMYAR BMYAR MLMYAR KMYAR "5MYAR "RRCL “E"FCL+ "0
o0[
1]
T-
. 2%y)G
LEL &g
STO “FM
RCL= LT
RECL+ "D
ECL "E"
4
eL0
eeTR
150N
-o0
O)
O
eoW
o=)
12 z.7
—
LM+
ofo
D0
D0
D00
D0D
00
D0
D0
0k
ek
[aa
Il
1.1118 figt 33 RCL "W
— S]
[
[ on
[yT
-", F: I::L 11 I."I I
17 RCLxo ROL+
It [:l 1
t E: "
1% 570 "R
2z GTO @122 Fe
24 1%25 A.9
2627+
84 5: Conduit Flow
44 w2
4& RCL O"PM
47 RECL+ "35¢
48 -
ETH
LEL &1
16
RCL= “R"GTO 80
EHD
onof
Roen
Oe5D
n T
Flow With a Free Surface
This Solver program allows you to solve for any of the five variables in theManning flow formula, provided the other four are known.
om0y2.2082r*3 x g2
Variables Used.
In Equation Description in Program
S Slope of the bottom (dimensionless). S
n Roughness coefficient. ri
r Hydraulic radius (in feet). r
Q Discharge flow rate (in ft3/sec). 5]
a Cross-sectional area (in ft?). a Program Instructions.
1. Key the “MANN” program (listed on page 87) into your calculator.
2. Press M(SOLVER] MAHHH to select the Manning flow formula
Solver program.
3. Use the variable menu to store the known values. Key in each valueand then press the corresponding menu key.
4. Solve for the unknown value by pressing the corresponding menukey.
Example. Find Q for S = 0.001,n = 0.013,R = 5/12ft,and4 = 5.0
fe2,
B(SOLVER] FfiAHH
5: Flow With a Free Surface 85
.001 S=0.08811>|M[R[o|&]|
013 H n=0.0130L¢|N[R|&]w]|
5 126R =0, 4167IIIIO
5 H a=5. 8000IOTTR
e 0=10.0826ITION
86 5: Flow With a Free Surface
“MANN”’ Program Listing.
. - b L S¥-Bute Praom iz RCL """
LEL "MAMHH" 12 4
MYRRE "5V 14 EMNTER
MMAR ' is 2
MYARRE "t 16 +
MYAR "R 17 Y4x
S MWAR "at 12 =+
RCL "n" 1% RCL "a"
RCL= "M 28 A
TTT
Mo%
LP
00oe
TDD) T
I 5 -t
Il
e P50WD™)
I+T T = [Xx]
Fel
kY
m - = P
5: Flow With a Free Surface 87
Unit Conversions
88 6: Unit Conversions
Introduction
This chapter contains three programs for converting values from onesystem of units to another: “LENGTH,” “FORCE,” and “TEMP.”Instructions for writing your own unit conversion programs and theconversion factors for 120 units of measure are also included.
Variable Used. UNIT contains the current value expressed in the base
units.
Remarks.
m The following “Program Instructions” can be used with any of the
programs in this chapter.
m The program tests flag 22 to determine when a number has been
keyed in.
m Flags 21 and 55 are used to control printer output.
Program Instructions.
1. Key the appropriate program into your calculator. There are threesample programslisted in this chapter: “LENGTH” (page 91),“FORCE” (page 93), and “TEMP”(page 95).
2. Press followed by the menu key corresponding to theprogram (such as FORCE).
3. Key in the value you want to convert and then press the menu key
corresponding to the old units.
4. Press the menu key corresponding to the new units. The new valueis displayed. Repeatthis step for as manydifferent units as you wish.
5. To perform another conversion, go to step 3. Press [EXIT] to quit.
Example 1: Length Conversions. How many inches are in onekilometer? (Key the “LENGTH” program into yourcalculator.)
LEHG % 0. 0000RIATOIT
6: Unit Conversions 89
1 KN 1.86008 kmLot[M[Hed]N]FT|I
N 39,378.0787 inotHOJEMINFTK
Whatis the same distance in feet?
FT 3,280.8399 4%IRNGEN
Now convert six miles to meters.
6 HI 6. 8600 miITITGT
N 9, 656.0640 mNNTGG
EXIT
Example 2: Force Conversions. Convert a 135 pound force toNewtons. (Key the “FORCE” program into your calculator.)
