1. The UPS Team 5

2. Team 5: Staff Michael Myers BSEE Fernando Muñoz Jesus Lopez
Adam Bitter
Jake Koturbo
BSEE

3. Team 5: Expertise & Experience
Michael Myers
Fernando Muñoz
Jesus Lopez
Adam Bitter
Jake Kotrba
Expertise: Power and Electromagnetics
Experience: Kimberly-Clark, General Motors
Expertise: Power, Motors
Experience: Airforce electrician
Expertise: Controls, Power
Experience: We energies, Gossen Corporation
Expertise: Controls
Experience: N/A
Expertise: Power, Motors
Experience: Chicago-Kenosha Building Developement

4. The UPS Power backup for small power consumption
appliances: features and functions!!!!!!
PCs
Space heaters
Elaborate more

5. + + + + Vac Sensor Jake AC Switch Jesus Main Switch Jesus Load Display
CPU
Adam
Quick
Charger
Fernando
Trickle
Charger
Fernando
Inverter
Mike + + + +
Battery
Fernando
Vdc
Sensor
Jake
Idc
Sensor
Jake

6. Performance Requirements
Input AC Voltage: V
Input AC Current: max 15 A
Input AC Frequency: 60Hz +/- 3Hz
Output AC Voltage: V
Output AC Current: max 15 A
Output AC Frequency: 60Hz +/- 3Hz
Battery Size: 12V battery
Battery Life: 1 hour
Digital Functions: User display refreshed every 1/10 sec, monitoring and display input AC
User Interface: LEDs indicator, push pad
Power Mode: On/Off manual switch
Sensory: Current, Voltage and Frequency
Mounting: Feet
Plug: Type B

7. Standard Requirements
Operating Range: ºC
Max Operating Relative Humidity: 95%
Operating Pressure Range: 1 atm +/- 15%
Max Storage Duration: 10 years
Energy Sources: AC, automotive battery
Source connections: AC utility and DC battery
Power Consumption: Watt hours per year
Max Volume: cm3
Max Weight: 14 kg

8. Project Plan

9. + + + + + Vac Sensor Jake AC Switch Jesus Main Switch Jesus Load User
Interface
Jesus +
CPU
Adam
Quick
Charger
Fernando
Trickle
Charger
Fernando
Inverter
Mike + + + +
Battery
Fernando
Vdc
Sensor
Jake
Idc
Sensor
Jake

10. Name: Michael Myers Major: Electrical engineering Team 5: UPS Assignment: block 1 Block 1: Inverter

11. + + + AC Vac Sensor Jake Charging Switch Jesus Power Source Switch
Load
User
Interface
Jesus +
CPU
Adam
Quick
Charger
Fernando
Trickle
Charger
Fernando
Inverter
Mike + +
Battery
Fernando
Vdc
Sensor
Jake
Idc
Sensor
Jake

12. Inverter
Once the power fluctuates outside the boundaries a control switch will allow the inverter power to transfer to the circuit.

13. Power Inverter
The job of this inverter is to transfer 12Vdc to 120Vac.
This device will always be on
Control switch will allow inverter power to flow

14. Analog and digital interfacing – N/A
Signal Table
Power Signals
Type
Direction
Voltage
Voltage Range
Freq
Freq Range
% V-Reg
V-Ripple
Current
Nominal
Min
Max
Power1 VCC +12
DC- Power
Input
12.0V
10.2
13.2V DC
N/A
5.00%
0.1V
18A
Power2 VCC -15V
AC- Power
Output
120.0V
102V
132.0V AC 57 63
0.25V
15.00A
Analog and digital interfacing – N/A

15. Prototyping Plan Inverter 700 Fiber Glass Solder Yes Flat Pins Block
Name
Block Area (cm2)
Total PCB
Area (cm2)
PCB
Substrate
Type
Comp
Attachment
Socketed
Components
Types of
Connectors
Inverter
700
Fiber Glass
Solder
Yes
Flat Pins

