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Steel Utility Poles

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Steel Distribution Poles - The Material of the Future Design & Testing of Steel Poles - presented by - Richard F. Aichinger, PE Manager of Engineering, Utility Products – PowerPoint PPT presentation

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Title: Steel Utility Poles


1
American Iron and Steel Institutes Technical
Session
Steel Distribution Poles - The Material of the
Future
Design Testing of Steel Poles
- presented by - Richard F. Aichinger,
PE Manager of Engineering, Utility
Products Valmont Industries, Inc.
2
Designing For Equivalency
  • Equivalency to what?
  • Expected Strength
  • Expected Life
  • Expected Performance
  • Deflection
  • Handling
  • Field Use

3
Designing For Equivalency
  • Most pole used to date have been wood
  • How do you design a Steel wood pole?
  • You cant but you dont want to
  • Instead you design a pole that meets minimum
    strength and performance requirements every time

4
Designing For Equivalency
  • How do you design a Steel Distribution Pole?
  • ANSI Standards
  • ANSI 05.1
  • National Electric Safety Code (ANSI C-2)
  • ASCE Manual 72
  • Material Manufacturing Proven Reliability
  • Testing and Proven Product Experience

5
ANSI 05.1
  • Provides performance and quality criteria for
    wood poles of various species
  • Provides strength requirements which define the
    various pole Class definition (Class 6 to H-6)
  • Defined by a Capacity Loading to be applied 2
    feet from the pole top
  • Provides direct embedment depth

6
National Electrical Safety Code (ANSI C-2)
  • A Safety Code
  • By default, also a Design Code
  • Provides for Design considerations for various
    line conditions (ice, wind ice, wind)
  • Provides for Construction Grades to differentiate
    the allowable risk accepted in the design

7
National Electrical Safety Code (ANSI C-2)
  • A Little History
  • Provided for loading and strength since the early
    1900s to present
  • Early editions were based on ultimate strength of
    materials
  • Steel was first to be changed to Load Factor in
    1941

8
National Electrical Safety Code (ANSI C-2)
  • 1941 Summary
  • Material Grade B Grade C
  • Steel 2.54 2.2
  • wood 25 37.5
  • (equiv. OLF) (4.0) (2.67)

9
National Electrical Safety Code (ANSI C-2)
  • 1973 Wood was modified
  • Material Grade B Grade C
  • Steel 2.54 2.2
  • wood 25 50
  • (equiv. OLF) (4.0) (2.0)
  • Familiar?
  • wood is now lower than steel in Grade C.
  • 1997 Edition introduced Strength Factors

10
National Electrical Safety Code (ANSI C-2)
  • 1997 Edition Grade B
  • Strength Factor Equiv.
    O.L.F.
  • Load Type Overload Steel Wood
    Steel Wood Ratio
  • Vertical 1.5 1.0 0.65
    1.5 2.31 0.65
  • Transverse
  • Wind 2.5 1.0
    0.65 2.5 3.85 0.65
  • Tension 1.65 1.0
    0.65 1.65 2.54 0.65

11
National Electrical Safety Code (ANSI C-2)
  • 1997 Edition Grade C
  • Strength Factor Equiv.
    O.L.F. Ratio
  • Load Type Overload Steel Wood
    Steel Wood
  • Vertical 1.5 1.0
    0.85 1.5 1.76 0.85
  • Transverse
  • Wind 2.2 (steel) 1.0
    0.85 2.2 2.06 1.07
  • 1.75(wood)
  • Tension 1.1 (steel) 1.0
    0.85 1.1 1.53 0.72
  • 1.3 (wood)

12
ASCE Manual 72
  • The Steel Pole Design Guide
  • Provides for the best practices of the industry
  • Provides for the Design Requirements equated to
  • AISC
  • ACI
  • AWS

13
Designing For Equivalency
  • Equivalent Wood Pole Loading (B)
  • ANSI Load x 2.5/4.0
  • ANSI 05.1 Working Equivalent
  • Pole Class Loading Load Steel Load
  • 2 3700 925 2313
  • 3 3000 750 1875
  • 4 2400 600 1500
  • 5 1900 475 1188

