多孔隙瀝青混凝土（Porous Asphalt Concrete, PAC）係指具有約70%~90%高比例粗粒料的開放級配，孔隙率高達15%~25%，可使雨水迅速由鋪面表面進入孔隙間，具有減少水霧現象、提高雨天行車能見度、提供良好的摩擦力及減少噪音提升環境品質等優點。但PAC鋪面受到交通量及天候環境等因素影響，使用一段時間後，可能導致發生剝落、鬆脫、孔隙堵塞壓實及車轍等情形。因此需要藉由各項PAC鋪面績效與交通流量資料之綜合分析，建立評估機制及提供一套完善維修養護方法，俾利延長服務年限及提供後續其他相關研究參考。
本研究範圍為國道6號西起霧峰系統交流道東至埔里端出口，全長37.6公里，選擇具代表性試驗路段進行現地鋪面透水量、噪音量檢測、平坦度、車轍量、Clegg衝擊及抗滑度等試驗，藉以評估PAC鋪面績效，然後再與交通流量及荷重資料進行綜合評估，俾便了解交通流量及荷重對於PAC鋪面績效之影響。
經綜合評估後，國道6號PAC鋪面檢測車轍值皆小於1 cm，初期隨交通荷重增加而緩慢增加，後期趨於穩定，顯示交通荷重影響PAC鋪面之平坦度，同時亦說明PAC具有抵抗永久變形之能力。在透水性方面，除2處外，其餘7處皆維持新工要求值 900ml/15sec以上。在現地噪音量方面，隨著ESAL值上升而增加，但同時受PAC自清效果而減緩增加趨勢，顯示PAC鋪面自清效果可延長績效年限。在抗滑度方面，隨交通荷重的增加而未有顯著變化，檢測路段之BPN值皆維持約在55以上，顯示PAC抗滑能力相當良好。整體而言，通車迄今PAC鋪面仍維持良好績效。

The goal of this research is to concentrate on the design, evaluation and efficiency of PAC. Porous Asphalt Concrete, which means a great proportion between 70 and 90 percent of coarse aggregations of open-graded gravel as well as high porosity, generally from 15 to 25 percent, allows rainwater to infiltrate promptly from the pavement surface into the air void. Also, PACs have been shown to be advantageous to us, such as increasing frictional resistance, reducing a number of splash and spray, lessening the potential for hydroplaning, enhancing the sight in rainy days, strengthening visibility of pavement markings and decreasing pavement noise. However, PAC pavements are subject to traffic, weather and environmental factors. For example, after a period of time, the frequent use of PAC pavements may lead to the occurrence of cracking, raveling, clogging and rutting. Therefore, it is necessary to establish various evaluations and provide a complete set of comprehensive repair and maintenance by the comprehensive analysis of various PAC pavement performance and traffic flow data in order to extend the length of service.
Secondly, the objective of this study was National Highway No.6, whose length was 36.7 kilometers. In addition, experimental accomplishing field permeameter, noise, roughness, rutting, Clegg Impact and Surface resistance tests in the specific and selective section of this highway was to conclude the efforts of the PAC pavement, which was associated with a exhaustive assessment of the statistic of passing vehicles and respectively loaded weight. Consequently, it was easier to further understand the influence of PAC pavement achievements.
Finally, all of tentative rutting values were less than 1 centimeter. The initial results came gradually high with the slow increases of traffic loads, and the later seemed to be sluggishly stabilized. According, traffic loads affected the flatness of the PAC pavement, while PACs had the ability to resist permanent deformation. In permeability, all tests, except for two, were required to maintain the beginning of the value of 900ml/15sec above. Also, the friction resistance of PACs didn’t make any significant changes. In a word, the use of PAC pavement in the transportation system has remained outstanding reputation so far.

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