HomeMy WebLinkAbout3501 W 18th St - Metal Canopy Technical - BuildingTECHNICAL
Permit
Address 3501 \n giA
Project description
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Date the permit was finaled
Number of technical pages Li- 3
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VP BUILDINGS
VAACO-PRUDEN
M6 P
Design
VP Buildings, Inc.
3200 Players Club Circle
Memphis, TN 38125-8843
STRUCTURAL DESIGN DATA
Project: Port Angeles Transfer Station
Name: CA0501693-01OE1
Builder PO 105 570
Jobsite: 3501 West 18th Street
City, State Port Angeles, Washington 98363
County Clallam
Country United States
TABLE OF CONTENTS
Date: 11/7/2005
Time: 4.54.37 PM
Page: 1 of 43
FILE
Letter of Certification 2
Building Loading Expanded Report 4
Reactions Summary Report 10
Bracing Summary Report 19
Secondary Summary Report 25
Framing Summary Report 28
Covering Summary Report 43
VPC File:CA0501693-010E1 vpc VPC Version .5.3a
VP BUILDINGS
VARCO- PRUDEN
Letter of Certification
Contact:
Name: CHG Building Systems, Inc.
Address: 1120 SW 16th, Suite A-4
City State: Renton, Washington 98055
Country United States
This is to certify that the above referenced VP BUILDINGS project has been designed for the applicable portions of the following Building Code and in
accordance with the order documents which have stipulated the following applied environmental loads and conditions:
Overall Building Description
Shape
Loads and Codes Shape: Metal Canopy
City Port Angeles County
Building Code: 2003 International Building Code
Building Use: Standard Occupancy Structure
Dead and Collateral Loads
Collateral Gravity7.00 psf
Collateral Uplift: 0.00 psf
Wind Load
Wind Speed: 100.00 mph
Wind Exposure (Factor): D (1.030)
Parts Wind Exposure Factor 1.030
Wind Enclosure: Open
Wind Importance Factor. 1.000
Topographic Factor 1.0000
NOT Windbome Debris Region
Base Elevation: 0/0/0
Primary Zone Strip Width: 7/0/12
Parts Portions Zone Strip Width: 3/0/0
Basic Wind Pressure: 22.42 psf
Per Article 2.9 in the Builder Agreement, VP Buildings assumes that the Builder has called the local Building Official or Project Engineer to obtain all code and
loading information for this specific building site.
The steel design is in accordance with VP BUILDINGS standard design practices, which have been established based upon pertinent procedures and
recommendations of the following organizations
American Institute of Steel Construction (AISC)
American Iron and Steel Institute (AISI)
American Welding Society (AWS) [Dl 1]
American Society for Testing and Materials (ASTM)
Metal Building Manufacturers Association (MBMA)
AISC Category MB Manufacturer Certification.
This certification DOES NOT apply to the design of the foundation or other on -site structures or components not supplied by VP BUILDINGS, nor does it
apply to unauthorized modifications to framing systems provided by VP BUILDINGS.
Furthermore, it is u �i certification is'based upon the premise that all components furnished by VP BUILDINGS will be erected or constructed in
strict complianc yr lei Ir. 't is furnished by VP BUILDINGS.
VP BUT
3200 Pia ers
Metal Canopy
Overall
Width
I 19/0/0 I
VPC File•CA050169
EXPIRES 07 18- O(
Design
Project: Port Angeles Transfer Station
Builder PO 105.570
Jobsite: 3501 West 18th Street
City State: Port Angeles, Washington 98363
County Country Clallam, United States
Overall I Floor Area Wall Area I Roof Area I Max. Eave I Min. Eave I Max. Roof I Min. Roof I Peak
Length (sq. ft.) I (sq. ft.) I (sq. ft.) I Height I Height 2 I Pitch I Pitch I Height
14/0/0 I 266 932 I 267 I 14/11/0 I 13/4/0 I 1.000:12 I I
Clallam
P.E. Prepared by 1 J
5 -8843
-1O +aS
State: Washington
Built Up: 89AISC
Cold Form: 01AISI
Roof Covering Second. Dead Load: 2.87 psf
Frame Weight (assumed for seismic):5.00 psf
Snow Load
Ground Snow Load: 39.68 psf
Design Snow (Sloped): 25.00 psf
Snow Exposure Category (Factor): 2 Partially
Exposed (0.90)
Snow Importance: 1.000
Thermal Category (Factor): Heated (1.00)
Ground Roof Conversion: 0.70
Snow Used in Seismic: 0.00
Seismic Snow Load: 0.00 psf
Unobstructed, Slippery Roof
Reviewed by
Live Load
Live Load: 20.00 psf Reducible
Seismic Load
Mapped Spectral Response Ss:124.10 %g
Mapped Spectral Response 51:50.90 %g
Seismic Hazard Use Group: Group 1
Seismic Importance: 1.000
Seismic Performance Design Category D
Framing Seismic Period: 0.2329
Bracing Seismic Period: 0.1457
Framing R-Factor 3.5000
Bracing R-Factor 3.5000
Soil Profile Type: Very dense soil and soft rock (C,
3)
Frame Redundancy Factor 1.0000
Brace Redundancy Factor 1.0000
Frame Seismic Factor (Cs): 0.2364
Brace Seismic Factor (Cs): 0.2364
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 2 of 43
Country United States
Rainfall: 4.00 inches per hour
Allow Overstress:
Frm: 1.03, Sec: 1.03, Brc: 1.03
VP BUILDINGS
VARCO.PRUDEN
The Structural Design and/or Manufacture of this VP BUILDINGS building will be or has been
at one of the following VP Buildings locations:
Rainsville, AL.
Memphis, TN.
Pine Bluff, AR.
Turlock, CA.
St. Joseph, MO
Kemersville, NC.
Evansville, WI.
Monterrey Mx.
Additional Structural Material may be fabricated and provided for use in a VP Buildings building
by one of the following fabricators:
BAR JOISTS
SMI, Inc. Hope, AR
SMI, Inc. Fallon, NV
SMI, Inc. Starke, FL
SMI, Inc. Iowa Falls, IA
SMI, Inc. Cayce West Columbia, SC
Hancock Salem, VA
Canam
Vulcraft
Vulcraft
Vulcraft
Vulcraft
ISP
Socar
Quincy
Washington, MO
Grapeland, TX
Norfolk, NE
Florence, SC
Brigham City UT
El Paso, TX
Florence, SC
Quincy FL
New Millennium
Building Systems Butler IN
Lake City FL
Design
VPC File:CA0501693 -010E1 vpc
VP Alabama Plant. .[Manufacture Only]
VP Headquarters. .[Design Only]
VP Arkansas Service Center .[Design Only]
VP California Service Center .[Design and Manufacture]
VP Missouri Service Center .[Design and Manufacture]
VP North Carolina Service Center.[Design and Manufacture]
VP Wisconsin Service Center .[Design and Manufacture]
VP Mexico Service Center .[Design and Manufacture]
STRUCTURAL STEEL FABRICATION
Addison Steel, Inc. Orlando, FL
PKM Steel Service, Inc. Salina, KS
Qualico Steel Co. Inc. Webb, AL
(This information is presented in compliance with VP Buildings' AISC Certification responsibilities.)
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 3 of 43
VP BUILDINGS
VA RCO -RR UDEN
Building Loading Expanded Report
Shape: Metal Canopy
Loads and Codes Shape: Metal Canopy
City- Port Angeles County Clallam
Building Code: 2003 International Building Code
Building Use: Standard Occupancy Structure
Allow Overstress:Frm: 1.03, Sec: 1.03, Brc: 1.03
Dead and Collateral Loads
Collateral Gravity7.00 psf
Collateral Uplift: 0.00 psf
Side Type Mag Units
A D 2.870 psf
A D 1130 psf
Live Load
Live Load: 20.00 psf Reducible
Wind Load
Wind Speed: 100.00 mph
Wind Enclosure: Open
Height Used: 15/0/0 (Type: Mean)
Base Elevation. 0/0/0
Primary Zone Strip Width: 7/0/12
Velocity Pressure: (qz) 25.60 psf
Topographic Factor 1.0000
Directionality Factor 0.8500
Wind Exposure (Factor): D (1.030)
Basic Wind Pressure: 22.42 psf
Snow Load
Ground Snow Load: 39.68 psf
Design Snow (Sloped): 25.00 psf
Snow Accumulation Factor 1.000
Snow Importance: 1.000
Ground Roof Conversion: 0.70
Shape
Entire
Entire
Seismic Load
Mapped Spectral Response Ss:124 10 %g
Mapped Spectral Response 51:50.90 %g
Seismic Hazard Use Group: Group 1
Seismic Performance Design Category D
Seismic Importance: 1.000
Frame Seismic Factor (Cs): 0.2364
Brace Seismic Factor (Cs): 0.2364
Framing R- Factor 3.5000
Bracing R- Factor 3.5000
Side Type Mag Units Shape Applied to
A E 3.515 psf Entire Frm
A E 3.515 psf Entire Brc
Applied to
Frm
Pur
Deflection Conditions
Frames are vertically supporting:Metal Roof Purlins and Panels
Frames are laterally supporting:Metal Wall Girts and Panels
Purlins are supporting:Metal Roof Panels
Girts are supporting:Metal Wall Panels
Deflection Limit Override H/180
Design
State: Washington
Built Up: 89AISC
Cold Form: 01AISI
Rainfall: 4.00 inches per hour
Frame Weight (assumed for seismic):5.00 psf
Description
Covering Weight 24 SSR Secondary Weight 1 74 Roof: A
Covering Weight 24 SSR Roof: A
Gust Factor 0.9009
Wind Importance Factor 1.000
Least Horiz. Dimension: 14/0/0
NOT Windbome Debris Region
Parts Portions Zone Strip Width: 3/0/0
qz= 0.00256 (1.00) (100.00) ^2 (1.00)
The All Heights' Method is Used
Snow Exposure Category (Factor): 2 Partially Exposed (0.90)
Thermal Category (Factor): Heated (1.00)
Unobstructed, Slippery Roof
Rain Surcharge: 0.00
Slope Reduction: 1.00
Slope Used: 4 764 1.000:12
Seismic Snow Load: 0.00 psf
Frame Redundancy Factor 1.0000
Brace Redundancy Factor 1.0000
Soil Profile Type: Very dense soil and soft rock (C, 3)
Framing Seismic Period: 0.2329
Bracing Seismic Period: 0.1457
Seismic Period Height Used: 14/1/8
Design Spectral Response Sds: 0.8273
Design Spectral Response Shc 0.4411
Description
Seismic: Covering Weight 24 SSR+ Secondary Weight 1 74 (Includes 7.000 Collateral
5.000 Frame Weight) Roof: A
Seismic: Covering Weight 24 SSR Secondary Weight 1 74 (Includes 7.000 Collateral
5.000 Frame Weight) Roof: A
Per Article 2.9 in the Builder Agreement, VP Buildings assumes that the Builder has called the local Building Official or Project Engineer to obtain all code and
loading information for this specific building site.
VPC File:CA0501693 010E1 vpc VPC Version 5.3a
Country United States
Date: 11/7/2005
Time:4.54.37 PM
Page: 4 of 43
VP BUILDINGS
VARCO- PRUDEN
Design Load Combinations Framin
No. Origin Factor
System 1.000
2 System 1.000
3 System 1.000
4 System 1.000
5 System 1.000
6 System 1.000
7 System 1.000
8 System 1.000
9 System 1.000
10 System 1.000
11 System 1.000
12 System 1.000
13 System 1.000
14 System 1.000
15 System 1.000
16 System 1.000
17 System 1.000
18 System 1.000
19 System 1.000
20 System 1.000
21 System 1.000
22 System 1.000
23 System 1.000
24 System 1.000
25 System 1.275
26 System 1.275
27 System 1.275
28 System 1.275
29 Special 1.275
30 Special 1.275
31 Special 1.275
32 Special 1.275
33 AISC Special 1 700
34 AISC Special 1 700
35 AISC Special 1 700
36 AISC Special 1 700
37 System Derived 1.000
38 System Derived 1.000
39 System Derived 1.000
40 System Derived 1.000
41 System Derived 1.000
42 System Derived 1.000
43 System Derived 1.275
44 System Derived 1.275
45 System Derived 1.275
46 System Derived 1.275
47 Special 1.275
48 Special 1.275
49 System Derived 1.000
50 System Derived 1.000
51 System Derived 1.000
52 System Derived 1.000
53 System Derived 1.000
54 System Derived 1.000
55 System Derived 1.275
56 System Derived 1.275
57 System Derived 1.275
58 System Derived 1.275
59 Special 1.275
60 Special 1.275
61 System Derived 1.000
62 System Derived 1.000
63 System Derived 1.000
64 System Derived 1.000
65 System Derived 1.000
66 System Derived 1.000
VPC File:CA0501693 -010E1 vpc
Design
Application
1.OD +I.00G +I.OL
1.OD +1.0CG +1.0S
1.OD +1.OWI>
1.0 D 1.0 <W1
1.0 D 1.0 W2>
1.0 D 1.0 <W2
1.0 D 1.0 CG 0.750 L +0.750 WI>
1.0 D 1.0 CG 0.750 L 0.750 <W1
1.0 D 1.0 CG 0.750 L 0.750 W2>
1.0 D 1.0 CG 0.750 L 0.750 <W2
1.0 D 1.0 CG 0.750 S 0.750 WI>
1.0 D 1.0 CG 0.750 S 0.750 <WI
1.0 D 1.0 CG 0 750 S +0.750 W2>
1.0 D 1.0 CG 0.750 S 0.750 <W2
0.600D +1.OWI>
0.600 D 1.0 <W1
0.600 D 1.0 W2>
0.600 D 1.0 <W2
1.0 D 1.0 CG 0.700 E> 0.700 EG+
1.0 D 1.0 CG 0.700 <E 0.700 EG+
1.0 D 1.0 CG 0.750 L 0.750 E> 0.750 EG+
1.0 D+ 1.0 CG+ 0.750 L 0.750 <E 0.750 EG+
0.600 D 0.600 CG 0.700 E> 0 700 EG-
0.600 D 0.600 CG 0.700 <E 0.700 EG-
0.900 D 0.900 CG 1.0 E> 0.700 EG-
0.900 D 0.900 CG 1.0 <E 0.700 EG-
1.200 D 1.200 CG 0.200 S 1.0 E> 0.700 EG+
1.200 D 1.200 CG 0.200 S 1.0 <E 0.700 EG+
D.900 D 0.900 CG 2.500 E> 1.0 EG-
0.900 D 0.900 CG 2.500 <E 1.0 EG-
1.200 D 1.200 CG 0.200 S 2.500 E> 1.0 EG+
1.200 D 1.200 CG 0.200 S 2.500 <E 1.0 EG+
0.900 D 0.900 CG
0.900 D 0.900 CG
1.200 D 1.200 CG 0.200 S
1.200 D 1.200 CG 0.200 S
1.0 D 1.0 CG 0.210 E> 0.700 EG+ 0 700 EB>
1.0 D 1.0 CG 0.210 <E 0.700 EG+ 0.700 ER>
1.0 D 1.0 CG 0.750 L 0.225 E> 0.750 EG+ 0.750 EB>
1.0 D 1.0 CG 0.750 L 0.225 <E 0.750 EG+ 0.750 EB>
0.600 D 0.600 CG 0.210 E> 0.700 EG- 0.700 EB>
0.600 D 0.600 CG 0.210 <E 0.700 EG- 0.700 EB>
0.900D +0.900 CG 0.300 E> 0 700 EG- 1.0 EB>
0.900 D 0.900 CG 0.300 <E 0.700 EG- 1.0 EB>
1.200 D 1.200 CG 0.200 S 0.300 E> 0.700 EG+ 1.0 EB>
1.200 D 1.200 CG 0.200 S 0.300 <E 0.700 EG+ 1.0 EB>
0.900 D 0.900 CG 2.500 EB> 1.0 EG-
1.200 D 1.200 CG 0.200 S 2.500 EB> 1.0 EG+
1.0 D+ 1.0 CG 0.210 E> 0.700 EG+ 0.700 <EB
1.0 D 1.0 CG 0.210 <E 0.700 EG+ 0.700 <EB
1.0 D 1.0 CG 0.750 L 0.225 E> 0.750 EG+ 0 750 <EB
1.0 D+ 1.0 CG 0.750 L 0.225 <E 0.750 EG+ 0.750 <EB
0.600 D 0.600 CG 0.210 E> 0.700 EG- 0.700 <EB
0.600 D 0.600 CG 0.210 <E 0.700 EG- 0.700 <EB
0.900 D 0.900 CG 0.300 E> 0.700 EG- 1.0 <EB
0.900 D 0.900 CG 0.300 <E 0.700 EG- 1.0 <ER
1.200 D 1.200 CG 0.200 S 0.300 E> 0.700 EG+ 1.0 <EB
1.200 D 1.200 CG 0.200 S 0.300 <E 0 700 EG+ 1.0 <EB
0.900 D 0.900 CG 2.500 <EB 1.0 EG-
1.200D+ 1.200 CG+ 0.200S +2.500 <EB +1.0EG+
1.0 D 0.750 WI> 0.750 WB1>
1.0 D 0.750 <WI +0.750 WB1>
1.OD +1.OWP +1.OWB1>
1.0 D 1.0 CG +0.750 L +0.563 Wl> 0.563 WB1>
1.0 D 1.0 CG 0.750 L 0.563 <WI 0.563 WBI>
1.0 D 1.0 CG 0.750 L 0.750 WP 0.750 WB1>
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 5 of 43
Description
D CG L
D +CG +S
D +WI>
D <Wl
D W2>
D <W2
D +CG +L +WI>
D +CG +L <Wl
D +CG +L +W2>
D +CG +L <W2
D +CG Wl>
D +CG +S <W1
D +CG +S +W2>
D +CG +5 <W2
D +Wl>
D +<W1
D W2>
D <W2
D +CG +F> +EG+
D +CG +<E +EG+
D +CG +L +F> +EG+
D +CG +L <E +EG+
D+CG +F> +EG-
D+CG+<E+EG-
D+CG+E>+EG-
D+CG+<E+EG-
D +CG +S +B> +EG+
D +CG +S <E +EG+
D CG E> EG-
D CG <E EG-
D CG S E> EG+
D +CG +S <E EGA-
D +CG
D CG
D CG S
D CG S
D +CG +B>+ EG+ +EB>
D CG <E EG+ EB>
D+CG+L+E>+EG++EB>
D +CG+L+<E +EG++EB>
D CG E> EG- EB>
D CG <E EG- EB>
D CG E> EG- EB>
D CG <E EG- EB>
D+CG+S +E>+EG++EB>
D+CG+S+<E +EG+EEB>
D CG EB> EG-
D CG S EB> EG+
D CG E> EG+ <EB
D CG <E EG+ <EB
D+CG+L +Ej+EG++<EB
D+CG+L+<E+EG I I <EB
D CG E> EG- <EB
D CG <E EG- <EB
D +CG +B> EG- <EB
D CG <E EG- <EB
D+CG+S +E> +EG++<EB
D+CG+S+<E+EG I I <EB
D CG <EB EG-
D CG S <EB EG+
D +WI +WB1>
D <WI +WBI>
D+WP +WB1>
D+CG +L +WI +WB1>
D+CG+L <W1 +WB1>
D CG+ L+ WP WB1>
Design
67 System Derived 1.000 1.0 D 1.0 CG 0 750 S 0.563 W1> +0.563 WBI>
68 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 <WI 0.563 WB1>
69 System Derived 1.000 1.0 D 1.0 CG 0 750 S 0.750 WP 0.750 WB1>
70 System Derived 1.000 0.600 D 0.750 W 1> 0.750 WB1>
71 System Derived 1.000 0.600 D 0 750 <W1 0 750 WB1>
72 System Derived 1.000 0.600 D 1.0 WP 1.0 WB1>
73 System Derived 1.000 1.0 D 0.750 WI> 0 750 <WB1
74 System Derived 1.000 1.0 D 0.750 <W1 0 750 <WBI
75 System Derived 1.000 1.0 D 1.0 WP 1.0 <WB1
76 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.563 W 1> 0.563 <WB1
77 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.563 <WI +0.563 <WB1
78 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.750 WP 0.750 <WB1
79 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 WI> 0.563 <WB1
80 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 <W I 0.563 <WB1
81 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.750 WP 0.750 <WB1
