HomeMy WebLinkAboutMerlino SP - vault struct calculations 11-03-14SITE STRUCTURES
A Division of Kosnik Engineering, PC
Merlino Short Plat
Storm Water Detention Vault
Renton, Washington
St�uctu�al Calculations
Project No. 5-14-067
First Issue 11-03-14
10511 19T" Ave SE, Suite C, Everett, WA 98208 ♦ (425) 357-9600 (phone) ♦ e-mail: dan@kosnik.com
Merlino Short Plat
Storm Water Detention Vault
Project No. 3-14-067
STRUCTURAL CALCULATIONS INDEX
Sheet
Design Criteria O1 - 04
Lid Review OS - 10
Wall Design &Footing Design 11 - 20
Grated Opening Framing 21 - 26
DESIGN CRITERIA
Permitting Agency:
Soil Cover:
Lid Loading:
Grating
Foundation Design:
Merlino Short Plat
Storm Water Detention Vault
r.
2012 IBC
City o f Renton
2.0 ft min to 5.2 ft max
HS20 Truck wheel loads
Fire Truck wheel loads
Fire Truck outrigger load
150 psf uniform live load
Uniform live load does not act concurrently with truck
wheel loading,
same as lid loading —excluding the outrigger load.
Foundation design is based on the following values:
Allowable Bearing Pressure: 3,000 psf
Lateral Earth Pressures on Vault Walls (drained backfill condition ):
Active:
35 pcf EFW -level backfill
At Rest:
Seismic Addition:
Saturated Soil Density:
Material Requirements:
55 pcf EFW- level backfill
E = 14H psf Uniform
125 pcf
Rebar: Grade 60
Concrete: fc= 4000 psi wall; f c=3000 psi footings and grade slab
Lid: Pre -cast, Pre -stressed Hollow Core Plank 12-1/2" thick.
VERTICAL LOADS ON VAULT LID � GRATING;
FUNIFORM LIVE LOAD ; ENTIRE LID
AFIRE TRUCK WHEEL LOADS
= 150PSF
MAX LOAD ON FRONT AXLE = 191000 Ib,
E
MAX LOAD ON REAR AXLES = 481000 lb,
Go
FRONT REAR) I (DUAL TANDEM AXLES)
co
8 8 TOTAL WEIGHT = 67,000 Ib,
OUTRIGGER PAD POINT LOAD; (NOT APPLICABLE TO GRATED OPNG I
DISTRIBUTED OVER 261146" PAD = 50,700 Ib,
�HS20 TRUCK WHEEL LOADS ;ENTIRE LID
13'-6" 14' to 30'
FRONT I REAR REAR
a a
TRACTOR
TRAILER
0
TRACTOR;
FRONT AXLE
SINGLE REAR AXLE
TRAILER ;
SINGLE REAR AXLE
TOTAL WEIGHT
= 8,000 Ib,
= 321000 lb,
= 32,000 lb,
= 721
000 ib,
� DESIGN LIVE LOADS TO BE APPLIED INDEPENDENTLY AND IN COMBINATION
WITH SOIL LOADS,
SOIL COVER ;
VARIES FROM 2,OFT MIN TO 5,2FT MAX, SEE LID PLAN.
SITE STRUCTURES
FRONT AXEL:
REAR AXEL # 1:
REAR AXFL #2:
Project EiZ L ,u �, sheet -3
date - G / q
prj . no. S - / ct - Otc 7
HS20-44 HS25-44
72,OOOLBS I WOOOLBS
8,000LBS I0,000LBS
329000LBS 40,5000LBS
32,000LBS 40,000LBS
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SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Project Merlino SP
PRECAST HOLLOW CORE PLANK REVIEW
Lid Data
Soil Desity
Soil Cover depth over lid
Plank design clear span
Design Uniform Live Load
Design Superimposed Load
Plank capacity based on uniform superim
Plank span
No of tendons
Allowable superimposed loads
125 pcf
4 ft
20 ft
150 psf
650 psf
ed load tables
Allowable superimposed loads base of design span of
Based on flexural capacity
Based on shear capacity
Plank ca
based on truck load charts
Plank span 20:25 ft
No of tendons 11
Allowable soil cover without knee -walls na ft
Allowable soil cover with knee -walls 1.5 to 5.25 ft
20.25 ft
sheet
date
prj . no. S44-067
413 psf
790 psf
571 psf
DIMENSIONS
FOR DETAILI�
N
r
17/1 s" I � 11 " � 111/z" � , 111/z" ATE 11 " ,.ISE 17/1 s��
3'-117,
(4'-0" Nominal Width)
SPAN -LOAD TABLE
ALLOWABLE SUPERIMPOSED LOAD in pounds per square foot
Effective No. of SIMPLE SPAN in feet
Prestress 1/2" �
(KIPS) STRANDS 28 32 36 40 44 48 52 56 60
70:7 3 78 44 20
77.7 4 126 80 49 26
101.3 5 174 117 78 50 t 27
124.8 6 221 153 106 70 43 23*
148.4 7 267 186 129 89 59 36
172.0 8 307 216 153 108 74 49 29
195..5 9. 343 243 174 125 89 61 40 23*
219.1 10 3781 270 195 142 103 73 50 31
242.7 11 4131 297 217 160 117 85 60 40 24*
SECTION PROPERTIES (with shear keys grouted)
ll-G3.1�1
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A = 313 int Zt = 1019 in3 Zb = 947 in3 w = 84 psf
I = 6136 in4 Yt = 6.02 in Yb = 6.48 in .
