General Problem Statement
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Transcript General Problem Statement
Multiple-output, Variable-output DC
Power Supply
May03-22
Team Members:
Erik Johnson
Joel Jorgensen
Peter Holm
Philip Schulz
Clients – Prof. Patterson, Prof. Lamont
Faculty Advisor – Dr. Allan Potter
April 30th, 2003
Presentation Overview
Problem statement and solutions
Summary of activities
Resource requirements
Summary of progress
Questions
General Problem Statement
Develop a power supply with the following
voltages: +1.5V, 3.0V, +3.2V, +4.5V,
5.0V, +6.0V, +7.5V, +9.0V, 12.0V,
+15.0V, +18.0V, +24.0V
Output 2 + voltage outputs and 2 + voltage
outputs simultaneously
Produce for a low cost (~$150)
Allow a maximum current of 1A through
each set of terminals
Solution Approach
Develop general design
Simulate and test on CAD program
Order parts
Assemble
Test
Modify and re-test if necessary
Operating Environment
Standard laboratory conditions
– Indoors
– Approximately 24 degrees Celsius
Standard 120V, 60 Hz wall output
End Users and Uses
Users
– Research and design students
– Faculty
Uses
– Power and test design projects
– Produce a small current at many voltages
– Provide several voltages simultaneously
Assumptions and Limitations
Assumptions
– All four outputs will be used simultaneously
– Power supply will be used indoors at room temp
– Power supply will be powered by 120V, 60 Hz
Limitations
– Output current limited to 1A max per output
– Total cost must be below $150
– Input must be 120V at 60 Hz
End Product Description
4 selectable output voltage terminal sets
Maximum current of 1A per output
Output voltage selected by rotary knobs
Digital readout of voltage, current and
wattage
Fuses for power supply protection
End Product
Present Accomplishments
Schematic simulated and successful
Successfully implemented transformer and
bridge rectifiers on circuit board
Successfully implemented +/- voltages on
circuit board
Examined methods of implementing
positive only voltages
Approaches to the Design
Recycle/modify/incorporate existing
insufficient power supplies
Create and design an original power supply
– Use store-bought voltage converters
– Design and create voltage converters
» Flyback converter
» Buck converters
» LM317T/LM337T voltage regulators
Project Definition Activities
The power supply specs were expanded
from the original to include the following:
– +3.2V, +7.5V, +15V, and +18V
– 2 + voltage outputs and 2 + voltage outputs
– Ammeter and voltmeter
Research Activities
The need for more voltage outputs was
researched.
– It was found that the additional voltages of
+3.2V, +7.5V, +15V, and +18V would be useful
for small home electronics
Also researched various power supply
designs for ideas to implement in the final
product.
LM317T/LM337T Voltage
Regulators
Adjustable output down to +1.2v
Adjustable current limiting feature
Line regulation typically .01%/V
Load regulation typically .1%
80 dB ripple rejection
TL494 PWM Control Circuit
Up to 200 kHz oscillator frequency
Feedback allows voltage and current
regulation
Design Activities
Different implementation schematics tested
Because the LM317T/LM337T voltage
regulators are not in the Workbench/Pspice
libraries, the circuits were physically tested
120V TX 124V
D1
C1
1n
V1
120V ac
0Vd c
D3
R1
D2
D4
10
0
24V
1
V = +24V
2
100uH
D13
V = +12.0V
100uH
5.1u
24.00
D13
5.1u
12.37
V = +6.0V
100uH
D13
5.1u
6.09
V = +3.2V
100uH
D13
5.1u
3.22
V = +1.5V
100uH
D13
1
5.1u
V = +18V
2
100uH
D13
1.51
V = +9.0V
100uH
5.1u
