HomeMy WebLinkAbout401 W Seminole Blvdn
r,
CITY OF SANFORD
— - BUILDING & FIRE PREVENTION
PERMIT APPLICATION
Application No: I ch, Documented Construction Value: $2. -
Job Address: 401 W Seminole Blvd Sanford FL 32771 Historic District: Yes ❑ Noz
Parcel ID: 25-19-30-300-0070-0000 Zoning:
Description of Work: Install one 100 amp service 240v from pole to existing lift station. Disconnect 208v single phase service from pad mount transformer.
Plan Review Contact Person: Joe Reaster Title: Project Manager
Phone: 407-656-2335 Fax: 407-290-2890 E-mail: joe.reaster@ies-co.com
Name Sailpoint at Lake Monroe
Street: 401 W. Seminole Blvd.
City, State Zip: Sanford, FL 32771
Nam IES Commercial, Inc.
Street: 3060 Mercy Drive
City, State Zip: Orlando, FL 32808
Name:
Street:
City, St, Zip:
Bonding Company:
Address:
Building Permit ❑
Square Footage:
No. of Dwelling Units:
Electrical ✓0
Property Owner Information
Phone: 407-322-1051
Resident of property? :
Contractor Information
Phone: 407-656-2335
Fax: 407-290-2890
State License No.: EC13004329
Architect/Engineer Information
Phone:
Fax:
E-mail:
Mortgage Lender:
Address:
PERMIT INFORMATION
Construction Type: Electrical No. of Stories:
Flood Zone:
New Service— No. of AMPS: 100 amp
Mechanical ❑ (Duct layout required for new systems)
Plumbing ❑
New Construction - No. of Fixtures:
Fire Sprinkler/Alarm 13 No. of heads:
N
ILL
NO. I DATE
I, . I
CONCRETE SEA WALL'
LAKE
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MONROE
........ ..
SEMINOLE Nn
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Work Description
1. Bore underground 1-1/4" conduit below existing paiking lot approximately 70' and install 4 #1 XHHW aluminum conductors.
2. Trench/backfill underground 1-1/4" pvc conduit with four #1 XHHW aluminum conductors at 3' burial depth approximately 220'
3. Remove one existing single phase 60 amp meter base and remove existing underground service lateral from existing pad mounted 7' 4 Z,
transformer. 9
3
4. Connect existing motor starter control cabinet to new 100 amp meter for lift station.
5. Install two new 8' ground rods with #8 bare CLI to earth bond.
6. Install one new 18' above finish grade wood pole within 50' of existing utility pole for overhead servcie lateral attachment by FP&L.
7. Replace existing rusted strut supports between posts with new strut supports,
8. Replace existing rusted alarm bell on top of control cabinet with new alarm bell.
9. Permitting fees, coordination with underground locates and coordination with utility provider included, 101"i
10. Down time to be limited to minimum time to disconnect existing utilities in pad mount transformer to connection to Pod mounted
transformer.
Note:
Service lateral from utility pole calcualted with 5% voltage drop to provide reasonable efficiency of operation, Zt
Max ampacity per 310.16 of NEC determine 100 amp @ 75%F and allows 10 amps over actual load.
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Exclusions: 12 '10 -k,)
1. Utility Fees
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2, Ground Penetrating Radar for utilities under pavement, vl`