. .NOTES:
1. The values given in this table are based on hollow core slabs without shear reinforcement. Superscripts (1, 2, etc.)
following values in the table indicate the number of filled voids required at the ends of slabs to develop the allowable
superimposed load. See page 2, "SHEAR" for discussion.
2. Asterisk (*) following values in the table indicate that the total deflection under all loads is greater than U360 but less
than U180.
3. Interpolation beiween values is acceptable. Do not extrapolate values into the blank spaces of the table.
4. These Span -Load Tables are intended as an aid to preliminary sizing. Sound engineering judgement is required for
the application of this information to specific design cases.
�0 MANUFACTURERS OF PRESTRESSED CONCRETE •TACOMA, WASHINGTON alas
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45 KIP OUTRIGGER ON 18x18" PADS @ 15'-0" O.C.
14 16 18 2d\
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Number of Filled Voids required
-
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22 24 26 28 30 32 34 36 38
SIMPLE SPAN (ft)
GENERAL NOTES:
mum cover depth of nine inches is required.
2.) Simple Span is centerline of bearing to centerline of bearing.
3.) Knee walls are required at all manhole and vent openings.
4.) Interpolation between strand contours is acceptable. DO NOT extrapolate beyond the bounds of this chart.
5.) Soil cover is assumed to be uniform.
6.) Except as noted, soil cover unit weight is assumed to be 120 pcf.
7.) Minimum span length = 14'-0".
8.) The values shown on this chart are in compliance with IBC 2012
& ACI 318-11.
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2/10/14 MANUFACTURERS OF PRESTRESSED CONCRETE •TACOMA, WASHINGTON 11
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12'/2" HOLLOW CORE S
HS25-44
14 16 18 20\ 22 24 26 28 30 32 34 36 38
FV'
SIMPLE SPAN (ft)
GENERAL NOTES:
1.) A minimum cover depth of six inches OR a three inch thick cast in place concrete topping slab is required.
2.) Simple Span is centerline of bearing to centerline of bearing.
3.) The Knee Wall envelope represents the maximum span and height of soil cover that can be supported by slabs
with standard notches for manhole openings, assuming void fill concrete f'c = 3,000 psi. Points falling outside this
envelope require knee walls to support the slabs at manhole openings.
4.) Interpolation between strand contours is acceptable. DO NOT extrapolate beyond the bounds of this chart.
5.) Soil cover is assumed to be uniform.
6.) Except as noted, soil cover unit weight is assumed to be 120 pcf.
7.) Minimum span length = 14'4".
8.) The values shown on this chart are in compliance with IBC 2012 & ACI 318-11.
9.) The Vent Notch envelope represents the maximum span and minimum/maximum height of soil cover that can
be supported by slabs with 6Y2' standard notches in adjacent slabs to accommodate 12" diameter vents, assuming
void fill concrete f'c = 3,000 psi. Refer to Detail 3 on page 13 of this brochure for vent notch details.
2/10/14 MANUFACTURERS OF PRESTRESSED CONCRETE •TACOMA, WASHINGTON 8
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Number of Filled Voids required
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14 16 18 20\ 22 24 26 28 30 32 34 36 38
FV'
SIMPLE SPAN (ft)
GENERAL NOTES:
1.) A minimum cover depth of six inches OR a three inch thick cast in place concrete topping slab is required.
2.) Simple Span is centerline of bearing to centerline of bearing.
3.) The Knee Wall envelope represents the maximum span and height of soil cover that can be supported by slabs
with standard notches for manhole openings, assuming void fill concrete f'c = 3,000 psi. Points falling outside this
envelope require knee walls to support the slabs at manhole openings.
4.) Interpolation between strand contours is acceptable. DO NOT extrapolate beyond the bounds of this chart.
5.) Soil cover is assumed to be uniform.
6.) Except as noted, soil cover unit weight is assumed to be 120 pcf.
7.) Minimum span length = 14'4".
8.) The values shown on this chart are in compliance with IBC 2012 & ACI 318-11.
9.) The Vent Notch envelope represents the maximum span and minimum/maximum height of soil cover that can
be supported by slabs with 6Y2' standard notches in adjacent slabs to accommodate 12" diameter vents, assuming
void fill concrete f'c = 3,000 psi. Refer to Detail 3 on page 13 of this brochure for vent notch details.
2/10/14 MANUFACTURERS OF PRESTRESSED CONCRETE •TACOMA, WASHINGTON 8
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12'/2" HULLO
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150 PSF
14 16 18 20' 22 24 26 28 30 32 34 36 38
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` SIMPLE SPAN (ft)
GENERAL NOTES:
minimum cover depth of six inches OR a three inch thick cast in place concrete topping slab is required.
2.) Simple Span is centerline of bearing to centerline of bearing.
3.) The Knee Wall envelope represents the maximum span and height of soil cover that can be supported by slabs
with standard notches for manhole openings, assuming void fill concrete ft = 3,000 psi. Points failing outside this
envelope require knee walls to support the slabs at manhole openings.