18.41
D13
5.1u
9.21
V = +4.5V
100uH
D13
1
5.1u
V = +15V
2
100uH
D13
4.55
V = +7.5V
100uH
5.1u
15.43
D13
5.1u
7.64
D1
120V TX 112.5V
D3
1
U9
IN
2
C7
C9
C1
V1
120V ac
0Vd c
2200u
D2
0
0
2200u
LM337T
Vreg
OUT
V = -3.0V
R9
.1u
120
0
D4
C10
1u
0
R8
C8
10u
1032
0
D7
1
U9
1
U9
IN
2
C7
0
2200u
LM317T
Vreg
OUT
C7
V = +12.0V
C9
R9
C10
240
1u
D6
.1u
IN
2
0
0
2200u
C9
.1u
120
0
0
C7
0
2200u
LM317T
Vreg
OUT
V = +5.0V
R9
C10
240
1u
D6
.1u
0
0
720
0
D7
IN
C7
V = +3.0V
C9
2200u
0
LM317T
Vreg
OUT
R9
C10
D6
.1u
240
0
R11
C8
10u
336
0
1u
0
C9
2200u
0
LM337T
Vreg
OUT
V =
-12.0V
C10
R9
.1u
120
0
R11
C8
10u
336
0
R10
2
IN
2
C7
C9
C8
10u
1
U7
360
2064
1
U7
IN
1u
0
0
D7
2
C10
R10
C8
10u
0
1
U9
V = -5.0V
R9
R8
C8
10u
LM337T
Vreg
OUT
1u
0
Personnel Effort Budget
Team Members
Paper Work
Research
Design
Construction
Totals
Est.
Act.
Est
Act.
Est.
Act.
Est.
Act.
Est.
Act.
Erik Johnson
8
10
21
14
32
25
12
13
73
58
Joel Jorgensen
5
27
25
13
34
26
13
14
77
76
Peter Holm
9
25
15
7
25
22
14
8
63
58
Philip Schulz
7
10
18
8
28
27
12
12
65
53
27
72
79
42
119
100
51
47
278
265
Totals
Financial Budget
Item
Original Estimated Cost
Cost to Date
Poster
$50.00
$50.00
Case
$14.99
$0.00
Transformers
$35.53
$21.94
Resistors/capacitors/diodes
$26.80
$21.18
Cooling fan
$9.99
$8.99
Switches, dials, and terminals
$25.00
$6.21
Meters ($10.25 each)
$30.75
$0.00
Variable voltage regulator
$4.00
$3.90
$197.07
$112.22
Total
Project Schedule
Project Schedule, cont.
Project Evaluation
Done on a scale of: incomplete = 0%, to complete = 100%
Milestones:
Define problem
100%
Determine solution
100%
Design power supply
95%
Order parts and assemble
75%
Test
75%
Revise and retest if necessary
75%
Release
0%
Overall Status: Prototype
Commercialization
Estimated cost to produce: $100 - $200
Estimated sales price: $400 - $1000
It is anticipated that this product would have
a very large market
– Versatile
– Financially viable
Recommendations for
Additional Work
Finish original implementation
Develop a commercial version
Add power factor correction
Make each set of terminals fully isolated
Make current limitation adjustable
Lessons Learned
What worked
– Team worked well at brainstorming, designing
– Advisor was helpful when we got stuck
– Regular, scheduled meeting
What did not work
–
–
–
–
–
Collaborating on reports and poster
Weekly status reports
Ordering parts
Gaining the necessary knowledge
Advisor absence for extended period of time
Lessons Learned (cont)
Technical knowledge gained
–
–
–
–
How power supplies work
How DC-DC converters work
How transformers work
How to use Workbench
Things to do differently
– Put more time into research early on
Risks and Risk Management
Illness
– Follow good health practices
– Take on some of the sick member’s workload among
the other members
Accidents such as electrocution or fire
– Follow high voltage safety procedures when
assembling
– Cut power, use First Aid, call 911, put out fire
Losing a team member
– Be such a good team that nobody wants to leave
– Divide the work among the remaining members, seek
assistance from colleagues
Summary
Problem: Replace the current power supplies with a
single versatile tool
Approach: Consider several different alternatives by
which multiple voltages can be provided
simultaneously by a single power supply
Solution: Provide two plus/ground terminals and
two plus/minus/ground terminals whose voltage can
be set independently of the others. Also provide
meters to display the voltage, current, and wattage of
the selected set of terminals
What questions do you have?