2. Sod, mulch, shrub and or plant replacement.
3. Concrete and or asphalt repair/replacement,
RISER DIAGRAM NEW 100 AMP SERVICE
REVISION
APP D
N V t L. = 3.5 J
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EX/ST 54AI,01-1-
rop
IA141 (W) = 7,53 1tV9 (�() =/0, 13
IAV- (s> 7.'Ag 1101.('44) = 10.12
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APPROVED FOR cotmrnuc,i,iom
MIup,�,,�",W..",--far -,-.---",----,---,
3040 Meicy Drive
Orlando. FL 32808
P: 407 656 2335
F:407 290 2890
M:
407 956 7024
IES Commercial, h1r. E:
License No.: EC 00021.90 wwwies co.colll
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SIT
EN
A P A Pff"I T M E IN T S
SANFORD. FLORIDA
FLYGiT
PERFORM
DATE
PROJECT
2010-08-02
_FLYGT US Ca
1/1 -LOAD 3/4 -LOAD
POWER FACTOR
0.83 0.77
EFFICIENCY
78.0% 79.0%
MOTOR DATA
--- ---
COMMENTS
18. Acutal Voltage with load = Voltage(Celli) - Acutal Voltage drop(CeII17)
INLETK
11. Multiplier = 1 (if cell 3 is single phase)
-/3.0
NEMA Code Letter: G
Multiplier =square root of 3 or 1,732050808 (if cell 3 is three phase)
IMP, TF
[hp]
12. Resistance/1000' of wire = resistance of the type wire in cell 14 and
sized per cell 13 from Table 8
3.5
3.0
21. Minimum wire size = the wire that has low enough resistance to carry
W
Lhrn Phase
:!�-
2.5
0
Selecd phase type
Distance =Cell 22 (if unknown and cell 6 is left blank)
2.0
Stranded Aluminum
DUTY -POINT
FLOW[usgprnl HEAD[f
B.E.P,
337 20.4
Amps(Cell 15) x Resistance(Cell 20) x Multiplier(Cell 11)
35-
AWG 1
30--_
Resistance/foot(Cell 20) x Distance(Cell 14) x Multiplier(Cell 11)
25--_
Select the size of wire if Known
16. Number of sets of parallel wireszCell 8 (if known and entered in cell 8)
The ampacity of the conductor listed in Cell 4 and Cell 13 per
290
Uj 20
r
Enter the length of wire (0-5000') it Known
then a calculated value will appear to the left of
the cell.
7
90
Enter Amps (0-6000) it known
0
0
100
11,1
NPSHre = NPSH3% +
inin. operational margin
Performance with clear water and ambient temp
The following voltage drop calculations were all based on the resistance
values in Table 8 of Chapter 9 of the 2002 NEC. This spreadsheet only
Voltage Drop Calculations considers voltage drop. Many other factors affect wire size. Refer to thi
entire NEC when sizing wire.
Minimum voltage allowed at load Actual voltage with load
21
Data Entry Window
Minimum wire size for voltage drop
20, Q0
22feetW
1�
Distance
Printable t iew
1���
x Distance(Cell 14) x Multiplier(Cell 11)
I Yes
10. Minimum Voltage drop allowed at load = Voltage(Cell 1) - Max vcI allowed (Cell 9)
18. Acutal Voltage with load = Voltage(Celli) - Acutal Voltage drop(CeII17)
11. Multiplier = 1 (if cell 3 is single phase)
19. Voltage Difference = Actual Voltage(Cell 16) - Min. voltage(Call 10)
Multiplier =square root of 3 or 1,732050808 (if cell 3 is three phase)
Select the max desired voltage drop (0%-5%)
j I
12. Resistance/1000' of wire = resistance of the type wire in cell 14 and
sized per cell 13 from Table 8
20. Total Resistance per foot = Res. in table 8 of Cell 4 and Cell 13
1000 x number of parallel wires (Cell 16)
13. Size wire =Cell 5 (if known and entered in cell 5)
21. Minimum wire size = the wire that has low enough resistance to carry
31
Lhrn Phase
the load without more than the max voltage drop.
14. Distance=Cell 6 (if known and entered in cell 5)
Selecd phase type
Distance =Cell 22 (if unknown and cell 6 is left blank)
n
Stranded Aluminum
15. Maximum Amps= Cell 7 (if known and entered in cell 7)
22. Distance = Max voltage drop(C 119) x parallel wires (Cell 16)
Select the type of wire
Amps(Cell 15) x Resistance(Cell 20) x Multiplier(Cell 11)
Max voltage dlrop(Cell_9) x Number of parallel wires(Cell 8-)--
AWG 1
Resistance/foot(Cell 20) x Distance(Cell 14) x Multiplier(Cell 11)
23. Max Ampacity of the selected wire in CeIll 3
Select the size of wire if Known
16. Number of sets of parallel wireszCell 8 (if known and entered in cell 8)
The ampacity of the conductor listed in Cell 4 and Cell 13 per
290
Note: If only one of cells 5,6 and 7 is left blank.
Enter the length of wire (0-5000') it Known
then a calculated value will appear to the left of
the cell.