82 System Derived 1.000 0.600 D 0.750 Wl> 0.750 <WBI
83 System Derived 1.000 0.600 D 0.750 <W1 0.750 <WB1
84 System Derived 1.000 0.600 D 1.0 WP 1.0 <WBI
85 System Derived 1.000 1.0 D 0.750 W2> 0.750 WB2>
86 System Derived 1.000 1.0 D 0 750 <W2 0.750 WB2>
87 System Derived 1.000 1.0 D 1.0 WP 1.0 WB2>
88 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.563 W2> 0.563 WB2>
89 System Derived 1.000 1.0 D 1.0 CG 0 750 L 0.563 <W2 0.563 WB2>
90 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.750 WP 0.750 WB2>
91 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 W2> 0.563 WB2>
92 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 <W2 0.563 WB2>
93 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.750 WP 0 750 WB2>
94 System Derived 1.000 0.600 D 0.750 W2> 0.750 WB2>
95 System Derived 1.000 0.600 D 0 750 <W2 0.750 W132>
96 System Derived 1.000 0.600 D 1.0 WP 1.0 WB2>
97 System Derived 1.000 1.0 D 0.750 W2> 0.750 <WB2
98 System Derived 1.000 1.0 D 0.750 <W2 0.750 <WB2
99 System Derived 1.000 1.0 D 1.0 WP 1.0 <WB2
100 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.563 W2> 0.563 <WB2
101 System Derived 1.000 1.0 D 1.0 CG 0 750 L 0.563 <W2 0.563 <WB2
102 System Derived 1.000 1.0 D 1.0 CG 0 750 L 0.750 WP 0.750 <WB2
103 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 W2> 0.563 <WB2
104 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 <W2 0.563 <WB2
105 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.750 WP 0.750 <WB2
106 System Derived 1.000 0.600 D 0.750 W2> 0.750 <WB2
107 System Derived 1.000 0.600 D 0.750 <W2 0.750 <WB2
108 System Derived 1.000 0.600 D 1.0 WP 1.0 <WB2
VPC File•CA0501693 -01OE1 vpc VPC Version .5.3a
Date: 11/7/2005
Time: 4 54.37 PM
Page: 6 of 43
D +CG +S +W1 +WB1>
D +CG +S <Wl +WBI>
D +CO +S +WP +WB1>
D +WI +WBI>
D <W1 +WB1>
D +WP +WB1>
D +Wl <WB1
D <W1 +<WB1
D WP <WB1
D +CG +L +WI <WB1
D +CG +L <W1 <WB1
D +CO +L +WP <WB1
D +CO +S +W1 <WB1
D +CG +S <WI <WB1
D +CO +S +WP <WB1
D WI> <WB1
D <W1 <WB1
D +WP <WB1
D W2> WB2>
D <W2 WB2>
D+WP +WB2>
D CG L W2> WB2>
D CO L <W2 WB2>
D CO L WP WB2>
D CG S W2> WB2>
D CO S <W2 WB2>
D +CO +S +WP +WB2>
D+W2 +WB2>
D <W2 WB2>
D +WP +WB2>
D W2> <WB2
D <W2 <WB2
D WP <WB2
D CG L W2> <WB2
D CO L <W2 <WB2
D CO L+ WP +<WB2
D CO S W2> <WB2
D CO S <W2 <WB2
D CO S WP <WB2
D W2> <WB2
D +<W2 <WB2
D WP <WB2
Design Load Combinations Bracing
No. Origin Factor Application Description
1 System 1.000 0.700 E> F>
2 System 1.000 0.700 <E <E
3 System 1.275 1.0 E> E>
4 System 1.275 1.0 <E <E
5 System 1.000 1.0 WI> WI>
6 System 1.000 1.0 <W1 <W1
7 System 1.000 1.0 W2> W2>
8 System 1.000 1.0 <W2 <W2
Design Load Combinations Purlin
No. Origin Factor Application Description
1 System 1.000 1.0 D+ 1.0 CG 1.0 S D CG S
2 System 1.000 1.0D +1.0W1> D WI>
3 System 1.000 1.0 D 1.0 <W2 D <W2
4 System 1.000 1.0 D 1.0 WP D WP
5 System 1.000 0.600 D 1.0 W l> D+ W l>
6 System 1.000 0.600 D 1.0 <W2 D <W2
7 System 1.000 0.600 D 1.0 WP D WP
8 System 1.000 1.OD +I.00G +0.750S +0.750W1> D +CG +S +WI>
9 System 1.000 1.0D +1.0CG +0.7505 +0.750 <W2 D +CG +S <W2
10 System 1.000 1.0 D 1.0 CG 0.750 S 0.750 WP D CG S WP
I I System 1.275 1.200 D 1.200 CG 0.200 S 1.0 E> 0.700 EG+ D CO S E> EG+
12 System 1.275 1.200 D 1.200 CG 0.200 S 1.0 <E 0.700 EG+ D CG S <E EG+
VP BUILDINGS
VAACO- PRUDEN
1 3
1 4
System
System
Design Load Combinations Girt
No. I Origin I Factor
1 System 1.000 1.0 WI>
2 System 1.000 1.0 <W2
3 System 1.000 1.0 WP
Design Load Combinations Roof Panel
No. I Origin I Factor I
1 System
2 System
3 System
Design Load Combinations Wall Panel
I No. I Origin 1 Factor I
1 1 System 1 1.000 11.0 Wl>
2 System 1.000 1.0 <W2
Deflection Load Combinations
No. Origin Factor
1 System 1.000
2 System 1.000
3 System 1.000
4 System 1.000
5 System 1.000
6 System 1.000
7 System 1.000
8 System 1.000
9 System 1.000
10 System 1.000
11 System 1.000
12 System 1.000
13 System 1.000
14 System 1.000
1 System
2 System
3 System
1.275 0.900 D 0.900 CG 1.0 E> 0.700 EG-
1.275 0.900 D 0.900 CG 1.0 <E 0.700 EG-
1.000
1.000
1.000
VPC File:CA0501693 010E1 vpc
1.000 1.OD+1.OS
1.000 1.0 D+ 1.0 WI>
1.000 1.0 D 1.0 <W2
Framin
Def H Def V
0 180
0 180
0 180
O 180
O 180
0 180
0 180
60 0
60 0
60 0
60 0
60 0
60 0
60 0
Deflection Load Combinations Purlin
I No. I Origin I Factor I Deflection I
11 I System 1 1.000 I 150 11.0 S
Deflection Load Combinations Girt
I No. I Origin I Factor I Deflection I
180
180
180
Deflection Load Combinations Roof Panel
I No. I Origin I Factor I Def H I Def VI
11 I System 1 1.000 1 150 1 150 11.0 S
1.0 L
1.0 S
0.700 WI>
0.700 <W1
0.700 W2>
0.700 <W2
0.700 WP
0.700 Wl>
0.700 <W1
0.700 W2>
0.700 <W2
0.700 WP
D.600 E> 0.700 EG-
0.600 <E 0.700 EG-
0.700 Wl>
0.700 <W2
0.700 WP
Load Type Descriptions
D Material Dead Weight
CG Collateral Load for Gravity Cases
L Live Load
^ASL Alternate Span Live Load, Shifted Left
S Snow Load
*US1 Unbalanced Snow Load I Shifted Left
*US2 Unbalanced Snow Load 2, Shifted Left
SS Sliding Snow Load
PF1 Partial Load, Full, 1 Span
PF2 Partial Load, Full, 2 Spans
W Wind Load
<W1 Wind Load, Case 1 Left
<W2 Wind Load, Case 2, Left
<W3 Wind Load, Case 3, Left
<W4 Wind Load, Case 4 Left
Design
Application
Application
Application
Application
Application
Application
Application
C
CU
ASL^
PL2
US I
US2*
SD
RS
PH1
PH2
WI>
W2>
W3>
W4>
W5>
Wl>
<W2
WP
D +S
D +W1>
D <W2
WI>
W2
L
S
Wl>
<W1
W2>
<W2
WP
Wl>
<W1
W2>
<W2
WP
E> EG-
<E EG-
IS
Collateral Load
Collateral Load for Wind Cases
Alternate Span Live Load, Shifted Right
Partial Live, Full, 2 Spans
Unbalanced Snow Load 1 Shifted Right
Unbalanced Snow Load 2, Shifted Right
Snow Drift Load
Rain Surcharge Load
Partial Load, Half, 1 Span
Partial Load, Half, 2 Spans
Wind Load, Case 1 Right
Wind Load, Case 2, Right
Wind Load, Case 3, Right
Wind Load, Case 4 Right
Wind Load, Case 5, Right
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 7 of 43
1 D CG +E> +EG-
D +CG <E +EG-
Description
Description
I Description
Description
I Description
IS
I Description
Wl>
<W2
WP
Description
VP BUILDINGS
VARCO- PRUDEN
<W5
<W6
WPR
WPA1
WPB I
WPC1
WPD1
WB1>
WB2>
WB3>
WB4>
WB5>
WB6>
E
<E
EG+
EB>
FL
*FL
AL
*AL>
*AL
*AL
*AL>(1)
*AL(1)
*AL(1)
*AL>(2)
*AL.(2)
*AL(2)
*AL>(3)
*AL(3)
*AL(3)
*AL>(4)
*AL(4)
*AL(4)
*AL>(5)
*AL(5)
*AL(5)
ALB>
WALB>
ALB >(1)
WALB >(1)
ALB >(2)
WALB >(2)
ALB >(3)
WALB >(3)
ALB >(4)
WALB >(4)
ALB >(5)
WALB >(5)
WALB
UO
U2
U4
U6
U8
UB
UB2
UB4
UB6
UB8
R
V
VPC File•CA0501693 -010E1 vpc
Wind Load, Case 5, Left
Wind Load, Case 6, Left
Wind Load, II Ridge, Right
Wind Parallel Ref A, Case 1
Wind Parallel Ref B, Case 1
Wind Parallel Ref C, Case 1
Wind Parallel Ref D, Case 1
Wind Brace Reaction, Case 1 Right
Wind Brace Reaction, Case 2, Right
Wind Brace Reaction, Case 3, Right
Wind Brace Reaction, Case 4, Right
Wind Brace Reaction, Case 5, Right
Wind Brace Reaction, Case 6, Right
Seismic Load
Seismic Load, Left
Vertical Seismic Effect, Additive
Seismic Brace Reaction, Right
Floor Live Load
Alternate Span Floor Live Load, Shifted Left
Auxiliary Live Load
Auxiliary Live Load, Right, Left
Auxiliary Live Load, Left, Left
Aux Live, Left
Auxiliary Live Load, Right, Left, Aisle 1
Auxiliary Live Load, Left, Left, Aisle 1
Aux Live, Left, Aisle 1
Auxiliary Live Load, Right, Left, Aisle 2
Auxiliary Live Load, Left, Left, Aisle 2
Aux Live, Left, Aisle 2
Auxiliary Live Load, Right, Left, Aisle 3
Auxiliary Live Load, Left, Left, Aisle 3
Aux Live, Left, Aisle 3
Auxiliary Live Load, Right, Left, Aisle 4
Auxiliary Live Load, Left, Left, Aisle 4
Aux Live, Left, Aisle 4
Auxiliary Live Load, Right, Left, Aisle 5
Auxiliary Live Load, Left, Left, Aisle 5
Aux Live, Left, Aisle 5
Aux Live Bracing Reaction, Right
Wind, Aux Live Bracing Reaction, Right
Aux Live Bracing Reaction, Right, Aisle 1
Wind, Aux Live Bracing Reaction, Right, Aisle 1
Aux Live Bracing Reaction, Right, Aisle 2
Wind, Aux Live Bracing Reaction, Right, Aisle 2
Aux Live Bracing Reaction, Right, Aisle 3
Wind, Aux Live Bracing Reaction, Right, Aisle 3
Aux Live Bracing Reaction, Right, Aisle 4
Wind, Aux Live Bracing Reaction, Right, Aisle 4
Aux Live Bracing Reaction, Right, Aisle 5
Wind, Aux Live Bracing Reaction, Right, Aisle 5
Wind, Aux Live Bracing Reaction
User Defined Load
User Defined Load 2
User Defined Load 4
User Defined Load 6
User Defined Load 8
User Brace Reaction
User Brace Reaction 2
User Brace Reaction 4
User Brace Reaction 6
User Brace Reaction 8
Rain Load
Shear
Design
W6>
WP
WPL
WPA2
WPB2
WPC2
WPD2
<WB1
<WB2
<WB3
<WB4
<WB5
<WB6
F>
EG
EG-
<EB
FL*
FD
AL
<AL*
AL*
AL >(1)
<AL *(1)
AL *(1)
AL >(2)
<AL *(2)
AL *(2)
AL >(3)
<AL *(3)
AL *(3)
AL >(4)
<AL *(4)
AL *(4)
AL >(5)
<AL *(5)
AL *(5)
ALB
<ALB
<WALB
<ALB(1)
<WALB(1)
<ALB(2)
<WALB(2)
<ALB(3)
<WALB(3)
<ALB(4)
<WALB(4)
<ALB(5)
<WALB(5)
AD
Ul
U3
U5
U7
U9
UB1
UB3
UB5
UB7
UB9
T
Wind Load, Case 6, Right
Wind Load, Parallel to Ridge
Wind Load, Ridge, Left
Wind Parallel Ref A, Case 2
Wind Parallel Ref B, Case 2
Wind Parallel Ref C, Case 2
Wind Parallel Ref D, Case 2
Wind Brace Reaction, Case 1 Left
Wind Brace Reaction, Case 2, Left
Wind Brace Reaction, Case 3, Left
Wind Brace Reaction, Case 4 Left
Wind Brace Reaction, Case 5, Left
Wind Brace Reaction, Case 6, Left
Seismic Load, Right
Vertical Seismic Effect
Vertical Seismic Effect, Subtractive
Seismic Brace Reaction, Left
Alternate Span Floor Live Load, Shifted Right
Floor Dead Load
Auxiliary Live Load, Right, Right
Auxiliary Live Load, Left, Right
Aux Live, Right
Auxiliary Live Load, Right, Right, Aisle 1
Auxiliary Live Load, Left, Right, Aisle 1
Aux Live, Right, Aisle 1
Auxiliary Live Load, Right, Right, Aisle 2
Auxiliary Live Load, Left, Right, Aisle 2
Aux Live, Right, Aisle 2
Auxiliary Live Load, Right, Right, Aisle 3
Auxiliary Live Load, Left, Right, Aisle 3
Aux Live, Right, Aisle 3
Auxiliary Live Load, Right, Right, Aisle 4
Auxiliary Live Load, Left, Right, Aisle 4
Aux Live, Right, Aisle 4
Auxiliary Live Load, Right, Right, Aisle 5
Auxiliary Live Load, Left, Right, Aisle 5
Aux Live, Right, Aisle 5
Aux Live Bracing Reaction
Aux Live Bracing Reaction, Left
Wind, Aux Live Bracing Reaction, Left
Aux Live Bracing Reaction, Left, Aisle 1
Wind, Aux Live Bracing Reaction, Left, Aisle 1
Aux Live Bracing Reaction, Left, Aisle 2
Wind, Aux Live Bracing Reaction, Left, Aisle 2
Aux Live Bracing Reaction, Left, Aisle 3
Wind, Aux Live Bracing Reaction, Left, Aisle 3
Aux Live Bracing Reaction, Left, Aisle 4
Wind, Aux Live Bracing Reaction, Left, Aisle 4
Aux Live Bracing Reaction, Left, Aisle 5
Wind, Aux Live Bracing Reaction, Left, Aisle S
Auxiliary Dead Load
User Defined Load 1
User Defined Load 3
User Defined Load 5
User Defined Load 7
User Defined Load 9
User Brace Reaction I
User Brace Reaction 3
User Brace Reaction 5
User Brace Reaction 7
User Brace Reaction 9
Temperature Load
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 8 of 43
VP BUILDINGS
VARCO- PRUDEN
C
a
VPC File:CA0501693 -010E1 vpc
Design
2
4
f7
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 9 of 43
VP BUILDINGS
VARCO- PRUDEN
Reactions Summary Report
Shape: Metal Canopy
Builder Contact: Ryan Grouws
Name: CHG Building Systems, Inc.
Address: 1120 SW 16th, Suite A-4
City State Zip. Renton, Washington 98055
Country United States
Loads and Codes Shape: Metal Canopy
City. Port Angeles County Clallam
Building Code: 2003 International Building Code
Building Use: Standard Occupancy Structure
Dead and Collateral Loads
Collateral Gravity7.00 psf
Collateral Uplift: 0.00 psf
Wind Load
Wind Speed: 100.00 mph
Wind Exposure (Factor): D (1.030)
Parts Wind Exposure Factor 1.030
Wind Enclosure: Open
Wind Importance Factor. 1.000
Topographic Factor 1.0000
NOT Windbome Debris Region
Base Elevation: 0/0/0
Primary Zone Strip Width: 7/0/12
Parts Portions Zone Strip Width: 3/0/0
Basic Wind Pressure: 22.42 psf
Load Type Descriptions
D Material Dead Weight
CG Collateral Load for Gravity Cases
L Live Load
AASL Altemate Span Live Load, Shifted Left
S Snow Load
*US1 Unbalanced Snow Load 1 Shifted Left
*US2 Unbalanced Snow Load 2, Shifted Left
SS Sliding Snow Load
PF1 Partial Load, Full, 1 Span
PF2 Partial Load, Full, 2 Spans
W Wind Load
<W1 Wind Load, Case 1 Left
<W2 Wind Load, Case 2, Left
<W3 Wind Load, Case 3, Left
<W4 Wind Load, Case 4 Left
<W5 Wind Load, Case 5, Left
<W6 Wind Load, Case 6, Left
WPR Wind Load, II Ridge, Right
WPA1 Wind Parallel Ref A, Case 1
WPB1 Wind Parallel Ref B, Case I
WPC1 Wind Parallel Ref C, Case 1
WPDI Wind Parallel Ref D, Case 1
WB I> Wind Brace Reaction, Case 1 Right
WB2> Wind Brace Reaction, Case 2, Right
WB3> Wind Brace Reaction, Case 3, Right
WB4> Wind Brace Reaction, Case 4 Right
WB5> Wind Brace Reaction, Case 5, Right
VPC File:CA0501693 -010E1 vpc
Design
State: Washington
Built Up: 89AISC
Cold Form: 01AISI
Roof Covering Second. Dead Load: 2.87 psf
Frame Weight (assumed for seismic):5.00 psf
Snow Load
Ground Snow Load: 39.68 psf
Design Snow (Sloped): 25.00 psf
Snow Exposure Category (Factor): 2 Partially
Exposed (0.90)
Snow Importance: 1.000
Thermal Category (Factor): Heated (1.00)
Ground Roof Conversion: 0.70
Snow Used in Seismic: 0.00
Seismic Snow Load: 0.00 psf
Unobstructed, Slippery Roof
Project: Port Angeles Transfer Station
Builder P011. 105.570
Jobsite: 3501 West 18th Street
City State Zip: Port Angeles, Washington 98363
County Country Clallam, United States
C
CU
ASLA
PL2
US1*
US2*
SD
RS
PH1
PH2
W l>
W2>
W3>
W4>
W5>
W6>
WP
WPL
WPA2
WPB2
WPC2
WPD2
<WB1
<WB2
<WB3
<WB4
<WB5
Country United States
Rainfall. 4.00 inches per hour
Allow Overstress:
Frm: 1.03, Sec: 1.03, Brc: 1 03
Live Load
Live Load: 20.00 psf Reducible
Collateral Load
Collateral Load for Wind Cases
Alternate Span Live Load, Shifted Right
Partial Live, Full, 2 Spans
Unbalanced Snow Load I Shifted Right
Unbalanced Snow Load 2, Shifted Right
Snow Drift Load
Rain Surcharge Load
Partial Load, Half, I Span
Partial Load, Half, 2 Spans
Wind Load, Case 1 Right
Wind Load, Case 2, Right
Wind Load, Case 3, Right
Wind Load, Case 4 Right
Wind Load, Case 5, Right
Wind Load, Case 6, Right
Wind Load, Parallel to Ridge
Wind Load, Ridge, Left
Wind Parallel Ref A, Case 2
Wind Parallel Ref B, Case 2
Wind Parallel Ref C, Case 2
Wind Parallel Ref D, Case 2
Wind Brace Reaction, Case 1 Left
Wind Brace Reaction, Case 2, Left
Wind Brace Reaction, Case 3, Left
Wind Brace Reaction, Case 4 Left
Wind Brace Reaction, Case 5, Left
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 10 of 43
Seismic Load
Mapped Spectral Response Ss:124 10 %g
Mapped Spectral Response S 1:50.90 %g
Seismic Hazard Use Group: Group 1
Seismic Importance: 1.000
Seismic Performance Design Category. D
Framing Seismic Period: 0.2329
Bracing Seismic Period: 0.1457
Framing R- Factor 3.5000
Bracing R-Factor 3.5000
Soil Profile Type: Very dense soil and soft rock (C,
3)
Frame Redundancy Factor• f .0000
Brace Redundancy Factor 1.0000
Frame Seismic Factor (Cs): 0.2364
Brace Seismic Factor (Cs): 0.2364
Per Article 2.9 in the Builder Agreement, VP Buildings assumes that the Builder has called the local Building Official or Project Engineer to obtain all code and
loading information for this specific building site.