FORCE |x: 9,656.0640 |LGFkPN[LeFJpPoL|
135 LEE 135.6008 1bf[GF [kIP |NJLeFJPOL]|
S H 600. 5899 NIATTAT
EXIT
90 6: Unit Conversions
“LENGTH” Program Listing. This program performs unitconversions using centimeters, meters, kilometers, inches, feet, and miles.
The base unit is the meter.
Program: Comments:
A L 122-Bute Fram
61 LBL “LEMGTH" Sets orclearsflag 21 to match flagB2 CF 21 55.
B3 FS7? 55
B4 SF 21
A5 CLMEHL Defines the unit menu. The value in@5 5TO “UMIT® the X-register is temporarily saved ina7 the variable UNIT.B3 K g1
63 KEQ
18 KEY 2 REQ 82
11 HEGR &3
12 KEY 2 HER 83
12 =ERQ 84
14 KEY 4 HE@ 64
13 HEQ 85
16 EEY 5 HEQ 835
17 HEQ @S
12 KEY & RER 88
13 KEEY 2 GTO @39
28 ECL “UMIT™
21 5F 22
2z LEL A Displays the menu and stops.MEHLSTOF
25 FCPC 22 If flag 22 is not set (no data entry),26 GTO ao converts the value into new units.
29
o8
6: Unit Conversions 91
oDDTe
LB
0Dy
D00
Ol
n
o oou
OO
oonodn
oL
oCRoCnon
e0F
00[
nTT
LN
o03POo0
00)
II
on
I
92
RCLx= "UHIT"
HZTO ST L
CLA
ARCL}_ I 1
ARCL ¢
AYIEL
GTO A
T ¥o
TL
LEL &1
"
[, 81
ETH
LEL &2Tt
1
ETH
LEL &z
"k
1R8E
ETH
LEL a4
LEL &9
EHD
6: Unit Conversions
Displays the new value and the unitstring.
Subroutines for each menu key.Each routine enters a string into theAlpha register and a conversionfactor into the X-register.
Ends the program (when ispressed).
“FORCE” Program Listing. This program performs unit conversionsusing gram-force, kilopound-force, Newtons, pound-force, and poundals.The base unit is the Newton.
Program: Comments:
BE L 193-Bute Fram
a1 LEL "FORCE® Sets orclearsflag 21 to match flagHZ CF 21 55.
Bz FSY 55
B4 BF 21
A5 CLMEMU Defines the unit menu. The value in@5 STO “UMIT® the X-register is temporarily saved ina7y HER 1 the variable UNIT.o2 KEY 1 =EQ 81
B3 WES Az
18 KEY 2 =ER B2
11 WED &
12 KEY 2 HE® @3
o omER 84
14 KEY 4 =EQ B4
15 wER 8%
1 KEY 5 HER A5
¥ OEEY 9 GTO 8%
13 RCL “"UHIT
19 5F 22
@ LEL A Displays the menu and stops.21 MEMU
2 STOP
= FC?C 22 If flag 22 is not set (no data entry),4 GTO 88 converts the value into new units.
STO "UHIT®
R »
2 LASTH
23 LEL 88 Displays the new value and the unitSR 1w string,
6: Unit Conversions 93
1 RCLx "HHIT®
23 CLA
24 ARCL ST &
25 k"o28 ARCL ST L
27 RAVIEN
22 GTO H
% LBL &1 Subroutines for each menu key.48 "af" Each routine entersa string into the41 F.2EEESE-Z Alpha register and a conversion42 ETH factor into the X-register.43 LBL B2
44 "kip"
45 4442, 22151528
48 BTH
47 LEL 82
43 "HY
49 1
S8 RTH
31 LEL P4
52 "lbe"
53 4,.44822151525
54 ETH
55 LEL 85
SE “pdl”57 B. 13825495438
=2 FETH
S9 LEL @2 Ends the program (when is&8 EMD pressed).
“TEMP” Program Listing. Conversions between the fourtemperature scales (Kelvin, °Celcius, °Fahrenheit, and °Rankine) involveadditive constants as well as multiplicative factors. Without these additiveconstants (on lines 47, 52, 57, and 62), only relative conversions would be
possible. Therefore, the “TEMP” program takes on a slightly differentform than the programslisted earlier.
