Publication 242 Pavement Policy Manual Pavement Type ... · The pilot period will extend six months at ... projects in ECMS as an unofficial plan set for a three ... Life Cycle Cost

482-14-21 DATE: June 25, 2014

SUBJECT: Publication 242

Pavement Policy Manual Chapter 11 Pilot Pavement Type Determination TO: District Executives FROM: R. Scott Christie, P.E. /s/ Brian Thompson, P.E. Deputy Secretary for Highway Administration This is a time and cost neutral activity. The intent of this Strike-off Letter is to establish, as pilot policy, updated requirements related to Life Cycle Cost Analyses (LCCA) and Alternate Pavement Type Bidding. The pilot period will extend six months at which time the alternate bidding process and LCCA will be evaluated for full implementation or potential extension of the pilot period. The attached policy in Publication 242, Chapter 11 – Pavement Type Determination has been rewritten to reflect the proposed changes for this pilot. The attached Chapter will apply to all projects requiring an LCCA during the evaluation period. The key components of the pilot policy include:

• Maintenance strategies for LCCA were revised to allow for equal 50-year Pavement Life (Analysis Period) for both bituminous and concrete pavement types with no residual life discount. The Residual Life Discount for treatments that extend pavement life beyond the analysis period is no longer used or needed.

• Sharing Pavement Designs and LCCA’s

o Within six months of Design Field View (DFV), the District will post the

pavement design package and LCCA for alternate pavement type bidding projects in ECMS as an unofficial plan set for a three-week review and comment period.

o Alternate Pavement Type Bidding projects will be identified in ECMS on

the “Planned Six-Month Letting Schedule,” which will be updated monthly.

• Alternate Bidding projects may be advertised in one of three ways:

1. The project is identified as a Design/Build project. Publication 448, Innovative Bidding ToolKit, is followed for project development. The District develops the

Bureau of Project Delivery | Administration | 400 North Street, Harrisburg, PA 17120 | 717-787-5023

(SOL 482-21) Page 2

LCCA and C-factor for the various alternates in the bid package. 2. Plans, Cross Sections, and Drainage Excavation shall be developed for the deepest

pavement type alternative. The intention is to minimize the design effort on the part of the District while designing drainage to accommodate all alternate pavement types in the bid package. This is also intended to minimize any additional design effort needed on the part of the contractor developing a bid on a pavement alternate. Typical Sections are provided for all pavement alternatives in the bid package. Item Numbers and quantities for all alternate pavement materials in the bid package are provided in the bid package and are provided in ECMS. Traffic Control Plans (TCP) shall be developed as per the normal project development processes. TCPs shall be fully developed for the worst case scenario in terms of the area of any necessary Temporary Construction Easements.

3. Plans, cross-sections, typical sections, item numbers, quantities, and traffic control plans are fully developed for all pavement alternates in the bid package. This option should only be utilized if it can be done in a cost-effective manner.

• Special Provisions

o The Standard Special Provision “Item Life Cycle Cost Analysis, C-Factor” has been revised in accordance with the policy and includes a reference to the Standard Special Provision “Price Adjustment of Bituminous Materials (Alternate Bid)”.

The Price Adjustment for Bituminous Materials is different for alternate bid

projects than for standard projects. The special provision includes a graduated scale according to the duration of the construction project and is required in all pavement type alternate bid projects.

The pilot policy and procedures outlined herein are effective immediately. After the six- month pilot period, the alternate bidding process and LCCA policy will be re-evaluated. If you require any additional information, please contact Lydia E. Peddicord, P.E., Chief, Pavement Design and Analysis Unit, at 717-787-4246. Attachment


(SOL 482-21) Page 3 4822/LEP/ses/sol4821409 cc: R. Sigel, FHWA B. J. Heigle, P.E., PTC G. L. Hoffman, P.E., PAPA J. M. Becker, P.E., ACPA E. G. Madden, ACEC ADEs, Design R. Scott Christie, P.E., 8th Floor, CKB Highway Administration Bureau Directors Project Delivery Division Chiefs B. A. Kendro, 8th Floor, CKB S. L. Koser, P.E., 7th Floor, CKB D. J. Azzato, P.E., 7th Floor, CKB L. E. Peddicord, P.E., 7th Floor, CKB J. T. Freeman, 7th Floor, CKB P. R. Grace, 8th Floor, CKB W. L. Sneeringer, 7th Floor, CKB File


Publication 242, Chapter 11 SOL 482-14-21 Attachment

CHAPTER 11 PAVEMENT TYPE DETERMINATION

11.1 PAVEMENT TYPE SELECTION FACTORS

A highway system designation shall not determine the choice of pavement type. The following factors should be considered when choosing a pavement type:

Economics – Pavement type determination can be influenced by the results of an Engineering Economic analysis (e.g., a Life-Cycle Cost Analysis) on the cost of construction and future maintenance. Life Cycle Cost Analysis - LCCA is used to compare the relative long-term costs of different pavement alternatives. LCCA allows the Department to objectively evaluate costs of two or more rehabilitation and/or new/reconstruction alternatives that may have significantly different initial costs and require very different levels of future preventive maintenance expenditures. Alternate Bidding – Pavement type may be determined through Alternate Bidding as described in Section 11.6. Alternate Bidding is a tool that may be used to stimulate competition in the paving market. Performance of Similar Pavement in the Area – Knowing how a particular design type performed in the past is a valuable guide in predicting future performance. However, there must be a good correlation between conditions and service requirements of the reference pavements and the designs under study. Caution is urged against relying on performance records of reference pavements subjected to much lighter loadings for a large portion of their service life. Caution is also urged when considering the performance of pavements containing materials and/or design features that are no longer commonly used or expected to be used. Reference pavements should be re-analyzed periodically. Adjacent Existing Pavements – The choice of pavement type may be influenced by the pavement types of adjacent sections that have similar conditions to the project and that have provided adequate long-term service. Municipal Preference, Participating Local Government Preference – While these considerations seem outside the realm of the highway engineer, the highway administrator cannot ignore them. Construction Considerations – Various construction considerations may influence the pavement type selection:

• Seasonal construction constraints • Reduction of maintenance and protection of traffic during construction • Need for reduced future maintenance in highly congested locations • Economic impact on local businesses due to duration of construction project

Grades, Curvature and Unusual Loadings – Slow-moving vehicles starting and stopping on steep grades and unusual loadings may affect the pavement type selection.

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The recommended pavement structure, chosen after careful consideration of the above factors, will be designated on Form D-4332. Any supporting documentation for the type selection must be included with the copies of Form D-4332 submitted to the Highway Design and Technology Section (HDTS) of the Bureau of Project Delivery.