4.) Interpolation between strand contours is acceptable. DO NOT extrapolate beyond the bounds of this chart.
5.) Soil cover is assumed to be uniform.
6.) Except as noted, soil cover unit weight is assumed to be 120 pcf.
7.) Minimum span length = 14'
8.) The values shown on this chart are in compliance with IBC 2012 & ACI 318-11.
9.) The Vent Notch envelope represents the maximum span and height of soil cover that can be supported by slabs
with 6�/2' standard notches in adjacent slabs to accommodate 12" diameter vents, assuming void fill concrete f'c =
3,000 psi. Refer to Detail 3 on page 13 of this brochure for vent notch details.
2/10/14 MANUFACTURERS OF PRESTRESSED CONCRETE •TACOMA, WASHINGTON
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SITE STRUCTURES Project Merlino SP sheet:
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Vault Walls -Lateral Pressures Review
Minimum soil cover depth to top of wall:
Maximum soil cover depth to top of wall:
Wall Height:
At -Rest soil pressure:
Active soil pressure:
Uniform Addition to At -Rest soil pressure:
Soil Density:
date : 11- 03 - 14
prj . no.
3 ft
6 ft
9:67 ft
55 pcf EFD
35 pcf EFD
0 psf
125 pcf
Load Combinations:
1.6 L (soil pressure) + 1.6 L (surcharge/wheel load)
16 L (soil pressure) + 1.0 L (seismic)
Due to HS25 Truck Loading:
2.0 ft min cover over lid:
5.0 ft max cover over lid:
Total Factored Lateral Force:
2.0 ft min cover over lid:
5.0 ft max cover over lid:
Due to Uniform Surcharge Load:
Uniform surcharge:
Equivalent lateral force:
Total Factored Lateral Force:
5.0 ft max cover over lid:
106 psf Uniform
44 psf Uniform
8307 plf
9901 plf
50 psf
66 psf U n iform
10241 plf
Due to Seismic Activity:
Uniform seismic addition: E = 14 H
Seismic lateral force: 135 psf Uniform
Total Factored Lateral Force:
5.0 ft max cover over lid:
Combined Load Factor:
7176 plf
1.49
5-14-067
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Design Data
Soil Density
Soil Cover depth to the top of the wall
Wall height
Soil Pressure EFW
Surcharge Information
Proj ect Merlin SP
125 pcf
Eft Ws1=
9:67 ft Ws2 =
55 pcf
sheet
date
prj . no.
r -03� /Lf
5-14-067
330 psf
531.85 psf
uniform S1 = 150 psf (on surface of ground) Equiv Ws = 66 psf
truck Ws = 44 psf ( on surface of wall - see design chart )
Critical Design Surcharge pressure = 66 psf (on the surface of the wall)
Calculated Design Forces
W1= 396 F1 = 3829.32 lbs R top = 2772 lbs
W2= 531.85 F2 = 2571.495 lbs R bot = 3629 lbs
M 1 = 4629
02 = 3190
M total= 7819 ft -lbs
Wall Reinforcing
Wall thickness 10 inches Comp block (a) = 0.78 inches
Clear cover 2 inches Depth to CL bar (d) = 7.63 inches
Rebar size 6 d -a/2 = 7.24 inches
Rebar area 0.44 sq -in
Bar spacing 10 inches Mn = 17261 ft -lbs
Rebar strength fy 60 ksi
conc strength f'c 4000 psi Mu = 12510 ft -lbs
Load Factor 1:6
max tension reinforcing spacing: fS = 24462 psi s = 19.5 in
S = 19.6 in
smax = 19.5 in - OK
Anchorage at Top of the Wall
Ru = 4435 plf Rebar Dowel Size = 8=
Dowel Area = 0:79 sq -in
Shear capacity of Dowel = 11376 plf Dowel strength fy= 60 ksi
Bearing capacity of Dowel = 6300 plf Dowel Spacing = > 20 inches
Dowel brg length = 2.5 inches
conc strength f'c = 3000 psi
Anchorage at Bottom of the Wall
Ru = 5806 plf Rebar Dowel Size = 1 5
Dowel Area = 0:31 sq -in
Nominal Shear friction capacity Dowel strength fy= 60 ksi
of the footing to wall Dowel 11383 plf Dowel Spacing = `10 inches
Coefficient of friction = 06 smooth surface
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Design Data
Soil Density
Soil Cover depth to the top of the wall
Wall height
Soil Pressure EFW
Proj ect Merlin SP sheet
date
125 pcf
6 ft Ws1 =
9667 ft Ws2 =
55 pcf
prj . no.
