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FDOT Aviation Pavement Inspection Training

2. Purpose (of Pavements). To carry traffic:Safely Smoothly Efficiently . 3. Pavement Types. RigidFlexibleComposite. 4. Pavement Types

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FDOT Aviation Pavement Inspection Training

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    1. FDOT Aviation Pavement Inspection Training Module 2 – Pavement Fundamentals – Overview

    2. 2 Airport pavements are designed, constructed, and maintained to support the critical loads imposed on them and to produce a smooth, skid-resistant, and safe-riding surface. The pavement must be of such quality and thickness to ensure it will not fail under the loads imposed and be durable enough to withstand the abrasive action of traffic, adverse weather conditions, and other deteriorating influences. To ensure the necessary strength of the pavement and to prevent unmanageable distresses from developing, the airport should consider various design, construction, and material-related parameters. This module helps users assess these parameters by providing information on the composition of pavement sections and the functional aspects of flexible and rigid pavement components. The pavement above the subgrade must be capable of reducing stresses imposed on the subgrade to values that are low enough to prevent excessive distortion or displacement of the subgrade soil layer.Airport pavements are designed, constructed, and maintained to support the critical loads imposed on them and to produce a smooth, skid-resistant, and safe-riding surface. The pavement must be of such quality and thickness to ensure it will not fail under the loads imposed and be durable enough to withstand the abrasive action of traffic, adverse weather conditions, and other deteriorating influences. To ensure the necessary strength of the pavement and to prevent unmanageable distresses from developing, the airport should consider various design, construction, and material-related parameters. This module helps users assess these parameters by providing information on the composition of pavement sections and the functional aspects of flexible and rigid pavement components. The pavement above the subgrade must be capable of reducing stresses imposed on the subgrade to values that are low enough to prevent excessive distortion or displacement of the subgrade soil layer.

    3. 3 Pavement Types Rigid Flexible Composite Generally, pavements fall into two classes: a. Rigid pavements b. Flexible pavements Combinations of different pavement types and stabilized layers form complex pavements that can be classified as variations of the normal rigid and flexible types. Composite (AC Overlay of Rigid) pavements—existing pavement structures that are overlaid by either of the pavement types—are also common. Generally, pavements fall into two classes: a. Rigid pavements b. Flexible pavements Combinations of different pavement types and stabilized layers form complex pavements that can be classified as variations of the normal rigid and flexible types. Composite (AC Overlay of Rigid) pavements—existing pavement structures that are overlaid by either of the pavement types—are also common.

    4. 4 Pavement Types – Concrete Surfaced Rigid Portland cement concrete Stabilized or unbound subbase Stabilized or natural subgrade Rigid pavements normally use Portland cement concrete as the prime structural element. Depending on conditions, engineers may design the pavement slab with plain, lightly reinforced, continuously reinforced, prestressed, or fibrous concrete. The concrete slab usually lies on a compacted granular or treated subbase, which is supported, in turn, by a compacted subgrade. The subbase provides uniform stable support and may provide subsurface drainage. Concrete Slab (Surface Layer). The concrete slab provides structural support to the aircraft, provides a skid-resistant surface, and prevents the infiltration of excess surface water into the subbase. Subbase. The subbase provides uniform stable support for the pavement slab. The subbase also serves to control frost action, provide subsurface drainage, control swelling of subgrade soils, provide a stable construction platform for rigid pavement construction, and prevent mud pumping of fine-grained soils. Rigid pavements generally require a minimum subbase thickness of 4 inches. Stabilized Subbase. All new rigid pavements designed to accommodate aircraft weighing 100,000 pounds or more must have a stabilized subbase. The structural benefit imparted to a pavement section by a stabilized subbase is reflected in the modulus of subgrade reaction assigned to the foundation. The concrete slab has considerable flexural strength and spreads the applied loads over a large area. The figure illustrates a typical rigid pavement structure. Rigid pavements normally use Portland cement concrete as the prime structural element. Depending on conditions, engineers may design the pavement slab with plain, lightly reinforced, continuously reinforced, prestressed, or fibrous concrete. The concrete slab usually lies on a compacted granular or treated subbase, which is supported, in turn, by a compacted subgrade. The subbase provides uniform stable support and may provide subsurface drainage. Concrete Slab (Surface Layer). The concrete slab provides structural support to the aircraft, provides a skid-resistant surface, and prevents the infiltration of excess surface water into the subbase. Subbase. The subbase provides uniform stable support for the pavement slab. The subbase also serves to control frost action, provide subsurface drainage, control swelling of subgrade soils, provide a stable construction platform for rigid pavement construction, and prevent mud pumping of fine-grained soils. Rigid pavements generally require a minimum subbase thickness of 4 inches. Stabilized Subbase. All new rigid pavements designed to accommodate aircraft weighing 100,000 pounds or more must have a stabilized subbase. The structural benefit imparted to a pavement section by a stabilized subbase is reflected in the modulus of subgrade reaction assigned to the foundation. The concrete slab has considerable flexural strength and spreads the applied loads over a large area. The figure illustrates a typical rigid pavement structure.