16. DFM Sub Circuit Type Applicable Worst Case Analysis Plan
(See DFM Analysis Guide)
 Task
Task 1
Task 2
Task 3
Task 4
Task 5
Task 6
Task 7
Task 8
Task 9
Task 10
Timer IC
R, L & C
Tol
RLC Specs
Gain vs
Freq
Phase vs
Slewrate BW
Step Resp
Input
Impedance
Output
DC Offset V
Total
Noise
Wave formation
Max Offset
Voltage
DC Gain vs
Component
Variations
DC Gain vs
Freq vs
Comp Var
Phase vs Freq
vs Comp Var
Power
Bandwidth
Pulse
Response &
Delay
Smoother
Step
Responce
Transformer
Nominal
Value or
Max Value
Adjustment
Range,
%/Turn
Tolerance
Around
Derated
Capacity
Maximum
Working
Constant
Current
Surge Current
Composition
Dielectric or
Form
Q Factor or
Frequency
Variation
Package

17. Inverter Block Diagram
Timing Unit
57-63 HZ
Transistor
switching
Transformer
Out to Load
DC input
12-15 VDC

18. Schematic Diagram

19. Functionality Simulation
Supposed to be -12<=V<=12 before
Transformed to -120<V<120
This is the desired output not
Yet achieved
Due to Pspice limitations, a worst
Case scenario was not able to be
Obtained.

20. Bill of Materials Part Part # Quantity Description Price Source R1
KFCT-ND 1
10k Resistor, ±.1%, .25W
0.88
Digikey R2
KFCT-ND
100k Resistor, ±.1%, .25W R3
FCT-ND
100 ohm Resistor, ±.1%, .25W R4
4LG54BK-ND
50k potentiometer, ±25%, .3W
0.59
C1, C2 ND
0.1 uF Capacitor, ±10%
0.26 C3
0.01 uF Capacitor, ±10%
0.54 C4
P11706-ND
2700 uF Capacitor,±10%
6.37 Q1 ND
TIP41A, NPN Resistor, 100V
0.95 Q2 ND
TIP42A, PNP Resistor, -100V
1.04 L1 ND
1uH, ±15%
0.67 T1
Transformer 1/10
10.49
Radio Shack

21. Name: Fernando Muñoz Major: Electrical engineering
Team 5: UPS Assignment: Power Block Block 2a: Charger (Rectifier)
Block 2b: Battery
Jjkjk

22. + + + Vac Sensor Jake Charging Switch Power Source Switch Load User
Interface
Jesus +
CPU
Adam
Quick
Charger
Fernando
Trickle
Charger
Fernando
Inverter
Mike + +
Battery
Fernando
Vdc
Sensor
Jake
Idc
Sensor
Jake

23. Main Purpose
Keep a constant charge in the battery so when commercial power is lost, the device to which the UPS is connected to stays on for about a half hour or until the battery drains completely.
Provide 5 VDC logic to the CPU which power s all essential controls and sensors.

24. Power Inputs and Outputs
Transformer Input : 120 VAC / 20Amp
Transformer Output / Rectifier Input :
15.7 VAC (Step Down)
Rectifier Output #1 : 14.3 VDC
Rectifier Output #2 : 5 VDC

25. Power Electrical Interface Signals
Power Signals
Type
Direction
Voltage
Voltage Range
Freq
Freq Range
% V-Reg
V-Ripple
Current
Nominal
Min
Max
Power-1 AC Input
AC Power
Input
120V
102V
132V
60Hz
57Hz
63Hz
15.00%
N/A
15A
Power-2 VCC +14.3V
DC Power
Output
14.3V
12.15V
15.73V DC
1.00%
0.01V
35A
Power-3 VCC +14.3V 2A

26. Block diagram of Power Supply System
120 VAC
Main Input
Transformer
Rectification
Smoothing
Regulation
14.3 / 5 VDC
Regulated
output
14.3 VDC
With
Ripple
15.7 VAC
14.3 VDC

27. 5 VDC Power Regulated System

28. Prototyping Plan Block Name Block Area (cm2) Total PCB Area (cm2) PCB
Substrate
Type
Comp
Attachment
Socketed
Components
Types of
Connectors
Power
700
Copper
Solder No
B type plug
Flat Pins

29. Functionality Simulations

30. Transient Response

31. Maximum WV for Capacitors
Referencing to the manufacturer (Digikey) specification the following value was chosen as WV.
470uF Capacitor:
WV : 10VDC
Leakage Current: 235uA
Ripple Current: 570mA
Dimensions: 32(L)*10.3(D)*0.8(d) mm

32. Power Ratings Diodes: P = V*I P = (16V)*(2A) = 32W
Resistors: They were only placed in Pspice simulation in order to have the transformer work properly and give accurate results.