11.2 LIFE-CYCLE COST ANALYSIS GUIDELINES The policies and methodologies outlined in this Chapter define when a Life-Cycle Cost Analysis (LCCA) must be completed and how to perform the analysis. The HDTS shall review and update (if necessary) the policies and processes every two years, in order to keep up with and reflect the latest innovations, technology developments and costs in the fields of pavement design, construction, maintenance and materials. Stakeholders (including industry) should participate in these reviews.

A LCCA must be submitted to the HDTS for all new construction, reconstruction or rehabilitation projects with at least 30,000 square yards of mainline pavement, including shoulders, regardless of roadway network or funding source.

Structural pavement designs are performed for each pavement type alternative. A LCCA

is performed to analyze which pavement structure is most cost-effective over an equivalent specified analysis period. Each pavement type alternative is assumed to have an equivalent performing pavement structure throughout the analysis period. It is important that all practical alternatives are considered when performing a LCCA for these projects, from rehabilitation with either a bituminous or concrete structural overlay to total reconstruction with either pavement type. Justification must be provided when an alternate is not practical and is excluded from the LCCA.

The current LCCA Excel spreadsheet can be downloaded from:

http://www.dot.state.pa.us/Internet/Bureaus/pdBOMO.nsf/LCCA?OpenForm The total Present Worth costs (Initial Construction + Maintenance Activities + User

Delay) of all design alternatives are to be compared and all alternates must have the same analysis period.

Perform the LCCA without factoring inflation. A Discount Rate shall be applied to all future maintenance and user delay costs within the analysis period. The Discount Rate is the five-year rolling average of the annual 30-Year Real Interest Rate on Treasury Notes and Bonds posted by Executive Office of the President, Office of Management and Budget (OMB) Circular A-94. HDTS will provide the updated Discount Rate to all District PMEs each January, based on the information posted at:

http://www.whitehouse.gov/omb/circulars_a094/a94_appx-c/

The cost of all bituminous items, adjusted as per Publication 408 Section 110.04, Price

Adjustment of Bituminous Materials, will be factored by the provided Asphalt Adjustment Multiplier (AAM). The AAM is to be applied to bituminous costs for both initial construction

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http://www.dot.state.pa.us/Internet/Bureaus/pdBOMO.nsf/LCCA?OpenForm

http://www.whitehouse.gov/omb/circulars_a094/a94_appx-c/

Publication 242, Chapter 11 SOL 482-14-21 Attachment and future maintenance in the LCCA so as to more accurately estimate the most current unit price of bituminous materials at the time of project bidding.

The AAM will be calculated semiannually based on the total of bituminous payments

made over the preceding twelve months and bituminous price adjustments applied to those payments. To further clarify, the following equation will be used:

AAM = 1 + Adjustments / Total of Bituminous Payments.

The AAM will be updated and provided to all District Pavement Management Engineers

by the HDTS semiannually during the first week of each July and January.

Construction Items

The pavement items quantity estimates for each alternative will be based on the actual typical cross section used for the project (e.g. wearing, binder, base, and subbase; or PCCP, treated base, and subbase).

The differences in costs for pavement-related items (e.g., pavement relief joints, and

approach slabs) must be included in the LCCA when calculating initial costs. Only the differences in these items quantities between alternatives shall be included in the LCCA; do not include the total item quantity for each alternative.

The differences in costs for earthwork items must be included in the LCCA when calculating initial costs. To determine the subgrade and excavation quantities, the estimated percentage of the project in total cut, total fill, and cut and fill shall be determined for each alternative. Only the differences in earthwork quantities between alternatives shall be included in the LCCA; do not include the total earthwork quantity for each alternative. Resurfacing

When calculating the total cost for resurfacing alternatives, include the cost of pavement resurfacing, shoulder modifications, necessary pavement patching, drainage and guide rail adjustments, maintenance and protection of traffic, etc.

For LCCA purposes, the first bituminous overlay for rigid pavements (not including

scratch or leveling courses) shall be 4" thick when 9.5 mm Wearing Course mix is used or 4.5" thick when 12.5 mm Wearing Course mix is used. All resurfacing of flexible pavements shall be 1.5" thick when 9.5 mm Wearing Course mix is used or 2" thick when 12.5 mm Wearing Course mix is used.

Shoulders

The LCCA must account for shoulder construction and maintenance. The shoulder type must match the mainline pavement type.

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Publication 242, Chapter 11 SOL 482-14-21 Attachment Miscellaneous

Engineering and mobilization costs must not be included in the LCCA. Regarding initial costs for non-pavement items, such as drainage, guiderail, utility

relocations, etc., only the differences between alternatives for these items shall be included in the LCCA. Do not include the total item quantity in each alternative.

Type Determination

Any of the following will be sufficient to conclusively determine the pavement type although alternate bidding is still permissible:

1. A difference of 10% or more in life-cycle cost, excluding user delay costs (to compare agency costs only). 2. A difference of 20% or more in life-cycle cost, including user delay costs (to account for impacts to the roadway user). 3. The District Pavement Type Selection Committee may provide justification for a single pavement type selection after consideration of regional factors such as: engineering judgment*, adjacent pavement types and performance, subgrade composition and condition, local materials, right-of-way constraints, maintenance and protection of traffic or utility impacts. The FHWA Technical Advisory “Use of Alternate Bidding for Pavement Type Selection” and NCHRP Report 703 “Guide for Pavement-Type Selection” shall be used as guides to the District Pavement Type Selection Committee. Projects with substantial non-pavement items may not be good candidates for alternate bidding. The LCCA, meeting minutes, and conclusions shall be recorded and included in the pavement design package to be submitted for HDTS approval. The composition of the District Pavement Type Selection Committee is at the discretion of the District Executive. *Engineering judgment should not be an opinion or preference. It must be a unique, extraordinary circumstance that would compel the Department and FHWA to support a more costly alternative. It must be fact-based and defendable to the public and both industries. In all other cases, Alternate Pavement Type Bidding (Section 11.6) must be applied to

determine pavement type. The impact of constructability/phasing issues and/or maintenance and protection of traffic constraints should be reflected by varying Initial Construction Costs, User Delay Costs, and/or Maintenance and Protection of Traffic Costs, and not considered separately.

If a LCCA is performed more than three (3) years prior to project letting, it must be

updated to reflect current prices, traffic data, Discount Rate, Construction Cost Index and any changes to the pavement design. For Alternate Bidding, the LCCA must be performed, or updated, within six months of project letting. Updated LCCA documents must be submitted to HDTS with changes indicated in red font, even if the previous LCCA has been approved by HDTS. Documentation supporting the changes must also be submitted.