1
ll -03-1`{
5-14-067
330 psf
531.85 psf
Surcharge Information
uniform S1 = 150 psf (on surface of ground) Equiv Ws = 66 psf
truck Ws = 44 psf ( on surface of wall - see design chart )
Critical Design Surcharge pressure = 0 psf (on the surface of the wall)
Calculated Design Forces
W1= 330 F1 = 3191.1 lbs R top = 2453 IDS
W2= 531.85 F2 = 2571.495 lbs R bot = 3310 lbs
M 1 = 3857
M2 = 3190
M total= 7048 ft-Ibs
Wall Reinforcing
Wall thickness 10 inches Comp block (a) = 0.78 inches
Clear cover 2 inches Depth to CL bar (d) = 7.63 inches
Rebar size 6 d -a/2 = 7.24 inches
Rebar area 0.44 sq -in
Bar spacing 110 inches OMn = 17261 ftdbs
Rebar strength fy 60 ksi
conc strength f 4000 psi Mu = 11276 ft -lbs
Load Factor 1.6;
max tension reinforcing spacing: fs = 22048 psi s = 22.2 in
S = 21.8 in
Smax = 21.8 in - OK
Anchorage at Top of the Wall
Ru = 3924 plf Rebar Dowel Size = 8
Dowel Area = 0.79 sq -in
Shear capacity of Dowel = 11376 plf Dowel strength fy= 60 ksi
Bearing capacity of Dowel = 6300 plf Dowel Spacing = 20 inches
Dowel brg length = 2.5 inches
conc strength f = 3000 psi
Anchorage at Bottom of the Wall
Ru = 5296 plf Rebar Dowel Size = 5
Dowel Area = 0.31 sq -in
Nominal Shear friction capacity Dowel strength fy= 60 ksi
of the footing to wall Dowel 11383 plf Dowel Spacing = 10 inches
Coefficient of friction = 0.6 smooth surface
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Proj ect Merlin SP
Vault Walls -Lateral Pressures Review
MMinimum soil cover depth to top of wall:
aximum soil cover depth to top of wall:
Wall Height:
At -Rest soil pressure:
Active soil pressure:
Uniform Addition to At -Rest soil pressure:
Soil Density:
Load Combinations:
106 L (soil pressure) + 1.6 L (surcharge/wheel load)
1.6 L (soil pressure) + 1.0 L (seismic)
Due to HS25 Truck Loading:
4.0 ft min cover over lid:
4.0 ft max cover over lid:
Total Factored Lateral Force:
4.0 ft min cover over lid:
4.0 ft max cover over lid:
44 psf Uniform
44. psf Uniform
13255 plf
13255 pif
Due to Uniform Surcharue Load:
Uniform surcharge: 1.50 psf
Equivalent lateral force: 66 psf Uniform
Total Factored Lateral Force:
4.0 ft max cover over lid:
13695 plf
Due to Seismic Activity:
Uniform seismic addition: E _ ' 14 H
Seismic lateral force: 175 psf Uniform
Total Factored Lateral Force:
4.0 ft max cover over lid:
Combined Load Factor:
10063 plf
1.47
sheet:
date
prj . no.
►N
1�03� tq
S-14-067
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Proj ect Merlin SP
Design Data gooEIZ4
Soil Density 125 pcf
Soil Cover depth to the top of the wall 5 ft Ws1 =
Wall height 12.5 ft Ws2 =
Soil Pressure EFW 55 pcf
Surc
e Information
uniform S1 = 150 psf (on surface of ground) Equiv Ws =
truck Ws = 44 psf ( on surface of wall - see design chart )
Critical Design Surcharge pressure =
Calculated Design Forces
66 psf (on the surface of the wall)
sheet
date
prj . no.
l�
1/- 03- 1 L
5-14-067
275 psf
687.5 psf
W1= 341 F1 = 4262.5 lbs R top = 3564 lbs
W2= 687.5 F2 = 4296.875 lbs R bot = 4996 lbs
M1 = 6660 M total= 13551 ft -lbs
M2 = 6891
Wall Reinforcing
Wall thickness 12 inches Comp block (a) = 1.06 inches
Clear cover 2 inches Depth to CL bar (d) = 9.56 inches
Rebar size 7 d -a/2 = 9.03 inches
Rebar area . 0.60 sq -in
Bar spacing 10 inches OMn = 29328 ft -lbs
Rebar strength fy 60 ksi
conc strength f'c 4000- psi Mu = 21682 ft -lbs
Load Factor 19 1
max tension reinforcing spacing: fs = 24951 psi S= 19.0 in
S = 19.2 in
Smax = 19.0 in - OK
Anchorage at Top of the Wa
Ru = 5702 plf -Rebar Dowel Size = 8
Dowel Area = 0:79' sq -in
Shear capacity of Dowel = 11376 pif Dowel strength fy= 60 ksi
Bearing capacity of Dowel = 6300 plf Dowel Spacing = 20 inches
Dowel brg length = 2.5 inches
conc strength f'c = 3000 psi
Anchorage at Bottom of the Wall
Ru = 7993 plf
Nominal Shear friction capacity
of the footing to wall Dowel 11383 plf
Rebar Dowel Size = 5
Dowel Area = Q31` sq -in
Dowel strength fy= 60 ksi
Dowel Spacing = 10 inches
Coefficient of friction = 0.6,, smooth surface
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
i
Proj ect Merlin SP
sheet
date
no.