33. Capacitor Tolerance
This Solid Axial 470uF Capacitor has a range of small long life (20000H).
Tolerance±20% and ±10% on request
Usable Temperature range:-80oC to +125oC

34. Off Board Connectors
Battery Post: To achieve a mechanically secure and tight connection we’ll be using adjustable clamps.
Transformer: It will be sitting on a hard surface at the bottom of the UPS, we’ll use flat pin connectors to connect wires going to the rectifier.
DC to DC Connector: Flat pin connectors.

35. Charge Type
Trickle Charge : Constantly supplies the battery with 14.3 VDC at 2 Amps.
Logic Charge : Constant +5 VDC converted from the 12 VDC coming out of the battery, this will power CPU, sensors and interface.

36. Bill of Materials Part Part # Quantity Description Price Source C1C1
4278PHCT-ND 1
470 uF Capacitor
4.49
Digikey
C2,C3 ND
0.1 uF Capacitor
0.54
Conv. ND
DC to DC Converter
71.5
Diode
1N4001
Bridge Rectifier
1.6
Maplin
VDC
P174-ND
Lead Acid Battery
34.56 T1
DCT
Transformer 120/16 56
Grainger

37. Name: Jesus Lopez Major: Electrical engineering Team 5: UPS Assignment: blocks 3 and Block 3: Switching Gear Block 4: Display

38. Switching Gear
The switching for this project will be effectuated by a solid state relay.
Main switch.
Charging switch.
Note: other switches may be needed for different.
Blocks.

39. + + + AC Vac Sensor Jake Charging Switch Jesus Main Switch Jesus Load
User
Interface
Jesus +
CPU
Adam
Quick
Charger
Fernando
Trickle
Charger
Fernando
Inverter
Mike + +
Battery
Fernando
Vdc
Sensor
Jake
Idc
Sensor
Jake

40. Switching Gear Sub-Blocks
Main Switch
Charging Switch
Note: switch elimination

41. From the Utility
Main
Switch
To the load
From the inverter
Charging
Switch
To the rectifier
From the utility

42. Main Switch
Selects utility or battery.
CPU control.

43. Main Switch Nominal Ratings
Control Input : 6 Vdc
Input: 120 Vac
Output: 25 A

44. Charging Switch
Battery Charging
CPU control

45. Switch Nominal Ratings
Control Input : 5 Vdc
Input: 120 Vac
Output: 30 A

46. Main Switch Signal Table
Power Signals
Type
Direction
Voltage
Nominal
Voltage Range
Freq
Freq Range
% V-Reg
Max
V-Ripple
Current
Min
Power1 DC +5
DC Power
Input
5.0V
4.75V
5.25V
5.00%
0.1V
1.2A
Power1 AC
AC Power
120V
102V
132V
60Hz
57Hz
63Hz
15.00%
N/A
1.0A
Power2 AC
Output
Power3 AC

47. Charging Switch Signal Table
Power Signals
Type
Direction
Voltage
Nominal
Voltage Range
Freq
Freq Range
% V-Reg
Max
V-Ripple
Current
Min
Power1 VCC +5
DC Power
Input
5.0V
4.75V
5.25V
5.00%
0.1V
1.2A
Power2 AC
AC Power
120V
102V
132V
60Hz
57Hz
63Hz
15.00%
N/A
1.0A
Power3 AC

48. Switching Key Components
SPDT switch
SPST switch
Note: zero cross switch application &
phase lock loop

49. Switches Bill of Materials
Item
Package
Units
Power Consumption
Price $
Vendor
Switch
Relay 1
27mW
34.00
Digikey
N/A

50. Switching Gear DFM Plan
Main Switch
Sub-Block Type
Input Type
Max input Voltage
Min Input Voltage
Power Consumption
Relay
AC: Output
DC: Control Input
Output:
132 V
Control Input:
6.5 V
102 V
Control Input: 3.5 V
17 mW

51. Display Features: On/Off manual power switch. On/Off LEDs. AC/DC LEDs.
Fast/Slow charging mode LEDs.
Remaining power LED array indicator.

