♦Manual Notice 2024-1
►1. General Principles
- ►1. Overview
  - ►Pavement Preservation
- ►2. Functions of Surface Treatments and Seal Coats
  - ♦General
- ►3. Factors Influencing Performance
  - ♦General
- ►4. Principal Faults or Defects in Seal Coats and Surface Treatments
  - ♦General
  - ♦Loss of Aggregate
  - ♦Poor Adhesion or Bond to Road Surface
  - ♦Streaking
  - ♦Flushing
  - ♦Surface Treatments Defects�
►2. Guidelines for Treatment Selection
- ►1. Seal Coats as a Preventive Maintenance Technique
  - ♦General
- ►2. Selecting Pavements for Seal Coat Treatment
  - ♦General
  - ♦Pavement Distress Types
- ►3. Traffic Volume Considerations for Seal Coat Treatment
  - ♦Overview
  - ♦Short-Term Aggregate Loss
  - ♦Vehicular Damage
  - ♦Tire Noise
  - ♦Prolonged Traffic Control
- ►4. Strip or Spot Sealing
  - ♦General
- ►5. Surface Treatments
  - ♦General
- ►6. Fog Seal
  - ♦General
►3. Material Selection and Plan Preparation
- ►1. Communication and Coordination
  - ♦General
- ►2. Selection of Binder
  - ♦General
  - ♦Asphalt Cement
  - ♦Cutback Asphalt
  - ♦Emulsified Asphalt
  - ♦Specification Tests
  - ♦Weather Conditions
- ►3. Selection of Aggregate
- ►4. Planning and Contracting
  - ♦Calculate Quantities
  - ♦Estimate of Materials
  - ♦Preparing Plans
  - ♦Estimating Cost
▼4. Binder and Aggregate Application Rates
- ►1. Modified Kearby Design Method
  - ♦General
  - ♦Laboratory Tests
  - ♦Determining Design Rates
- ►2. McLeod Design Method
  - ♦General
  - ♦Design Procedure Components
  - ♦McLeod Seal Coat Design Equations
- ►3. Transversely Varying Asphalt Rates
  - ♦General
  - ►Considering Why and When to Require TVAR�
►5. Duties of Inspector or Crew Chief
- ►1. Authority of Inspector
  - ♦General
  - ♦Inspection of Materials and Work
- ►2. Duties of the Inspector or Crew Chief
  - ♦General
  - ♦Duties
- ►3. Specifications and Plans
  - ♦General
  - ♦Standard Specifications
  - ♦Special Specifications
  - ♦Special Provisions
  - ♦Plans
- ►4. Safety
  - ♦General
►6. Pre-Seal Coat Activities
- ►1. Overview
  - ♦General
- ►2. Repairs and Patching
  - ♦General
  - ♦Timing
  - ♦Types of Repairs
- ►3. Stockpiling Aggregate
  - ♦General
  - ♦Supplier
  - ♦Aggregate Sampling and Testing
  - ♦Stockpile Locations
  - ♦Contamination
  - ♦Area Preparation
  - ♦Proper Stockpile Techniques
- ►4. Preconstruction Meeting
  - ♦General
  - ♦Meeting Objectives
  - ♦Attendees
►7. Equipment Inspection
- ►1. Introduction
  - ♦General
  - ♦Provisions for Inspection
  - ♦Inspecting for Leaks
  - ♦Safety
- ►2. Rotary Broom
  - ♦General
  - ♦Identifying Data
  - ♦Safety Markings
  - ♦Bristles
  - ♦Brush Controls
  - ♦Older Model Brooms
- ►3. Asphalt Distributor
  - ♦General
  - ♦Asphalt Binder Tank
  - ♦Distributor Heating System
  - ♦Distributor Circulation and Pumping System
  - ♦Filter Screens
  - ♦Distributor Spray Bar
  - ♦Hand Sprayer
  - ♦Distributor Controls and Gauges
- ►4. Aggregate Spreader
  - ♦General
  - ♦Truck Hitch
  - ♦Receiving Hopper
  - ♦Belt Conveyors
  - ♦Discharge Hopper
  - ♦Discharge Gates
  - ♦Discharge Roller
  - ♦Wheels and Tires
  - ♦Brakes and Clutch
  - ♦Tailgate Aggregate Spreader
- ►5. Haul Trucks
  - ♦General
  - ♦Size
  - ♦Condition
  - ♦Hoist
  - ♦Tailgate
  - ♦Hitch
  - ♦Identifying Numbers
  - ♦Bed Measurements
  - ♦Volume of Truck Bed with Deduction for Hydraulic Ram Cover
  - ♦Acceptable Size
- ►6. Rollers
  - ♦General
  - ♦Identifying Data