14
Designing For Equivalency
  • CLASS 4 Pole has ANSI rated capacity of 2400.
  • GRADE B CONSTRUCTION
  • WOOD O.L.F. 4.0
  • STEEL O.L.F. 2.5
  • STEEL RATED LOAD BECOMES 2400 x 2.5/4.0
    1500
  • GRADE C CONSTRUCTION
  • WOOD O.L.F. 2.0
  • STEEL O.L.F. 2.2
  • STEEL RATED LOAD BECOMES 2400 x 2.2/2.0
    2640

15
Designing For Equivalency
  • CLASS 4 Pole has ANSI rated capacity of 2400.
  • GRADE B CONSTRUCTION
  • WOOD O.L.F. 4.0
  • STEEL O.L.F. 2.5
  • STEEL RATED LOAD BECOMES 2400 x 2.5/4.0
    1500
  • GRADE C (Expected NESC Change for 2002)
  • WOOD O.L.F. 2.06
  • STEEL O.L.F. 1.75
  • STEEL RATED LOAD BECOMES 2400 x
    1.75/2.06 2039 (vs. 2640)

16
Designing For Equivalency
  • Steel Allows for Designs that Consistently meet
    strength requirements by varying diameter and
    thickness
  • ASCE Manual 72 provides criteria for Local
    Buckling of Tubular Steel
  • Proven through years of use in other products
  • Verified by EPRI and manufacturer testing
  • Provides a pole that is consistent by design

17
Designing For Life
  • Steel Allows for the Design of a Product that can
    be protected against deterioration
  • Galvanizing provides a proven inside/out
    protection for most environments
  • An additional groundline barrier coating provides
    extra protection at the most corrosive location
  • When damaged by overload conditions, Steel will
    tend to locally yield rather than break or
    collapse, often times allowing the line to
    remain in service

18
Designing For Performance
  • Deflection of steel poles are normally less than
    the equivalent wood pole based on the pole size
    defined by ANSI 05.1
  • The following graph shows a representative
    comparison indicating the deflection of a Steel
    versus wood poles

19
Load Deflection of Steel vs. Wood Poles (40
Class 4, NESC Grade B)
20
Designing For Performance
  • Weight of steel poles are normally much less than
    the equivalent wood pole providing added
    savings for field handling and maneuvering
  • The following chart is a representative
    comparison of the weight of wood poles versus
    Steel Poles

21
Weight Comparison of Wood to Steel
22
Designing For Performance
  • Additionally, Steel can be Designed for true
    design applications wood is seldom correctly
    considered for
  • Guyed angles and corners
  • NESC requirements
  • Unguyed angles and corners
  • Steel provides the necessary strength and
    flexibility of size and application

23
Designing For Reliability
  • Steel Poles have been successfully used
  • for over 30 years for the Electric Utility
    industry
  • for over 40 years with the same product in other
    industries (lighting and traffic)
  • Fabrication and Quality systems have evolved to
    keep up with customer demand, technology, and
    increasing Design sophistication

24
Designing Proven by Testing
  • Steel Poles have been tested for as long as Steel
    Poles have been fabricated. But there is a
    difference
  • Steel Poles are tested to Verify Design strength
    is attained as a Minimum
  • wood poles are tested to determine the mean
    rupture strength

25
Designing Proven by Testing
  • Steel Distribution Poles have been tested by
    independent firms (EDM in Fort Collins) and by
    the manufacturers using controlled conditions and
    sophisticated systems.
  • Strength / Buckling tests to verify design
    acceptance for conditions including
  • full tube sections
  • tube sections with many cut holes to verify that
    condition
  • attachment and guy hardware loading
  • All showing the Strength and Reliability of Steel

26
Post Insulator Test On Steel Pole
27
Guy Attachment Test On Steel Pole
28
EPRI Test On 70 Class 2 Steel Pole
29
Testing at EPRI (Class 2) and EDM (Class 3 5)
30
Steel Distribution Poles - The Material of the
Future
31
Steel Distribution Poles - The Material of the
Future
  • In Conclusion
  • Steel Distribution Poles Provide
  • Expected Strength
  • Expected Life
  • Expected Performance in
  • Deflection
  • Handling
  • Field Use
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