II -o3 -I
S-14-067
Design Data
Soil Density 125 pcf
Soil Cover depth to the top of the wall 5 ft Ws1 = 275 psf
Wall height 12.5 ft Ws2 = 687.5 psf
Soil Pressure EFW 55 pcf
Surcharge Information
uniform S1 = 150 psf (on surface of ground) Equiv Ws = 66 psf
truck Ws = 44 psf ( on surface of wall - see design chart )
Critical Design Surcharge pressure =
Calculated Design Forces
0 psf (on the surface of the wall)
W1= 275 F1 = 3437.5 lbs R top = 3151 lbs
W2= 687.5 F2 = 4296.875 lbs R bot = 4583 lbs
Al. = 5371 M total= 12262 ft -lbs
M2 = 6891
Wall Reinforcing
Wall thickness 12 inches Comp block (a) = 1.06 inches
Clear cover 2 inches Depth to CL bar (d) = 9.56 inches
Rebar size 117 d -a/2 = 9.03 inches
Rebar area 0.60 sq -in
Bar spacing 1`0 inches OMn = 29328 ft -lbs
Rebar strength fy 60 ksi
conc strength f'c 4000 psi Mu = 19620 ft-Ibs
Load Factor 1.6
max tension reinforcing spacing: fs = 22578 psi s = 21.6 in
S = 21.3 in
smax = 21.3 in - OK
Anchorage at Top of the Wa
Ru = 5042 plf Rebar Dowel Size = 8
Dowel Area = 0;79: sq -in
Shear capacity of Dowel = 11376 plf Dowel strength fy= 60 ksi
Bearing capacity of Dowel = 6300 plf Dowel Spacing = 20 inches
Dowel brg length = 2.5 inches
conc strength f'c = 3000 psi
Anch
at Bottom of the Wall
Ru =
( Nominal Shear friction capacity
of the footing to wall Dowel
7333 plf Rebar Dowel Size =
Dowel Area =
Dowel strength fy=
11383 plf Dowel Spacing =
Coefficient of friction =
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Proj ect Merlin SP
INTERIOR WALL HEADER GEOMETRY AND LOADS ANALYSIS
Header Overburden &Uniform Loads
Lid weight
Soil Desity
Soil Cover depth over lid
Plank design clear span left
Plank design clear span right
Design Uniform Live Load
Lid tributary width to header
Uniform service load to header
Uniform factored load to header
Truck Wheel Loads to Header
Truck type
Axle Load
Wheel Spacing
:;over depth
90 psf
125 pcf
4 ft
20 ft
20 ft
150 psf
14800 plf
18960 plf
Axle assumed centered over & perpendicular to header
distribution width 8.50 ft opening width
distribution length 15.00 ft length ea side of hdr
uniform load @top of plank 314 psf
wheel load to header from left span 1912 plf
wheel load to header from right span 1912 plf
Total wheel load to header 3824 plf
Factored wheel load to header 6118 plf
Design Loads &Forces in Header
Service
Factored
Critical section for shear is at
Design Vu =
Design Mu =
18.6 klf
25.1 klf
0.75 feet from the face of the support
44 k
78 k -ft
sheet
date
prj .
no,
Load Factors
LL 1.6
DL 1.2
5.00 ft
7.50 ft
I�
5-14-067
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Proj ect Merlino SP
INTERIOR WALL HEADER DESIGN
Header Data
Header width
Header span
Header depth
In/d ratio
-8 inches
5.00 ft
32 inches
2007
Min shear steel (Area / spacing) ratio
Max spacing of shear steel
Min horiz steel (Area / spacing) ratio
Max spacing of horzontal steel
Review shear ca
of header
Reinforcing yield strength
Shear reinforcing area
spacing
Reinf shear capacity CVs
Total Shear Capacity
Max OW @ 2 < In/d < 5
Review flexural capac
min As based on 200 bwd/fy
min As based on eq 10-3
0.012
Concrete Strength
d=
sheet j
date
no. S-14-067
29.00 inches
Deep Beam limit In/d < 5.0
6.4 inches
0.02
10.66667 inches
45 k
of header
0.773333 sq inches
0.73 sq inches
As regd based on bending model
0.65s
Horz reinf area
Horz reinf spacing
Min Rebar spacing
#3@ 9.17
# 4 @ 16.67
Conc shear capacity �Vc
Factored shear Vu
inches
As regd based on tie -strut model
assume Vu is focused @the center of the header
then Tu = 45.40 k
As regd = 0.84 sq inches
1
10.00
15.50
25 k
44 k
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Proj ect Merlino SP
Design Data :Wall Foundation Loads Analysis
Soil Desity
Soil Cover over the lid
Plank weight
Uniform Live Load
Truck Rating
Wall Height
12.5 ft
sheet J
date
prj . no. S44-067
125 pcf Per. wall Cell Width 20 ft
3 f
Int. wall Cell Width left 20 ft
90 psf Int. wall Cell Width right 20 ft
150 psf
HS2544
Front Axle Load
Rear Axle #1 Load
Rear Axle #2 Load
Total vehicle wt
1 0000 lbs
40000 lbs
40000 lbs
90000 lbs
Truck Wheel Load Distribution to Perimeter Wall Foundation
Truck Perpendicular to the perimeter wall w/rear axle #2 directly over wall & distance to axle #1 = 14ft
total truck load to wall =
52000 lbs
distribution width =
Truck
total truck load to wall =
calc distribution width =
39 ft
eter wall w/one
68000 lbs
47 ft
Load @base of wall = 1333 plf
ill & 2nd wheel on plank (incl axle 1
Load @base of wall =
1447 plf
Truck Wheel Load Distribution to Interior Wall Foundation
Truck Perpendicular to the int. _wall w/ rear axle #2 centered over the wall & dist between axles = 14ft
total truck load to wall = 52000 lbs
distribution width = 39 ft Load @ base of wall =
Truck Perpendicular to the interior wall w/rear axle #2 directly over wall & dis
total truck load to wall =
total truck load to wall =
distribution width =
Truck Para.