VP BUILDINGS
MARCO- PRUDEN
WB6>
E
<E
EG+
EB>
FL
*FL
AL
*AL>
*AL
*AL
*AL>(1)
*AL(1)
*AL(1)
*AL>(2)
*AL.(2)
*ALP)
*AL>(3)
*AL(3)
*AL(3)
*AL>(4)
*AL(4)
*AL(4)
*AL>(5)
*AL(5)
*AL(5)
ALB>
WALB>
ALB >(1)
WALB >(1)
ALB >(2)
WALB >(2)
ALB >(3)
WALB >(3)
ALB >(4)
WALB >(4)
ALB >(5)
WALB >(5)
WALB
UO
U2
U4
U6
U8
UB
UB2
UB4
UB6
UB8
R
V
VPC File:CA0501693 -010E1 vpc
Wind Brace Reaction, Case 6, Right
Seismic Load
Seismic Load, Left
Vertical Seismic Effect, Additive
Seismic Brace Reaction, Right
Floor Live Load
Alternate Span Floor Live Load, Shifted Left
Auxiliary Live Load
Auxiliary Live Load, Right, Left
Auxiliary Live Load, Left, Left
Aux Live, Left
Auxiliary Live Load, Right, Left, Aisle 1
Auxiliary Live Load, Left, Left, Aisle 1
Aux Live, Left, Aisle 1
Auxiliary Live Load, Right, Left, Aisle 2
Auxiliary Live Load, Left, Left, Aisle 2
Aux Live, Left, Aisle 2
Auxiliary Live Load, Right, Left, Aisle 3
Auxiliary Live Load, Left, Left, Aisle 3
Aux Live, Left, Aisle 3
Auxiliary Live Load, Right, Left, Aisle 4
Auxiliary Live Load, Left, Left, Aisle 4
Aux Live, Left, Aisle 4
Auxiliary Live Load, Right, Left, Aisle 5
Auxiliary Live Load, Left, Left, Aisle 5
Aux Live, Left, Aisle 5
Aux Live Bracing Reaction, Right
Wind, Aux Live Bracing Reaction, Right
Aux Live Bracing Reaction, Right, Aisle 1
Wind, Aux Live Bracing Reaction, Right, Aisle 1
Aux Live Bracing Reaction, Right, Aisle 2
Wind, Aux Live Bracing Reaction, Right, Aisle 2
Aux Live Bracing Reaction, Right, Aisle 3
Wind, Aux Live Bracing Reaction, Right, Aisle 3
Aux Live Bracing Reaction, Right, Aisle 4
Wind, Aux Live Bracing Reaction, Right, Aisle 4
Aux Live Bracing Reaction, Right, Aisle 5
Wind, Aux Live Bracing Reaction, Right, Aisle 5
Wind, Aux Live Bracing Reaction
User Defined Load
User Defined Load 2
User Defined Load 4
User Defined Load 6
User Defined Load 8
User Brace Reaction
User Brace Reaction 2
User Brace Reaction 4
User Brace Reaction 6
User Brace Reaction 8
Rain Load
Shear
Design
<WB6
F>
EG
EG-
<EB
FL*
FD
AL
<AL*
AL*
AL >(1)
<AL *(1)
AL *(1)
AL >(2)
<AL *(2)
AL *(2)
AL >(3)
<AL *(3)
AL *(3)
AL >(4)
<AL *(4)
AL *(4)
AL >(5)
<AL *(5)
AL *(5)
ALB
<ALB
<WALB
<ALB(1)
<WALB(1)
<ALB(2)
<WALB(2)
<ALB(3)
<WALB(3)
<ALB(4)
<WALB(4)
<ALB(5)
<WALB(5)
AD
Ul
U3
U5
U7
U9
UB1
UB3
UB5
UB7
UB9
T
Wind Brace Reaction, Case 6, Left
Seismic Load, Right
Vertical Seismic Effect
Vertical Seismic Effect, Subtractive
Seismic Brace Reaction, Left
Alternate Span Floor Live Load, Shifted Right
Floor Dead Load
Auxiliary Live Load, Right, Right
Auxiliary Live Load, Left, Right
Aux Live, Right
Auxiliary Live Load, Right, Right, Aisle 1
Auxiliary Live Load, Left, Right, Aisle 1
Aux Live, Right, Aisle 1
Auxiliary Live Load, Right, Right, Aisle 2
Auxiliary Live Load, Left, Right, Aisle 2
Aux Live, Right, Aisle 2
Auxiliary Live Load, Right, Right, Aisle 3
Auxiliary Live Load, Left, Right, Aisle 3
Aux Live, Right, Aisle 3
Auxiliary Live Load, Right, Right, Aisle 4
Auxiliary Live Load, Left, Right, Aisle 4
Aux Live, Right, Aisle 4
Auxiliary Live Load, Right, Right, Aisle 5
Auxiliary Live Load, Left, Right, Aisle 5
Aux Live, Right, Aisle 5
Aux Live Bracing Reaction
Aux Live Bracing Reaction, Left
Wind, Aux Live Bracing Reaction, Left
Aux Live Bracing Reaction, Left, Aisle I
Wind, Aux Live Bracing Reaction, Left, Aisle 1
Aux Live Bracing Reaction, Left, Aisle 2
Wind, Aux Live Bracing Reaction, Left, Aisle 2
Aux Live Bracing Reaction, Left, Aisle 3
Wind, Aux Live Bracing Reaction, Left, Aisle 3
Aux Live Bracing Reaction, Left, Aisle 4
Wind, Aux Live Bracing Reaction, Left, Aisle 4
Aux Live Bracing Reaction, Left, Aisle 5
Wind, Aux Live Bracing Reaction, Left, Aisle 5
Auxiliary Dead Load
User Defined Load 1
User Defined Load 3
User Defined Load 5
User Defined Load 7
User Defined Load 9
User Brace Reaction 1
User Brace Reaction 3
User Brace Reaction 5
User Brace Reaction 7
User Brace Reaction 9
Temperature Load
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 11 of 43
VP BUILDINGS
VARCO- PRUDEN
c
a
Design
Date: 11/7/2005
Time: 4.54.37 PM
Page: 12 of 43
Overall Building Description
Shape I Overall I Overall I Floor Area I Wall Area I Roof Area I Max. Eave I Min. Eave I Max. Roof I Min. Roof I Peak
Width Length (sq. ft.) (sq. ft.) (sq ft.) Height Height 2 Pitch Pitch Height
Metal Canopy I 19/0/0 I 14/0/0 I 266 I 932 267 I 14/11/0 I 13/4/0 I 1.000:12 I I
Overall Shape Description
I Roof 1 I Roof 2 I From Grid I To Grid I Width I Length I Eave Ht. I Eave Ht. 2 I Pitch I Pitch 2 I Dist. to Ridge I Peak Height I
I A I I 1 -A I 1 -B I 19/0/0 I 14/0/0 I 13/4/0 I 14/11/0 I 1.000:12 I
2
P)
4
VPC File•CA0501693 -010E1 vpc VPC Version .5.3a
VP BUILDINGS
VAACO- PRUDEN
Wall. 2 (Grid.A
Design
n1 "III
Portal Brace reactions ARE included with frame reactions. See respective frame cross sections for reactions.
VPC File•CA0501693 -01OE1 vpc VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 13 of 43
VP BUILDINGS
VARCo-PRUDEN
Wall. 4 (Grid.B
Vy
x
Design
Vy
Portal Brace reactions ARE included with frame reactions. See respective frame cross sections for reactions.
/Hx
VPC File:CA0501693 -01OE1 vpc VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 14 of 43
VP BUILDINGS
VARCO- PRUDPN
Wall. 2, Frame at: 1/0/0
Design Load Combinations Framing
No. Origin
1 System
2 System
3 System
4 System
5 System
6 System
7 System
8 System
9 System
10 System
11 System
12 System
13 System
14 System
15 System
16 System
17 System
18 System
19 System
20 System
21 System
22 System
23 System
24 System
25 System
26 System
27 System
28 System
37 System Derived
38 System Derived
39 System Derived
40 System Derived
41 System Derived
42 System Derived
43 System Derived
44 System Derived
45 System Derived
46 System Derived
49 System Derived
50 System Derived
51 System Derived
52 System Derived
53 System Derived
54 System Derived
55 System Derived
56 System Derived
57 System Derived
58 System Derived
61 System Derived
62 System Derived
63 System Derived
64 System Derived
65 System Derived
66 System Derived
67 System Derived
68 System Derived
69 System Derived
70 System Derived
71 System Derived
72 System Derived
73 System Derived
74 System Derived
75 System Derived
76 System Derived
77 System Derived
Factor
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.275
1.275
1.275
1.275
1.000
1.000
1.000
1.000
1.000
1.000
1.275
1.275
1.275
1.275
1.000
1.000
1.000
1.000
1.000
1.000
1.275
1.275
1.275
1.275
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
VPC File:CA0501693 -010E1 vpc
Design
Application
1.0 D+ 1.0 CG+1.0L
1.0 D 1.0 CG 1.0 S
1.OD +1.0WI>
1.0 D+ 1.0 <WI
1.OD +I.0W2>
1.0 D 1.0 <W2
1.0 D 1.0 CG 0.750 L 0.750 W 1>
1.0 D +1.0 CO 0.750 L 0.750 <W1
1.0 D 1.0 CG 0 750 L 0.750 W2>
1.0 D 1.0 CG 0.750 L 0.750 <W2
1.0 D 1.0 CG 0.750 S 0.750 W I>
1.0 D 1.0 CG +0750 S +0.750 <WI
1.0 D 1.0 CG 0.750 S 0 750 W2>
1.0 D 1.0 CG 0.750 S 0.750 <W2
0.600D +1.0W1>
0.600D +1.0 <W1
0.600 D 1.0 W2>
0.600 D 1.0 <W2
1.0 D 1.0 CG 0.700 E> 0.700 EG+
1.0 D+1.0 CG+0700<E+0.700 EG+
1. 0D +1.0CG +0.750L +0.750F> +0.750EG+
1.0 D 1.0 CG 0.750 L 0.750 <E 0.750 EG+
0.600 D 0.600 CG 0 700 E> 0.700 EG-
0.600 D 0.600 CG 0 700 <E 0 700 EG-
0.900 D 0.900 CG 1.0 E> 0.700 EG-
0.900 D 0.900 CG 1.0 <E 0.700 EG-
1.200 D 1.200 CG 0.200 S 1.0 E> 0 700 EG+
1.200 D 1.200 CG 0.200 S 1.0 <E 0.700 EG+
1.0 D 1.0 CO 0.210 E> +0.700 EG+ 0.700 EB>
1.0 D+ 1.0 CG +0.210 <E +0.700 EG+ +0.700 EB>
1.0 D 1.0 CO 0.750 L 0.225 E> 0.750 EG+ 0.750 EB>
1.0 D 1.0 CO 0.750 L 0.225 <E 0.750 EG+ 0.750 EB>
0.600 D 0.600 CG 0.210 E> 0.700 EG- 0 700 EB>
0.600 D 0.600 CO 0.210 <E 0.700 EG- 0 700 EB>
0.900 D 0.900 CG 0.300 E> 0.700 EG- 1.0 EB>
0.900 D 0.900 CG 0.300 <E 0.700 EG- 1.0 EB>
1.200 D 1.200 CG 0.200 S 0.300 F> 0.700 EG+ 1.0 EB>
1.200 D 1.200 CG 0.200 S 0.300 <E 0.700 EG+ 1.0 EB>
1.0 D+ 1.0 CG 0.210 E> +0.700 EG+ +0.700 <EB
1.0 D 1.0 CO 0.210 <E 0.700 EG+ 0.700 <EB
1.0 D 1.0 CO 0.750 L 0.225 F> 0.750 EG+ 0.750 <EB
1.0 D 1.0 CO 0.750 L 0.225 <E 0.750 EG+ 0.750 <EB
0.600 D 0.600 CO 0.210 E> 0.700 EG- 0.700 <EB
0.600D+0.60000 +0.210 <E +0.700 EG- +0700 <EB
0.900 D 0.900 CG 0.300 E> 0.700 EG- 1.0 <EB
0.900 D 0.900 CG 0.300 <E 0.700 EG- 1.0 <EB
1.200D +1.200 CG +0.200 S+ 0.300E> +0.700 EG+ +1.0 <ER
1.200 D 1.200 CG 0.200 S 0.300 <E 0.700 EG+ 1.0 <ER
1.0 D 0.750 WI> +0.750 WB1>
1.0 D 0.750 <W1 +0.750 WB1>
I.OD +1.0WP +1.OWB1>
1.0 D 1.0 CG 0.750 L 0.563 W 1> 0.563 WB1>
1.0 D+ 1.0 CG 0.750 L 0.563 <W1 0.563 WB1>
1.0 D 1.0 CG 0.750 L 0.750 WP 0.750 WB1>
1.0 D 1.0 CG 0.750 S 0.563 W I> 0.563 WB1>
1.0 D+ 1.0 CG +0.7505 +0.563 <W1+ 0.563 WB1>
1.0 D 1.0 CG 0.750 S 0 750 WP 0 750 WB1>
0.600 D 0.750 W l> 0.750 WB1>
0.600 D 0.750 <W1 0.750 WB1>
0.600 D+ 1.0 WP 1.0 WBI>
1.0 D +0.750 WI> 0.750 <WB1
1.0 D 0.750 <W l 0.750 <WB1
1.OD +1.0WP +1.0<WBI
1.0 D 1.0 CG 0.750 L 0.563 W 1> 0.563 <WB1
1.0D +1.0CG +0.750L +0.563 <WI +0.563 <WE1
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 15 of 43
Description
D CG L
D CG S
D +WI>
D <W1
D W2>
D <W2
D +CO +L +WI>
D +CO +L <W1
D +CG +L +W2>
D +CG +L <W2
D +CO +S +WI>
D +CO+S <W1
D +CG +S +W2>
D +CO +S <W2
D WI>
D <WI
D W2>
D <W2
D +CG +F> +EG+
D CO <E EG+
D +CO +L +F> +EG+
D+ CO L+<E+ EG+
D +C, +F> +EG-
D+CO+<E+EG-
D+CO+F>+EG-
D+CO+<E+EG-
D +S +E> +EG+
D +CO+S <E +EG+
D CO E> EG+ EB>
D CO <E EG+ EB>
D +CG+L +E>+EG H
D+CG+L+<E +EG H
D CO F> EG- EB>
D +<E EG- +EB>
D +CG +F> EG- +EB>
D +CO <E EG- +EB>
D +CG+S+E>+EG++EB>
D+CG+S+<E +EG++EB>
D +CO+E> +EG+ <EB
D CO <E EG+ <EB
D+CG+L +E>+EG++ <EB
D+CG+L+<E+EG I <EB
D CO E> EG- <EB
D CO <E EG- <EB
D +CG +F> EG- <EB
D +CO <E EG- <EB
D +CG+S +E>+EG++<EB
D+CG+S+<E +EG++<EB
D +W1 +WB1>
D <W1 +WB1>
D +WP +WB1>
D +CG +L +W1 +WB1>
D+CG +L <W1 +WB1>
D +CG +L +WP+WB1>
D +CO +S +Wl +WB1>
D +CO +S <W1 WB1>
D+CG +S +WP +WB1>
D +WI +WB1>
D <W1 +WB1>
D WP WB1>
D +WI <WB1
D <W1 <WB1
D+WP <WBI
D +CG +L +WI <WB1
D +CG +L <WI <WB1
VP BUILDINGS
VARCO- PRUDEN
Design
78 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0 750 WP 0 750 <WB1
79 System Derived 1.000 1.0 D 1.0 CG 0 750 S 0.563 W 1> 0.563 <WB1
80 System Derived 1.000 1.0 D 1.0 CG 0 750 S 0.563 <WI 0.563 <WB I
81 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.750 WP 0.750 <WB1
82 System Derived 1.000 0.600 D 0.750 W 1> 0.750 <WBI
83 System Derived 1.000 0.600 D 0.750 <W1 0 750 <WB1
84 System Derived 1.000 0.600 D 1.0 WP 1.0 <WB 1
85 System Derived 1.000 1.0 D 0.750 W2> 0 750 WB2>
86 System Derived 1.000 1.0 D 0 750 <W2 0 750 WB2>
87 System Derived 1.000 1.0 D 1.0 WP 1.0 WB2>
88 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.563 W2> 0.563 WB2>
89 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.563 <W2 0.563 WB2>
90 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.750 WP 0 750 WB2>
91 System Derived 1.000 1.0 D 1.0 CG 0 750 S 0.563 W2> 0.563 WB2>
92 System Derived 1.000 1.0 D 1.0 CG 0 750 S 0.563 <W2 0.563 WB2>
93 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.750 WP 0.750 WB2>
94 System Derived 1.000 0.600 D 0.750 W2> 0.750 WB2>
95 System Derived 1.000 0.600 D 0.750 <W2 0.750 WB2>
96 System Derived 1.000 0.600 D 1.0 WP 1.0 WB2>
97 System Derived 1.000 1.0 D 0 750 W2> 0 750 <WB2
98 System Derived 1.000 1.0 D 0.750 <W2 0 750 <WB2
99 System Derived 1.000 1.0 D 1.0 WP 1.0 <WB2
100 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.563 W2> 0.563 <WB2
101 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.563 <W2 0.563 <WB2
102 System Derived 1.000 1.0 D 1.0 CG 0.750 L 0.750 WP 0.750 <WB2
103 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 W2> 0.563 <WB2
104 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0.563 <W2 0.563 <WB2
105 System Derived 1.000 1.0 D 1.0 CG 0.750 S 0 750 WP 0.750 <WB2
106 System Derived 1.000 0.600 D 0 750 W2> 0 750 <WB2
107 System Derived 1.000 0.600 D 0.750 <W2 0.750 <WB2
108 System Derived 1.000 0.600 D 1.0 WP 1.0 <WB2
VPC File:CA0501693 -010E1 vpc VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 16 of 43
D +CG +L +WP <WB1
D +CG +S +Wl +<WB1
D +CG +S <W1 +<WB1
D +CG +S +WP <WBI
D +W1 WB1
D <W1 WB1
D WP WB1
D +W2 +WB2>
D W2 WB2>
D +WP +WB2>
D CG L W2> WB2>
D CO L <W2 WB2>
D CG L WP WB2>
D CG S W2> WB2>
D CG S <W2 WB2>
D CG S WP WB2>
D W2> WB2>
D <W2 WB2>
D +WP +WB2>
D W2> <WB2
D <W2 <WB2
D WP <WB2
D CG L W2> <WB2
D CG L <W2 <W82
D CG L WP <WB2
D CO S W2> <WB2
D CO S <W2 <WB2
D CG S WP <WB2
D W2> <WB2
D W2 <WB2
D WP <WB2
VP BUILDINGS
VARCO -PRU DEN
Wall. 2, Frame at: 1/0/0
Frame ID:Rigid Frame
Values shown are resisting forces of the
Reactions Load Type at Frame Cro s
Type
X -Loc
Gridl Grid2
Base Plate W x L (in.)