94 6: Unit Conversions
.é To key in lines 46 and 47 of the following program, press1 [¢] 0. Use the same technique (pressing
Note and [¢] after the first number and before the second) to keyin lines 51 and 52, 56 and 57, and 61 and 62.
Program: Comments:
196-Bute Prom 3
LEL “TEMF" Sets or clearsflag 21 to match flagCF 21 55.
Fa® 55
SF 21
g 15
12
£o0[oT
[}
=l
o CLMEHLU Defines the unit menu. The value in
S OETO CUHITH the X-register is temporarily saved inWER the variable UNIT.
EEY
AEL
EEY
AED
2 EEY 2
HEL
EEY sEG B4
EEY GTO QA3
S RCL "UHIT!
7 SF 22
.._i T
=
[}e
HED @1
ote
[\™ L
WLTg
MER @z
e= 2]
=[
LA
-
oo0
BA
—_fa HER B3
-.
&Ns
e0
0 L
ot
S LEL A Displays the menu and stops.MEHLSTOFM
y=Vo
Tg)
21 STO e If flag 22 is not set (no data entry),z: converts the value into new units.
6: Unit Conversions 95
> Fx +
STO+ “UHIT®R
COEL)OT
w0
a1=
1.3RCL "UNIT®
II+II
S00
o
Vo=A [}
r-
RAREYA
TI
=A £=
bexd
._i
AECL ST L
Y IEL
GTO A
faoooO
g}
DMg
o=o0
N
LEL &1nao F: t
TNb
T
P
eoPooe
Taoo
000
=g
~A
mTy [x
]I
D]
Ja
03Mo~oD
Ol
oLnon
DM
-aM-
=}
cooou.
4
LEL &4
n r L]
il Ln n LN N .1 1 1 A n [
oo
on
Sown
0o
=]
TL
o
96 6: Unit Conversions
Displays the new value and the unitstring,
Subroutines for each menu key.Each routine entersa string into theAlpharegister, a conversion factorinto the Y-register, and an additiveconstant into the X-register.
Ends the program (when ispressed).
Writing Your Own Unit Conversion Programs
If the sample programsin this chapter do not contain the units that youwork with regularly, you may want to write your own unit conversionprograms.
1. Using thetable at the end ofthis chapter (or from other referencematerial), select up to six units of measure.
2. Using the conversion program thatfollows,fill in the blank lines asfollows:
a. Line 01 should be a globallabel that indicates the type ofunits included (such as LEL "MASS" or LEL "TIME").
b. The two lines immediately following each label, LEL @1(line 41) through LEL &¢ (line 61), should include the unitname and the conversion factor.
Each conversion factor you use should be expressed inrelation to the same base unit. (For example,in the“LENGTH” program above, the base unitis the meter.)
€. Optional: If you assign your unit conversion programsto thecustom menu, you can make them appear to be submenus ofCUSTOM by inserting SF 27 after LEL @9,
6: Writing Your Own Unit Conversion Programs 97
The Blank Conversion Program.
II onnn~-Buate Pram b A=TO =T L
a
@1 LEL "program name here" S CLA
@z CF 21 & ARCL ST W
Bz F37 55 il i
84 SF 21 @ ARCL ST L
85 CLMEHU 3 AVIEW
BE STO "UMIT B GTO A
Ay HER B1 LEL &1
— [x] EEY
HEQ
EEY
=ER
12 KEY
o wER
14 KEY
o aElR
18 KEY
17 HEL
2 OREEY & X
12 KEY S
28 RCL "UMIT®
HER B1 "unit name here"
conversion factor here
RTHLEL B2"unit name here"
conversion factor here
FTHLEL &%"unit name here"
conversion factor here
RETHLEL &4“"unit name here"
I
I%
oowDs)
AER Bz
oMo
.s5
et
n
HER @3
T3)
o
¥
~E& B4
Lo
0OJa
Ti_
n
m Jo)
oL
e0NeoeeebooBo
00
Q00
00
D00
00
oo — = (o]
nLo
Q0
POo
CaonD
00)
in
35 conversion factor here
SE HTH57 LEL 85S5 "unit name here"
conversion factor hereFTH
LEL B&"unit name here"
conversion factor here
ETH
LEL 8%
EME
0 oL
D=]
DAY
TuT
A =
o(T
L00e
S R
86 LAS
LEL && &5
1%RCL= "LHIT"
o1
e0
0OL9
£[o=
Tw0
98 6: Writing Your Own Unit Conversion Programs
Dimensionless Units of Angle
Plane and solid angles are called dimensionless because they involve nophysical dimensions. The following table relates these dimensionless unitsto their actual values.