  - ♦Weight Certification
  - ♦Pneumatic Rollers
- ►7. Front-End Loader
  - ♦General
  - ♦Identifying Data
  - ♦Visual Inspection
- ►8. Heater and Storage Unit
  - ♦General
  - ♦Temperature
  - ♦Safety
  - ♦Storage Tank
  - ♦Heater
  - ♦Pump Unit
  - ♦Heater Unit Location
  - ♦Recording Thermometer
  - ♦Transporter and Booster
  - ♦Identifying Data
  - ♦Manifest
  - ♦Cleanliness
  - ♦Contamination
  - ♦Booster Tanks
  - ♦Insulation
►8. Seal Coat/Surface Treatment Application Process
- ►1. Overview
  - ♦General
- ►2. Weather
  - ♦Introduction
  - ♦Temperature
  - ♦Humidity
  - ♦Wind
  - ♦Rain
- ►3. Traffic Control
  - ♦Introduction
  - ♦Pre-Positioning
  - ♦Displaying Signs
  - ♦Traffic Cones
  - ♦Flaggers
  - ♦Pilot Vehicle
  - ♦Repositioning Traffic Control Devices
  - ♦Intersections
  - ♦Arrow Boards
- ►4. Removing Pavement Markers
  - ♦General
- ►5. Cleaning the Pavement
  - ♦Introduction
  - ♦Safety During Sweeping Operations
  - ♦Sweeping Pattern
  - ♦Sweeping Distance from Operation
- ►6. Placing Temporary Tabs
  - ♦General
- ►7. Setting the Rock Lands
  - ♦Introduction
  - ♦Purpose
  - ♦Calculating the Length of Rock Land
  - ♦Marking the Rock Lands
- ►8. Setting the Asphalt Shots
  - ♦Introduction
  - ♦Asphalt Application Rate
  - ♦Distributor Capacity
  - ♦Calculating the Length of Asphalt Shot
  - ♦Marking the Asphalt Shot
- ►9. Checking the Loader Operation
  - ♦Introduction
  - ♦Loader Operation Checklist
- ►10. Placing Paper Joints
  - ♦Introduction
  - ♦Equipment
  - ♦Beginning of Asphalt Shot
  - ♦End of Asphalt Shot
  - ♦Subsequent Asphalt Shots with Multiple Distributors
- ►11. Shooting the Asphalt
  - ♦Introduction
  - ♦Distributor Preparation
  - ♦Blow the Nozzles
  - ♦Check Spray Bar Height
  - ♦Final Equipment Check
  - ♦Paper Joint Check
  - ♦Transverse Alignment
  - ♦Applying the Asphalt
  - ♦Timing for Aggregate Application
  - ♦Additional Distributors
- ►12. Strapping the Distributor
  - ♦Introduction
  - ♦Determining Asphalt Application Rate
- ►13. Spreading the Aggregate
  - ♦Introduction
  - ♦Aligning the Spreader Box
  - ♦Truck Hookup
  - ♦Test Strip
  - ♦Spreading the Aggregate
  - ♦Truck/Spreader Separation
  - ♦Rock Land Marker
  - ♦Visual Checks
  - ♦Recording Truck Loads
  - ♦Asphalt on Tires
- ►14. Timing for Aggregate Application
  - ♦Introduction
  - ♦Immediate Aggregate Application
- ►15. Rolling the Aggregate
  - ♦Introduction
  - ♦Rolling Pattern
  - ♦Checking the Rolling Pattern
- ►16. Patching or Hand Work
  - ♦Introduction
  - ♦Immediate Repairs
  - ♦Delayed Repairs
- ►17. Intersections and Irregular Shapes
  - ♦Introduction
  - ♦Transitions
  - ♦Radii at Intersections
  - ♦Crossovers on Divided Highways
  - ♦Driveways and Private Roads
  - ♦Problems with Hand Work
- ►18. Brooming Excess Aggregate
  - ♦Introduction
  - ♦Timing
  - ♦Equipment
  - ♦Procedures
  - ♦Inspection
- ►19. Opening to Traffic
  - ♦Introduction
  - ♦Traffic Volume
  - ♦Truck Traffic
  - ♦Traffic Speed
  - ♦Asphalt Type and Weather Conditions
  - ♦Changing Lanes
- ►20. Temporary or Permanent Pavement Markings
  - ♦General
  - ♦Temporary Markings
  - ♦Permanent Markings
- ►21. Placing Raised Pavement Markers
  - ♦General
- ►22. Cleanup
  - ♦Joint Paper
  - ♦Spilled Asphalt
  - ♦Stockpile Area
  - ♦Signs and Barricades
  - ♦Repairs to Damaged Property
►9. Public Perception and Complaints
- ►1. Handling Complaints
  - ♦General
- ►2. Public Perception and Education
  - ♦General