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Upon approval of a LCCA and pavement type selection, pavement type shall not be changed, whether the project is in design or construction status, unless approved by the HDTS. 11.3 GUIDELINES FOR DEVELOPING INITIAL COSTS

The following guidelines shall be used to develop initial costs for each particular rehabilitation strategy. Adjust these guidelines to include any items that may occur on a particular project that would affect the initial cost of a particular rehabilitation strategy.

11.3.1 Bituminous Rehabilitation Strategies Bituminous Overlay 1. Design according to Chapter 10. 2. Patching based on actual field measurements. The quantity shall anticipate additional deterioration that will occur between the time of the design field view and the actual construction of the project. Replace concrete pavement with concrete (as per Section 4.2) and bituminous pavement with matching depths of like bituminous courses. 3. Slab stabilization where necessary to restore support to the existing concrete pavement. 4. Bituminous tack coat, if necessary. 5. Continuous pavement base drain. Replace as appropriate. 6. Longitudinal and transverse joint cleaning and sealing of concrete pavements. Asphalt joint and crack sealing on bituminous pavements. Use of heavy-duty membranes, as necessary. Sawing and sealing of bituminous overlays on concrete or on existing sawed and sealed bituminous. 7. Type 6 or Type 7 paved shoulders as applicable. 8. Sawing and sealing the overlay over existing transverse and patch joints. 9. Adjusting or replacing existing guide rail and drainage structures as necessary. Bituminous Overlay on Crack and Seated Concrete 1. Cracking and seating the existing concrete pavement. 2. Base repair with Base Course/Superpave Base Course. 3. Continuous pavement base drain. 4. Leveling course (1 inch minimum), includes cross-slope correction. 5. Bituminous overlay (thickness as required by design).

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Publication 242, Chapter 11 SOL 482-14-21 Attachment 6. Full-depth bituminous shoulders. 7. Resetting and/or replacing guide rail and drainage structures, as necessary. Bituminous Overlay on Rubblization 1. Rubblizing and seating the existing concrete pavement. 2. Base repair with AASHTO #1 aggregate, as necessary. 3. Continuous pavement base drain. 4. Leveling course (1 inch minimum), includes cross-slope correction. 5. Bituminous thickness, as required by design. 6. Full-depth bituminous shoulders. 7. Resetting and/or replacing guide rail and drainage structures, as necessary. Bituminous Reconstruction – Remove and Replace 1. Design according to Chapter 9. 2. Undercutting and replacement of subgrade, if necessary. 3. Continuous pavement base drain. 11.3.2 Concrete Rehabilitation Strategies Concrete Pavement Rehabilitation 1. Patching and spall repair based on actual field measurements and/or deflection tests. The quantity shall anticipate additional deterioration that will occur between the time of the design field view and the actual construction of the project. 2. Slab stabilization, as required, to restore full support to the pavement around patches and at other locations. 3. Slabjacking as required. 4. Diamond grinding to improve ride quality as per Publication 408, Section 514, with the exception of concrete pavements constructed with Vanport Limestone aggregate. An ultra-thin friction course may be used on concrete pavements constructed with any aggregate susceptible to rapid polishing. (Data has shown that grinding a concrete surface removes the effective mortar layer on the pavement and the skid resistance of the exposed Vanport Limestone is susceptible to rapid decline.)

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Publication 242, Chapter 11 SOL 482-14-21 Attachment 5. Continuous pavement base drain. 6. Rehabilitation of all failed transverse joints, if not previously performed. Otherwise, cleaning and resealing of all joints. 7. Cleaning and sealing all longitudinal joints and pavement/shoulder joints. 8. Adjusting or replacing guide rail and drainage structures, as necessary. 9. Dowel bar retrofit at mid-panel cracks and transverse joints. Concrete Overlays – Bonded and Unbonded

1. Design in accordance with Chapter 10. 2. Rehabilitation of all failed transverse joints. 3. Concrete pavement patching based on actual field measurements. 4. Slab stabilization around patches and where necessary to restore uniform support. 5. Cleaning and sealing all existing joints, if unbonded overlay. 6. Continuous pavement base drain. 7. Concrete shoulders required if existing shoulders are concrete, otherwise, may match existing shoulder type. 8. Leveling course, if needed, and bond breaker to be included, if unbonded design. 9. Adjusting or replacing all guide rail and drainage structures, as necessary. 10. Fill widening to retain proper shoulder widths, and checking bridge underclearances. Concrete Overlay - Unbonded – Crack and Seat 1. Cracking and seating existing concrete pavement. 2. Base repair with HMA Base Course/Superpave Base Course, as necessary. 3. Continuous pavement base drain. 4. Leveling course and bond breaker includes cross-slope correction. 5. Unbonded concrete overlay, as designed using the procedure in Chapter10.

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Publication 242, Chapter 11 SOL 482-14-21 Attachment 6. Concrete shoulders required if existing shoulders are concrete, otherwise, may match existing shoulder type. 7. Resetting and/or replacing guide rail and drainage structures, as necessary. 8. Fill widening to retain proper shoulder widths, and checking bridge underclearances. Concrete Reconstruction on Rubblization 1. Rubblizing and seating existing concrete pavement. 2. Base repair with AASHTO #1 aggregate, as necessary. 3. Continuous pavement base drain. 4. Leveling course and bond breaker includes cross-slope correction. 5. Concrete thickness, as required by design. 6. Concrete shoulders. 7. Resetting and/or replacing guide rail and drainage structures, as necessary. 8. Fill widening to retain proper shoulder widths, and checking bridge underclearances. Concrete Reconstruction – Remove and Replace 1. Design according to Chapter 8.