7
90
Enter Amps (0-6000) it known
11,1
Select the number of parallot wires
(I is non -parallel) Or -25pairs
,LAMM
Minimum voltage allowed at load Actual voltage with load
Enter a into these cells 17,77 77,001out5tK"', ::atio$� EMMM
21
Wire Size
Minimum wire size for voltage drop
20, Q0
22feetW
1�
Distance
Maximum distance with this load
Enter a into these cells 17,77 77,001out5tK"', ::atio$� EMMM
24. Amps above or below load = Ampacity of Cell 23 - Ampacity of Cell 15
of
Disclaimer: Voltage drop calculations and Table 310.16 are not the
only considerations when sizing conductors. Many other factors
must be considered, such as: the type of load, the ambient temp,
the type of insulation, the association with other conductors,
the temperature rating of the equipment, the type of environment,
the size of the breaker, the type of circuit (branch, feeder, service,
grounding, or control), continuous load, etc. Use this spreadsheet
to check voltage drop, See the NEC to size wires.
ALBANY TECHNICAL COLLEGE
Please report any errors to:
Bill Bamford
Albany, Georgia
Email: lbbarnford0albanytech.ora
Date of last revision or correction: Aug. 28, 2004
Formulas used:
9. Maximum voltage drop allowed = Circuit Voltage(Cell 1) X Maximum voltage drop
17. Actual voltage drop = Resistance(Cell 20) x Amps(Cell 15)
% allowed(Ce112).
x Distance(Cell 14) x Multiplier(Cell 11)
10. Minimum Voltage drop allowed at load = Voltage(Cell 1) - Max vcI allowed (Cell 9)
18. Acutal Voltage with load = Voltage(Celli) - Acutal Voltage drop(CeII17)
11. Multiplier = 1 (if cell 3 is single phase)
19. Voltage Difference = Actual Voltage(Cell 16) - Min. voltage(Call 10)
Multiplier =square root of 3 or 1,732050808 (if cell 3 is three phase)
If ok then this cell turns green, if not then it turns red
12. Resistance/1000' of wire = resistance of the type wire in cell 14 and
sized per cell 13 from Table 8
20. Total Resistance per foot = Res. in table 8 of Cell 4 and Cell 13
1000 x number of parallel wires (Cell 16)
13. Size wire =Cell 5 (if known and entered in cell 5)
21. Minimum wire size = the wire that has low enough resistance to carry
Size wire =Cell 21 (if unknown and cell 5 is left blank)
the load without more than the max voltage drop.
14. Distance=Cell 6 (if known and entered in cell 5)
Resistance = Max voltage drop((Cell 9) x parallel wires(Cell 16)
Distance =Cell 22 (if unknown and cell 6 is left blank)
Amps(Cell 15) x Length(Cell 14) x Multiplier(Cell 11)
15. Maximum Amps= Cell 7 (if known and entered in cell 7)
22. Distance = Max voltage drop(C 119) x parallel wires (Cell 16)
Maximum Amps= see below (if cell 7 is left blank)
Amps(Cell 15) x Resistance(Cell 20) x Multiplier(Cell 11)
Max voltage dlrop(Cell_9) x Number of parallel wires(Cell 8-)--
Resistance/foot(Cell 20) x Distance(Cell 14) x Multiplier(Cell 11)
23. Max Ampacity of the selected wire in CeIll 3
16. Number of sets of parallel wireszCell 8 (if known and entered in cell 8)
The ampacity of the conductor listed in Cell 4 and Cell 13 per
Number of sets of parallel wireszl (if unknown and cell 8 is left blank)
Article 110.14(C) and Table 310,16. Note: This is the maximum
ampacity allowed under ideal conditions.
24. Amps above or below load = Ampacity of Cell 23 - Ampacity of Cell 15
of
Disclaimer: Voltage drop calculations and Table 310.16 are not the
only considerations when sizing conductors. Many other factors
must be considered, such as: the type of load, the ambient temp,
the type of insulation, the association with other conductors,
the temperature rating of the equipment, the type of environment,
the size of the breaker, the type of circuit (branch, feeder, service,
grounding, or control), continuous load, etc. Use this spreadsheet
to check voltage drop, See the NEC to size wires.
ALBANY TECHNICAL COLLEGE
Please report any errors to:
Bill Bamford
Albany, Georgia
Email: lbbarnford0albanytech.ora
Date of last revision or correction: Aug. 28, 2004