Base Plate Thickness (in.)
Anchor Bolt Qty /Diam. (in.)
Column Base Elev
Load Type Desc.
D Frm
CG Frm
L Frm
S Frm
WI> Frm
<W1 Frm
W2> Frm
<W2 Frm
F> Frm
EG+ Frm
<E Frm
EG- Frm
EB> Brc
<EB Brc
WB 1> Brc
WP Frm
<WB I Brc
WB2> Brc
<WB2 Brc
Bracing
X -Loc
I
0/0/0 I
19/0/0
Grid
A -2
B -2
VPC File:CA0501693 -010E1 vpc
Maximum Reactions Summary Framing
X -Loc Grid Hrz left Load Hrz Right Load
-Hx) Case (Hx) Case
(k) (k)
0 9//0/0 I 2 -B I 0.44 122 I 0.41 1 21 I
19/0/0 72
foundation.
Section: 2
Exterior Column
0/0/0
2 -A
8x9
0.375
4 0.750
100' -0'
Hx Hz Vy
0.04 0 46
0.07 0.47
0.20 1.34
0.25 1.67
0.05 -0.70
0.09 1.28
-0.05 -0.70
-0.09 1.28
0.25 0.38
0.02 0.16
-0.25 -0.38
-0.02 -0.16
-0.01 -0.23 0.53
0.01 0.23 -0.53
-0.04 -0.88 2.00
-0.10 1 49
0.04 0.88 -2.00
0.04 -0.88 2.00
0.04 0.88 2.00
Hrz In
-Hz)
(k)
0.88
0.88
Exterior Column
19/0/0
2 -B
9x9
0.375
4 0 750
100' -0'
Hx Hz Vy
-0.04 0.50
-0.07 0.47
0.20 1.34
-0.25 1.67
0.18 -0.93
0.34 1 70
0.18 -0.93
0.34 1 70
0.22 -0.34
-0.02 0.16
-0.22 0.34
0.02 -0.16
0.01 -0.23 0.57
0.01 0.23 -0.57
0.04 -0.88 2.14
0.39 1.97
-0.04 0.88 2.14
0.04 -0.88 2.14
-0.04 0.88 2.14
Load
Case
63
63
Design
1 O -n
Frame Type:Rigid Frame
Vy
x
Hrz Out Load Uplift Load Vrt Down Load Mom cw Load Mom ccw Load
(Hz) Case (Vy)
(k) (k)
0.88 175 3.22 84 4
0.88 75 3.82 8
Case (Vy) Case -Mzz) Case (Mzz) Case
(k) (in -k) (in -k)
2.91 67
2.91 67
Description
Portal Brace is attached to column. Reactions ARE included with frame reactions.
Portal Brace is attached to column. Reactions ARE included with frame reactions.
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 17 of 43
VP BUILDINGS
VARCO PRUDEN
0/0/0 I 1 -A
19/0/0 I 1 -B
Bracing
X -Loc
0/0/0
19/0/0
Wall. 2, Frame at: 13/0/0
Frame ID:Rigid Frame
Values shown are resisting forces of the
Reactions Load Type at Frame Cross
Type
X -Loc
Gridl Grid2
Base Plate W x L (in.)
Base Plate Thickness (in.)
Anchor Bolt Qty/Diam. (in.)
Column Base ElPv
Load Type Desc.
D Frm
CG Frm
L Frm
S Frm
W 1> Frm
<W1 Frm
W2> Frm
<W2 Frm
E> Frm
EG+ Frm
<E Frm
EG- Frm
EB> Brc
<EB Brc
WBl> Brc
WP Frm
<WB 1 Brc
WB2> Brc
<WB2 Brc
Grid
A -1
B -1
-Hx) Case
(k)
0.17 I26I
0.44 22
VPC File:CA0501693 -010E1 vpc
foundation.
Section: 1
Exterior Column
0/0/0
1 -A
8x9
0.375
4 0.750
100' -0'
Hx Hz Vy
0.04 0.46
0.07 0.47
0.20 1.34
0.25 1.67
0.05 -0.70
-0.09 1.28
-0.05 -0.70
0.09 1.28
0.25 0.38
0.02 0.16
-0.25 -0.38
-0.02 -0.16
0.01 -0.23 -0.51
0.01 0.23 0.51
0.05 -0.88 1.90
-0.10 1 49
0.05 0.88 1.90
0.05 -0.88 1.90
-0.05 0.88 1.90
Maximum Reactions Summary Framing
X -Loc Grid Hrz left Load Hrz Right Load Hrz In
(Hx) Case -Hz)
(k) (k)
0.47 121 0.88
0.41 84 0.88
1 Hx
Exterior Column
19/0/0
1 -B
9x9
0.375
4 0.750
100' -0'
Hx Hz Vy
-0.04 0.50
-0.07 0.47
0.20 1.34
-0.25 1.67
0.18 -0.93
0.34 1 70
0 18 -0.93
0.34 1 70
0.22 -0.34
-0.02 0.16
0.22 0.34
0.02 -0 16
-0.01 -0.23 -0.60
0.01 0.23 0.60
-0.05 -0.88 2.24
0.39 1.97
0.05 0.88 2.24
-0.05 -0.88 2.24
0.05 0.88 2.24
Load
Case
1 63 63
Design
i c e _n'
Hrz Out Load
(Hz) Case
(k)
0.88 75
0.88 75
Frame Type:Rigid Frame
Vy
Uplift
Vy)
(k)
3 12
3.91
'Hx
Date: 11/7/2005
Time: 4.54.37 PM
Page: 18 of 43
Load Vrt Down Load Mom cw Load Mom ccw Load
Case (Vy) Case -Mzz) Case (Mzz) Case
(k) (in -k) (in -k)
1 72 I 2.97 179 I
I
1
Description
Portal Brace is attached to column. Reactions ARE included with frame reactions.
Portal Brace is attached to column. Reactions ARE included with frame reactions.
VPC Version .5.3a
VP BUILDINGS
VARCO- PRUDEN
Shape: Metal Canopy
Loads and Codes Shape: Metal Canopy
City Port Angeles County Clallam
Building Code: 2003 International Building Code
Building Use: Standard Occupancy Structure
Dead and Collateral Loads
Collateral Gravity 7.00 psf
Collateral Uplift: 0.00 psf
Wind Load
Wind Speed: 100.00 mph
Wind Exposure (Factor): D (1.030)
Parts Wind Exposure Factor 1.030
Wind Enclosure: Open
Wind Importance Factor 1.000
Topographic Factor. 1.0000
NOT Windbome Debris Region
Base Elevation: 0/0/0
Primary Zone Strip Width: 7/0/12
Parts Portions Zone Strip Width: 3/0/0
Basic Wind Pressure: 22.42 psf
Deflection Conditions
Frames are vertically supporting:Metal Roof Purlins and Panels
Frames are laterally supporting:Metal Wall Girts and Panels
Purlins are supporting:Metal Roof Panels
Girts are supporting:Metal Wall Panels
Deflection Limit Override H/180
Design Load Combinations
No. I Origin
1 System
2 System
3 System
4 System
5 System
6 System
7 System
8 System
VPC File:CA0501693 -010E1 vpc
Bracing
Factor
1.000 0.700 E>
1.000 0.700 <E
1.275 1.0 E>
1.275 1.0 <E
1.000 1.0 Wl>
1.000 1.0 <W1
1.000 1.0 W2>
1.000 1.0 <W2
Design
Bracing Summary Report
DESCRIPTION
Diagonal Roof Bracing is typically used by VP Buildings to resist lateral wind loads and seismic forces acting perpendicular to the rigid frames. This Diagonal 'X'
Bracing transmits the applied loads throughout the roof planes, delivering them to vertical bracing systems, and eventually into the foundation. Vertical Bracing
systems are typically diagonal 'X' Bracing similar to roof plane bracing, although may also utilize vertical diaphragms, moment- resisting frames, concentric braced
frames utilizing tension /compression members or tension only members, or other types of bracing systems, as permitted by Specifications.
ANALYSIS.
VP Buildings Diagonal Bracing is analyzed by the Stiffness Method for the applied wind loads and seismic loads acting on the structure. All diagonal members are
assumed to be considered to have pinned connections, while moment frames are typically assumed to be AISC Type 1 Construction (rigid frames). with pinned base
connections.
DESIGN
Diagonal Bracing is designed for axial forces, using the prevailing AISC Allowable forces acting on the Net Area of each member Moment frames are also designed
in accordance with AISC allowed working stresses.
MATERIAL.
Typical Rod Bracing used by VP Buildings is 65 ksi Structural Steel. Angle bracing is typically 50 ksi steel, tube bracing is 46 ksi, and moment frames are typically
designed and constructed from 50 ksi steel.
Application
State: Washington
Built Up: 89AISC
Cold Form: 01AISI
Roof Covering Second. Dead Load: 2.87 psf
Frame Weight (assumed for seismic):5.00 psf
Snow Load
Ground Snow Load: 39.68 psf
Design Snow (Sloped): 25.00 psf
Snow Exposure Category (Factor): 2 Partially
Exposed (0.90)
Snow Importance: 1.000
Thermal Category (Factor): Heated (1.00)
Ground Roof Conversion. 0.70
Snow Used in Seismic: 0.00
Seismic Snow Load: 0.00 psf
Unobstructed, Slippery Roof
Country. United States
Rainfall: 4.00 inches per hour
Allow Overstress:
Frm: 1.03, Sec: 1.03, Brc: 1.03
Live Load
Live Load: 20.00 psf Reducible
E>
<E
E>
<E
WI>
<WI
W2>
<W2
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 19 of 43
Seismic Load
Mapped Spectral Response Ss:124 10 %g
Mapped Spectral Response S1:50.90 %g
Seismic Hazard Use Group: Group 1
Seismic Importance: 1.000
Seismic Performance Design Category D
Framing Seismic Period: 0.2329
Bracing Seismic Period: 0.1457
Framing R- Factor 3.5000
Bracing R- Factor 3.5000
Soil Profile Type: Very dense soil and soft rock (C,
3)
Frame Redundancy Factor 1.0000
Brace Redundancy Factor 1 0000
Frame Seismic Factor (Cs): 0.2364
Brace Seismic Factor (Cs): 0.2364
Per Article 2.9 in the Builder Agreement, VP Buildings assumes that the Builder has called the local Building Official or Project Engineer to obtain all code and
loading information for this specific building site.
Description
VP BUILDINGS
VARCO- PR'UDEN
VPC Fi1e•CA0501693 -010E1 vpc
Design
/91
Diagonal Bracing Member Design Summary Roof A
Mem. Bracing Length Angle Design Seismic Stress Stress
No. I Shape (ft) I Axial (k) Factor I Factor Ratio 1.0000 0.000 1 2 I R R 0.375 0.375 I 19.871 57.8 0 00 1.00001 1.000 0.000 I
Governing
Load Case
1.0W2>
1.0W2>
Mem.I End I Diagonal Connection Design Informati
I Left SQW 5.0x5.0x3/8 to web and stiffener, design angle 56.1 deg, flange offset 4in. F 0
0.00 k -in, web /stiffener bending OK, web punching shear OK, flange/web weld OK, SQW
weld 3/16 fillet both sides passed
Right SQW 5.0x5.0x3/8 to web and stiffener design angle 56.1 deg, flange offset 4in. F 0
0.00 k -in, web /stiffener bending OK, web punching shear OK, flange/web weld OK, SQW
weld 3/16 fillet both sides passed
2 Left SQW 5.0x5.0x3/8 to web and stiffener, design angle 56.1 deg, flange offset 4in. F 0
0.00 k -in, web /stiffener bending OK, web punching shear OK, flange/web weld OK, SQW
weld 3/16 fillet both sides passed
Right SQW 5.0x5.0x3/8 to web and stiffener, design angle 56.1 deg, flange offset 4in. F 0
0.00 k -in, web /stiffener bending OK, web punching shear OK, flange/web weld OK, SQW
weld 3/16 fillet both sides passed
Design
Status
I passed I
passed
Date: 11/7/2005
Time: 4.54.37 PM
Page: 20 of 43
Comment
on
.0k, E factor 1.000, stress increase 1.000, Me
to web weld 3/16 fillet one side, SQW to stiffener
.0k, E factor 1.000, stress increase 1.000, Me
to web weld 3/16 fillet one side, SQW to stiffener
.0k, E factor 1.000, stress increase 1.000, Me
to web weld 3/16 fillet one side, SQW to stiffener
.0k, E factor 1.000, stress increase 1 000, Me
to web weld 3/16 fillet one side, SQW to stiffener
VPC Version .5.3a
VP BUILDINGS
YARCO PRUDEN
0
Knee Brace Connection Design
Design
1 1
Date: 11/7/2005
Time: 4.54.37 PM
Page: 21 of 43
The following apply to all portal braces unless otherwise specified.
Lateral supports for portal beam at kicker locations are required
Four 3/4 inch A325 bolts for portal beam to frame connection at each end.
All portal beam stiffeners are full depth 3/16 inch thick, both sides of the web with one side 3/16 inch weld to the web and flanges. These stiffeners are located
over the end supports and struts.
Struts are double angles with 3/8 inch separation, connected at both ends with two 3/4 inch A325 bolts, 3 inches apart. This is a slip critical connection with a
34.5 kip capacity including 1.33 stress increase).
Spacers between double angles are used automatically if the design length is greater than 24 inches. If the design length is 24 inches or less, angles are
designed as single.
Clips are 3/8 inch thick at the column web and bottom flange of a portal beam where angles are connected.
Portal Brace Member Design Summary. Sidewall 2, Bay 1
Knee Brace Design
Bracing Length Design I Seismic 1 Stress I Stress Load IDesign1 Left
Shape (ft) Axial (k) Factor Factor Ratio Case Status End Conn
Left KBD 2L 3.0x3.0x0.1875 -0.375 4.24 5.54 1.0000 1.00001 0.449 1.0W2> passed (2) 3/4 A325
Right KBD 2L 3.0x3.0x0.1875 -0.375 4.241 5.541 1.0000 1.0000 0.449 1.0 <W2 'passed I (2) 3/4 A325
VPC File:CA0501693 010E1 vpc VPC Version .5.3a
Right
End Conn
(2) 3/4 A325
(2) 3/4 A325
VP BUILDINGS
VARCO- PRUDEN
Portal Brace Beam Design
Design Size
Combined Ratio 0.286 1.03
Axial Force
Compressive Stress Ratio
Moment
Bending Stress Ratio
Shear
Shear Stress Ratio
Stress Increase Used
Load Case
Left Connection Design:
Right Connection Design:
VPC File:CA0501693 010E1 vpc
3P 6x3/16x0.1345x8.5
Design passed
3.91(k)
0.0507
70.46(in -k)
0.2357
1.96
0.1007
1.0000
1.0<W2
FS (4) 3/4 A325N, F 3.9 V 2.0, E factor
web yielding OK, haunch web crippling OK
FS (4) 3/4 A325N, F 3.9 V 2.0, E factor
web yielding OK, haunch web crippling OK
Design
VPC Version .5.3a
Kx =1.0
Ky 1.0
Lx 12.00(ft)
Ly 6.00(ft)
Lb 6.00(ft)
CMx= 1.0
CMy 1.0
Bending coefficient (Cb) 2.30
Column Connection: Flange Special
Left KBD Knee /Column. F 5.5k, E factor 1.000, stress increase 1.000, 3/8 x 4 S2 stiffener one side, S2 bending OK, 3/16 S2 to flange weld both
sides, 3/16 KC gusset weld passed
Knee /Beam: KBC standard connection (2) 3/4 in. A325SC, Bolt shear OK nassed
Right KBD Knee /Column. F 5.5, E factor 1.000, stress increase 1.000, 3/8 x 4 S2 stiffener one side, S2 bending OK, 3/16 S2 to flange weld both sides,
3/16 KC gusset weld passed
Knee /Beam: KBC standard connection (2) 3/4 in. A325SC, Bolt shear OK nassed
1 000 stress factor
passed
1.000 stress factor
passed
Date: 11/7/2005
Time: 4 54.37 PM
Page: 22 of 43
Governing Drift Case: 0.700 <W2
Horz. Deflection 1.32
H/1.32 121 60 Passed
1 000, bolt shear tension OK, local FS bending OK, haunch
1 000, bolt shear tension OK, local FS bending OK, haunch
VP BUILDINGS
VARCO- PRUDEN
Portal Brace Beam Design
Design Size
Combined Ratio 0.320 1.03
Axial Force
Y
A._n.
/I
Portal Brace Member Design Summary Sidewall 4, Bay 1
Knee Brace Design
Bracing I Length I Design Seismic I Stress I Stress Load IDesignl Left Right
Shape (ft) Axial (k) Factor Factor Ratio Case Status End Conn 1 End Conn
Left KBD 2L 3.0x3.0x0.1875 -0.375 4.24 6.19 1.0000 1.00001 0.502 1.0<W2 passed (2) 3/4 A325 (2) 3/4 A325
Right KBD 2L 3.0x3.0x0.1875 -0.375 I 4.241 6.191 1.0 1. 0.502 1.0W2> I passed I (2) 3/4 A325 I (2) 3/4 A325
Knee Brace Connection Design
Left KBD Knee /Column: F 6.2k, E factor 1.000, stress increase 1.000, 3/8 x 4 S2 stiffener one side, S2 bending OK, 3/16 S2 to flange weld both
sides, 3/16 KC gusset weld passed
Knee/Beam: KBC standard connection (2) 3/4 in. A325SC, Bolt shear OK nassed
Right KBD Knee /Column: F 6.2, E factor 1.000, stress increase 1.000, 3/8 x 4 S2 stiffener one side, S2 bending OK, 3/16 S2 to flange weld both sides,
3/16 KC gusset weld passed
Knee/Beam: KBC standard connection (2) 3/4 in. A325SC, Bolt shear OK nassed
3P 6x3/16x0.1345x8.5
Design passed
4.38(k)
Design
19'1T
Kx 1.0
Ky= 1.0
Lx 12.00(ft)
/i '_n'
/I
VPC File -010E1 vpc VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 23 of 43
VP BUILDINGS
VARCO- PRUDEN
Compressive Stress Ratio
Moment
Bending Stress Ratio
Shear
Shear Stress Ratio
Stress Increase Used
Load Case
Left Connection Design.
Right Connection Design:
VPC File:CA0501693 010E1 vpc
0.0567
78.83(in -k)
0.2637
2.19
0.1127
1.0000
1.0<W2
Design
FS (4) 3/4 A325N, F 4 4 V 2.2, E factor 1 000 stress factor
web yielding OK, haunch web crippling OK passed
FS (4) 3/4 A325N, F 4 4 V 2.2, E factor 1.000 stress factor
web yielding OK, haunch web crippling OK passed
Ly 6.00(ft)
Lb 6.00(ft)
CMx= 1.0
CMy 1.0
Bending coefficient (Cb) 2.30
Column Connection: Flange Special
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 24 of 43
Governing Drift Case: 0.700W2>
Horz. Deflection 1.34
H/1.34 134 60 Passed
1 000, bolt shear tension OK, local FS bending OK, haunch
1 000, bolt shear tension OK, local FS bending OK, haunch
VP BUILDINGS
VARCO PRUDEN
5LI
LI 7-21) a 9 02_.
r 2
7
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/y a 1,3 y k
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1., Z 30,
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Date
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Reviewed by
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VP BUILDINGS
VAACO- PAUDEN
Secondary Summary Report
Loads and Codes Shape: Metal Canopy
City Port Angeles County
Building Code: 2003 International Building Code
Building Use: Staidard Occupancy Structure
Dead and Collateral Loads
Collateral Gravity psf
Collateral Uplift: 0.00 psf
Wind Load
Wind Speed: 100.00 mph
Wind Exposure (Factor): D (1.030)
Parts Wind Exposure Factor 1.030
Wind Enclosure: Open
Wind Importance Factor 1.000
Topographic Factor 1.0000
NOT Windbome Debris Region
Base Elevation: 0/0/0
Primary Zone Strip Width: 7/0/12
Parts Portions Zone Strip Width: 3/0/0
Basic Wind Pressure: 22.42 psf
Per Article 2.9 in the Builder Agreement, VP Buildings assumes that the Builder has called the local Building Official or Project Engineer to obtain all code and
loading information for this specific building site.