2. Undercutting and replacement of subgrade, if necessary.

3. Continuous pavement base drain. 11.4 MAINTENANCE STRATEGIES FOR LIFE-CYCLE COST ANALYSIS (LCCA) 11.4.1 Bituminous New Construction or Reconstruction (including construction on fractured concrete pavement) – 50 Year Pavement Life (Analysis Period) 5 years Clean and Seal, 25% of longitudinal joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders, if Type 1, 1S, 3, 4, 6 or 6S Maintenance and Protection of Traffic User Delay 10 years Clean and Seal, 25% of longitudinal joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay

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Publication 242, Chapter 11 SOL 482-14-21 Attachment 15 years Full Depth Patching, 2% of pavement area Mill wearing course Bituminous Inlay, 1.5” or 2.0” Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 20 years Clean and Seal, 25% of longitudinal joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 25 years Full Depth Patching, 4% of pavement area Mill wearing course Bituminous Inlay, 1.5” or 2.0” Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 30 years Clean and Seal, 25% of longitudinal joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 35 years Full Depth Patching, 4% of pavement area Scratch Course, 60 PSY Bituminous Overlay, 1.5” or 2.0” Type 7 Paved Shoulders Adjust guide rail and drainage structures, if necessary Maintenance and Protection of Traffic User Delay 40 years Clean and Seal, 25% of longitudinal joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 45 years Clean and Seal, 25% of longitudinal joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface roadway and shoulders Partial Depth Asphalt Surface Patching, 2% of pavement area Maintenance and Protection of Traffic User Delay

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Publication 242, Chapter 11 SOL 482-14-21 Attachment 11.4.2 Concrete New Construction, Reconstruction (including construction on fractured concrete pavement), Unbonded Concrete Overlay – 50 Year Pavement Life (Analysis Period) 10 years Clean and Seal, 25% of longitudinal joints including shoulders Clean and Seal, 25% of transverse joints Maintenance and Protection of Traffic User Delay 15 years Concrete Patching, 2% of pavement area Diamond Grinding, 50% of pavement area Clean and Seal, all longitudinal joints including shoulders Clean and Seal, all transverse joints Maintenance and Protection of Traffic User Delay 25 years Concrete Patching, 4% of pavement area Diamond Grinding, 100% of pavement area (full width) Clean and Seal, all longitudinal joints including shoulders Clean and Seal, all transverse joints Maintenance and Protection of Traffic User Delay 35 years Concrete Patching, 6% of pavement area Clean and Seal, all longitudinal joints including shoulders Clean and Seal, all transverse joints Scratch Course, 60 PSY Bituminous Overlay, 4” or 4.5” Saw and Seal, all transverse joints Type 7 Paved Shoulders Adjust guide rail and drainage structures, if necessary Maintenance and Protection of Traffic User Delay 40 years Clean and Seal, 25% of longitudinal joints Clean and Seal, 25% of transverse joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 45 years Crack Seal, 500 lineal feet per mile Partial Depth Asphalt Surface Patching, 2% of pavement area Clean and Seal, 25% of all longitudinal joints, including shoulders Clean and Seal, 25% of all transverse joints Micro Surface roadway Maintenance and Protection of Traffic

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Publication 242, Chapter 11 SOL 482-14-21 Attachment User Delay 11.4.3 Bonded Concrete Overlay – 30 Year Pavement Life (Analysis Period) 5 years Clean and Seal, 25% of longitudinal joints including shoulders Clean and Seal, 25% of transverse joints Seal Coat or Micro Surface shoulders, if bituminous Maintenance and Protection of Traffic User Delay 10 years Concrete Patching, 5% of pavement area Diamond Grinding, 50% of pavement area Clean and Seal, 25% of longitudinal joints including shoulders Clean & Seal, 25% of transverse joints Seal Coat or Micro Surface shoulders, if bituminous Maintenance and Protection of Traffic User Delay 15 years Clean and Seal, 25% of longitudinal joints including shoulders Clean and Seal, 25% of transverse joints Seal Coat or Micro Surface shoulders, if bituminous Maintenance and Protection of Traffic User Delay 20 years Concrete Patching, 8% of pavement area Clean and Seal, all longitudinal joints including shoulders Clean and Seal, all transverse joints Scratch Course, 60 PSY Bituminous Overlay, 4" or 4.5" Saw and Seal, all transverse joints Type 7 Paved Shoulders Adjust guide rail and drainage structures, if necessary Maintenance and Protection of Traffic User Delay 25 years Clean and Seal, 25% of sawed and sealed joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 11.4.4 Concrete Pavement Rehabilitation (CPR) & Bituminous Overlay – 30 Year Pavement Life (Analysis Period) 10 years Mill Wearing Course Bituminous Inlay, 1.5" or 2.0" Saw & Seal, all transverse joints Seal Coat or Micro Surface shoulders, if Type 1, 1S, 3, 4, 6 or 6S

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Publication 242, Chapter 11 SOL 482-14-21 Attachment Maintenance and Protection of Traffic User Delay 15 years Clean & Seal, 25% of sawed & sealed joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders, if Type 1, 1S, 3, 4, 6 or 6S Maintenance and Protection of Traffic User Delay 20 years Concrete Patching, 2% of pavement area Scratch Course, 60 PSY Bituminous Overlay, 1.5" or 2.0" Saw & Seal, all transverse joints Type 7 Paved Shoulders Adjust guide rail and drainage structures, if necessary Maintenance and Protection of Traffic User Delay 25 years Clean & Seal, 25% of longitudinal and transverse joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 11.4.5 Bituminous Overlay on Bituminous Pavement – 10 Year Pavement Life 5 years Clean and Seal, 25% of longitudinal joints Crack Seal, 500 lineal feet per mile Seal Coat or Micro Surface shoulders, if Type 1, 1S, 3, 4, 6 or 6S Maintenance and Protection of Traffic User Delay 11.4.6 Ultra-Thin Whitetopping on Bituminous Pavements – 10 Year Pavement Life 5 years Clean and Seal, 25% of longitudinal joints including shoulders Clean and Seal, 25% of transverse joints Seal Coat or Micro Surface shoulders Maintenance and Protection of Traffic User Delay 11.5 USER DELAY COSTS

Roadway users incur User Delay Costs while roads are being maintained, repaired or reconstructed. User Delay Costs must be accounted for in the life-cycle cost analysis for each alternate to be compared. These costs must be determined, and included in the LCCA, for each year of each alternate that user delays are incurred, including the year of Initial Construction if the User Delay Costs vary for the alternates due to differences in traffic control and/or project phasing. User Delay Costs are divided into three categories:

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1. Idling Cost (or Speed Reduction Cost)

2. Time Value Costs (for Idling and Stopping)

3. Stopping Cost

If any of these types of user delays are incurred, the number of vehicles affected by the delay must be calculated. The following sections provide an overview of the items that User Delay Costs entail.