52. + + + AC Vac Sensor Jake Charging Switch Power Source Switch Load
Display
Jesus +
CPU
Adam
Quick
Charger
Fernando
Trickle
Charger
Fernando
Inverter
Mike + +
Battery
Fernando
Vdc
Sensor
Jake
Idc
Sensor
Jake

53. Display Sub-Blocks Remaining power LED bar indicator UPS status LEDs
On/Off Switch

54. To the battery terminal
Manual Input
Power
On/Off Switch
From the CPU
LED Bar
From the CPU
Status LEDs

55. Display Signal Table Power Signals Type Direction Voltage Nominal
Type
Direction
Voltage
Nominal
Voltage Range
Freq
Freq Range
% V-Reg
Max
V-Ripple
Current
Min
Power1 VCC +5 (switch)
DC Power
Input
5.0V
4.75V
5.25V DC
N/A
5.00%
0.1V
1.2A
8-bit channel
Digital

56. Display Key Components
LED Bar Graph Arrays
Manual Switch
LEDs

57. Display Bill of Materials
Item
Package
Units
Power Consumption
Price $
Vendor
LED bar graph array
Chip 1
750 mW
2.10
DigiKey
LEDs
N/A 4
300mW
2.00
On/Off
switch
Minimal Resistance
1.50

58. Display DFM Plan Display Sub-Block Type Input Type Max input Voltage
Min Input Voltage
Power Consumption
Remaining Power LED Chip DC
6.0 V
3.5 V
750 mW
Status LEDs Indicators
300 mW
On/Off Switch
Manual
N/A

59. End of UPS blocks 3 and 4 !!!

60. Name: Adam Bitter Major: Electrical engineering Team 5: UPS Assignment: CPU

61. + + + AC Vac Sensor Jake Charging Switch Power Source Switch Load User
Interface
Jesus +
CPU
Adam
Quick
Charger
Fernando
Trickle
Charger
Fernando
Inverter
Mike + +
Battery
Fernando
Vdc
Sensor
Jake
Idc
Sensor
Jake

62. CPU The CPU will do the following things:
Read in a utility (AC) voltage signal
Read in a battery voltage signal
Control the switching of the power source switch
Control the switching of the charging switch
Output a battery life signal to the display

63. CPU
The CPU will switch to the battery when the voltage read in is below 105 V
When the battery is run dead the CPU will switch on the fast charger for a certain period of time

64. CPU
The CPU will send a signal to the display indicating the life of the battery based on the battery voltage level
If necessary it will also be able to send more outputs to the display

65. Sensor Signals 8 bits = 28 = 256 values Vac range = 0 – 132V
132/256 approx = .5V per bit
Vdc range = 0 – 14.3V
14.3/256 approx = 50mV per bit

66. Vac Sensor Input Digital Input 8 bits of input at 5V
Approx .5V per bit
UPS switched on when input is less than 105V =

67. Vdc Sensor Input Digital Input 8 bits of input at 5V
Approx 50mV per bit

68. Display Output Digital Output 8 bits of output at 5V Display is LED’s
8 levels of battery life
is fully charged battery
is dead battery

69. Lattice M4 64/32 15JC

70. DC Drive Device Parameters
CPU
Dig
Device
Output
Type
Input Type
Tech Type
DC Drive Device Parameters
Vil
max
Vih
min
Iil (-)
Max
Iih
Vol
Voh
Iol
Ioh (-)
Min
Vhyst
Checked
CPU
Std
CMOS
0.8V
2.0V
0.2uA
-0.2uA
0.6V
4.3V
4.6mA
-2mA
N/A

71. CPU Timing Min Clock Setup Time: 5ns Min Clock Hold Time: 3.5ns
Min Input Register Setup Time: 2ns
Min Input Register Hold Time: 3ns
Min Input Latch Setup Time: 2ns
Min Input Latch Hold Time: 3ns
Max Output Enable Time: 9.5ns
Max Output Disable Time 9.5ns