    5. 5 Pavement Types – Asphalt Surfaced Flexible Asphalt concrete Base (stabilized, unbound) Subbase (stabilized,unbound) Subgrade (stabilized,natural) Composite Asphalt overlay Rigid system Flexible pavements support loads through bearing rather than flexural action. They comprise several layers of carefully selected materials designed to gradually distribute loads from the pavement surface to the layers underneath. The figure is a typical flexible pavement section. Composite pavement is an asphalt overlay of a rigid pavement system.Flexible pavements support loads through bearing rather than flexural action. They comprise several layers of carefully selected materials designed to gradually distribute loads from the pavement surface to the layers underneath. The figure is a typical flexible pavement section. Composite pavement is an asphalt overlay of a rigid pavement system.

    6. 6 Pavement Materials Rigid – materials (Portland cement and aggregates) Very strong, durable Expensive to repair

    7. 7 Pavement Structural Behavior Rigid Rigid pavements normally use Portland cement concrete as the prime structural element. Depending on conditions, engineers may design the pavement slab with plain, lightly reinforced, continuously reinforced, prestressed, or fibrous concrete. The concrete slab usually lies on a compacted granular or treated subbase, which is supported, in turn, by a compacted subgrade. The subbase provides uniform stable support and may provide subsurface drainage. The concrete slab has considerable flexural strength and spreads the applied loads over a large area. The figure shows how this rigidity and the resulting beam action enable rigid pavements to distribute loads over large areas of the subgrade. Better pavement performance requires that support for the concrete slab be uniform. Rigid pavement strength is most economically built into the concrete slab itself with optimum use of low-cost materials under the slab. Rigid pavements normally use Portland cement concrete as the prime structural element. Depending on conditions, engineers may design the pavement slab with plain, lightly reinforced, continuously reinforced, prestressed, or fibrous concrete. The concrete slab usually lies on a compacted granular or treated subbase, which is supported, in turn, by a compacted subgrade. The subbase provides uniform stable support and may provide subsurface drainage. The concrete slab has considerable flexural strength and spreads the applied loads over a large area. The figure shows how this rigidity and the resulting beam action enable rigid pavements to distribute loads over large areas of the subgrade. Better pavement performance requires that support for the concrete slab be uniform. Rigid pavement strength is most economically built into the concrete slab itself with optimum use of low-cost materials under the slab.

    8. 8 Pavement Materials Flexible – materials (asphalt cement and aggregates) Strength affected by temperature Relatively easy to repair Asphalt Concrete (Bituminous) Surface (Wearing Course). The bituminous surface, or wearing course, is made up of a mixture of various selected aggregates bound together with asphalt cement or other bituminous binders. This surface prevents the penetration of surface water to the base course; provides a smooth, well-bonded surface free from loose particles, which might endanger aircraft or people; resists the stresses caused by aircraft loads; and supplies a skid-resistant surface without causing undue wear on tires. Base Course. The base course serves as the principal structural component of the flexible pavement. It distributes the imposed wheel load to the pavement foundation, the subbase, and/or the subgrade. The base course must have sufficient quality and thickness to prevent failure in the subgrade and/or subbase, withstand the stresses produced in the base itself, resist vertical pressures that tend to produce consolidation and result in distortion of the surface course, and resist volume changes caused by fluctuations in its moisture content. The materials composing the base course are select hard and durable aggregates, which generally fall into two main classes: stabilized and granular. The stabilized bases normally consist of crushed or uncrushed aggregate bound with a stabilizer, such as Portland cement or bitumen. The quality of the base course is a function of its composition, physical properties, and compaction of the material. Subbase. This layer is used in areas where the subgrade soil is extremely weak. The subbase course functions like the base course. The material requirements for the subbase are not as strict as those for the base course since the subbase is subjected to lower load stresses. The subbase consists of stabilized or properly compacted granular material. Subgrade. The subgrade is the compacted soil layer that forms the foundation of the pavement system. Subgrade soils are subjected to lower stresses than the surface, base, and subbase courses. Since load stresses decrease with depth, the controlling subgrade stress usually lies at the top of the subgrade. The combined thickness of subbase, base, and wearing surface must be great enough to reduce the stresses occurring in the subgrade to values that will not cause excessive distortion or displacement of the subgrade soil layer.Asphalt Concrete (Bituminous) Surface (Wearing Course). The bituminous surface, or wearing course, is made up of a mixture of various selected aggregates bound together with asphalt cement or other bituminous binders. This surface prevents the penetration of surface water to the base course; provides a smooth, well-bonded surface free from loose particles, which might endanger aircraft or people; resists the stresses caused by aircraft loads; and supplies a skid-resistant surface without causing undue wear on tires. Base Course. The base course serves as the principal structural component of the flexible pavement. It distributes the imposed wheel load to the pavement foundation, the subbase, and/or the subgrade. The base course must have sufficient quality and thickness to prevent failure in the subgrade and/or subbase, withstand the stresses produced in the base itself, resist vertical pressures that tend to produce consolidation and result in distortion of the surface course, and resist volume changes caused by fluctuations in its moisture content. The materials composing the base course are select hard and durable aggregates, which generally fall into two main classes: stabilized and granular. The stabilized bases normally consist of crushed or uncrushed aggregate bound with a stabilizer, such as Portland cement or bitumen. The quality of the base course is a function of its composition, physical properties, and compaction of the material. Subbase. This layer is used in areas where the subgrade soil is extremely weak. The subbase course functions like the base course. The material requirements for the subbase are not as strict as those for the base course since the subbase is subjected to lower load stresses. The subbase consists of stabilized or properly compacted granular material. Subgrade. The subgrade is the compacted soil layer that forms the foundation of the pavement system. Subgrade soils are subjected to lower stresses than the surface, base, and subbase courses. Since load stresses decrease with depth, the controlling subgrade stress usually lies at the top of the subgrade. The combined thickness of subbase, base, and wearing surface must be great enough to reduce the stresses occurring in the subgrade to values that will not cause excessive distortion or displacement of the subgrade soil layer.