11.5.1 Delayed Vehicles

In order to calculate the number of delayed vehicles during an activity in a specific year, the following traffic information is required:

1. Initial ADT, Design Year, and Design Year ADT

2. Composition of the traffic mix by vehicle class (i.e., cars, single unit trucks, combination trucks)

3. Directional Factor

4. Total Days of the Activity From this information, the following items must then be calculated:

• Traffic Growth Factor • ADT in each Activity Year • ADT in each Direction • ADT Delayed in each Direction • Total Number of Vehicles Delayed During the Activity • Total Number of Vehicles Delayed in each vehicle class

11.5.2 Stopped Vehicles

If during construction, the number of lanes that are being maintained is reduced, then the capacity of the facility is affected. If the actual traffic exceeds capacity, then a backup will occur as traffic enters the construction zone. Vehicles will be stopped due to congestion at the restricted area, and Stopping Costs must be determined. To determine the number of vehicle stops, the ADT for the applicable year and the composition of the traffic must be determined, as described for determining Delayed Vehicles. In addition, the following items must be calculated:

1. Hourly breakdown of traffic

2. Roadway Capacity

The hourly breakdown (by percent of the total daily traffic) can be determined by a traffic

study. If a study is not done, Table 11.1 provides hourly percentages of total vehicles based on average values for all roadways in a specific Traffic Pattern Group category.

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Roadway Capacity is determined for one direction, and is dependent on the total number of lanes in that direction under normal operation, and the number of lanes maintained during construction. Figure 6-12 of the Highway Capacity Manual, Special Report 209, by the Transportation Research Board can be used to determine roadway capacity at a desired confidence level. For the purposes of determining the number of stopped vehicles while calculating User Delay Costs, this figure has been simplified as shown in Table 11.2.

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Table 11.1 Hourly Percentages of Total Vehicles *

HOUR TRAFFIC PATTERN GROUP

1 2 3 4 5 6 7 8 9 10

0-1 1.23 1.80 0.83 0.81 0.73 0.80 0.77 0.72 0.80 0.81 1-2 0.90 1.49 0.51 0.54 0.42 0.52 0.47 0.43 0.47 0.50 2-3 0.82 1.38 0.42 0.48 0.34 0.47 0.40 0.35 0.39 0.34 3-4 0.85 1.39 0.45 0.56 0.35 0.52 0.47 0.37 0.42 0.34 4-5 1.13 1.58 0.76 1.00 0.64 0.94 0.90 0.70 0.77 0.59 5-6 2.23 2.29 2.04 2.47 1.84 2.23 2.48 1.96 2.13 1.45 6-7 4.81 3.62 4.74 4.76 4.46 4.30 5.05 4.37 4.68 3.01 7-8 6.58 4.69 6.71 6.10 6.46 5.76 6.32 6.09 6.34 4.79 8-9 5.86 4.83 5.97 5.61 5.80 5.50 5.45 5.61 5.62 5.01

9-10 5.14 5.12 5.12 5.28 4.99 5.38 5.08 5.12 4.96 5.14 10-11 5.11 5.46 5.09 5.39 5.00 5.54 5.17 5.26 4.97 6.47 11-12 5.29 5.67 5.42 5.59 5.45 5.85 5.42 5.60 5.28 5.99 12-13 5.45 5.72 5.72 5.80 5.86 6.07 5.80 5.93 5.62 6.30 13-14 5.52 5.89 5.75 5.99 5.75 6.18 5.73 5.98 5.64 6.39 14-15 6.04 5.27 6.32 6.57 6.34 6.82 6.45 6.56 6.31 6.83 15-16 6.97 6.78 7.34 7.54 7.53 7.82 7.66 7.74 7.60 7.86 16-17 7.46 7.05 7.84 7.91 8.11 8.00 8.11 8.12 8.10 8.51 17-18 7.20 6.50 7.68 7.42 7.93 7.26 7.61 7.69 7.83 8.12 18-19 5.52 5.31 5.93 5.59 6.16 5.58 5.74 6.04 6.16 6.31 19-20 4.35 4.40 4.58 4.32 4.89 4.41 4.47 4.81 4.85 5.23 20-21 3.71 3.92 3.80 3.63 4.07 3.68 3.78 3.97 4.04 4.20 21-22 3.29 3.49 3.16 2.99 3.20 2.88 3.05 3.10 3.22 3.12 22-23 2.59 2.94 2.26 2.14 2.21 2.08 2.17 2.11 2.28 2.20 23-24 1.95 2.41 1.56 1.47 1.45 1.41 1.45 1.37 1.52 1.48

TRAFFIC PATTERN GROUP (TPG) CATEGORIES:

1: Urban Interstate 6: North Rural Minor Arterials 2: Rural Interstate 7: Central Rural Minor Arterials 3: Urban Principal Arterial 8: North Rural Collectors 4: Rural Principal Arterial 9: Central Rural Collectors 5: Urban Minor Arterials or Collectors 10: Special Recreational * From PennDOT, Bureau of Planning and Research, Transportation Planning Division, Pub. 601 "2007 Pennsylvania Traffic Data "Factoring Process: Traffic Adjustment Factors, Table 350.

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Table 11.2 Roadway Capacity *

Number of Lanes (1 direction) Capacity

(veh/hr/lane) Normal

Operation During

Construction 3 1 1000 2 1 1260 5 2 1340 4 2 1430 3 2 1440 4 3 1480

* From Figure 6-12 of the Highway Capacity Manual, Special Report 209, by the Transportation Research Board, based on ninety percent confidence level.

11.5.3 Example Calculations EXAMPLE 1 Urban Interstate Initial ADT (Year 2010) = 30,500 Traffic Breakdown (by vehicle type): Design Year ADT (Year 2030) = 49,978 88% Cars Directional Distribution Factor = 0.50 12% Trucks - 20% Single Unit

- 80 % Combination Traffic Breakdown (by percentage):

HOUR %

VEHICLES HOUR %

VEHICLES HOUR %

VEHICLES 0-1 1.23 8-9 5.86 16-17 7.46 1-2 0.90 9-10 5.14 17-18 7.20 2-3 0.82 10-11 5.11 18-19 5.52 3-4 0.85 11-12 5.29 19-20 4.35 4-5 1.13 12-13 5.45 20-21 3.71 5-6 2.23 13-14 5.52 21-22 3.29 6-7 4.81 14-15 6.04 22-23 2.59 7-8 6.58 15-16 6.97 23-24 1.95

Under normal conditions, the roadway has two lanes in each direction. Calculate the

number of delayed and stopped vehicles in each class during the maintenance activities in Year 15 (2025) if one lane will be maintained in one direction as follows:

1) Traffic Growth Factor = (49,978 / 30,500)[1/20] = 1.025 2) Percent of Daily Vehicles Delayed = 100

(Lanes will remain closed all day, and traffic in both directions is affected)

3) ADT in Year 2025 = 30,500 x 1.0 x (1.025)[15] = 44,173

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4) ADT in One Direction = 44,173 x 0.50 = 22,087 (Since the Directional Distribution Factor equals 0.50, the ADT is the same in both directions.)