Dimensionless
Unit Abbreviation Value
Arcmin arcmin 1 it ciunit circle21600
Arcsec arcs 1 it ci——— unit circle1296000
Degree ° 1 unit circle360
Grade grad L unit circle400
Radian r 1 unit circle2
Steradian sr i unit sphere
6: Dimensionless Units of Angle
Conversion Factors
The conversion factorsin the following table are based on theInternational System of Units (SI).
If you use a unit that is not in the table, be sure that the conversion factorcorrectly relates the unit to the base unit for your program.
Unit Full Name Description Value
a Are Area 100 m?
A Ampere Electric current 1A
acre Acre Area 404687260987 m*
arcmin Minute of arc Plane angle 4.62962962963E -5
arcs Second of arc Plane angle 7.71604938272E-7
atm Atmosphere Pressure 101325 N/m?
au Astronomical unit Length 149597900000 m
A° Angstrom Length 0.0000000001 m
b Barn Area 1.E-28m?
bar Bar Pressure 100000 N/m2
bbl Barrel, oil Volume 0.158987294928 m’
Bq Becquerel Activity 11/s
Btu International Table Energy 1055.05585262 Kg-mz/s2Btu
bu Bushel Volume 0.03523907 m’
c Speed of light Velocity 299792458 m/s
C Coulomb Electric charge 1A-s
cal International Table Energy 4.1868 Kg-m2/s2calorie
cd Candela Luminous intensity 1cd
chain Chain Length 20.1168402337 m
100 6: Conversion Factors
Unit Full Name Description Value
Ci Curie Activity 3.7E101/s
ct Carat Mass 0.0002 Kg
cu US cup Volume 2.365882365E -4 m°
d Day Time 86400 s
dyn Dyne Force 0.00001 Kg-m/:?.2
erg Erg Energy 0.0000001 Kg-mz/s2
eV Electron volt Energy 1.60219E - 19 Kg-m?/s?
F Farad Capacitance 1 A2-s4/Kg-rn2
tath Fathom Length 1.82880365761 m
fom Board foot Volume 0.002359737216 m’
fe Footcandle Luminance 0.856564774909
Fdy Faraday Electric charge 96487 A-s
fermi Fermi Length 1.E-15m
flam Footlambert Luminance 3.42625909964 cd/m?
ft International foot Length 0.3048 m
ftUS Survey foot Length 0.304800609601 m
g Gram Mass 0.001 Kg
ga Standard freefall Acceleration 9.80665 m/s2
gal US gallon Volume 0.003785411784 m®
galC Canadian gallon Volume 0.00454609 m®
galUK UK gallon Volume 0.004546092 m>
of Gram-force Force 0.00980665 Kg-m/s2
grad Grade Plane angle 0.0025
grain Grain Mass 0.00006479831 Kg
Gy Gray Absorbed dose 1 mz/s2
h Hour Time 3600 s
H Henry Inductance 1 Kg-mz/Az-s2
6: Conversion Factors 101
Unit Full Name Description Value
hp Horsepower Power 745.699871582 Kg-m2/s3
Hz Hertz Frequency t1/s
in Inch Length 0.0254 m
inHg Inches of mercury Pressure 3386.38815789 N/m2
inH20 Inches of water Pressure 248.84 N/m?
J Joule Energy 1 Kg-mz/s2
kip Kilopound-force Force 4448.22161526 Kg-m/s?
knot Knot Speed 0.514444444444 m/s
kph Kilometer per hour Speed 0.277777777778 m/s
| Liter Volume 0.001 m*
lam Lambert Luminance 3183.09886184 cd/m2
Ib Avoirdupois pound Mass 0.45359237 Kg
Ibf Pound-force Force 4.44822161526 Kg-m/s?