Chapter 4: Binder and Aggregate Application Rates

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Section 1: Modified Kearby Design Method

General

The design method described in this section is based on a modification of the original Kearby method and was first recommended to TxDOT by Texas Transportation Institute in 1981 (Epps et al., 1981). It is still the method most commonly used by TxDOT today. A formal design method such as this can effectively serve to guide inexperienced personnel through the “art” of seal coat design and to train personnel including inspectors, designers, and laboratory personnel. Correction factors for binder application rates for varying conditions including traffic and surface condition may be developed for conditions unique to a district and will ensure a much faster learning curve for inexperienced personnel. Examples of some adjustment factors, which were developed by the Brownwood and Abilene districts, are shown in Appendix A. Sample calculations are shown in Appendix B.

A design method such as described herein should be used to determine initial binder and aggregate application rates, but it should not take the place of good engineering judgment. Field conditions will require the adjustment of both binder and aggregate rates.

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Laboratory Tests

This design methodology requires the knowledge of some physical characteristics of the aggregate, such as unit weight, bulk specific gravity, and the quantity of aggregate needed to cover one square yard of roadway. Once the contractor has identified the aggregate to be used for the seal coat, samples of the stockpiled materials should be obtained to perform the following laboratory tests:

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Dry Loose Unit Weight—TxDOT Test Method Tex-404-A

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Bulk Specific Gravity—TxDOT Test Method Tex-403-A for all natural aggregate and Tex-433-A for lightweight aggregates

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Board Test—described below.

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Determining Design Rates

Aggregate Spread Rate. The Board Test is used to find the quantity of aggregate on a board of known aggregate such that full coverage, one stone in depth, is obtained. A one-half square yard area is a convenient laboratory size. The weight of aggregate applied in this area is obtained and converted to units of pounds per square yard. Good lighting is recommended and care should be taken to place the aggregate only one stone deep. The quantity of aggregate needed to cover one square yard of roadway can also be determined in terms of volume as shown in Equation 4.1.

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Equation 4-1..

where:

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S = quantity of aggregate required in square yards per cubic yard (SY/CY);

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W = dry loose unit weight in pounds per cubic foot (lbs/CF); and

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Q = aggregate quantity determined from the board test (lbs/SY).

Asphalt Application Rate. The asphalt application rate for asphalt cement can be obtained from Equation 4.2 once the aggregate properties and existing roadway conditions are known.

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Equation 4-2.

where:

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A = asphalt rate in gal/SY at 60°F

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E = embedment depth calculated using Eq. 3

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G = dry bulk specific gravity of the aggregate

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T = traffic correction factor (see Table 4-1)

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V = correction for surface condition (see Table 4-2).

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Equation 4-3.

where:

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d = average mat depth in inches, as calculated from Eq. 4

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e = percent embedment expressed as a decimal from Figure 4‑1.

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Equation 4-4.

where:

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Q = aggregate quantity determined from the board test in lbs/SY

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W = dry loose unit weight in lbs/CF.

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Figure 4-1. Relation of Percent Embedment to Mat Thickness for Determining Quantity of Asphalt. (After Epps et al., 1981)

Anchor: #i1001499Table 4-1. Asphalt Application Rate Correction for Traffic.
	Traffic – Vehicles per day per lane
Traffic Correction Factor (T)	>1000	500-1000	250-500	100-250	<100
Traffic Correction Factor (T)	1.00	1.05	1.10	1.15	1.20

Anchor: #i1001524Table 4-2. Asphalt Application Rate Correction for Existing Pavement Surface Conditions.
Description of Existing Surface	Correction for Surface Condition (V), gal/SY
Flushing, slightly bleeding surface	-0.06
Smooth, nonporous surface	-0.03
Slightly porous, slightly oxidized surface	0.00
Slightly pocked, porous, oxidized surface	+0.03
Badly pocked, porous, oxidized surface	+0.06

These surface conditions may vary throughout the project, and adjustments should be made accordingly.

Adjustment for Asphalt Emulsions or Cutbacks. For emulsions, the application rate (A from Eq. 2) should be increased to take into account the water in the emulsion. Therefore, Equation 5 is presented to determine the recommended emulsion application rate. In theory, the asphalt cement rate from Eq. 2 can be converted to the required emulsion rate by dividing this amount by the residual asphalt present in the emulsion. However, field experience shows that if this value is utilized, flushing is likely to occur. Therefore, the recommended emulsion application rate is adjusted as shown below:

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