total truck load to wall =
total truck load to wall =
distribution width =
Truck P,
52000 lbs left plank
52000 lbs right plank
39 ft
wall w/one
68000 lbs left plank
68000 lbs right plank
47 ft
he interior wall w/ t
total truck load to wall =
distribution width =
68000 lbs
47 ft
Load @base of wall =
Load @base of wall =
� 2nd wheel on plank (incl
Load @base of wall =
Load @ base of wall =
`eyed over the wall (incl axlE
Load a. base of wall =
Uniform Live Load distribution to Wall Footings
Perimeter Wall 1500 plf ' }
Interior Wall 3000 pl
f �
1333 plf
axle #1 = 14ft
1333 plf
1333 plf
1447 plf
1447
plf
1447 plf
SITE STRUCTURES
10511 19th Ave SE, Suite C
Project Merlino SP
Everett, WA, (425)-357-9600
Design Data : Wall Foundation Design
sheet
date
prj . no.
v
5-14-067
Allowable Bearing Pressure 3000 psf Per. wall Cell Width 20 ft
Rebar strength fy = 60 ksi Int. wall Cell Width left 20 ft
Concrete strength = 3000 psi Int. wall Cell Width right 20 ft
Soil Desity 125 pcf Plank weight 90 psf
Soil Cover over the lid 3 ft Wall Height 1205 ft
Wall Thickness 12 inches
Perimeter Wall Footing Design
L.F Wu
Design live load 1500 plf 1.6 2400 plf
Soil Cover dead load 4125 plf 1.2 4950 plf
Plank dead load 990 plf 1.2 1188 plf
Wall dead load 1875 plf 1.2 2250 plf
total dead load 6990 plf 8388 plf
Total live + dead Load 8490 plf 10788 plf
Required Ftg Width 2.8 ft
i
Selected Ftg Width 2.83 ft Selected Ftg Thickness 12 in
Qu = 3812 of
Mu = 1596 ft -lbs at face of wall
Vu = 3488 pif at face of wall
As regd = 0.04 sq-in/ft phi Vn= 9498 plf at face of wall
Asmin = 0.35 sq-in/ft�
1.33 x As regd = 0.06 sq-in/ftp
Interior Wall Footing Design
L.F Wu
Design live load
Soil Cover dead load
Plank dead load
Wall dead load NW
total
Total live +dead Load
Required Ftg Width
Selected Ftg Width
Qu =
� As regd =
Asmin =
1.33 x As regd =
3770 psf
-3000 plf
7500 plf
1800 plf
1875 plf
11175 plf
14175 plf
0.19 sq-in/ft
0.35 sq-in/ft
0.25 sq-in/ft
4.7 ft
4.83` ft
1.6
4800 plf
9000 plf
2160 plf
2250 pif
13410 plf
18210 Of
Selected Ft
phi Vn=g Thickness 12 in
6913 ft-Ibs at face of wall
7220 plf at face of wall
9498 plf at face of wall
M1 I
SITE STRUCTURES Project sheet:
10511 19th Ave SE, Suite C date.
Everett, WA, (425)-357-9600
Reinforcing at Top of Wall Below Grated Opening
Design Data
Top of Footing to Inside Top of Vault (H1)
Top of Footing to Finished Grade (H2)
Soil Pressure EFW
Controlling Lateral Surcharge
Grating Span
Calculated Design Forces
Fbot of curb = 286 If
12,5 ft
17.5 ft
55 pcf
66 psf
10 ft
�R6�7E
curb height
curb horz reinf bar
curb horz reinf spacing
depth to center of reinf
curb thickness
M U horn curb 3575 ft -lbs
—
Fbot otwall = 1028.5 plf cpMncurb =
Mwall uniform = 26062 ft -lbs Mbase of wall =
Mwall triangle = 17904 ft-IbS R =
Load Factor 1.6 Mu norcwau =
Wu = 5628
Wall Reinforcing
Wall Thickness 12 in
Clear Cover '= 2 in
Addl Horz Reinf 6`
Vert Rebar Size 7
Rebar Area 0.60 sq -in
conc strength f c 4000psi
Closure Reinf (3) - # 6
As in Closure 1.33 sq -in
7868 ft -lbs
43965 ft -lbs
3517 plf
70345 ft -lbs
prj . no.
