Difference between revisions of "751.35 Concrete Pile Cap Integral End Bents"

751.35.1 General

751.35.1.1 Material Properties

Concrete
Class B Concrete (Substructure)	${\displaystyle \,f'_{c}}$	= 3.0 ksi
	${\displaystyle \,n}$	= 10

Class B-1 Concrete (Substructure) may also be used in special cases (See Project Manager). The following equations shall apply to both concrete classes:

Modulus of elasticity,

${\displaystyle E_{c}=33,000\ K_{1}\ (w_{c}^{1.5}){\sqrt {f_{c}^{'}}}}$

Where:

f'_c in ksi

w_c = unit weight of nonreinforced concrete = 0.145 kcf

K₁ = correction factor for source of aggregate

= 1.0 unless determined by physical testing

Modulus of rupture:	For minimum reinforcement,	${\displaystyle \,f_{r}=0.37{\sqrt {f'_{c}}}}$
	For all other calculations,	${\displaystyle \,f_{r}=0.24{\sqrt {f'_{c}}}}$
${\displaystyle \,{\sqrt {f'_{c}}}}$  is in units of ksi

Reinforcing Steel
Minimum yield strength,	${\displaystyle \,f_{y}}$	= 60.0 ksi
Steel modulus of elasticity,	${\displaystyle \,E_{s}}$	= 29000 ksi

751.35.2 Design

751.35.2.1 Limit States and Factors

In general, each component shall satisfy the following equation:

${\displaystyle \,Q=\sum \eta _{i}\gamma _{i}Q_{i}\leq \phi R_{n}=R_{r}}$

Where:

${\displaystyle \,Q}$	= Total factored force effect
${\displaystyle \,Q_{i}}$	= Force effect
${\displaystyle \,\eta _{i}}$	= Load modifier
${\displaystyle \,\gamma _{i}}$	= Load factor
${\displaystyle \,\phi }$	= Resistance factor
${\displaystyle \,R_{n}}$	= Nominal resistance
${\displaystyle \,R_{r}}$	= Factored resistance

Limit States

The following limit states shall be considered for abutment design:

STRENGTH – I

STRENGTH – III

STRENGTH – IV

STRENGTH – V

SERVICE – I

FATIGUE

EXTREME EVENT - II

See LRFD Table 3.4.1-1 and LRFD 3.4.2 for Loads and Load Factors applied at each given limit state.

Resistance factors

STRENGTH limit states, see LRFD 5.5.4.2 and LRFD 6.5.4.2

For all other limit states, ${\displaystyle \,\phi }$ = 1.00

Load Modifiers

751.35.2.2 Loads

Dead Loads

Loads from stringers, girders, etc. shall be applied as concentrated loads applied at the centerline of bearing. Loads from concrete slab spans shall be applied as uniformly distributed loads.

Live Loads

Loads from stringers, girders, etc. shall be applied as concentrated loads applied at the centerline of bearing. Dynamic load allowance (impact) should be included for the design of the beam. No dynamic load allowance should be included for foundation design.

For wings with detached wing walls, no portion of the bridge live load shall be distributed to the detached wall. The detached wing wall shall be designed as a retaining wall. The weight of the safety barrier curb on top of the wall shall be included in the dead load.

Collision

Collision shall be designed if abutments are located within a distance of 30.0 feet to the edge of roadway, or within a distance of 50.0 feet to the centerline of a railway track and conditions do not qualify for exemptions given in EPG 751.2.2.6.

751.35.2.3 General Design Assumptions

Beam

The beam shall be assumed continuous over supports at centerline of piles.

One half of the dead load of the approach slab shall be included in the beam design.

Wing

The standard horizontal reinforcement shown below was designed for soil pressure, EH, live load surcharge, LS and a railing collision force, CT for Extreme Limit State II Load Combination.

The minimum steel placed horizontally in wings shall be as shown in the figure below.

751.35.2.4 End Bent Analysis

The following steps shall be used to design integral end bents.

Step 1 – Obtain loads from superstructure

The live load reactions (LL), dead load of structural components (DC), and dead load of future wearing surface (DW) will be needed to design the end bents. Strength I Load Combination will be used to design the reinforcement.

Step 2 – Design bearing pads or girder chairs

From the loads obtained in Step 1, design the bearing pads or girder chairs according to EPG 751.11.

Step 3 – Find beam cap width

The standard beam cap width will be 3’-0”. However, if the bearing pad size required exceeds the allowable edge distance, the beam cap width may be widened. The bearing pads shall be centered over the centerline of pile location, which is 15” away from the stream or crossing face of the cap.

Step 4 – Design longitudinal steel in beam cap

If the centerline of bearing is 12” or less on the centerline of piles, use 4 - #6 bars at the top and bottom of the beam cap. Otherwise, the ultimate moment used for designing the longitudinal steel shall be approximated by the following equation and figure. The loads shall be factored according to the Strength I Load Combination.

${\displaystyle \,M_{u}=0.2R_{u}L+0.13WL^{2}}$

Where:

${\displaystyle \,R_{u}}$	= maximum interior girder reaction of factored superstructure loads, kips.
${\displaystyle \,L}$	= pile spacing, ft.
${\displaystyle \,W}$	= factored substructure loads equally distributed across the beam, k/ft.

File:751.35 basic assumption for beam analysis.gif

Basic Assumption for Beam Analysis

A minimum of 4 - #6 Bars shall be used for the longitudinal steel in the beam cap. If more steel is required, increase bar size and keep the number of bars to 4. For example, use 4 - #7 bars instead of 5 - #6 bars.

