1、道路工程施工概况英文OverviewConstruction quality is crucial to the long-term pavement performance. Construction factors such as surface preparation, placement, joint construction and paction/consolidation have an overwhelming effect on pavement performance, which cannot be ignored or pensated for in mix or st
2、ructural design.pactionpaction is the process by which the volume of air in an HMA mixture is reduced by using external forces to reorient the constituent aggregate particles into a more closely spaced arrangement. This reduction of air volume produces a corresponding increase in HMA density (Robert
3、s et al., 19961).Figure 1: A Steel Wheel and a Pneumatic Tire Roller Working Side-by-Side.paction is the greatest determining factor in dense graded pavement performance (Scherocman and Martenson, 19842; Scherocman, 19843; Geller, 19844; Brown, 19845; Bell et. al., 19846; Hughes, 19847; Hughes, 1989
4、8). Inadequate paction results in a pavement with decreased stiffness, reduced fatigue life, accelerated aging/decreased durability, rutting, raveling, and moisture susceptibility (Hughes, 19847; Hughes, 19898).paction Measurement and Reportingpaction reduces the volume of air in HMA. Therefore, the
5、 characteristic of concern is the volume of air within the pacted pavement, which is typically quantified as a percentage of air voids in relation to total volume and expressed as “percent air voids”. Percent air voids is calculated by paring a test specimens density with the density it would theore
6、tically have if all the air voids were removed, known as “theoretical maximum density” (TMD) or “Rice density” after the test procedure inventor.Although percent air voids is the HMA characteristic of interest, measurements are usually reported as a measured density in relation to a reference densit
7、y. This is done by reporting density as: Percentage of TMD (or “percent Rice”). This expression of density is easy to convert to air voids because any volume that is not asphalt binder or aggregate is assumed to be air. For example, a density reported as 93 percent Rice means that there are 7 percen
8、t air voids (100% 93% = 7%). Percentage of a laboratory-determined density. The laboratory density is usually a density obtained during mix design. Percentage of a control strip density. A control strip is a short pavement section that is pacted to the desired value under close scrutiny then used as
9、 the paction standard for a particular job.Pavement air voids are measured in the field by one of two principal methods: Cores (Figures 2 and 3). A small pavement core is extracted from the pacted HMA and sent to a laboratory to determine its density. Usually, core density results are available the
10、next day at the earliest. This type of air voids testing is generally considered the most accurate but is also the most time consuming and expensive. Nuclear gauges (Figures 4 and 5). A nuclear density gauge measures in-place HMA density using gamma radiation. Gauges usually contain a small gamma so
11、urce (about 10 mCi) such as Cesium-137 located in the tip of a small probe, which is either placed on the surface of the pavement or inserted into the pavement. Readings are obtained in about 2 3 minutes. Nuclear gauges require calibration to the specific mixture being tested. Usually nuclear gauges
12、 are calibrated to core densities at the beginning of a project and at regular intervals during the project to ensure accuracy.Each contracting agency or owner usually specifies the paction measurement methods and equipment to be used on contracts under their jurisdiction.Figure 2: Core ExtractionFi
13、gure 3: Pavement CoreFigure 4: Thin Lift Nuclear Density GaugeFigure 5: Taking a Nuclear Density ReadingFactors Affecting pactionHMA paction is influenced by a myriad of factors; some related to the environment, some determined by mix and structural design and some under contractor and agency contro
14、l during construction (see Table 1).Table 1: Factors Affecting pactionEnvironmental FactorsMix Property FactorsConstruction FactorsTemperatureAggregateRollers*Ground temperature*Gradation*Type*Air temperature*Size*Number*Wind speed*Shape*Speed and timing*Solar flux*Fractured faces*Number of passes*V
15、olume*Lift thicknessAsphalt BinderOther*Chemical properties*HMA production temperature*Physical properties*Haul distance*Amount*Haul timeFoundation supportA Note on the Time Available for pactionHMA temperature directly affects asphalt binder viscosity and thus paction. As HMA temperature decreases,
16、 the constituent asphalt binder bees more viscous and resistant to deformation resulting in a smaller reduction in air voids for a given pactive effort. As the mix cools, the asphalt binder eventually bees stiff enough to effectively prevent any further reduction in air voids regardless of the appli