Design Load Combinations
binations
No. Origin
1 System
2 Sy
3 System
4 System
5 Sy
6 System
7 System
8 System
9 System
10 System
11 System
12 System
13 System
14 System
Purlin
Factor
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.275
1.275
1.275
1.275
Design Load Combinations Girt
I No. I Origin I Factor I
1 System 1.000 1.0 Wl>
2 System 1.000 1.0 <W2
3 System 1.000 1.0 WP
Deflection Load Combinations Purlin
I No. I Origin I Factor I Deflection
1 1 I System 1 1.000 I 150 11.0 S
Deflection Load C ombinations Girt
I No. Origin 1 Factor 1 Deflection
1 System 1.000 180
2 System 1.000 180
3 System 1.000 180
VPC File 010E1 vpc
Clallam
Roof Covering Second. Dead Load: 2.87 psf
Frame Weight (assumed for seismic):5.00 psf
1
Snow Load
Ground Snow Load: 39.68 psf
Design Snow (Sloped): 25.00 psf
Snow Exposure Category (Factor): 2 Partially
Exposed (0.90)
Snow Importance: 1.000
Thermal Category (Factor): Heated (1.00)
Ground Roof Conversion: 0.70
Snow Used in Seismic: 0.00
Seismic Snow Load: 0.00 psf
Unobstructed, Slippery Roof
1.0 D 1.0 CG 1.0 S
1.OD +1.0Wl>
1.0 D+ 1.0 <W2
1.OD +1.OWP
0.600D +1.0WI>
0.600 D 1.0 <W2
0.600 D +1.OWP
1.0 D 1.0 CG 0.750 S 0.750 WI>
1.0 D 1.0 CG 0.750 S 0.750 <W2
1.0 D 1.0 CG 0.750 S 0.750 WP
1.200 D 1.200 CG 0.200 S 1.0 E> 0.700 EG+
1.200 D 1.200 CG 0.200 S 1.0 <E 0.700 EG+
0.900 D 0.900 CG 1.0 E> 0.700 EG-
0.900 D 0.900 CG 1.0 <E 0 700 EG-
1
0.700 WI>
0700 <W2
0.700 WP
Design
Application
State: Washington
Built Up: 89AISC
Cold Form: OIAISI
Application
Application
Application
Country United States
Rainfall: 4.00 inches per hour
Allow Overstress:
Frm: 1.03, Sec: 1.03, Brc: 1 03
Live Load
Live Load: 20.00 psf Reducible
Seismic Load
Mapped Spectral Response Ss:124 10 %g
Mapped Spectral Response SI:50.90 %g
Seismic Hazard Use Group: Group 1
Seismic Importance: 1.000
Seismic Performance Design Category D
Framing Seismic Period: 0.2329
Bracing Seismic Period: 0.1457
Framing R- Factor 3.5000
Bracing R- Factor 3.5000
Soil Profile Type: Very dense soil and soft rock (C, 3)
Frame Redundancy Factor
Brace Redundancy Factor1.0000
Frame Seismic Factor (Cs): 0.2364
Brace Seismic Factor (Cs): 0.2364
Wl>
<W2
WP
1
IS
1
Wl>
<W2
WP
VPC Version .5.3a
D +CG +S
D +WI>
D <W2
D WP
D +Wl>
D <W2
D WP
D +CG +S +WI>
D +CG +S +<W2
D +CG +S +WP
D +CG +S +E> +EG+
D +CG +S <E +EG+
D +CG+F> +EG-
D+CG+<E+EG-
Date: 11/7/2005
Time: 4.54.37 PM
Page: 25 of 43
Description
Description
Description
Description
VP BUILDINGS
MARCO -PRU DEN
Roof: A
Des Ler
Id (ft;
1 1,1 1 14.001
2, 14.00
Y
Maximum secondary Designs for Shape Metal Canopy on
Detail 1
Design Lap
Status (in.) Bnd
Description
Side A
8.50x0.082 Z Sim 1 Yes 1 0 1 0.85 1 0.00 1 0.85 1 0.00 91
8.50x0.059 EZ Sim Yes 0 0.01 0 15 0.29 0.43 9
Maximum Secondary Deflections for Shape Metal Canopy on Side A
VPC File:CA0501693 -010E1 vpc
Design
Exterior
Ld Lap
Shr Cmb Wcp Cs (in.)
1 Interior
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 26 of 43
t Exterior 1
L ap
Bnd I Shr Cmb Wcp Cs d B d S; Cmb Wcp Cs Ld L (in.)
VP BUILDINGS
VARCO-PRUDEN
Design
Design Id I Segment I Deflection(in.) I Ratio I Location(ft) I Load Case I
1 1 2 1 I -0.07 I I 7.00 I 1
Description
S
S
Date: 11/7/2005
Time: 4.54.37 PM
Page: 27 of 43
Purlin Anchorage Forces
Shape I Force(k) I Resistance(k) I Numb. Purlins I Roof Angle (Pitch) I
A I 0.63 I 2.27 I 7 14 764 1.000:12) I
VPC Fi1e•CA0501693 -010E1 vpc VPC Version .5.3a
VP BUILDINGS
VARCO- PRUDEN
Framing Summary Report
Loads and Codes Shape: Metal Canopy
City Port Angeles County Clallam
Building Code: 2003 International Building Code
Building Use: Standard Occupancy Structure
Dead and Collateral Loads
Collateral Gravity7.00 psf
Collateral Uplift: 0.00 psf
Wind Load
Wind Speed. 100.00 mph
Wind Exposure (Factor): D (1.030)
Parts Wind Exposure Factor 1.030
Wind Enclosure: Open
Wind Importance Factor 1.000
Topographic Factor 1.0000
NOT Windbome Debris Region
Base Elevation: 0/0/0
Primary Zone Strip Width: 7/0/12
Parts Portions Zone Strip Width: 3/0/0
Basic Wind Pressure: 22.42 psf
Deflection Conditions
Frames are vertically supporting:Metal Roof Purlins and Panels
Frames are laterally supporting:Metal Wall Girts and Panels
Purlins are supporting:Metal Roof Panels
Girts are supporting:Metal Wall Panels
Deflection Limit Override H/180
VPC File:CA0501693 -010E1 vpc
Design
State: Washington
Built Up: 89AISC
Cold Form: 01AISI
Roof Covering Second. Dead Load: 2.87 psf
Frame Weight (assumed for seismic):5.00 psf
Snow Load
Ground Snow Load: 39.68 psf
Design Snow (Sloped): 25.00 psf
Snow Exposure Category (Factor): 2 Partially
Exposed (0.90)
Snow Importance: 1.000
Thermal Category (Factor): Heated (1.00)
Ground Roof Conversion: 0.70
Snow Used in Seismic: 0.00
Seismic Snow Load: 0.00 psf
Unobstructed, Slippery Roof
Live Load
Live Load: 20.00 psf Reducible
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 28 of 43
Country United States
Rainfall: 4.00 inches per hour
Allow Overstress:
Frm: 1.03, Sec: 1.03, Brc: 1.03
Seismic Load
Mapped Spectral Response Ss:124 10 %g
Mapped Spectral Response S 1:50.90 %g
Seismic Hazard Use Group: Group 1
Seismic Importance: 1.000
Seismic Performance Design Category D
Framing Seismic Period: 0.2329
Bracing Seismic Period: 0.1457
Framing R-Factor 3.5000
Bracing R- Factor 3.5000
Soil Profile Type: Very dense soil and soft rock (C,
3)
Frame Redundancy Factor 1.0000
Brace Redundancy Factor1.0000
Frame Seismic Factor (Cs): 0.2364
Brace Seismic Factor (Cs): 0.2364
Per Article 2.9 in the Builder Agreement, VP Buildings assumes that the Builder has called the local Building Official or Project Engineer to obtain all code and
loading information for this specific building site.
VP BUILDINGS
VARCO.PRUDEN
Wall. 2, Frame at: 1/0/0
Frame Cross Section. 2
Dimension Key
1 8 1/2'
2 3'- 611/16'
3 2' -8 3/4'
4 3 3/8'
Y
x
Frame Clearances
Horiz. Clearance between members 1(CX001) and 4(CX002): 16' 3'
Vert. Clearance at member 1(CX00I): 12'-0'
Vert. Clearance at member 4(CX002): 13'-4 1/4'
Finished Floor Elevation 100' -0' (Unless Noted Otherwise)
Design
5(a>2' �I
IIllHI� f31
19' -0 11116" 1 000
u.
u.
r21
1
VPC File:CA0501693 -010E1 vpc VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 29 of 43
VP BUILDINGS
VARCO PRUDEN
Frame Location Design Parameters:
Location I Avg. Bay Space I
1/0/0 I 7/0/0 Rigid Frame
DESCRIPTION
VP Buildings RIGID FRAMES (Type 'RF are solid -web framing systems consisting of tapered or uniform rafters rigidly connected to tapered or uniform
depth columns. The frame provides a clear span (no interior columns) and is designed to support the applied loads as specified. (AISC Type 1 Construction)
ANALYSIS.
The boundary conditions established for RIGID FRAMES assume the rafter beam is a fully continuous member spanning from building eave to building eave,
with exterior columns rigidly attached (moment- resisting connection). The Exterior Columns are typically pinned connected (free to rotate) at their base
connection to the foundation.
DESIGN
RIGID FRAMES are designed in accordance with the AISC 'Specification for Structural Steel Buildings' 9th Edition.
MATERIAL.
Structural steel plate, bar, and/or sheet intended for use in RIGID FRAME bolted and/or welded constructions typically will be of material based on the
requirements of ASTM A529 A572, A570, or A607 Grade 50.
Design Load Combinations Framing
No. Origin Factor
1 System 1.000
2 System 1.000
3 System 1.000
4 System 1.000
5 System 1.000
6 System 1.000
7 System 1.000
8 System 1.000
9 System 1.000
10 System 1.000
11 System 1.000
12 System 1.000
13 System 1.000
14 System 1.000
15 System 1.000
16 System 1.000
17 System 1.000
18 System 1.000
19 System 1.000
20 System 1.000
21 System 1.000
22 System 1.000
23 System 1.000
24 System 1.000
25 System 1.275
26 System 1.275
27 System 1.275
28 System 1.275
29 Special 1.275
30 Special 1.275
31 Special 1.275
32 Special 1.275
33 AISC Special 1 700
34 AISC Special 1 700
35 AISC Special 1 700
36 AISC Special 1 700
37 System Derived 1.000
38 System Derived 1.000
39 System Derived 1.000
40 System Derived 1.000
41 System Derived 1.000
42 System Derived 1.000
43 System Derived 1.275
44 System Derived 1.275
45 System Derived 1.275
46 System Derived 1.275
47 Special 1.275
48 Special 1.275
49 System Derived 1.000
VPC File:CA0501693 01OE1 vpc
Description
Design
Application
I Angle I Group I Trib. Override I
1 90.0000 I I I
1.0 D 1.0 CG 1.0 L
1.0D +1.0CG +1.0S
1.OD +1.0WI>
1.OD +1.0 <Wl
1.OD +1.0W2>
1.0 D 1.0 <W2
1.0 D 1.0 CG 0.750 L +0.750 Wl>
1.0D +1.0CG +0.750L +0750 <W1
1.0 D 1.0 CG 0.750 L 0.750 W2>
1.0 D+ 1.0 CG 0.750 L 0.750 <W2
1.0 D 1.0 CG 0.750 S 0.750 WI>
1.0 D 1.0 CG 0.750 S 0.750 <W1
1.0 D 1.0 CG 0.750 S 0 750 W2>
1.0 D 1.0 CG 0.750 S 0.750 <W2
0.600 D 1.0 WI>
0.600 D 1.0 <W1
0.600 D 1.0 W2>
0.600 D 1.0 <W2
1.0 D 1.0 CG 0.700 E> 0.700 EG+
1.0 D 1.0 CG 0.700 <E 0.700 EG+
1. 0D +1.0CG +0.750L +0.750E> +0.750EG-f
1.0 D 1.0 CG 0.750 L 0.750 <E 0.750 EG+
0.600 D 0.600 CG 0.700 E> 0.700 EG-
0.600 D 0.600 CG 0.700 <E 0.700 EG-
0.900 D 0.900 CG 1.0 E> 0.700 EG-
0.900 D 0.900 CG 1.0 <E 0.700 EG-
1.200 D 1.200 CG 0.200 S 1.0 E> 0.700 EG+
1.200 D 1.200 CG 0.200 S 1.0 <E 0.700 EG+
0.900 D 0.900 CG 2.500 F> 1.0 EG-
0.900 D 0.900 CG 2.500 <E 1.0 EG-
1.200 D 1.200 CG 0.200 S 2.500 E> 1 0 EG+
1.200 D 1.200 CG 0.200 S 2.500 <E 1.0 EG+
0.900 D 0.900 CG
0.900 D 0.900 CG
1.200 D 1.200 CG 0.200 S
1.200 D 1.200 CG 0.200 S
1.0 D 1.0 CG 0.210 B> 0.700 EG+ +0.700 EB>
1.0 D 1.0 CG 0.210 <E 0.700 EG+ 0.700 EB>
1.0 D 1.0 CG 0.750 L 0.225 E> 0.750 EG+ 0.750 EB>
1.0 D 1.0 CG 0.750 L 0.225 <E 0.750 EG+ 0 750 EB>
0.600 D 0.600 CG 0.210 E> 0.700 EG- 0.700 EB>
0.600 D 0.600 CG 0.210 <E 0.700 EG- 0.700 EB>
0.900 D 0.900 CG 0.300 E> 0.700 EG- 1.0 EB>
0.900 D 0.900 CG 0.300 <E 0.700 EG- 1.0 EB>
1.200 D 1.200 CG 0.200 S 0.300 E> 0.700 EG+ 1.0 EB>
1.200 D 1.200 CG 0.200 S 0.300 <E 0.700 EGl- 1.0 EB>
0.900 D 0.900 CG 2.500 EB> 1.0 EG-
1.200 D 1.200 CG 0.200 S 2.500 EB> 1.0 EG+
1.0 D 1.0 CG 0.210 E> 0.700 EG+ +0.700 <EB
VPC Version .5.3a
Date: 11/7/2005
Time: 4 54.37 PM
Page: 30 of 43
Design Status
Automatic Design
Description
D +CG +L
D +CG +S
D +W1>
D +<WI
D W2>
D <W2
D +CG +L +Wl>
D +CG+L <W1
D +CG +L +W2>
D +CG +L <W2
D +CG +S +WI>
D +CG +S <WI
D +CG +S +W2>
D +CG +S <W2
D +Wl>
D <Wl
D W2>
D <W2
D CG E> EG+
D CG <E EG+
D +CG +L +E> +EG+
D+ CG +L +<E EGA-
D +CG +E> +EG-
D+CG+<E+EG-
D+CO+E>+EG-
D+CO+<E+EG-
D +CO +S+F> +EG+
D +CO +S <E +EG+
D +CO +E>+EG-
D+CO+<E+EG-
D +S +F> +EG+
D +CG +S <E +EG+
D CG
D CG
D CG S
D CG S
D +CG +F>+ EG+ +EB>
D +CO <E EG+ +EB>
D +CG+L +E>+EG+ +EB>
D+CGI-L+<E +EG++EB>
D +CG+E> +EG +EB>
D CO <E EG- EB>
D CG E> EG- EB>
D CG <E EG- EB>
D+CG+S +E>+EG++EB>
D+CG+S+<E +EG++EB>
D CO EB> EG-
D CO S EB> EG+
D +CO +B> +EG+ <EB
VP BUILDINGS
VARCO.PRUDEN
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
Special
Special
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
System Derived
Frame Member Sizes
Mem. I Fig Width I Flg Thk I Web Thk I
No. (in.) (in.) (in.)
1 7.00 0.2500 0.1345
2 5.00 0.1345 0.1345
3 5.00 0.1345 0.1345
4 8.00 0.2500 0.1345
VPC File:CA0501693 -01OE1 vpc
1.000 1.0 D 1.0 CG 0.210 <E 0 700 EG+ 0.700 <EB
1.000 1. OD +1.00G +0.750L +0.225E> +0750 EG+ +0.750 <EB
1.000 1.0 D 1.0 CG 0.750 L 0.225 <E 0.750 EG+ 0.750 <EB
1.000 0.600 D 0.600 CG 0.210 F> 0.700 EG- 0 700 <EB
1.000 0.600 D 0.600 CG 0.210 <E 0 700 EG- 0.700 <EB
1.275 0.900 D 0.900 CG 0.300 E> 0.700 EG- 1 0 <EB
1.275 0.900 D 0.900 CG 0.300 <E 0.700 EG- 1.0 <EB
1.275 1.200 D 1.200 CG 0.200 S 0.300 F> 0.700 EG+ 1.0 <EB
1.275 1.200 D 1.200 CG 0.200 S 0.300 <E 0.700 EG+ 1.0 <EB
1.275 0.900 D 0.900 CG 2.500 <EB 1.0 EG-
1.275 1.200 D I.200 CG 0.200 S 2.500 <EB 1.0 EG+
1.000 1.0 D 0.750 W I> 0.750 WB1>
1.000 1.0 D 0.750 <W1 0.750 WB1>
1.000 1.OD +I.OWP +1.OWB1>
1.000 1.0 D+ 1.0 CG 0.750 L +0.563 W1> +0.563 WB1>
1.000 1.0 D+ 1.0 CG 0.750 L+ 0.563 <W1 0.563 WB1>
1.000 1.0 D+ 1.0 CG 0.750 L+ 0 750 WP 0.750 WB1>
1.000 1.0 D+ 1.00G +0.750S +0.563 Wl> +0.563 WB1>
1.000 1.0 D 1.0 CG 0.750 S 0.563 <W l 0.563 WB1>
1.000 1.0 D+ 1.0 CG+ 0.750 S 0.750 WP 0 750 WB1>
1.000 0.600 D 0.750 W 1> 0.750 WB1>
1.000 0.600 D 0.750 <W 1 0 750 WB1>
1.000 0.600 D 1.0 WP 1.0 WB1>
1.000 1.0 D 0.750 W 1> 0.750 <WB1
1.000 1.O D 0.750 <W1 0.750 <WB I
1.000 1.OD +1.0WP +1.0 <WB1
1.000 1.0 D 1.0 CG 0.750 L 0.563 WI> 0.563 <WB1
1.000 1.0 D+ 1.0 CG 0.750 L 0.563 <W1 0.563 <WB1
1.000 1.0 D 1.0 CG 0.750 L 0.750 WP 0.750 <WB1
1.000 1.0 D+ 1.0 CG +0.750 S +0.563 W1> +0.563 <WB1
1.000 1.O D 1.O CG 0.750 S 0.563 <W1 0.563 <WB1
1.000 1.0 D+ 1.O CG 0.750 S+ 0 750 WP 0.750 <WB 1
1.000 0.600 D 0.750 W l> 0.750 <WB l
1.000 0.600 D 0.750 <W1 0.750 <WB1
1.000 0.600 D 1.0 WP +1.0 <WB1
1.000 1.0 D 0.750 W2> 0.750 WB2>
1.000 1.0 D 0.750 <W2 0.750 WB2>
1.000 1.0 D 1.0 WP 1.0 WB2>
1.000 1.0 D 1.0 CG 0.750 L 0.563 W2> 0.563 WB2>
1.000 1.0 D 1.0 CG 0.750 L 0.563 <W2 0.563 WB2>
1.000 1.0 D 1.0 CG 0.750 L 0.750 WP 0.750 WB2>
1.000 1.0 D 1.0 CG 0.750 S 0.563 W2> 0.563 WB2>
1.000 1.0 D 1.0 CG 0.750 S 0.563 <W2 0.563 WB2>
1.000 1.0 D 1.0 CG 0.750 S 0.750 WP 0.750 WB2>
1.000 0.600 D 0.750 W2> 0.750 WB2>
1.000 0.600 D 0.750 <W2 0.750 WB2>
1.000 0.600 D 1.0 WP 1.0 WB2>
1.000 1.0 D 0 750 W2> 0.750 <WB2
1.000 1.0 D 0.750 <W2 0.750 <WB2
1.000 1.0D +1.0 WP +1.0 <WB2
1.000 1.0 D 1.0 CG 0.750 L 0.563 W2> 0.563 <WB2
1.000 1.0 D 1.0 CG 0.750 L 0.563 <W2 0.563 <WB2
1.000 1.O D 1.O CG 0.750 L 0.750 WP 0.750 <WB2
1.000 1.0 D 1.0 CG 0.750 S 0.563 W2> 0.563 <WB2
1.000 1.0 D 1.0 CG 0.750 S 0.563 <W2 0.563 <WB2
1.000 1.0 D 1.0 CG 0.750 S 0.750 WP 0.750 <WB2
1.000 D.600 D 0.750 W2> 0.750 <WB2
1.000 0.600 D 0.750 <W2 0.750 <WB2
1.000 0.600D +1.0 WP +1.0 <WB2
Depth]
(in.)