The minimum reinforcement and bar spacing shall also be checked against the appropriate limits.

Step 5 – Design for number and size of pile

751.35.2.5 Beam Reinforcement Special Cases

SPECIAL CASE I

If centerline bearing is 12" or less on either side of centerline piles, for all piles (as shown below), use 4-#6 top and bottom and #4 at 12" cts. (stirrups), regardless of pile size.

SPECIAL CASE II

When beam reinforcement is to be designed assuming piles to take equal force, design for negative moment in the beam over the interior piles.

751.35.3 Dimensions

751.35.3.1 Front Sheet

751.35.3.2 Wing Brace

The wing brace dimensions will only vary on the wing with obtuse angle. Wing brace dimensions shown are minimum dimensions. The wing brace with the acute angle will always be 18" minimum.

751.35.3.3 Prestressed Girder End Bent

Section Near Wing	Section A-A

Detail of Keyed Const. Jt.

Elevation
Plan (Squared)
Plan (Skewed)

751.35.3.4 Steel Girder or Beam End Bent

Section Near Wing	Section A-A

Detail of Keyed Const. Jt.

Elevation
Plan (Squared)
Plan (Skewed)

751.35.3.5 Wing & Detached Wing Walls

Section A-A	Detail "C"
Detail "B"	Section D-D

751.35.4 Reinforcement

751.35.4.1 Wide Flange Beams & Plate Girders

Part Section Near End Bent
Section A-A	Section B-B	Section C-C
	Place all U bars and V pairs parallel to centerline roadway. File:751.35 circled 1.gif #6 U-bar File:751.35 wide flange and plate girders--6-u-bar.gif at 9" centers between barrier curbs. File:751.35 circled 2.gif U4 bars 13px and #6-U5 bars File:751.35 wide flange and plate girders--6-u-bar.gif placed with U1 and V1 bars. U4 bars shall be same size as U1 bars. File:751.35 circled 3.gif U1 bars File:751.35 wide flange and plate girders-u1-bar.gif at 12" centers. #5 bars, except special cases. Replace with pairs of #5-V1 bars at piles. File:751.35 circled 4.gif Stirrups shall clear step by 1 1/2" min., if not lengthen step or skew step. File:751.35 circled 5.gif #6-V-bars at no more than 9” centers at the end of girders or beams. File:751.35 circled 6.gif #5-H-bars at 12" centers placed parallel to centerline roadway, 2'-6" long with 15” embedment. File:751.35 circled 7.gif See tables for 1 1/16" round hole spacing for #6-H bars. File:751.35 circled 8.gif Same number of bars as 1 1/16" round holes in beam or girder.
Section D-D

Instructions:

Keep 1 1/2" clearance between the piles and the U1 or U2 bars.

Keep 1 1/2" clearance between the beams or girders and the U1 or V1 bars.

Keep 1 1/2" clearance between the angles of beam/girder chairs and the U2 or U3 bars.

Replace U1 bars with U3 bars at piles under beams or girders.

Replace U1 bars with V1 bars at piles between beams or girders.

See EPG 751.50 G1 Concrete Bents for appropriate notes to be placed with details.

751.35.4.2 Prestressed I-Girders

Part Section Near End Bent
Section A-A	Section B-B	Section C-C
	Place U1, U2, U3, U4, and V1 bars parallel to centerline roadway. File:751.35 circled 1.gif #6 U-bars File:751.35 wide flange and plate girders--6-u-bar.gif (horiz. leg placed parallel to centerline roadway) and #6 V-bar at 9" cts. min. (between barrier curbs). File:751.35 circled 2.gif #5-U4 bars at 12" cts. 13px - spaced with U1 and V1 bars. File:751.35 circled 3.gif U1 bars at 12" cts. File:751.35 wide flange and plate girders-u1-bar.gif - spaced between piles and girders. #5 bars, except special cases. File:751.35 circled 4.gif By design - development length (top bars) min. File:751.35 circled 6.gif #5 bars, 2'-6" long, spaced at abt. 12" cts. placed parallel to centerline roadway.
Section D-D

Instructions:

Keep 1 1/2" clearance between the piles and the U1 or U2 bars.

Keep 1 1/2" clearance between the angles of girder chairs and the U2 or U3 bars.

Replace U1 bars with U3 bars at piles under the girders.

Replace U1 bars with V1 bars at piles between the girders.

See Office Notes for appropriate notes to be placed with details.

751.35.4.3 Wide Flange Beams, Plate Girders & Prestressed I-Girders

Prestressed I-girders shown in the following details, steel structures are similar.

Elevation of Wing	Part Section Thru Wing

Section A-A (Square) (K bars not shown for clarity)	Part Section Thru End of Wing

Part Plan - Skewed End Bent

Section Thru Square End Bent (between piles and girders or beams)	Section Thru Skewed End Bent (between piles and girders or beams)
File:751.35 circled 1.gif	Use same as bottom reinforcement.
File:751.35 circled 2.gif	Use construction joint on steel structures only.
Plan Square End Bent	Plan Skewed End Bent

751.35.5 Details

751.35.5.1 Reinforcing Holes

Reinforcing Holes for Wide Flange Beams

	File:751.35 details-section a-a.gif
Section at End of Stringer	Section A-A

Reinforcing Holes for Plate Girders

Section at End of Girder

751.35.5.2 Vertical Drains

Elevation at End Bent
Section A-A	Detail "B"
Detail "C"	Elevation of Wing

Elevation of Wing	Part Plan
Optional Bent Drain (*)
(*) Only if rock is encountered at outside of wings.