17、ed pactive effort. The temperature at which this occurs, monly referred to as cessation temperature, is often reported to be about 175F for dense-graded HMA (Scherocman and Martenson, 19849; Hughes, 19898). Below cessation temperature rollers can still be operated on the mat to improve smoothness an
18、d surface texture but further paction will generally not occur.Mat temperature is crucial to both the actual amount of air void reduction for a given pactive effort, and the overall time available for paction. If a mats initial temperature and cool-down rate are known, the temperature of the mat at
19、any time after laydown can be calculated. Based on this calculation rolling equipment and patterns can be employed to: Take maximum advantage of available roller pactive effort. Rollers can be used where the mat is most receptive to paction and avoided where the mat is susceptible to excessive shovi
20、ng. Ensure the mat is pacted to the desired air void content before cessation temperature is reached. This can be done by calculating the time it takes the mat to cool from initial temperature to cessation temperature. All paction must be acplished within this “time available for paction”.MultiCool,
21、 developed by Professor Vaughn Voeller and Dr. David Timm, is a Windows based program that predicts HMA mat cooling. MultiCool can be used to predict the time available for paction and is available on the National Asphalt Pavement Associations A Guide for Hot Mix Asphalt Pavement CD-ROM or for downl
22、oad at: University of California Pavement Research Center (http:/.ucprc.ucdavis.edu/SoftwarePage.aspx) National Asphalt Pavement Association (http:/.asphaltpavement.org/index.php?option=_content&task=view&id=178&Itemid=273)paction EquipmentThere are three basic pieces of equipment available for HMA
23、paction: (1) the paver screed, (2) the steel wheeled roller and (3) the pneumatic tire roller. Each piece of equipment pacts the HMA by two principal means:1. By applying its weight to the HMA surface and pressing the material underneath the ground contact area. Since this pression will be greater f
24、or longer periods of contact, lower equipment speeds will produce more pression. Obviously, higher equipment weight will also increase pression.2. By creating a shear stress between the pressed material underneath the ground contact area and the adjacent unpressed material. When bined with equipment
25、 speed, this produces a shear rate. Lowering equipment speed can decrease the shear rate, which increases the shearing stress. Higher shearing stresses are more capable of rearranging aggregate into more dense configurations.These two means are of pacting HMA are often referred to collectively as “p
26、active effort”.Steel Wheel RollersSteel wheel rollers (see Figures 6 and 7) are self-propelled paction devices that use steel drums to press the underlying HMA. They can have one, two or even three drums, although tandem (2 drum) rollers are most often used. The drums can be either static or vibrato
27、ry and usually range from 35 to 85 inches in width and 20 to 60 inches in diameter. Roller weight is typically between 1 and 20 tons (see Figures 5 and 6).Some steel wheel rollers are equipped with vibratory drums. Drum vibration adds a dynamic load to the static roller weight to create a greater to
28、tal pactive effort. Drum vibration also reduces friction and aggregate interlock during paction, which allows aggregate particles to move into final positions that produce greater friction and interlock than could be achieved without vibration. As a general rule-of-thumb, a bination of speed and fre
29、quency that results in 10 12 impacts per foot is good. At 3000 vibrations/minute this results in a speed of 2.8 3.4 mph.Figure 6: Steel Wheel RollersFigure 7: Steel Wheel RollersPneumatic Tire RollersPneumatic tire rollers are self-propelled paction devices that uses pneumatic tires to pact the unde
30、rlying HMA. Pneumatic tire rollers employ a set of smooth tires (no tread) on each axle; typically four or five on one axle and five or six on the other. The tires on the front axle are aligned with the gaps between tires on the rear axle to give plete and uniform paction coverage over the width of
31、the roller. pactive effort is controlled by varying tire pressure, which is typically set between 60 and 120 psi (TRB, 200010). In addition to a static pressive force, pneumatic tire rollers also develop a kneading action between the tires that tends to realign aggregate within the HMA. Because asph
32、alt binder tends to stick more to cold tires than hot tires, the tire area is sometimes insulated with rubber matting or plywood to maintain the tires near mat temperature while rolling (see Figures 8 and 9).Figure 8: Pneumatic Tire RollerFigure 9: Pneumatic Tirespaction SequenceHMA paction is typically acplished by a sequence of paction equipment. This allows each piece of equipment to be used only in its most advantageous situation resultin