5) ADT in One Direction for each Hour:

HOUR VEHICLES HOUR VEHICLES HOUR VEHICLES 0-1 272 8-9 1,294 16-17 1,648 1-2 199 9-10 1,135 17-18 1,590 2-3 181 10-11 1,129 18-19 1,219 3-4 188 11-12 1,168 19-20 961 4-5 250 12-13 1,204 20-21 819 5-6 493 13-14 1,219 21-22 727 6-7 1,062 14-15 1,334 22-23 572 7-8 1,453 15-16 1,539 23-24 431

6) Roadway Capacity in One Direction = 1260 veh/hr (From Table 11.2, one lane open in each direction) (Note that the hour from 7:00 am to 8:00 am is the first hour of the day that capacity

is exceeded.) 7) Number of Vehicle Stops in One Direction:

Number of Hourly Vehicle Stops in One Direction = (Hourly % of Vehicles) x (ADT in One Direction) - (Roadway Capacity in One Direction) + (Previous Hour's Queue)

Since the Directional Distribution Factor and the lane configuration is the same in both

directions, the Roadway Capacity and the Number of Hourly Vehicle Stops in both directions is the same.

HOUR VEHICLES HOUR VEHICLES HOUR VEHICLES

0-1 0 8-9 227 16-17 741 1-2 0 9-10 102 17-18 1,071 2-3 0 10-11 0 18-19 1,030 3-4 0 11-12 0 19-20 731 4-5 0 12-13 0 20-21 290 5-6 0 13-14 0 21-22 0 6-7 0 14-15 74 22-23 0 7-8 193 15-16 353 23-24 0

Total = 4,812 vehicles/day

8) Total Number of Stopped Vehicles = 4,812 x 2 = 9,624 vehicles/day (Conditions are the same in both directions) 9) Total Number of Vehicles Delayed During Activity = 22,087 x 2 = 44,174

vehicles/day in both directions 11-17


10) Total Number of Vehicle Stops During Activity = 4,812 x 2 = 9,624 vehicles/day in both directions

11) Vehicles Delayed by Class: Cars: 44,174 x 0.88 = 38,873 S.U. Trucks: 44,174 x 0.12 x 0.20 = 1,060 Comb. Trucks: 44,174 x 0.12 x 0.80 = 4,241 12) Vehicle Stops by Class: Cars: 9,624 x 0.88 = 8,469 S.U. Trucks: 9,624 x 0.12 x 0.20 = 231 Comb. Trucks: 9,624 x 0.12 x 0.80 = 924

EXAMPLE 2

All of the same conditions as Example 1, except one lane in each direction will be closed only during the hours of 8:00 am to 4:00 pm (8 hours):

1) Percent of Daily Vehicles Delayed = 45.7 (Sum of the Hourly Percentages of Total Traffic for the hours of lane closure.) 2) ADT Delayed in One Direction = 22,087 x 0.457 = 10,094 (Since the Distribution Factor equals 0.50, the ADT is the same in both directions.) 3) Number of Hourly Vehicle Stops in One Direction:

HOUR VEHICLES HOUR VEHICLES HOUR VEHICLES

0-1 0 8-9 34 16-17 0 1-2 0 9-10 0 17-18 0 2-3 0 10-11 0 18-19 0 3-4 0 11-12 0 19-20 0 4-5 0 12-13 0 20-21 0 5-6 0 13-14 0 21-22 0 6-7 0 14-15 74 22-23 0 7-8 0 15-16 353 23-24 0

Total = 461 vehicles

8) Total Number of Stopped Vehicles = 461 x 2 = 922vehicles (Conditions are the same in both directions) 9) Total Number of Vehicles Delayed During Activity = 10,094 x 2 = 20,188

vehicles/day in both directions 10) Total Number of Vehicle Stops During Activity = 461 x 2 = 922 vehicles/day in

both directions 11-18


11) Vehicles Delayed by Class: Cars: 20,188 x 0.88 = 17,765 S.U. Trucks: 20,188 x 0.12 x 0.20 = 485 Comb. Trucks: 20,188 x 0.12 x 0.80 = 1,938 12) Vehicle Stops by Class: Cars: 922 x 0.88 = 811 S.U. Trucks: 922 x 0.12 x 0.20 = 22 Comb. Trucks: 922 x 0.12 x 0.80 = 89

11.5.4 Added Time

Due to the reduced speeds, travel time is increased for all vehicles that pass through a construction zone. This added time must be determined in order to calculate User Delay Costs. The added time may be dependent on the traffic control pattern to be implemented (i.e., high-speed crossovers, detours, etc.).

For each traffic control pattern to be implemented during the life-cycle, the following

information must be known:

1. Restricted Flow Length

2. Initial and Reduced Speeds

The following items must then be calculated:

1. Restricted Flow Time

2. Overall Increased Travel Time

The Restricted Flow Length is the length of roadway for which a speed reduction or lane closure is implemented. If traffic is detoured, the detour length is the Restricted Flow Length.

The Restricted Flow Time is the time required to travel through the Restricted Flow

Length. If traffic is detoured, then the Restricted Flow Time equals the time necessary to travel through the Detour Length. Restricted Flow Time is used to determine Idling Costs.

The Overall Increased Travel Time is the difference between the Restricted Flow Time and the time required to travel the same distance at the normal posted speed limit. Overall Increased Travel Time is necessary to compute the Time Value Cost for Idling.

For each traffic control pattern that applies a different Restricted Flow Length, Initial Speed, or Reduced Speed, there is a different Restricted Flow Time and the Overall Increased Travel Time.

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Publication 242, Chapter 11 SOL 482-14-21 Attachment 11.5.5 Cost Factors

Cost factors for Stopping, Idling, and Time Value were determined for cars, single-unit trucks, and combination trucks in 1972 and were published in NCHRP Report 133, Procedures for Estimating Highway User Costs, Air Pollution, and Noise Effects. (Table 11.3 presents the information from Table 5 of NCHRP Report 133.) The Time Value Costs were $3.00/hr for cars and $5.00/hr for all trucks. 11.5.6 Inflation Factor The cost factors shown in Table 11.3 are inflated to present day costs by use of the Inflation Factor, which is based on the Engineering News-Record (ENR) Construction Cost Index. The 1972 Construction Cost Index is 1753. The current Construction Cost Index is found in the current edition of ENR under "Market Trends." The Inflation Factor (I) is determined as follows:

I = Current Index 1972 Index

Table 11.3 Added Time and Vehicle Running Costs Per 1000 Stops,

and Idling Costs (Shading indicates interpolated values)

Initial Speed (mi/hr)

Added Time (hr/1000 stops) (excludes Idling Time)