Ibt Troy Ib Mass 0.3732417 Kg
Im Lurmen Luminance flux 7.95774715459E-2 cd
Ix Lux lluminance 7.95774715459E -2 cd/m?
lyr Light year Length 9.46052840488E15 m
m Meter Length im
mho Mho Electric 1 A2-s3/Kg-m2conductance
mi International mile Length 1609.344 m
mil Mil Length 0.0000254 m
min Minute Time 60s
miUS US statute mile Length 1609.34721869 m
mmHg Millimeter of Pressure 133.322368421 N/m2mercury
mol Mole Amount of 1 mol
substance
mph Miles per hour Speed 0.44704 m/s
102 6: Conversion Factors
Unit Full Name Description Value
N Newton Force 1 Kg-m/2
nmi Nautical mile Length 1852 m
ohm Ohm Electric resistance 1 Kg-rnz/Az-s3
oz Ounce Mass 0.028349523125 Kg
ozfl US fluid oz Volume 2.95735295625E-5 m>
ozt Troy oz Mass 0.031103475 Kg
0zUK UK fluid oz Volume 0.000028413075 m*
P Poise Dynamic viscosity 0.1 N/m
Pa Pascal Pressure 1 N/m2
pc Parsec Length 3.08567818585E16 m
pdi Poundal Force 0.138254954376 Kg-m/‘.-‘»2
ph Phot Luminance 795.774715459 cd/m?
pk Peck Volume 0.0088097675 m>
psi Pounds per square Pressure 6894.75729317 N/m2
inch
pt Pint Volume 0.000473176473 m>
qt Quart Volume 0.000946352946 m®
r Radian Plane angle 0.159154943092
R Roentgen Radiation exposure 0.000258 A-s/Kg
rad Rad Absorbed dose 0.01 m?/s?
rd Rod Length 5.02921005842 m
rem Rem Dose equivalent 0.01 mz/s2
s Second Time 1s
S Siemens Electric 1A23/Kg-m2conductance
sb Stilb Luminance 10000 cd/m?
slug Slug Mass 14.5939029372 Kg
sr Steradian Solid angle 7.95774715459E -2
6: Conversion Factors 103
Unit Full Name Description Value
st Stere Volume 1m?
St Stokes Kinematic viscosity 0.0001 m2/s
Sv Sievert Dose equivalent 1 mz/s.2
t Metric ton Mass 1000 Kg
T Tesla Magnetic flux 1 Kg/A-s2
tbsp Tablespoon Volume 1.47867647813E-5 m>
therm EEC therm Energy 105506000 Kg-r'r'rz/s2
ton Short ton Mass 907.18474 Kg
tonUK Long ton Mass 1016.0469088 Kg
torr Torr Pressure 133.322368421 N/m?
tsp Teaspoon Volume 4.92892159375E-6 m°
u Unified atomic mass Mass 1.66057E-27 Kg
Vv Volt Electric potential 1 Kg-mz/A-s3
w Watt Power 1 Kg-m2/s3
Wb Weber Magnetic flux 1 Kg-mZ/A-ta2
yd International yard Length 09144 m
yr Year Time 31556925.9747 s
° Degree Angle 2.77777777778E-3
°C Degree Celsius Temperature 1 K*
°F Degree Fahrenheit Temperature 0.555555555556 K*
K Degree Kelvin Temperature 1 K*
°R Degree Rankine Temperature 0.555555555556 K*
@ Micron Length 0.000001 m
*Refer to the “TEMP" program listing starting on page 94.
104 6: Conversion Factors
Step-by-Step Solutions for Your
HP-42S Calculator
Mechanical Engineering contains a variety of programs and examples toprovide solutions for mechanical engineers and engineering students.
m Forces and Vectors
Vectors in the HP-42S o Static Equilibrium at a Point
® Equations of Motion
w Analysis Programs
Mohr Circle Analysis » Soderberg’s Equation for Fatigue ¢ CompositeSection Properties o Spring Constant e Linear or AngularDeformation
® Thermodynamics
Equations of State Black Body Thermal Radiation
u Fluid Dynamics
Conduit Flow e Flow With a Free Surface
= Unit Conversions
Writing Your Own Unit Conversion Programs e Dimensionless Unitsof Angle e Conversion Factors
HEWLETT
(D PACKARD \
Reorder Number
00042-90022 :
00042-90024 English
0""88698"00038"" o0Printed in Canada 10/88