II•o3�1�1
S-14-0(07
4 ft
4
12 in o/c
6 in
8 in
Ws1 = 962.5
Ws2 = 66
curb self -supported
# of Addl Bars 3
As @ Top of Wall 1.32 sq -in
depth to reinf (d) 8.75 in
comp block (a) 1.95 in
d - a/2 7.78 in
(DMn = 92582 ft -lbs Mu = 70345 ft -lbs
SITE STRUCTURES
10511 19th Ave SE, Suite C
Everett, WA, (425)-357-9600
Project �2 W �V a� ��
Beam Design Below Grated Opening
Design Data
Height of Curb:
Curb Thickness:
Soil Density:
Beam Width:
Beam Span:
Truck Rear Axle Load:
Calculated Design Forces
Soil Weight =
Curb Weight =
Self Weight =
Max Beam Reaction
Load Factor:
Wu=
Pu =
Design for Flexure
Reinf Size
# of Top &Bot Reinf
Area of Steel
Depth to Reinf (d)
Comp Block (a)
d - a/2
�Mn =
Design for Shear
.6.1.3. plf
36800 Ib
159987 ft -lbs
Tie Reinf Size __ , : 4:
Area of Steel 0:20
Depth to Reinf (d) 10.50
Max Spacing 5 25 in
Reinf Spacing ;' 5; in
�Vc = 5866 lbs
CVs = 42057- lbs
cpVc +CVs = 47923 lbs
sheet: �'� �
date: � 1- �3 -.��1
prj . no. S - ��/ - aC�7
r
����(�a ��' VJI�� l�
Mu = ' 102270 ft -lbs
�''w�n�
�H�il��
x (�O
Vu =
0
���ot�I��v����12� " �il��Da. ���
613.31. lbs
_� �O��D� I �y
ite Project —�_� IUC'
tructures
A Division of Kosnik Engineering PC
Sheet
Job No s Gr G�7.1
:..
OF
Nor
MOW-
� . 5� �k
� t
X d f� ;00�Z
b Project
tructures
A Division of Kosnik Engineering PC
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H-15 TRUCK
Sheet
Date
Job No S /V
o c /
6° ON GENT L:Hl CROSS BAM65 4" ON UNI LH (Z" UR
-�—®- o
H -f0 TRUCK AUTO TRAFFIC
WEIGH T LBS, SECTION MOD. CROSS BAR n kf2O7RUCK
PER SQ. FTPER FT. OF WIDTH SIZE
10.1 0.421 1'-1" 0
12.3 0.526 SEE 11411 0
14.6 0.632 1'-211
H4
�' TRUCK
1-1/2 x 5/16 18.0 1.184 BAR 1'-6" 1'-4"
1-1/2 x 318. . . 21.3 . 1.421 1'-8" 1'-6"
2 x 1/4 19.1 1.684 1'-10" 1'-8"
2 x 3/8 28.2 2.526 214" 2'-2"
:•^,, Ivr, n•'t°' m , r°Th! ul;':P ' 1 16' y,6t. °,.�,.,,,,'an-r , : 11 -,:n •, P :
116, 6"1 \ 1..6, '6 ,. 1 l '6 u, ,t7 t. :.1..1'1 y'n11 'An' ,rR,q` :, .,,,..,r,�16i1 ::\r,
"4 ., . \ 1 ,: i " 1, . c16y: i1 A, 'n , 11F . �" `
EY...1� 1 \,s. c,:, ,G�\ r�. �,1' Cpl, .+ p.,. 1 .,'m: 4k 1.,N1,..,, p1�
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1\r q�1 \ ,! `41 \ 1 .H\ `„ ,:a G �1�' \, �11 1 „`1P`:Ae41\d \:� 141 + \w \n,0 1,� .:
\, , \' l``�\ `t• G`1, W\, `1: 1 , l``1:\ n.,8 \ 1 �t \\1111 .,`:4, \, t, F.\1 n�\_ \,\,41i. q \ \ \! ,\
P�im°\I.. "1\\ 11 1 \ ya. , 11� �q\\`;r \, ��' 11 , �` 1 \ 1.1. \11``. , 4 ,\,'1 1:, Y �..•\1\�\t . ,\
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\ ,, \\I \� rl `,:. ,, , 1 \ 1�'4\,\",1`1`a:\: r.. 1\11 1�:r ,pr, •\, 1.\1 �1 \'\.�.� 1. ,1\
;C�
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1,. �`-a
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F,� 1, ,1 •\�`�xr?.,?�4�%�\1 q 1, '�a� \\ \ \ `\ \ t1�u. 1�,..1\`, 1 ' „�}I \`p�\ 11 1`r`. ` .
1,r.!16 P,Jr,,\H114�[F��l�`L���' 111%y�sti`1";;1,\:11'\lp��`1"1K�tCS1u1\F5`41,'•t\\� P!� 6L'1111U11 f:�1P`� I6\�jli1L„d116i\Y:�, lidtil�W
2-1/•2 x 1/4 23.7 2.631 2'-4" 2'-3"
2-1/2 x 5/16 29.3 3.289 10 2'-9" 2'-7"
2-1/2 x.3/8 ' 34.9 1947 3'-211 3141
3=1/2 x'1/4 - : - ��•� 32.:8 .. � 5:157 --:. � � 3'.-7:0" � � 3.'-9,"
3-1/2 x 3 8 48.6 7.736 5'-0" 5'-0"
n N , - 1' \ r\ ry T\ 1 .1• L• `x: : ll' ' 'h 1" " <, 1 1 : - "l
1'° h'`6 \' `n \n.r;"n`\11
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41\l, \\` n , ,tr: �fi a. \\, \\ \., \,\ ,`� \id,. „`��1\ \\NII \,, \1•\\, \: '�:101,
11•_ 1,0\l1 '\+,, �,\ 1, ',\. 1 dl ,lo d+. ,h�
.,1 � � ,1., � � ��1
}'•1'. I\ +, :11 1\ 1 \ \\\ \ \1 Y [ �\\\ \1.\1 11Mt
`1., `� 1 �—,13`'
\ u \,m.