8.00
8.81
8.81
8.00
Design
Depth2 Length Weight Flg Fy Web Fy
(in.) I (ft) I (p) I (ksi) I (ksi)
8.00 12.68 206.4 50.00 50.00
8.81 8.82 69.5 50.00 50.00
8.81 8.82 68.9 50.00 50.00
8.00 1415 253.6 50.00 50.00
Total Frame Weight 598.4 (p) (Includes all plates)
Splice
Jt. l
BP
KN
SS
BP
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 31 of 43
D +CG +<E EG+ <EB
D +CG+L +E> +EGIi <EB
D+CG+L+<E +EG+ <EB
D CG E> EG- <EB
D CG <E EG- <EB
D +CG +F> EG- <EB
D +CG +<E +EG +<EB
D+CG+S+E>+EG I I <EB
D +CG+S+<E +EGII
D +CG <EB +EG-
D +CG +S <EB +EG+
D +Wl +WB1>
D <W1 +WBI>
D +WP +WB1>
D +CG +L +WI +WB1>
D +CG +L <W1 +WB1>
D CG+ L+ WP WB1>
D +CG +S +W1 +WB1>
D +CG +S +<W1 +WBI>
D +CG +S +WP +WB1>
D +WI +WB1>
D <W1 +WBI>
D +WP +WBI>
D +W1 <WB1
D <W1 +<WBI
D +WP +<WBI
D +CG +L +WI <WB1
D +CG +L+ <W1 +<WB1
D +CG +L +WP+ <WB1
D +CG +S +W1 <WBI
D +CG +S +<W1 +<WB1
D +CG +S+ WP+ <WB1
D +WI <WB1
D <W1 +<WB1
D WP <WB1
D W2> WB2>
D <W2 WB2>
D +WP +WB2>
D CG L W2> WB2>
D +CG +L +<W2 +WB2>
D +CG +L +WP +WB2>
D CG S W2> WB2>
D +CG +S +<W2 +WB2>
D CG S WP WB2>
D +W2 +WB2>
D <W2 WB2>
D WP WB2>
D W2> <WB2
p +<W2 <WB2
D +WP <WB2
D CO L W2> <WB2
D +CG +L <W2 <WB2
D +CG +L +WP <WB2
D +CG +S +W2> <WB2
D CO S <W2 <WB2
D CO S WP <WB2
D +W2 <WB2
D <W2 <WB2
D +WP <WB2
Codes I Shape
Jt.2
KN 3P
SS 3P
KN 3P
KN 3P
VP BUILDINGS
VARCO- PRUDEN
Design
Boundary Condition Summary
J Member X -Loc I Y -Loc I Supp. X I Supp. Y J Moment J Displacement X(in.) I Displacement Y(in.) 1 Displacement ZZ(rad.) J
1 0 /0 /0 I 0 /0 /0 I Yes I Yes I No 0 /0 /0 0 /0 /0 0.0000
4 19/0/0 0 /0 /0 Yes Yes No I 0 /0 /0 0/0/0 0.0000
Frame Reactions Load Cases at Frame Cross Section: 2
X -Loc 0/0/0 19/0/0
Grid] Grid2 2 -A 2 -B
Ld Description Hx Hz Vy Hx Hz Vy
Cs (application factor not shown) (k) (k) (k) (k) (k) (k)
1 D +CG +L 0.31 2.27 -0.31 2.31
2 D CG S 0.36 2.60 -0.36 2.65
3 D W 1> -0.01 -0.24 0.14 -0.42
4 D <W 1 -0.05 -0.82 0.30 1 19
5 D W2> -0.01 -0.24 0.14 -0.42
6 D <W2 -0.05 -0.82 0.30 1 19
7 D+CG +L +W1> 0.22 141 -0.12 1.28
8 D +CG +L +<W1 0.19 0.97 -0.01 0.70
9 D +CG +L +W2> 0.22 141 -0.12 1.28
10 D +CG +L <W2 0.19 0.97 -0.01 0.70
11 D +CG +S +W1> 0.26 1.66 -0.16 1.53
12 D CG S <W 1 0.23 1.22 -0.04 0.95
13 D CG S W2> 0.26 1.66 -0.16 1.53
14 D +CG +S +<W2 0.23 1.22 -0.04 0.95
15 D W 1> -0.02 -0.42 0.16 -0.62
16 D <W I -0.06 1.01 0.31 1.39
17 D W2> -0.02 -0.42 0 16 -0.62
18 D <W2 -0.06 1.01 0.31 1.39
19 D +CG +E> +EG+ 0.30 1.31 0.02 0.85
20 D CG <E EG+ -0.05 0.78 -0.28 1.33
21 D CG L E> EG+ 0.47 2.34 -0.11 1.84
22 D CG L <E EG+ 0.09 1 77 -0.44 2.36
23 D+CG+E>+EG- 0.23 0.71 0.10 0.23
24 D CG <E EG- -0.13 0 17 -0.20 0.71
25 D+CG+E>+EG- 0.34 1 10 0.13 0.42
26 D CG <E EG- -0.17 0.34 -0.30 1 10
27 D CG S E> EG+ 0.45 1.95 0.02 1.27
28 D CG S <E EG+ -0.05 1 18 -0.42 1.96
37 D +CG +E> +EG+ +EB> 0.17 -0.16 1.50 -0.07 -0.16 142
38 D CG <E EG+ EB> 0.07 -0.16 1.34 -0.16 -0.16 1.56
39 D+CG+L+E>+EG- I-+EB> 0.32 -0.18 2.54 -0.22 -0.18 2.45
40 D+CG+L+<E+EG++EB> 0.21 -018 2.37 -0.32 -0.18 2.61
41 D+CG +E> +EG +EB> 0.09 -0.16 0.89 0.00 -0.16 0.80
42 D CG <E EG- EB> -0.01 -0.16 0.73 -0.09 -0.16 0.94
43 D +CG +E> +EG +EB> 0.15 -0.23 1.37 -0.01 -0.23 1.23
44 D CG <E EG- EB> -0.01 -0.23 1 14 -0.14 -0.23 1 43
45 D+CG+S +E>+EG++EB> 0.26 -0.23 2.21 -0.12 -0.23 2.09
46 D+CG+S+<E +EG++EB> 0.11 -0.23 1.98 -0.25 -0.23 2.29
49 D CG E> EG+ <EB 0.19 0.16 0.75 -0.09 0.16 0.62
50 D CO <E EG+ <EB 0.08 0.16 0.59 -0.18 0.16 0.76
51 D+CG+L +E>+EG I I <EB 0.34 0.18 1 74 -0.24 0.18 1.59
52 D+CG+L+<E +EG I I <EB 0.23 0.18 1.57 -0.33 0.18 175
53 D +CG +E> +EG +<EB 0.11 0.16 0.15 -0.01 0.16 -0.00
54 D CG <E EG- <EB 0.00 0.16 -0.01 -0.10 0.16 0.14
55 D CG E> EG- <EB 0 17 0.23 0.30 -0.03 0.23 0.09
56 D CG <E EG- <EB 0.02 0.23 0.07 -0.16 0.23 0.29
57 D+CG+S +E>+EG I I <EB 0.29 0.23 1 14 -0.15 0.23 0.94
58 D+CG+S+<E +EG I I <EB 0.13 0.23 0.92 -0.28 0.23 1 15
61 D W l> WB1> -0.03 -0.66 1 44 0.13 -0.66 1 42
62 D <W1 WBl> -0.06 -0.66 1.00 0.24 -0.66 0.84
63 D +WP +WB1> -0.11 -0.88 0.97 0.39 -0.88 0.68
64 D CG L WI> WB1> 0.21 -0.50 2.66 -0.13 -0.50 2.66
65 D CG L <W1 WB I> 0.18 -0.50 2.34 -0.04 -0.50 2.23
66 D +CG +L +WP +WB1> 0.15 -0.66 2.31 0.07 -0.66 2.10
67 D +CG +S +W1 +WBI> 0.24 -0.50 2.91 -0.17 -0.50 2.91
68 D CG S <W1 WB1> 0.22 -0.50 2.59 -0.08 -0.50 2.48
69 D CG S WP WBl> 0.19 -0.66 2.56 0.03 -0.66 2.36
70 D +W1 +WB1> -0.05 -0.66 1.25 0.15 -0.66 1.22
VPC File:CA0501693 -010E1 vpc VPC Version 5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 32 of 43
VP BUILDINGS
VARCO. PRUDEN
Design
71 D +<W1 +WB1> -0.07 -0.66 0.82 0.26 -0.66 0.64
72 D +WP +WB1> -0.12 -0.88 0.79 041 -0.88 0.47
73 D +WI <WB1 0.04 0.66 1.57 0.06 0.66 1.80
74 D <W1 +<WB1 0.01 0.66 2.00 0.18 0.66 2.38
75 D WP <WB1 -0.02 0.88 3.03 0.30 0.88 3.61
76 D +CG +L +W1 <WB1 0.26 0.50 0.41 -0.18 0.50 0.25
77 D CG L+ <W l <WB1 0.23 0.50 0.08 -0.09 0.50 -0.18
78 D CG L WP <WB I 0.22 0.66 -0.69 0.00 0.66 1 11
79 D +CG +S +WI +<WBI 0.29 0.50 0.66 -0.22 0.50 0.50
80 D CG S <W1 <WB1 0.27 0.50 0.33 -0.13 0.50 0.07
81 D CG S WP <WB1 0.25 0.66 -0.44 -0.04 0.66 -0.86
82 D W l> <WB1 0.02 0.66 1 75 0.08 0.66 2.00
83 D <W1 <WB1 -0.01 0.66 2.19 0.19 0.66 -2.58
84 D WP <WB1 -0.03 0.88 3.22 0.32 0.88 3.82
85 D W2> WB2> -0.03 -0.66 1 44 0.13 -0.66 1 42
86 D <W2 WB2> -0.06 -0.66 1.00 0.24 -0.66 0.84
87 D WP WB2> -0.11 -0.88 0.97 0.39 -0.88 0.68
88 D +CG +L +W2 +WB2> 0.21 -0.50 2.66 -0.13 -0.50 2.66
89 D CG L <W2 WB2> 0.18 -0.50 2.34 -0.04 -0.50 2.23
90 D CG L WP WB2> 0.15 -0.66 2.31 0.07 -0.66 2.10
91 D CG S W2> WB2> 0.24 -0.50 2.91 -0.17 -0.50 2.91
92 D Co S <W2 WB2> 0.22 -0.50 2.59 -0.08 -0.50 2.48
93 D CG S WP WB2> 0.19 -0.66 2.56 0.03 -0.66 2.36
94 D W2> WB2> -0.05 -0.66 1.25 0.15 -0.66 1.22
95 D <W2 WB2> -0.07 -0.66 0.82 0.26 -0.66 0.64
96 D WP WB2> -0.12 -0.88 0.79 0.41 -0.88 0.47
97 D W2> <WB2 0.04 0.66 1.57 0.06 0.66 1.80
98 D <W2 <WB2 0.01 0.66 2.00 0.18 0.66 2.38
99 D WP <WB2 -0.02 0.88 3.03 0.30 0.88 3.61
100 D CG L W2> <WB2 0.26 0.50 0.41 -0.18 0.50 0.25
101 D CG L <W2 <WB2 0.23 0.50 0.08 -0.09 0.50 -0.18
102 D CG L WP <WB2 0.22 0.66 -0.69 0.00 0.66 1 11
103 D CG S W2> <WB2 0.29 0.50 0.66 -0.22 0.50 0.50
104 D CG +'S <W2 <WB2 0.27 0.50 0.33 -0.13 0.50 0.07
105 D CG S WP <WB2 0.25 0.66 -0.44 -0.04 0.66 -0.86
106 D W2> <WB2 0.02 0.66 1 75 0.08 0.66 2.00
107 D <W2 <WB2 -0.01 0.66 -2.19 0.19 0.66 2.58
108 D WP <WB2 -0.03 0.88 3.22 0.32 0.88 3.82
Date: 11/7/2005
Time: 4.54.37 PM
Page: 33 of 43
Maximum Reactions Summary Framing
X -Loc Grid Hrz left Load Hrz Right Load Hrz In Load Hrz Out Load Uplift Load Vrt Down Load Mom cw Load Mom ccw Load
-Hx) Case (Hx) Case -Hz) Case (Hz) Case (Vy) Case (Vy) Case -Mzz) Case (Mzz) Case
(k) (k) (k) (k) (k) (k) (in-k) (in-k)
1 9 0/0 I 2 -B I 0.44 122 I O 0 47 41 172 I 0.88 163 I 0.88 175 I 3.82 184 I 2.91 I 67
Sum of Forces with Reactions Check Framing
Horizontal Ver ical
Load Type Load Reaction Load Reaction
(k) (k) (k) (k)
D 0.00 0.00 0.98 0.96
CG 0.00 0.00 0.94 0.94
L 0.00 0.00 2.68 2.68
S 0.00 0.00 3.34 3.34
Wl> 0.14 0.14 1.63 1.63
<W1 0.25 0.25 2.98 2.98
W2> 0.14 014 1.63 1.63
<W2 0.25 0.25 2.98 2.98
F> 0.47 0.47 0.00 0.04
EG+ 0.03 0.00 0.33 0.33
<E 0.47 0.47 0.00 0.04
EG- 0.03 0.00 0.33 0.33
EB> 0.00 0.00 0.00 110
<EB 0.00 0.00 0.00 110
WB1> 0.00 0.00 0.00 415
WP 0.29 0.29 3 47 3 47
<WB1 0.00 0.00 0.00 4 15
VPC File:CA0501693 -010E1 vpc VPC Version .5.3a
VP BUILDINGS
VARCO- PRUDEN
WB2>
<WB2
I 0.00 I 0.00 I 0.00 4 15
Base Plate Summary
X -Loc Grid Mem. Th ickness Width Length Num. Of Bolt Diam. Type
No. I (in.) (in.) (in.) Bolts I (in.) I 9
109/00/0 2 2-A
-B 14 I 0.375 I 9 8
9 I 4 4 I 0.750 I A36
Bolted Connections (A325 Bolts)
Flange Brace Summary
I Member I From Member Joint 1 I From Side Point 1
2 3 1/8/4 I 16/0/11
6/0/6 3/6/11
Maximum Frame Deflection Summary for Cross Section: 2
Design
Welds to
Flange
OS- 0.1875
OS- 0.1875
Date: 11/7/2005
Time: 4.54.37 PM
Page: 34 of 43
Welds to
Web
OS -0 1875
OS- 0.1875
Web Stiffener Summary
Mem. Stiff. Desc. Loc. Web Depth h/t a/h a Thick. Width Side Welding
No. I No. (ft) (in.) (in.) I (in.) (in.) Description
1 1 S3 11.97 7.500 N/A N/A N/A 0.2500 3.000 Both F -FP W- OS- 0.1875
1 2 S2 9.65 7.500 55 76 N/A N/A 0.3750 4.000 Far F- BS- 0.1875,W -OS -0 1875
1 3 S5 0.13 7.500 55.76 N/A N/A 0.5000 5.000 Near W -BS- 0.1875
4 1 S5 0 17 7.500 55.76 N/A N/A 0.5000 5.000 Near W -BS 0.1875
4 2 S3 13.32 7.500 N/A N/A N/A 0.3125 3.500 Both F -FP W- OS- 0.1875
4 3 S2 11.06 7.500 55.7 �NLA..,. N11A. S1L3750 4.000 Near F- BS- 01875,W -OS- 0.1875
E. P/ E- 2-
1 1 $v'lty 1- RedgfOut I Rows -In I Moment Out I Moment In
Mem. Jt. Type Conn. Thick. Width Length Diam. Pitch 2 4 2 4 Ld Actual Capacity Ld Actual Capacity
No. No. (in.) (in.) (in.) (in.) (in.) I Bolt I Bolt I Bolt I Bolt I Cs I (in -k) I (in -k) I Cs I (in -k) (in -k)
1 2 KN(Face) AISC 7.00 8.72 0.00 0 0 0 0 34 211.8 0.0 33 211.8 0.0
2 1 KN(Face) AISC 6.00 8.72 0.00 0 0 0 0 34 211.8 0.0 33 211.8 0.0
3 2 KN(Face) AISC 6.00 8.72 0.00 0 0 0 0 34 211.8 0.0 33 211.8 0.0
4 2 KN(Face) AISC 8.00 8.72 0.00 0 0 0 0 34 211.8 0.0 33 211.8 0.0
Part I Design Note
FB2050
FB2050
Frame Design Member Summary Controlling Load Case and Maximum Combined Stresses per Member (Locations are from Joint 1
I Actual Forces I Actual Stresses I Allowable I Stress Condition I
Mem I Lo Depth Load I Axial I Shear I Mom -x I Mom -y I Axial I Shear Bnd- XBnd -Y Stress I /Force Sum
No. ft in. Case k k in -k in -k ksi ksi ksi ksi Axial I Shear Bnd -X I Bnd -Y Bnd +Ax Shear
1 10.33 8.00 84 3.2 0.0 16.6 109.2 0.71 0.03 116 26.74 30.00 19.27 30.00 30.00 0.954 0.002
2 7.05 8.81 72 0.2 01 38.3 0.0 0.10 0.05 5.64 0.00 30.00 16.91 14.21 26.61 0.397 0.003
3 0.00 8.81 72 0.2 0.3 35.2 0.0 0.10 0.26 4.80 0.00 30.00 16.91 14.21 26.61 0.338 0.015
4 11.92 8.00 72 1 7 -0 4 59 7 125.9 0.34 0.41 3.68 23.61 30.00 19.27 26.25 28.30 0.975 0.021
Mem. Loc. Depth Area Rx R Lx -1 L -2 Klx Kl l Kl 2 Sx Lbl Rt -1 Lb2 Rt -2 s a Cbl Cb2
I No. I ft in. I in.2 I in. in. in. I L n. n. I /Rx I /Ry I /Ry I in.3 I in. I in. I in. I in. I I
1 10.33 8.00 4.51 3.56 178 144.00 216.0 0.0 60.6121.3 0.0 14.33 144.0 2.13 0.0 0.00 0.99 1.00 1.00 0.00
2 7.05 8.81 2.49 3.60 1.06 195.68 30.0 0.0 54 4 28.3 0.0 6.79 150.0 1.37 0.0 0.00 0.89 1.00 1.00 0.00
3 0.00 8.81 2.49 3.60 1.06 195.68 30.0 0.0 54 4 28.3 0.0 7.33 150.0 1.37 0.0 0.00 0.89 1.00 1.00 0.00
4 11.92 8.00 5 01 3.60 2.06 160.25 240.4 0.0 66.8 116.5 0.0 16.20 160.3 2.43 0.0 0.00 0.94 1.00 1.00 0.00
Deflection Load Combinations Framing
No. Origin Factor I Def H Def V Application Description
1 System 1.000 0 180 1.0 L L
2 System 1.000 0 180 1.0 S S
3 System 1.000 0 180 0.700 W 1> W 1>
4 System 1.000 0 180 0.700 <W 1 <W 1
5 System 1.000 0 180 0.700 W2> W2>
6 System 1.000 0 180 0.700 <W2 <W2
7 System 1.000 0 180 0.700 WP WP
8 System 1.000 60 0 0.700 Wl> Wl>
9 System 1.000 60 0 0.700 <W 1 <W 1
10 System 1.000 60 0 0.700 W2> W2>
11 System 1.000 60 0 0.700 <W2 <W2
12 System 1.000 60 0 0.700 WP WP
13 System 1.000 60 0 0.600 E> 0.700 EG- F> EG-
14 System 1.000 60 0 0.600 <E 0.700 EG- <E EG-
VPC File:CA0501693 -01OE1 vpc VPC Version .5.3a
VP BUILDINGS
VARCO•PRUDEN
Description
Max. Horizontal Deflection
Max. Vertical Deflection for Span 1
Design
VPC File:CA0501693 -010E1 vpc VPC Version :5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 35 of 43
I Deflection (in.) I Ratio 'Member) Joint I Load Case I Load Case Description
-0.130 I (U1565) 2 2 2 123 I E> SEG-
Negative horizontal deflection is left
Negative vertical deflection is down
Lateral deflections of primary frames are calculated on a bare frame basis and do not include resistance from systems such as roof and endwall diaphragms.