Added Cost ($/1000 stops)a (excludes Idling Cost)

Passenger Car Single Unit Truck

Combination Truck

Passenger Car Single Unit Truck

Combination Truck

5 1.02 0.73 1.10 0.71 2.43 8.83 10 1.51 1.47 2.27 2.32 5.44 20.35 15 2.00 2.20 3.48 3.98 8.90 34.13 20 2.49 2.93 4.76 5.71 12.71 49.91 25 2.98 3.67 6.10 7.53 16.80 67.37 30 3.46 4.40 7.56 9.48 21.07 86.19 35 3.94 5.13 9.19 11.57 25.44 106.05 40 4.42 5.87 11.09 13.84 29.83 126.63 45 4.90 6.60 13.39 16.30 34.16 147.62 50 5.37 7.33 16.37 18.99 38.33 168.70 55 5.84 8.07 20.72 21.92 42.25 189.54 60 6.31 8.80 27.94 25.13 47.00 209.82 65 6.78 9.53 37.65 28.63 51.43 227.69 70 7.25 10.16 49.54 32.46 55.67 247.21 75 7.71 10.89 64.41 36.64 59.84 266.72 80 8.17 11.60 82.74 41.19 64.39 288.84

Idling Cost ($/veh-hr)b 0.1819 0.2017 0.2166 a Includes fuel, tires, engine oil, maintenance, and depreciation. b Includes fuel, engine oil, maintenance, and depreciation. Source: R. Winfrey, Economic Analysis for Highways (International Textbook Co., 1969) 923 pp.

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Publication 242, Chapter 11 SOL 482-14-21 Attachment 11.5.7 Example Calculations (continued)

Calculate the User Delay Costs based on the total number of delayed and stopped vehicles that were calculated in Section 11.5.3, Example 1:

Delayed: Stopped:

Cars: 38,873 Cars: 9,624 S.U. Trucks: 1,060 S.U. Trucks: 231 Comb. Trucks: 4,241 Comb. Trucks: 924

The following information is also known: Restricted Flow Length = 4.7 miles Initial Speed = 55 mph Reduced Speed = 40 mph Current Construction Cost Index = 8,574

1) Restricted Flow Time = Restricted Flow Length/Reduced Speed = 4.7/40 = 0.1175 hr

2) Overall Increased Travel Time = (Restricted Flow Length / Reduced Speed) - (Restricted Flow Length / Initial Speed)

= (4.7/40) - (4.7/55) = 0.0320 hr 3) Inflation Factor = Current Index / 1972 Index = 8,574/1753 = 4.891 4) Cost Factors (From Table 11.3): Added Time Added Cost Idling Time Time Value (hr/1000 stops) ($/1000 stops) ($/veh-hr) ($/hr) Cars 5.84 21.92 0.1819 3.00 S.U. Trucks 8.07 42.25 0.2017 5.00 Comb. Trucks 20.72 189.54 0.2166 5.00 5) Current Cost Factors: Added Time Added Cost Idling Time Time Value (hr/1000 stops) ($/1000 stops) ($/veh-hr) ($/hr) Cars 5.84 73.40 0.6091 10.05 S.U. Trucks 8.07 141.48 0.6754 16.74 Comb. Trucks 20.72 634.68 0.7253 16.74

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6) User Delay Costs:

Number of Added Delay Cost Vehicles Time per Unit COST

CARS

Idling 38,873 x 0.1175 x 0.6091 = 2,782 Time Value/Idling 38,873 x 0.0320 x 10.05 = 12,502 Stopping 9,624 x 0.001 x 73.40 = 706 Time Value/Stopping 9,624 x 5.84/1000 x 10.05 = 565

S.U. TRUCKS

Idling 1,060 x 0.1175 x 0.6754 = 84 Time Value/Idling 1,060 x 0.0320 x 16.74 = 568 Stopping 231 x 0.001 x 141.48 = 33 Time Value/Stopping 231 x 8.07/1000 x 16.74 = 31

COMBINATION TRUCKS

Idling 4,241 x 0.1175 x 0.7253 = 361 Time Value/Idling 4,241 x 0.0320 x 16.74 = 2,272 Stopping 924 x 0.001 x 634.68 = 586 Time Value/Stopping 924 x 20.72/1000 x 16.74 = 320

TOTAL $ 20,810

11.5.8 Days of Construction The total daily User Delay Cost is multiplied by the total number of Days of Construction that the roadway will be under repair. The total number of Days of Construction is determined by applying daily production rates to the specific work activities to be performed, accounting for concurrent activities, and summing the days of controlling operations. Production rates will vary depending on whether the Maintenance and Protection of Traffic is a short-term (partial-day) or long-term (full-day) closure. Standard values to be used in LCCAs are provided in Table 11.4; these values are based on typical production rates provided by industry. Concurrent activities are indicated and accounted for in the LCCA Excel spreadsheet, so that the total days for each maintenance year reflect the total required time of closure and not the sum of each activity’s duration in that year.

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Table 11.4 Standard Production Rates for Maintenance Activities

Production Rate Per Shift

Activity Short Term

Closure Long Term

Closure Adjust Drainage Structures 8 inlets 10 inlets Bituminous Inlay or Overlay 1,800 tons 2,400 tons Clean & Seal Transverse Joints – concrete surface 3,200 LF 4,200 LF Clean & Seal Joints – bituminous surface 6,000 LF 8,000 LF Clean & Seal Longitudinal Joints – concrete surface 6,500 LF 8,500 LF Concrete Patching 300 SY 400 SY Crack Seal 6,000 LF 8,000 LF Diamond Grinding 1,500 SY 2,000 SY Full-Depth (Bituminous) Patching 75 CY 150 CY Scratch Course, 60 PSY 1,800 tons 2,400 tons Mill Wearing Course 16,400 SY 21,900 SY Reinstall Guide Rail 1,500 LF 2,000 LF Remove Existing Guide Rail 2,250 LF 3,000 LF Saw & Seal Transverse Joints 6,400 LF 8,500 LF Seal Coat or Micro Surface Shoulders 16,000 SY 18,000 SY Type 7 Paved Shoulders 1,800 tons 2,400 tons

11.6 ALTERNATE BIDDING

The following guidelines on Alternate Bidding have been developed to facilitate competition in the paving industry, and to allow PennDOT to realize bid savings for construction projects and take advantage of fluctuating material costs without compromising sound engineering principles and practices. The Department met with the industries and developed the following requirements for alternate bidding. It should be acknowledged that the outcome of these meetings and compromises produced the process as stated herein. Ongoing efforts with the industries will continue to further refine the process, as necessary.