\\
�.�..._,_���n>�
5 x 1/4 46.4 10.525 6'-3'i 6'-3"
5 x 3/8 68.9 15.788 7'-1" 7141
5 x 1/2 91.3 21.050 7'-10" 7'-11"
7 x 3/8 96.0 30.944 ' 9'-11" 1Q'-0"
7 x 1/Z 127.3 41.258 10'-11" 11'-1"
i
.,an
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H-15 TRUCK
Sheet
Date
Job No S /V
o c /
6° ON GENT L:Hl CROSS BAM65 4" ON UNI LH (Z" UR
-�—®- o
H -f0 TRUCK AUTO TRAFFIC
WEIGH T LBS, SECTION MOD. CROSS BAR n kf2O7RUCK
PER SQ. FTPER FT. OF WIDTH SIZE
10.1 0.421 1'-1" 0
12.3 0.526 SEE 11411 0
14.6 0.632 1'-211
H4
�' TRUCK
1-1/2 x 5/16 18.0 1.184 BAR 1'-6" 1'-4"
1-1/2 x 318. . . 21.3 . 1.421 1'-8" 1'-6"
2 x 1/4 19.1 1.684 1'-10" 1'-8"
2 x 3/8 28.2 2.526 214" 2'-2"
:•^,, Ivr, n•'t°' m , r°Th! ul;':P ' 1 16' y,6t. °,.�,.,,,,'an-r , : 11 -,:n •, P :
116, 6"1 \ 1..6, '6 ,. 1 l '6 u, ,t7 t. :.1..1'1 y'n11 'An' ,rR,q` :, .,,,..,r,�16i1 ::\r,
"4 ., . \ 1 ,: i " 1, . c16y: i1 A, 'n , 11F . �" `
EY...1� 1 \,s. c,:, ,G�\ r�. �,1' Cpl, .+ p.,. 1 .,'m: 4k 1.,N1,..,, p1�
'�i n : l\; , , 16,. ,:f :1\t '1 \I1��\ : 1 S ,:\ l . , `1,.. 'V` �\ , \.\ PI \.� ,. t , \ u 1 \\ `;1,``1�1
r.il ,, �: �,�\a r @ ,,\, .r.,�!1 ,-\� `\\: 11 i „p� :.\ ` -�.,11. \ _\`
1\r q�1 \ ,! `41 \ 1 .H\ `„ ,:a G �1�' \, �11 1 „`1P`:Ae41\d \:� 141 + \w \n,0 1,� .:
\, , \' l``�\ `t• G`1, W\, `1: 1 , l``1:\ n.,8 \ 1 �t \\1111 .,`:4, \, t, F.\1 n�\_ \,\,41i. q \ \ \! ,\
P�im°\I.. "1\\ 11 1 \ ya. , 11� �q\\`;r \, ��' 11 , �` 1 \ 1.1. \11``. , 4 ,\,'1 1:, Y �..•\1\�\t . ,\
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F,� 1, ,1 •\�`�xr?.,?�4�%�\1 q 1, '�a� \\ \ \ `\ \ t1�u. 1�,..1\`, 1 ' „�}I \`p�\ 11 1`r`. ` .
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2-1/•2 x 1/4 23.7 2.631 2'-4" 2'-3"
2-1/2 x 5/16 29.3 3.289 10 2'-9" 2'-7"
2-1/2 x.3/8 ' 34.9 1947 3'-211 3141
3=1/2 x'1/4 - : - ��•� 32.:8 .. � 5:157 --:. � � 3'.-7:0" � � 3.'-9,"
3-1/2 x 3 8 48.6 7.736 5'-0" 5'-0"
n N , - 1' \ r\ ry T\ 1 .1• L• `x: : ll' ' 'h 1" " <, 1 1 : - "l
1'° h'`6 \' `n \n.r;"n`\11
\ Y \ ,1\',\ ,\ \1 . ,\ \` ,1\, 1 :t �•., f „ 1\I 1�{� , 'l,` : 1\1� '\ . \ �1 r', \\ ' 1 1 y� 1. I IUB, f \, p\ ' \ 3 ,t1\\''e
41\l, \\` n , ,tr: �fi a. \\, \\ \., \,\ ,`� \id,. „`��1\ \\NII \,, \1•\\, \: '�:101,
11•_ 1,0\l1 '\+,, �,\ 1, ',\. 1 dl ,lo d+. ,h�
.,1 � � ,1., � � ��1
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`1., `� 1 �—,13`'
\ u \,m.
\\
�.�..._,_���n>�
5 x 1/4 46.4 10.525 6'-3'i 6'-3"
5 x 3/8 68.9 15.788 7'-1" 7141
5 x 1/2 91.3 21.050 7'-10" 7'-11"
7 x 3/8 96.0 30.944 ' 9'-11" 1Q'-0"
7 x 1/Z 127.3 41.258 10'-11" 11'-1"
M Project V
,tructures
of Kosnik Engineering PC
Sheet
Date �'t J Iq
Job No
C
J�t4J 0, /�W
cU
Vt 4
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