Therefore, these deflections may be considerably overstated.
VP BUILDINGS
VARCO- PRUDEN
Note:
Typical haunch connection.
Tension Side
Member data: Design Forces: Primary Variables: Section Properties :(w /o web)
bf 5.0 in. Mx 211.8 in -k Pf (3.5 0.1345 )/2 1.68275 in. S(flange) 5.83 in3
tf 0.1345 in. T 0 kips w 1/8 in. S(stiffener) in
tw 0.1345 in. V 2 kips db 3/4 in. Area 1.35 in
d 8.8 in. bp 6 in. Comp. side stiff's NOT USED
Pe 1.68275 (0.75/4) 707(0.125)= 1 407 in.
C 1 090 Cb= 0.913
Aw 1 15 In`
At 0.67
am 0.974
Flange Fillet Weld: Dreq'd
USE:.. Reid
0.60(50) x 0 1345
Web Fillet Weld: D 2.17 16ths
(Near Flanges)
Stiffener Length:
(Based on Web Shear)
USE: (8)'0.75 in, diam.
x 2 in. A325 -X
AISC Moment Connection
USE: 0.5 in thick
x6.in. x 14.6755 in. plate
Fy 50 ksi I
1 USE 3116" Fillet Weld
No tension stiffener is used:: I
N /A
Design per DM 3.1 2
1.25'
-I-
3.5'
Tension Side
Results:
Bolt Stress 24 6%
Weld Stress 67.9%
Plate Bend 58.3%
'Connection Capacity= 3211n -kips.
Flange Force.Ff 24.4 kips
Stiff. Force Fs= 04 kips:
Me 8.37 in-k
Allowable Stress Factor 1.53
Req'd Tp 0.376 in.
24 41 [2 (5 +0.1345) 0.1345] 0.928 (1.27 o7 1 98 16ths
2 x 0.928
Copy of MOMCONst1693.xls
C JF
x
3.0"
x.
Stiffener Tension [M /S(stiff) T /A] x Ast 0.00 kips
Lreq 0 [0.3 (65) 1.275 x 0.1345 (1) 1.03) 0 00 in.
Stiffener to Web Weld: D 0.00 [2 x 3 x 0.928 (1.275) 1.03] 0 00 /16ths
Fillet weld one side
Job No. CA0501693 -01OE1
Page: I 35.1
Date: I 11/07/05
Prepared By I BDF
Location: I CA
Rev 13 (4 -1 -05) Z
CJ?
3/16' 3.5 in.
No Stiffener
VP BUILDINGS
VAACO- PRUOFN
0 r---v ric)E A, L
N
Typ
r
No CA0501693 -01OE1
Page 35.2
Date 11/8/05
Prepared By BDF
Reviewed By
12 '1
e?) ')q A
'FOl -T AL
VP BUILDINGS
VA RCO- PRUDEN
Wall. 2, Frame at: 13/0/0
Frame Cross Section: 1
y
Dimension Key
1 8 1/2'
2 3'-6 11/16'
3 2' -8 3/4'
4 3 3/8'
V II
Y
1
C
Frame Clearances
Horiz. Clearance between members 1(CX003) and 4(CX004): 16' 3'
Vert. Clearance at member 1(CX003): 12'-0'
Vert. Clearance at member 4(CX004): 13'4 1/4
Finished Floor Elevation 100' -0' (Unless Noted Otherwise)
Design
5(a)2'
9'- 013116" 1 000
rzl
1
VPC File•CA0501693 -01OE1 vpc VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 36 of 43
VP BUILDINGS
V *ACO.PRUDEN
Frame Location Design Parameters:
I Location I Avg. Bay Space
I 13/0/0 I 7/0/0 (Rigid Frame
Design Load Combinations
No. Origin
1 System
2 System
3 System
4 System
5 System
6 System
7 System
8 System
9 System
10 System
11 System
12 System
13 System
14 System
15 System
16 System
17 System
18 System
19 System
20 System
21 System
22 System
23 System
24 System
25 System
26 System
27 System
28 System
29 Special
30 Special
31 Special
32 Special
33 AISC Special
34 AISC Special
35 AISC Special
36 AISC Special
37 System Derived
38 System Derived
39 System Derived
40 System Derived
41 System Derived
42 System Derived
43 System Derived
44 System Derived
45 System Derived
46 System Derived
47 Special
48 Special
49 System Derived
Framing
Factor
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.000
1.275
1.275
1.275
1.275
1.275
1.275
1.275
1.275
1 700
1 700
1 700
1 700
1.000
1.000
1.000
1.000
1.000
1.000
1.275
1.275
1.275
1.275
1.275
1.275
1.000
VPC File:CA0501693 010E1 vpc
Description
Design
I Angle I Group I Trib. Override I
1 90.0000 I I I
DESCRIPTION
VP Buildings RIGID FRAMES (Type 'RE") are solid -web framing systems consisting of tapered or uniform rafters rigidly connected to tapered or uniform
depth columns. The frame provides a clear span (no interior columns) and is designed to support the applied loads as specified. (AISC Type 1 Construction)
ANALYSIS.
The boundary conditions established for RIGID FRAMES assume the rafter beam is a fully continuous member spanning from building eave to building eave,
with exterior columns rigidly attached (moment- resisting connection). The Exterior Columns are typically pinned connected (free to rotate) at their base
connection to the foundation.
DESIGN
RIGID FRAMES are designed in accordance with the AISC 'Specification for Structural Steel Buildings' 9th Edition.
MATERIAL.
Structural steel plate, bar and /or sheet intended for use in RIGID FRAME bolted and/or welded constructions typically will be of material based on the
requirements of ASTM A529 A572, A570, or A607 Grade 50.
Application
1.0 D 1.0 CG 1.0 L
1.OD +1.0CG +1.0S
1.OD +1.0WI>
1.OD +1.0<W1
1.0 D+ 1.0W2>
1.0 D+ 1.0 <W2
1.0 D+ 1.0 CG 0.750 L +0.750 Wl>
1.0 D 1.0 CG 0.750 L 0.750 <Wl
1.0 D+ 1.0 CG +0.750 L +0.750 W2>
1.OD +1.0CG +0750L +0.750 <W2
1.O D+ 1.O CG +0.750 S +0.750 W1>
1.0 D 1.0 CG 0.750 5 +0.750 <WI
1.O D+ 1.O CG 0.750 S +0.750 W2>
1.O D+ 1.O CG 0.750 S 0.750 <W2
0.600 D 1.0 WI>
0.600D +1.0 <W1
0.600 D 1.0 W2>
0.600 D 1.0 <W2
1.0 D 1.0 CG 0.700 E> 0.700 EG+
1.0 D 1.0 CG 0.700 <E 0.700 EG+
1.0 D+ 1.00G +0.750 L 0.750 E> 0.750 EG+
1.0D +1.0CG +0.750L +0.750 <E +0750EG+
0.600 D 0.600 CG 0 700 E> 0.700 EG-
0.600 D 0.600 CG 0.700 <E 0.700 EG-
0.900 D 0.900 CG 1.0 E> 0.700 EG-
0.900 D 0.900 CG 1.0 <E 0.700 EG-
1.200 D 1.200 CG 0.200 S 1.0 E> 0 700 EG+
1.200 D+ 1.200 CG+ 0.200 S 1.0 <E 0.700 EG+
0.900 D 0.900 CG 2.500 E> 1.0 EG-
0.900 D 0.900 CO 2.500 <E 1.0 EG-
1. 200D +1.20000 +0.200S +2.500F> +1.0EG+
1.200 D 1.200 CG 0.200 S 2.500 <E 1.0 EG+
0.900 D 0.900 CG
0.900 D 0.900 CG
1.200 D 1.200 CG 0.200 S
1.200 D 1.200 CG 0.200 S
1.0 D 1.0 CO 0.210 F> 0.700 EG+ 0.700 EB>
1.0 D+ 1.0 CG 0.210 <E +0.700 EG+ 0.700 EB>
1.0 D 1.0 CG 0.750 L 0.225 E> 0.750 EG+ 0.750 EB>
1.0 D 1.0 CO 0.750 L 0.225 <E 0.750 EG+ 0.750 EB>
0.600 D 0.600 CG 0.210 F> 0.700 EG- 0.700 EB>
0.600 D 0.600 CG 0.210 <E 0.700 EG- 0.700 EB>
0.900 D 0.900 CG 0.300 E> 0.700 EG- 1.0 EB>
0.900 D 0.900 CG 0.300 <E 0.700 EG- 1.0 EB>
1.200 D 1.200 CG 0.200 S 0.300 E> 0.700 EG+ 1.0 EB>
1.200 D 1.200 CG 0.200 S 0.300 <E 0.700 EG+ 1.0 EB>
0.900 D 0.900 CG 2.500 EB> 1.0 EG-
1.200 D 1.200 CG 0.200 S 2.500 EB> 1.0 EG+
1.0 D 1.0 CG 0.210 E> 0.700 EG+ 0.700 <EB
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 37 of 43
Design Status
Automatic Design
Description
D +CG +L
D CG S
D +Wl>
D <Wl
D W2>
D <W2
D +CG +L +WI>
D+CG +L <Wl
D +CG +L +W2>
D +CG +L <W2
D +CG +S +WI>
D +CG +S <W1
D+ CG+S +W2>
D +CG +5 +<W2
D +WI>
D <W1
D W2>
D <W2
D +CG +F> +EG+
D CO <E EG+
D+CG +L +F>+EG+
D CG L <E EG+
D +CG +E> +EG-
D+CG+<E+EG-
D+CG+F>+EG-
D+CO+<E+EG-
D +CG +S +F> +EG+
D CO S <E EG+
D +CG +F>+EG-
D+CG+<E+EG-
D +CG +S +E> +EG+
D CG S <E EG+
D CG
D CG
D CG S
D CG S
D CG E> EG+ EB>
D CG <E EG+ EB>
D+CG+L +E>+EG++EB>
D+CG+L+<E +EG+ +EB>
D +CG +F> EG- +EB>
D CG <E EG- EB>
D+CG +E> +EG +EB>
D CG <E EG- EB>
D +CG+S +E>+EG++EB>
D+CG+S+<E +EG++EB>
D CG EB> EG-
D CG S EB> EG+
D +CO +E> EG+ <EB
VP BUILDINGS
VARCO- PRUDEN
50 System Derived 1.000
51 System Derived 1.000
52 System Derived 1.000
53 System Derived 1.000
54 System Derived 1.000
55 System Derived 1.275
56 System Derived 1.275
57 System Derived 1.275
58 System Derived 1.275
59 Special 1.275
60 Special 1.275
61 System Derived 1 000
62 System Derived 1.000
63 System Derived 1.000
64 System Derived 1.000
65 System Derived 1.000
66 System Derived 1.000
67 System Derived 1.000
68 System Derived 1.000
69 System Derived 1.000
70 System Derived 1.000
71 System Derived 1.000
72 System Derived 1.000
73 System Derived 1.000
74 System Derived 1.000
75 System Derived 1.000
76 System Derived 1.000
77 System Derived 1.000
78 System Derived 1.000
79 System Derived 1.000
80 System Derived 1.000
81 System Derived 1.000
82 System Derived 1.000
83 System Derived 1.000
84 System Derived 1.000
85 System Derived 1.000
86 System Derived 1.000
87 System Derived 1.000
88 System Derived 1.000
89 System Derived 1.000
90 System Derived 1.000
91 System Derived 1.000
92 System Derived 1.000
93 System Derived 1.000
94 System Derived 1.000
95 System Derived 1.000
96 System Derived 1.000
97 System Derived 1.000
98 System Derived 1.000
99 System Derived 1.000
100 System Derived 1.000
101 System Derived 1.000
102 System Derived 1.000
103 System Derived 1.000
104 System Derived 1.000
105 System Derived 1.000
106 System Derived 1.000
107 System Derived 1.000
108 System Derived 1.000
Frame Member Sizes
I Mem. I Flg Width I Flg Thk I Web Thk
No. (in.) (in.) (in.)
1 7.00 0.2500 0.1345
2 5.00 0.1345 0.1345
3 5.00 0.1345 0.1345
4 8.00 0.2500 0.1345
VPC File:CA0501693 -01OE1 vpc
1.0 D+ 1.0 CG +0.210 <E +0.700EG+ +0700 <EB
1.0 D 1.0 CG 0.750 L 0.225 E> 0.750 EG+ 0 750 <EB
1.0 D 1.0 CG 0.750 L 0.225 <E 0.750 EG+ 0.750 <EB
0.600 D 0.600 CG 0.210 E> 0 700 EG- 0.700 <EB
0.600 D 0.600 CG 0.210 <E 0.700 EG- 0.700 <EB
0.900 D 0.900 CG 0.300 E> 0.700 EG- 1.0 <EB
D.900 D 0.900 CG 0.300 <E 0.700 EG- 1.0 <EB
1.200 D 1.200 CG 0.200 S 0.300 F> 0.700 EG+ 1.0 <EB
1.200 D 1.200 CG 0.200 S 0.300 <E 0 700 EG+ 1.0 <EB
D.900 D 0.900 CG 2.500 <EB 1.0 EG-
1.200 D 1.200 CG 0.200 S 2.500 <EB 1.0 EG+
1.0 D 0.750 Wl> 0.750 WB1>
1.0 D 0.750 <WI 0.750 WBI>
1.0D+1.OWP +1.OW131>
1.0 D 1.0 CG 0 750 L+ 0.563 Wl> 0.563 WB1>
1.0D +1.000 +0750L +0.563 <W1+ 0.563 WBI>
1.0 D 1.0 CG 0.750 L 0.750 WP 0.750 WB1>
1. 0D +1.0CG +0750S +0.563W1 +0.563WB1>
1.0D +1.0CG +0.7505 +0.563 <W1+ 0.563 WB1>
1.0D +1.0CG +0.7505 +0750WP +0.750WB1>
0.600 D 0.750 W 1> 0.750 WB1>
0.600 D 0.750 <W1 0.750 WB1>
D.600D +1.0WP+1.0WBI>
1.0 D 0.750 Wl> 0.750 <WBI
1.0 D 0.750 <WI 0.750 <WB1
1.OD +1.0WP+1.0 <WBI
1.0 D+ 1.0 CG +0750L +0.563 W1>+ 0.563 <WB1
1.0 D+ 1.0 CG +0.750 L+ 0.563<WI +0.563<WB1
1.0 D 1.0 CO 0.750 L 0.750 WP 0.750 <WB1
1.0 D 1.0 CG 0.750 S 0.563 Wl> 0.563 <WB1
1.0 D 1.0 CG 0.750 S 0.563 <W 1 0.563 <WB1
1.0 D 1.0 CO 0.750 S 0.750 WP 0.750 <WB1
0.600 D 0.750 W 1> 0.750 <WB1
0.600 D 0.750 <W l 0.750 <WB1
0.600D +1.0WP +1.0 <WB1
1.0 D 0.750 W2> 0.750 WB2>
1.0 D 0.750 <W2 0 750 WB2>
1.OD +I.OWP +1.OWB2>
1.0 D 1.0 CG 0.750 L 0.563 W2> 0.563 WB2>
1.0 D 1.0 CG 0.750 L 0.563 <W2 0.563 WB2>
1.0 D 1.0 CG 0 750 L 0.750 WP 0.750 WB2>
1.0 D 1.0 CG 0.750 S 0.563 W2> 0.563 WB2>
1.0 D 1.0 CG 0.750 S 0.563 <W2 0.563 WB2>
1.0 D 1.0 CG 0.750 S 0.750 WP 0.750 WB2>
0.600 D 0.750 W2> 0.750 WB2>
0.600 D 0.750 <W2 0.750 WB2>
0.600 D+ 1.0 WP 1.0 WB2>
1.0 D 0.750 W2> 0.750 <WB2
1.0 D 0.750 <W2 0.750 <WB2
1.OD +1.0WP +1.0 <WB2
1.0 D 1.0 CG 0.750 L 0.563 W2> 0.563 <WB2
1.0 D 1.0 CG 0.750 L 0.563 <W2 0.563 <WB2
1.0 D 1.0 CO 0.750 L 0.750 WP 0.750 <WB2
1.0 D 1.0 CG 0.750 S 0.563 W2> 0.563 <WB2
1.0 D 1.0 CG 0.750 S 0.563 <W2 0.563 <WB2
1.0D +1.0CG +07505 +0.750WP +0.750 <WB2
0.600 D 0.750 W2> 0.750 <WB2
0.600 D 0.750 <W2 0.750 <WB2
0.600 D 1.0 WP 1.0 <WB2
Depthl
(in.)
8.00
8.81
8.81
8.00
Design
Depth2 I Length Weight
(in.) (ft) I (D)
8.00 12.68 206.4
8.81 8.82 69.5
8.81 8.82 68.9
8.00 14 15 253.6
Total Frame Weight 598.4
Flg Fy Web Fy Splice
(ksi) I (ksi) I Jt.l
50.00 50.00 BP
50.00 50.00 KN
50.00 50.00 SS
50.00 50.00 BP
(p) (Includes all plates)
VPC Version .5.3a
Date: 11/7/2005
Time: 4.54.37 PM
Page: 38 of 43
D CO <E EG+ <EB
D +CG+L +E>+EG H<EB
D +CG+L +<E +EG++<EB
D CG E> EG- <EB
D +CG <E EG- <EB
D CG F> EG- <EB
D CO <E EG- <EB
D+CG+S +E> +EG++<EB
D +CG+S+<E +EG++<EB
D +CG <EB +EG-
D +CG +S <EB +EG+
D +W1 +WBI>
D <Wl +WBI>
D +WP +WBI>
D +CG +L +WI +WB1>
D +CG +L <W1 +WB1>
D +CG +L +WP +WBl>
D +CG +S +WI +WB1>
D +CG +S <W1 +WB1>
D CG S WP WB1>
D +WI +WB1>
D <W1 WB1>
D WP WB 1>
D +Wl <WB1
D+ <W1 <WB1
D +WP +<WB1
D +CG +L +Wl +<WB1
D +CG +L <W1 <WBI
D +CG +L +WP <WB1
D +CG +S +WI <WB1
D +CG +S <WI <WB1
D +CG +S +WP <WBI
D +Wl <WB1
D <Wl +<WB1
D WP <WB1
D +W2 +WB2>
D <W2 WB2>
D WP WB2>
D CG L W2> WB2>
D CG L <W2 WB2>
D CG L WP WB2>
D CG S W2> WB2>
D +CG +S <W2 +WB2>
D CG S WP WB2>
D W2> WB2>
D +<W2 +WB2>
D WP WB2>
D W2> <WB2
D <W2 <WB2
D +WP <WB2
D CO L W2> <WB2
D CO L <W2 <WB2
D CG L WP <WB2
D CO S W2> <WB2
D +CG +S +<W2 <WB2
D CO S WP <WB2
D W2> <WB2
D <W2 <WB2
D WP <WB2
Codes
Jt.2
KN
SS
KN
KN
Shape
3P
3P
3P
3P
VP BUILDINGS
VARCO-PRUDEN
I Member I X -Loc
Boundary Condition Summary
1 I 0 /0 /0
4 19/0/0
Design
Date: 11/7/2005
Time: 4 54.37 PM
Page: 39 of 43
Y -Loc I Supp. X I Supp. Y I Moment I Displacement X(in.) I Displacement Y(in.) I Displacement ZZ(rad.)