72. CPU Prototype Plan Block Name Block Area (cm2) Total PCB Area (cm2)
Substrate
Type
Comp
Attachment
Socketed
Components
Types of
Connectors
CPU
100 12
Copper
solder
Yes
Ribbon Cable

73. CPU Signals

74. CPU Power

75. Pseudo Code Start: Read in Vac if Vac < 11010010
switch on power switch
if power switch on
if Vac >
switch off power switch
Read in Vdc
output Vdc to display
if Vdc < Dead Battery
switch on fast charger for 1 hour
Loop Start

76. CPU Signals Input: AC voltage: 8 bits, 5V DC DC voltage: 8 bits, 5V DC
Output:
Display: bits, 5V DC
Charging Switch: 1 bit, 5V DC
Power Switch: bit, 5V DC

77. Name: Jake Koturbo Assignment: block 6 Block 6: Sensors

78. Purpose:
It’s how the CPU interfaces with the input and output power.

79. Advantages of Using Sensors
Upper and lower limit can be adjusted with a small change in the CPU’s programming.
Provide accurate user interface read-outs

80. Sensor Performance Requirements
Input: Analog (nominal)
120Vac
5Vdc
Output: Digital (nominal)
8-bits (5V logic)

81. Output continued… Directly interface with only the CPU
All sensor outputs will supply the eight bit signal to the CPU.
All sensors will use A/D converters and therefore use 5volt.

82. The reason for 8-bits 28 = 256 partitions
132V divided by 256 gives us a measuring accuracy of about 0.5V

83. Sensor Standard Requirements
Operating Voltage:
Max 5.25Vdc
Min 4.75Vdc
Operating Temperature:
Max 50 C
Min -15 C
Humidity:
Max 95% r.h.

84. + + + AC Vac Sensor Jake Charging Switch Power Source Switch Load User
Interface
Jesus +
CPU
Adam
Quick
Charger
Fernando
Trickle
Charger
Fernando
Inverter
Mike + +
Battery
Fernando
Vdc
Sensor
Jake
Idc
Sensor
Jake

85. Sensor Power Interface
Type
Direction
Voltage Nominal
Voltage Range
Frequency Nominal
Frequency Range
% V-Reg.
V-Ripple
Current
Min
Max
DC Power
Input
5.0V
4.75V
5.25V 5%
0.2V
0.5A

86. Sensor Analog Interface
Analog Signal
Type
Direction
Coupling
Voltage Amplitude Maximium
Impedence
Frequency Range
Leakage Max
Min
Max
Vac
Analog
Input
Xfmr
132V 5k
20k
63Hz
500uA
Vdc
14.3V
1Hz
Idc
5.25V

87. Sensor Digital Interface
Digital Signals
Type
Direction
Input Structure
Technology
Logic Voltage
Output Characteristics
Voh Min
Ioh Max
Vol Max
Iol Min
Vac 8-bits
Digital
Output
Standard
TTL 5V
3.25V
0.5mA
1.8V
0.1mA
Vdc 8-bits
Idc 8-bits

88. Convert to a proportional 0-5Vdc analog signal
Simplified Sensor
Analog Signal
CPU
Convert to a proportional 0-5Vdc analog signal
ADC
Vcc~5V

89. Vac Sensor Measure the input voltage from the commercial supply.
Produce an eight bit output.
Signal is monitored by the CPU to initilize the use of the inverter.

90. Placement of the Vac Sensor
AC power
AC power
CPU

91. Basic Schematic Layout

92. Because of the large voltage capabilities of the bridge rectifier, no step-down transformer is needed

93. Basic Schematic Layout
Without the transformer

94. Calculations for the Vac Sensor
If Rtotal = R1 + R2 and resistors are .25W
I=P/Vmax, I = 0.25W/132V = 2.08mA
Rtotal = 132V/2.08mA = 122k
R2 = 5*122k/132 = 4.6k
R1 = Rtotal – R2 = 117.4k

96. Transient Analysis

97. DC Sweep

98. Major Components Bridge Rectifier Resistors Capacitor
Analog to Digital Converter

99. Vdc Sensor Measure the battery voltage.
Produce an eight bit output directed to the CPU.
Used to determine emergency CPU shutdown (when battery runs too low).
Used in conjunction with the Idc sensor to estimate battery expectancy.