    9. 9 Pavement Structural Behavior Flexible Flexible pavements support loads through bearing rather than flexural action. They comprise several layers of carefully selected materials designed to gradually distribute loads from the pavement surface to the layers underneath. The design ensures the load transmitted to each successive layer does not exceed the layer's load-bearing capacity. The figure depicts the distribution of the imposed load to the subgrade.Flexible pavements support loads through bearing rather than flexural action. They comprise several layers of carefully selected materials designed to gradually distribute loads from the pavement surface to the layers underneath. The design ensures the load transmitted to each successive layer does not exceed the layer's load-bearing capacity. The figure depicts the distribution of the imposed load to the subgrade.

    10. 10 What is Performance/Failure? General Categories of Distress: cracking, distortion, disintegration, loss of skid resistance Causes Environment: Swell, blowups (Non-Load, including drainage and environmental effects) Load (too much traffic or weak structure (or both)) Alligator, corner breaks, joint spalls Construction/materials related Bleeding, crazing/map cracking

    11. 11 Why and How Pavements Fail

    12. 12 Why and How Pavements Fail

    13. 13 Pavement Preservation Concepts Right treatment, Right pavement, Right time Includes maintenance, rehabilitation and reconstruction Built upon a Pavement Management System

    14. 14

    15. 15 Pavement Management ? What & Why? Decision support tool Identifies sections needing treatment Allows cost-effective prioritization and allocation of resources

    16. 16 Pavement Management ? Why? Planning performance prediction prioritization budgeting Maintenance identify repair needs track effectiveness of repairs

    17. 17 Elements of a Pavement Management System (PMS) Database inventory, condition, traffic, maintenance and rehab (M&R) history, cost Analysis & Reporting tools

    18. 18 Factors Indicative of Pavement Condition Visible: surface distress, smoothness, friction Non-Visible: load response, material strength, environmental effects on materials; load-related damage

    19. 19 Measures of Pavement Condition Visual condition survey; drainage and shoulder survey Ride quality (smoothness/roughness) measurement Safety (skid/friction measurement) Structural capacity – surface deflection measurement

    20. 20 PCI for Airports ASTM Standard D-5340-04 16 years of refinement before selection USACE ’70’s FAA Accepted as an ASTM Standard Practice

    21. 21 Components of the Standard Distress definitions Deduct curves PCI Calculation Procedure

    22. 22 PCI Procedure Inspect sample units Determine deduct values Determine allowable number of deducts (m) Compute the total deduct value (TDV) Perform the correction for multiple distresses (if necessary) Compute the PCI for each sample unit (S.U.) Calculate area-weighted average the S.U. PCI’s for the section Send to FDOT for entry and PCI calculation

    23. 23 FDOT Inspections Locate SU for inspection – use Network Definition drawing Wheel and paint to identify Locate centroid of SU – Obtain and record GPS coordinates Perform distress data collection using PDA (handheld) or PenTablet (paper forms always for backup) No need for curves or calculations – all computerized

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    26. 26 Network Definition Drawing - Detail

    27. 27 Locate A Specific Sample Unit Where is 6105 106 ? Measure 300 feet from RW end to SU 106 Mark corners of “begin” end of SU Measure forward 50 ft to end of SU Mark Corners of end of SU

    28. 28 What is a Centroid?

    29. 29 What is a Centroid?

    30. 30 Paper Forms

    31. 31 Paper Forms

    32. 32 Field Maps and GIS Use network definition drawings to locate sample units Record undocumented new construction Modifications to the proposed sampling plan and additional sample units. If pavement abandoned do not survey If new pavement record dimensions, surface type and survey during this inspection Use of Geographic Information System and the global positioning system (GPS) to assist in locating sample units (always have wheel for backup)

    33. 33 Safety Considerations During Pavement Inspections Safety requirements for personnel conducting airside pavement inspections Notify airfield prior to arrival Check in on arrival Ask about local communication and operations issues: UNICOM radio Never one-person survey (make sure someone is aware you are on the field and they are watching you)

    34. 34 Data Quality – Accuracy and Consistency How to maintain quality, accuracy and consistency of field inspections? Training Planning Always have the field manual Resurvey and compare every day – 2-3 SU for each person/crew

    35. 35 Review / Questions?

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