0 /0 /0 Yes Yes No 0 /0 /0 I 0 /0 /0 0.0000
0 /0 /0 I Yes I Yes I No I 0/0/0 I 0/0/0 0.0000
Frame Reactions Load Cases at Frame Cross Section: 1
X -Loc I 0/0/0 19/0/0
Gridl Grid2 I 1 -A 1 -B
Ld Description I Hx Hz Vy Hx Hz Vy
Cs (application factor not shown) I (k) (k) (k) (k) (k) (k)
1 D +CG +L 0.31 2.27 0.31 2.31
2 D CG S 0.36 2.60 -0.36 2.65
3 D W 1> -0.01 -0.24 0.14 -0.42
4 D <W 1 -0.05 -0.82 0.30 1 19
5 D W2> -0.01 -0.24 0.14 -0.42
6 D <W2 -0.05 -0.82 0.30 1 19
7 D +CG +L +Wl> 0.22 141 -0.12 1.28
8 D +CG +L <W1 0.19 0.97 -0.01 0.70
9 D +CG +L +W2> 0.22 141 -012 1.28
10 D +CG +L <W2 019 0.97 -0.01 0.70
11 D +CG +S +Wl> 0.26 1.66 -0.16 1.53
12 D CG S <W 1 0.23 1.22 -0.04 0.95
13 D +CG +S+W2> 0.26 1.66 -0.16 1.53
14 D CG S <W2 0.23 1.22 -0.04 0.95
15 D W 1> -0.02 -0 42 0.16 -0.62
16 D <W 1 -0.06 1.01 0.31 1.39
17 D W2> -0.02 -0.42 0.16 -0.62
18 D <W2 -0.06 1.01 0.31 1.39
19 D CG E EG+ 0.30 1.31 0.02 0.85
20 D CG <E EG+ -0.05 0.78 -0.28 1.33
21 D +CG +L +E> +EG+ 047 2.34 -0.11 1.84
22 D CG L <E EG+ 0.09 1 77 0.44 2.36
23 D+CG+E>+EG- 0.23 0.71 0.10 0.23
24 D+CG+<E+EG- -0.13 0.17 -0.20 0.71
25 D+CG+E>+EG- 0.34 1 10 0.13 0.42
26 D+CG+<E+EG- -0.17 0.34 -0.30 1 10
27 D +CG +S +E> +EG+ 0.45 1.95 0.02 1.27
28 D CG S <E EG+ -0.05 1 18 -0.42 1.96
37 D CG E> EG+ EB> 0.19 -0.16 0 77 -0.09 -0.16 0.60
38 D CG <E EG+ EB> 0.08 -0.16 0.61 -0.18 -0.16 0.74
39 D+CG+L +Ej +EG++EB> 0.34 -0.18 176 -0.24 -0.18 1.57
40 D+CG+L+<E +EG++EB> 0.23 -0.18 1.59 -0.33 -018 173
41 D +CG +E> +EG +EB> 0.11 -0.16 0.17 -0.01 -0.16 -0.02
42 D CO <E EG- EB> 0.00 -0.16 0.01 -0.10 -0.16 0.12
43 D CG E> EG- EB> 0.17 -0.23 0.33 -0.03 -0.23 0.06
44 D CG <E EG- EB> 0.02 -0.23 0 10 -0 16 -0.23 0.27
45 D +CG+S +E>+EG++EB> 0.29 -0.23 117 -0.15 -0.23 0.92
46 D+CG+S+<E+EG-H-EB> 0.14 -0.23 0.94 -0.28 -0.23 112
49 D +CG +E> +EG+ <EB 0.17 0.16 148 -0.07 0.16 143
50 D +CG <E +EGF+ <EB 0.06 0.16 1.32 -0.16 0.16 1.58
51 D+CG+L+E>+EG++<EB 0.32 018 2.52 -0.22 0.18 2.47
52 D+CG+L+<E +EG++<EB 0.21 0.18 2.35 -0.32 0.18 2.63
53 D CG E> EG- <EB 0.09 0.16 0.88 0.01 0.16 0.81
54 D CG <E EG- <EB -0.01 0.16 0.72 -0.09 0.16 0.96
55 D +CG +E> +EG <EB 0.15 0.23 1.34 -0.00 0.23 1.26
56 D CG <E EG- <EB -0.01 0.23 1 11 -0.13 0.23 1 46
57 D+CG+S +E> +EG I I <EB 0.26 0.23 2.18 -0.12 0.23 2.11
58 D+CG+S+<E +EG++<EB 0.11 0.23 1.96 -0.25 0.23 2.32
61 D W1>+ WB 1> 0.04 -0.66 1 49 0.06 -0.66 1.87
62 D <W1 +WBI> 0.01 -0.66 1.93 0.18 -0.66 2.45
63 D WP WBI> -0.01 -0.88 2.94 0.30 -0.88 3 71
64 D +CG +L +WI +WB1> 0.26 -0.50 047 -0.18 -0.50 0.19
65 D CG L <W 1 WBI> 0.24 -0.50 0.14 -0.10 -0.50 -0.24
66 D CG L WP WB 1> 0.22 -0.66 -0.62 -0.00 -0.66 1 19
67 D +CG +S +WI +WBI> 0.30 -0.50 0.72 -0.22 -0.50 0.44
68 D CG S <W1 WB1> 0.27 -0.50 0.39 -0.13 -0.50 0.01
69 D CG S WP WBI> 0.25 -0.66 -0.36 -0.04 -0.66 -0.94
70 D +W1 +WBI> 0.02 -0.66 1.68 0.08 -0.66 2.07
VPC File:CA0501693 -010E1 vpc VPC Version .5.3a
VP BUILDINGS
VARCO.PRUDEN
Design
71 D +<W1 +WBI> -0.01 -0.66 2.11 0.19 -0.66 -2.65
72 D WP WB1> -0.03 -0.88 3 12 0.32 -0.88 3.91
73 D +W1 <WB1 -0.03 0.66 1.36 0.13 0.66 149
74 D <W1 +<WBI -0.06 0.66 0.93 0.25 0.66 0.92
75 D WP <WB1 -0.11 0.88 0.87 0.40 0.88 0.77
76 D +CG +L +W1 +<WB1 0.20 0.50 2.61 -0.13 0.50 2.72
77 D +CG +L <Wl <WB1 018 0.50 2.28 -0.04 0.50 2.28
78 D +CG +L +Wp <WB1 0.15 0.66 2.24 0.07 0.66 2.18
79 D CG S W 1> <WB 1 0.24 0.50 2.86 -0 17 0.50 2.97
80 D +CG +S <W1 +<WB1 0.22 0.50 2.53 -0.08 0.50 2.53
81 D +CG +S +WP+<WB1 0.18 0.66 2.49 0.03 0.66 2.43
82 D +W1 <WB1 -0.05 0.66 118 015 0.66 1.29
83 D <W1 <WB 1 -0.08 0.66 0 74 0.26 0.66 0.71
84 D WP <WB1 -0.12 0.88 0.69 0.41 0.88 0.57
85 D W2> WB2> 0.04 -0.66 1 49 0.06 -0.66 1.87
86 D <W2 WB2> 0.01 -0.66 1.93 0.18 -0.66 2.45
87 D WP WB2> -0.01 -0.88 -2.94 0.30 -0.88 3.71
88 D +CG +L +W2 +WB2> 0.26 -0.50 0.47 -0 18 -0.50 0.19
89 D CG L <W2 WB2> 0.24 -0.50 0.14 -0.10 -0.50 -0.24
90 D CG L WP WB2> 0.22 -0.66 -0.62 -0.00 -0.66 1 19
91 D CG S W2> WB2> 0.30 -0.50 0.72 -0.22 -0.50 0.44
92 D CG S <W2 WB2> 0.27 -0.50 0.39 -0 13 -0.50 0.01
93 D CG S WP WB2> 0.25 -0.66 -0.36 -0.04 -0.66 -0.94
94 D W2> WB2> 0.02 -0.66 1.68 0.08 -0.66 -2.07
95 D <W2 WB2> -0.01 -0.66 2.11 0.19 -0.66 2.65
96 D WP WB2> -0.03 -0.88 3 12 0.32 -0.88 3.91
97 D W2> <WB2 -0.03 0.66 1.36 0.13 0.66 1 49
98 D <W2 <WB2 -0.06 0.66 0.93 0.25 0.66 0.92
99 D WP <WB2 -0.11 0.88 0.87 0.40 0.88 0.77
100 D CG L W2> <WB2 0.20 0.50 2.61 -0.13 0.50 2.72
101 D +CG +L <W2 <WB2 0.18 0.50 2.28 -0.04 0.50 2.28
102 D +CG +L +WP <WB2 0.15 0.66 2.24 0.07 0.66 2.18
103 D CG S W2> <WB2 0.24 0.50 2.86 -0.17 0.50 2.97
104 D CG S <W2 <WB2 0.22 0.50 2.53 -0.08 0.50 2.53
105 D CG S WP <WB2 0.18 0.66 2.49 0.03 0.66 2.43
106 D W2> <WB2 -0.05 0.66 1 18 0.15 0.66 1.29
107 D <W2 <WB2 -0.08 0.66 0.74 0.26 0.66 0.71
108 D WP <WB2 -0.12 0.88 0.69 0.41 0.88 0.57
Date: 11/7/2005
Time: 4.54.37 PM
Page: 40 of 43
Maximum Reactions Summary Framing
X -Loc Grid Hrz left Load Hrz Right Load Hrz In Load Hrz Out Load Uplift Load Vrt Down Load Mom cw Load Mom ccw Load
-Hx) Case (Hx) Case -Hz) Case (Hz) Case (Vy) Case (Vy) Case -Mzz) Case (Mzz) Case
(k) (k) (k) (k) (k) (k) I (in -k) (in-k)
1 9 0/0 I 1 -B I 0.44 122 I 0.41 184 I 0.88 163 I 0.88 175 I 3.91 172 I 2.97 179 I
Sum of Forces with Reactions Check Framing
Horizontal Ver ical
Load Type Load Reaction Load Reaction
(k) (k) (k) (k)
D 0.00 0.00 0.98 0.96
CG 0.00 0.00 0.94 0.94
L 0.00 0.00 2.68 2.68
S 0.00 0.00 3.34 3.34
WI> 0.14 0.14 1.63 1.63
<W1 0.25 0.25 2.98 2.98
W2> 0.14 0.14 1.63 1.63
<W2 0.25 0.25 2.98 2.98
E> 0.47 0.47 0.00 0.04
EG+ 0.03 0.00 0.33 0.33
<E 0 47 0.47 0.00 0.04
EG- 0.03 0.00 0.33 0.33
EB> 0.00 0.00 0.00 110
<EB 0.00 0.00 0.00 110
WB1> 0.00 0.00 0.00 415
WP 0.29 0.29 3 47 3 47
<WB I 0.00 0.00 0.00 4 15
VPC File:CA0501693 -010E1 vpc VPC Version .5.3a
VP BUILDINGS
VARCO.PRUDEN
WB2>
<WB2
Design
0.00 0.00 0.00 I 4 15
Base Plate Summary
X Loc Grid Mem. Thickness Width Length Num. Of Bolt Diam. I Type
I No. I (in.) I (in.) I (in.) I Bolts I (in.)
I 1 0 4! 0 0/0 1 -B 14 1 I 0.375 I 9 9 9 I 4 4 10 750 I A36
Welds to
Flange
OS- 0.1875
OS- 0.1875
Date: 11/7/2005
Time: 4 54.37 PM
Page: 41 of 43
Welds to
Web
OS- 0.1875
OS -0 1875
Web Stiffener Summary
Mem. Stiff. Desc. Loc. Web Depth hit a/h a Thick. Width Side I Welding
No. No. (ft) (in.) I (in.) I (in.) (in.) Description
1 1 S3 11.97 7.500 N/A N/A N/A 0.2500 3.000 Both F -FP W -OS -0 1875
1 2 S2 9.65 7.500 55 76 N/A N/A 0.3750 4.000 Near F- BS- 0.1875,W- OS- 0.1875
1 3 S5 013 7.500 55.76 N/A N/A 0.5000 5.000 Far W- BS- 0.1875
4 1 S5 017 7.500 55.76 N/A N/A 0.5000 5.000 Far W- BS- 0.1875
4 2 S3 13.32 7.500 N/A N/A N/A 0.3125 3.500 Both F -FP W- OS- 0.1875
4 3 S2 11.06 7.500.- ..•.....,552_. _N/A N/A 0.3750 4.000 Far F- BS -0.1875,W- OS- 0.1875
Bolted Connections (A325 Bolts) c...-F: e_ PA, 6 E SS
21
-k_.......1 Bolt ows -Out I Rows -In I Moment Out I Moment In I
Mem. Jt. Type Conn. Thick. Width Length tam. i ch 2 4 2 4 Ld Actual Capacity Ld Actual Capacity
No. No. (in.) (in.) (in.) (in.) I (in.) I Bolt I Bolt I Bolt I Bolt I Cs I (in -k) I (in -k) I Cs I (in -k) I (in -k) I
1 2 KN(Face) AISC 7.00 8.72 0.00 0 0 0 0 34 211.8 0.0 33 211.8 0.0
2 1 KN(Face) AISC 6.00 8.72 0.00 0 0 0 0 34 211.8 0.0 33 21L8 0.0
3 2 KN(Face) AISC 6.00 8.72 0.00 0 0 0 0 34 211.8 0.0 33 211.8 0.0
4 2 KN(Face) AISC 8.00 8.72 0.00 0 0 0 0 34 211.8 0.0 33 211.8 0.0
Flange Brace Summary
I Member I From Member Joint 1 I From Side Point 1 I Part I Design Note
2 1/8/4 I 16/0/11 FB2050
3 6/0/6 3/6/11 FB2050
Frame Design Member Summary Controlling Load Case and Maximum Combined Stresses per Member (Locations are from Joint 1
I Actual Forces I Actual Stresses I Allowable I Stress Condition
Mem. I Loc. Depth I Load I Axial I Shear I Mom -x Mom -y I Axial I Shear I Bnd -XI Bnd -YI I Stress /Force I Sum
No. ft in. Case k k in -k in -k ksi ksi ksi ksi Axial I Shear Bnd -X I Bnd -Y Bnd +Ax I Shear
1 10.33 8.00 84 1.3 0.1 16.4 109.2 0.28 0.12 114 26.74 30.00 19.27 25.83 29.61 0.947 0.006
2 7.05 8.81 84 0.3 -0.0 36.7 0.0 0.10 0.04 5 40 0.00 30.00 16.91 14.21 26.61 0.380 0.002
3 0.00 8.81 84 0.3 0.2 35.3 0.0 0.10 0.17 4.82 0.00 30.00 16.91 14.21 26.61 0.339 0.010
4 11.92 8.00 72 3.9 -0.3 59.6 125.9 0.78 0.32 3.68 23.61 30.00 19.27 26.25 28.30 0.975 0.016
Mem. Loc. Depth Area Rx Lx Ly -1 Ly -2 Klx Klyl Kly2 Sx Lbl Rt -1 Lb2 Rt -2 Qs Qa Cbl Cb2
No. ft I in. I in.2 in. I R in. in. I in. I in. I /Rx /Ry I /Ry in.3 I in. I in. I in. I in. I I i
1 10.33 8.00 4.51 3.56 178 144.00 216.0 0.0 60.6 121.3 0.0 14.33 144.0 2.13 0.0 0.00 0.99 1.00 1.00 0.00
2 7.05 8.81 2.49 3.60 1.06 195.68 30.0 0.0 54 4 28.3 0.0 6.79 150.0 1.37 0.0 0.00 0.89 1.00 1.00 0.00
3 0.00 8.81 2.49 3.60 1.06 195.68 30.0 0.0 54 4 28.3 0.0 7.33 150.0 1.37 0.0 0.00 0.89 1.00 1.00 0.00
4 11.92 8.00 5.01 3.60 2.06 160.25 240.4 0.0 66.8 116.5 0.0 16.20 160.3 2.43 0.0 0.00 0.94 1.00 1.00 0.00
Deflection Load Combinations Framin
No. Origin Factor Def H Def V Application Description
1 System 1.000 0 180 1.0 L L
2 System 1.000 0 180 1.0 S S
3 System 1.000 0 180 0.700 WI> Wl>
4 System 1.000 0 180 0.700 <W1 <W1
5 System 1.000 0 180 0.700 W2> W
6 System 1.000 0 180 0.700 <W2 <W
7 System 1.000 0 180 0.700 WP WP
8 System 1.000 60 0 0.700 Wl> Wl>
9 System 1.000 60 0 0.700 <W1 <W1
10 System 1.000 60 0 0.700 W2> W
I 1 System 1.000 60 0 0.700 <W2 <W
12 System 1.000 60 0 0.700 WP WP
13 System 1.000 60 0 0.600 E> 0 700 EG- E> EG-
14 System 1.000 60 0 0.600 <E 0.700 EG- <E EG-
Maximum Frame Deflection Summary for Cross Section: 1
VPC File:CA0501693 -010E1 vpc VPC Version .5.3a
VP BUILDINGS
VARCO- PRUDEN
I Deflection (in.) I Ratio I MemberI Joint I Load Case I Load Case Description
I Max. Horizontal Deflection -0.227 (H/651 1 2 13 E> EG-
Max. Vertical Deflection for Span 1 I -0.130 I (L/1565) I 2 2 2 S
Description
Negative horizontal deflection is left
Negative vertical deflection is down
Lateral deflections of primary frames are calculated on a bare frame basis and do not include resistance from systems such as roof and endwall diaphragms.
Therefore, these deflections may be considerably overstated.
Design
VPC File:CA0501693 -010E1 vpc VPC Version .5.3a
Date: 11/7/2005
Time: 4 54.37 PM
Page: 42 of 43
VP BUILDINGS
VARCO•PRUOEN
Design
Date: 11/7/2005
Time: 4.54.37 PM
Page: 43 of 43
Covering Summary Report
Shape: Metal Canopy
Panel Data
IWall/Roof I Type I Thickness I Finish I Color Direction I Gable Dir I Max. Length
Wall. 1 Open Exposed to wind
Wall: 2 Open
Wall: 3 Open Exposed to wind
Wall: 4 Open
Roof: A SSR 24 KXL Egyptian White Right to Left Not Applicable 51/0/0
Fastener Data
IWall/Roof I Type I Length I Spacing I Washers I hisul. Block I Mod. Ctrl. IIce Damming
Wall: I Not Applicable
Wall: 2 Not Applicable
Wall: 3 Not Applicable
Wall. 4 Not Applicable
Roof: A Stainless Steel Capped Standard Option Ice Damming UL90 Uplift Yes None No Yes
VPC File:CA0501693 -010E1 vpc VPC Version .5.3a