100. Placement of the Vdc Sensor
Quick
Charger
Trickle
Charger
Inverter
Vdc and Idc
Sensors
Battery

102. Calculations for the Vdc Sensor
If Rtotal = R1 + R2 and resistors are .25W
I=P/Vmax, I = 0.25W/15.7V = 15.9mA
That’s too much current, Use I = 500uA
Rtotal = 15.7V/500uA = 31.4k
R2 = 5*31.4k/15.7 = 10k
R1 = Rtotal – R2 = 21.4k

105. Major Components
Resistors
Analog to Digital Converter

106. The ADC is in both sensors
It’s the major major component

107. Comparison between CPU and ADC
ADC output
CPU input
Vlow(max)
0.4V
0.8V
Vhigh(min)
2.4V
2.0V
Ilow(max)
1.6mA
N/A
Ihigh(min)
-360uA
Limits fall within acceptable range

108. Further Comparison between CPU and ADC
ADC Conversion time 103us – 114us
CPU
Setup time = 6ns
Hold time = 0ns
Total time required for latch => 6ns ?

111. Bill of Materials Resistors Rated: 0.25W 200V working max 4.64k Ω ±1%

112. B.O.M. continued…
Capacitor
470uF±20%
WV = 10V
Voltage range 6V-200V

113. B.O.M. continued… Bridge Rectifier Imax = 1A
50V < Vrated < 1000V
50Hz < operating frequency < 1kHz
1Vmax, drop per diode

114. B.O.M. continued… Analog to Digital Converters (ADC)
Vcc supply = 5V ± 0.25V
Clock frequency: 100kHz – 1460kHZ
Output
High:
2.4Vmin
-360uA
Low:
0.4Vmax
1.6mA
Input
0-5V range
1uA max

115. B.O.M. continued… 8- Conductor Ribbon (6’’ long) 300Vmax
26AWG stranded

116. Block Prototyping Plan Template
Name
Block Area (cm2)
Total PCB
Area (cm2)
PCB
Substrate
Type
Comp
Attachment
Socketed
Components
Types of
Connectors
Sensors
120
700
Fiber Glass
Wire Wrap
N/A
Spade connector, Cupper bus, easy disconnect

117. Compiled B.O.M. Part Part # Quantity Description Price (1) Source R1
MFR-25FBF-4K64 1
4.64k Resistor
0.11
Digikey R2
MFR-25FRF-118K
118k Resistor R3
MFR-25FBF-10K0
10k Resistor R4
MFR-25FBF-21K5
21.5k Resistor C1
4173PHBK-ND
470uF Capacitor
3.01

118. Compiled B.O.M. cont… Part Part # Quantity Description Price (1)
Source
ADC
ADC0804 2
Analog-to-Digital Conv.
3.00
Iguana Labs D ND 1
Bridge Rectifier ?
Ribbon
WM08-06-ND
1.08
Digikey
PCB
Chester's
Con1 4
spade connectors (m&f pairs)
2.50
Con2
Ribbon Connectors(m&f pairs)
5.10

119. Compiled B.O.M. cont… Approximately $25 without the bridge rectifier
Original Material Estimate: $126
Well under bid
Original Estimated Hours 50 hrs.
Quickly approching

120. Analog-to-Digital Conv.
Bill of Materials
Part
Part #
Quantity
Description
Price (1)
Source R1
KFCT-ND 1
4.6k Resistor
0.88
Digikey R2
KFCT-ND
120k Resistor R3
311-10kFCT-ND
10k ohm Resistor R4
4LG22K-ND
22k potentiometer
0.59 C1
4173PHBK-ND
470uF Capacitor
3.01
ADC
ADC0804 2
Analog-to-Digital Conv.
3.00
IguanaLabs D ND
Bridge Rectifier ?

122. Chronological Disparities
Can’t begin to construct prototype until all parts have been obtained.
Can’t obtain all parts until part list has been compiled.
Can’t test the whole project as a hole until everyone gets their blocks put together and debugged.
Can’t test the whole project until all safety standards and regulations have been met.

123. Prototype UPS Shelf