It is in the best interest of PennDOT to apply Alternate Bidding whenever appropriate so

that both industries are competitive and lower costs can be realized. Rather than a predetermined pavement type selection based on a LCCA and historical cost information, there is motivation to determine pavement type based on low bid. Within 6 months of Design Field View (DFV), when the pavement design is completed, the District shall submit the pavement design and LCCA to HDTS for review. Once HDTS has preliminarily approved the pavement design and LCCA, only then will it be shared. The District will then post the pavement design package and LCCA in ECMS as an unofficial plans set for a 3-week review and comment period. If the Department chooses to make any corrections or changes, then HDTS will make the final approval of PennDOT Oversight projects or submit to FHWA for Federal Oversight final approval. Alternate Pavement Type Bidding projects will be identified in ECMS on the “Planned 6-Month Letting Schedule” which will be updated monthly.

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Alternate Bidding that requires a LCCA includes the determination of a C-Factor which accounts for future maintenance costs, but excludes User Delay Costs, and is added to the construction cost so that the low bid is based on life-cycle costs. Additional requirements for Alternate Bidding are as follows:

• Alternates must be “equivalent,” meaning they provide comparable levels of service

and performance over the same analysis period. • The bid package will indicate the appropriate C-Factors for each alternative,

determined by PennDOT based on LCCA methodology for the project. • Typical sections for all alternatives must meet RC standards, DM-2 and Pub. 242

requirements. • Lane width, shoulder width, cross slope and all other geometric features unrelated to

pavement type, shown on the Typical Sections must remain as per the plans. 11.6.1 Alternate Bidding Project Selection

Alternate Bidding shall be considered for any new construction, reconstruction or rehabilitation project. Alternate bidding stimulates competition in the paving market, resulting in the potential for considerable savings in construction costs. Enhanced competition in the paving market also spurs innovation and improved pavement quality. Alternate bidding also takes advantage of fluctuating material costs that cannot be predicted during the preconstruction phase of a project. The FHWA Technical Advisory “Use of Alternate Bidding for Pavement Type Selection” and NCHRP Report 703 “Guide for Pavement-Type Selection” shall be used as guides. Projects with substantial non-pavement items may not be good candidates for alternate bidding.

When a LCCA is not required for a project, as per Section 11.2, pavement type selection

is based on initial costs or other factors. Alternate Bidding may still be considered in these cases, with no C-Factor calculation, using alternate designs that have the same scope of treatment, service lives and expected performance. Notify HDTS for tracking purposes.

When a new construction, reconstruction or rehabilitation project requires a LCCA,

Alternate Bidding must be applied, except as defined in Section 11.2, “Type Determination,” or with approval by the HDTS. The HDTS is responsible for monitoring and tracking Alternate Bidding projects and results.

For Alternate Bidding projects, pavement type shall not be changed after the project is

awarded to a contractor unless approved by the HDTS. The pavement type selection was the basis of the contract award and post-award change orders for pavement type negate the purpose of the alternate bidding process.

Alternate Bidding projects may be advertised in one of three ways: 1. The project is identified as a Design/Build project. Publication 448, Innovative Bidding ToolKit is followed for project development. The District develops the LCCA and C-factor for the various alternates in the bid package.

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2. Plans, Cross Sections, and Drainage Excavation shall be developed for the deepest pavement type alternative. The intention is to minimize the design effort on the part of the District while designing drainage to accommodate all alternate pavement types in the bid package. This is also intended to minimize any additional design effort needed on the part of the contractor developing a bid on a pavement alternate. Typical Sections are provided for all pavement alternatives in the bid package. Item Numbers and quantities for all alternate pavement materials in the bid package are provided in ECMS. Traffic Control Plans (TCP) shall be developed as per the normal project development processes. TCPs shall be fully developed for the worst case scenario in terms of the area of any necessary Temporary Construction Easements.

Conceptual Bidding Presentation Example for ECMS: Either Concrete Pavement And Asphalt Treated Permeable Base Course And Subbase And Class 1 Excavation – Concrete Pavement Or Concrete Pavement And Cement Treated Permeable Base Course And Subbase And Class 1 Excavation – Concrete Pavement Or SuperPave Wearing And SuperPave Binder And SuperPave Base Course And Subbase And Class 1 Excavation – Asphalt Pavement

3. Plans, cross-sections, typical sections, item numbers, quantities, and traffic control plans are fully developed for all pavement alternates in the bid package. This option should only be utilized if it can be done in a cost-effective manner.

11.6.2 C-Factor Calculation

The C-Factor is determined by summing the Present Worth (PW) value of the future maintenance costs: C = (PWmaint) Where: C = C-Factor PWmaint = PW of future maintenance costs, excluding User Delay Costs

Low Bid is determined by the Bid Amount plus the C-Factor of the respective pavement type alternate.

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Publication 242, Chapter 11 SOL 482-14-21 Attachment 11.6.3 LCCA/Alternate Pavement Type Bid Flow Chart District Pavement Project:

New Construction, Reconstruction, or Rehabilitation (Excludes Preservation)

Life-Cycle Cost Analysis (LCCA) required as per Pub. 242, Chapter 11?

(≥ 30,000 SY of mainline*)

The District Pavement Type Selection Committee may recommend a pavement type after consideration of regional factors as outlined in Pub. 242. Meeting minutes and conclusions shall be recorded and included in pavement design package, which is to be submitted to HDTS for approval.

Perform LCCA to develop C-Factor**

District may select pavement type OR

elect to alternate bid without a C-Factor.

NO

Notify HDTS for tracking purposes.

HDTS approved LCCA shows a

difference of 10% or more in life-cycle

cost, excluding user-delay costs?

HDTS approved LCCA shows a

difference of 20% or more in life-cycle

cost, including user-delay costs?

NO

District selects the lower life-cycle cost pavement type.***

YES

YES

Develop plans for Alternate Bidding as per Section 11.6.1.

Note: Low Bid is determined by the Bid Amount plus the

C-Factor of the respective pavement type alternate.

NO

*A LCCA must be submitted to the Highway Design and Technology Section for all new construction, reconstruction, or rehabilitation projects with at least 30,000 square yards of mainline pavement, including shoulders, regardless of roadway network or funding source. ** See 11.6.2 for C-Factor Calculation *** Alternate bidding is still a permissible option with the C-Factors.

YES

NO

Design/Build

Single plans developed for deepest alternate.

Plans developed for all alternates.

Submit to HDTS for approval

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Documents

Publication 242 Pavement Policy Manual Pavement Type ... · The pilot period will extend six months at ... projects in ECMS as an unofficial plan set for a three ... Life Cycle Cost