Fundamental Study on Earthwork Quality Control Based on Intelligent Compaction Technology

Sung-Ha Baek; Jin-Young Kim; Jin-Woo Cho; Namgyu Kim; Yeong-Hoon Jeong; Changho Choi

doi:10.7843/kgs.2020.36.12.45

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2020 Vol.36, Issue 12 Preview Page Next Page

Research Article

Fundamental Study on Earthwork Quality Control Based on Intelligent Compaction Technology 지능형 다짐기술을 통한 토공사 품질관리를 위한 기초 연구

31 December 2020. pp. 45-56

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Abstract

In this paper, intelligent compaction (IC) technology and the earthwork quality control specifications based on IC were analyzed, and the field study was conducted to investigate the relationship between the representative IC value CMV (Compaction Meter Value) and spot test results (plate bearing test and field density test). As the number of roller passes increased, both the CMV and spot test results increased. However, point-by-point comparison between CMV and spot test results yielded poor quality correlations; this is because the ununiform stiffness of the underlying layer and the moisture content of the lift layer affected the CMV and spot test results, respectively. Most international specifications related to IC requires knowledge of the IC values and their relationships with the soil properties obtained by the traditional spot tests. Therefore, for the successful implementation of intelligent compaction technology into earthwork construction practice, the number of roller passes as well as the lift thickness and the moisture content of the soil should be carefully considered.

Keywords

Compaction Meter Value (CMV) earthwork

Intelligent Compaction (IC)

Quality control

Soil compaction

본 연구에서는 지능형 다짐기술과 이를 활용한 토공사 품질관리 기준을 분석하고, 현장시험을 통해 대표적인 지능형 다짐값인 CMV(Compaction Meter Value)와 일점시험(평판재하시험 및 현장밀도시험) 결과를 비교 분석했다. CMV와 일점시험 결과 모두 다짐횟수가 증가할수록 커지는 경향을 나타냈다. CMV와 일점시험 결과의 상관성은 높지 않았는데, 이는 불균질한 원지반 강성, 성토재료의 포설 깊이 및 함수비가 각각 CMV와 일점시험 결과에 영향을 주었기 때문이다. 지능형 다짐과 관련한 대부분의 국외 기준에서 지능형 다짐값과 일점시험 결과의 상관관계를 바탕으로 토공사 품질을 관리를 하도록 명시하고 있다. 따라서 지능형 다짐기술을 활용해 토공사 현장의 다짐품질을 관리하기 위해서는 적절한 다짐횟수와 더불어 원지반의 상태, 성토재료의 포설 깊이 및 함수비가 종합적으로 고려되어야 할 것으로 판단된다.

References

Adam, D. (1997), Continuous Compaction Control (CCC) with Vibratory Rollers, Proceedings of GeoEnvironment 97, Melbourne, Australia, Balkema, Rotterdam, pp.245-250.

Adam, D. and Brandl, H. (2003), Sophisticated Roller Integrated Continuous Compaction Control, 12th Asian Regional Conference on Soil Mechanics and Geotechnical Engineering - Geotechnical Infrastructure for the New Millennium, Singapore, pp.427-430.

Anderegg R. and Kaufmann, K. (2004), Intelligent Compaction with Vibratory Rollers - Feedback Control Systems in Automatic Compaction and Compaction Control, Transportation Research Record 1868, Journal of the Transportation Research Board, National Academy Press, pp.124-134. 10.3141/1868-13

Anderegg, R., von Felten, D., and Kaufmann, K. (2006), Compaction Monitoring Using Intelligent Soil Compactors, Proceedings of GeoCongress 2006: Geotechnical Engineering in the Information Technology Age, Atlanta, CDROM. 10.1061/40803(187)41

ASTM D1557-02 (2009), Standard Test Methods for Laboratory Compaction Characteristics of Soil Using Modified Effort (56,000 ft-lbf/ft3 (2,700 kN-m/m³)).

Caicedo, N. (2019), Geotechnics of Roads : Fundamentals, CRC Press/Balkema. 10.1201/9780429025914

Cho, S.M. and Jung, G. (2000), Development of a new compaction test method based on ground reaction force, Korea Expressway Corparation Research Institute.

Forssblad, L. (1980), Compaction Meter on Vibrating Rollers for Improved Compaction Control, Proceedings of International Conference on Compaction, Vol. II, Assoc. Amicale de Ingenieus, Paris, France, pp.541-546.

Hansbo, S. and Pramborg, B. (1980), Compaction control, in Proceedings of the International conference on Compaction, Paris, France, pp.559-564.

https://www.intelligentconstruction.com/resources/ic-specifications/ (FHWA [Intelligent Compaction Technology for Soils Applications (2014)]).

ISSMGE (2005), Roller-integrated continuous compaction control (CCC), Technical contractual provisions - recommendations. International Society for Soil Mechanics and Geotechnical Engineering: Geotechnics for Pavements in Transportation Infrastructure.

Korea Institute of Construction Technology (2009), Intelligent Compaction Management System using Telematics.

Korea Institute of Construction Technology (2018), Technical Demand Study for Automation of Smart Earthwork to Improve Construction Productivity (KICT 2018-088).

KS F 2310 (2015), Standard test method for plate load test of road construction.

KS F 2311 (2016), Standard test method for density of soil in place by the sand cone method.

Ministry of Land, Infrastructure and Transport (2016), Korean Construction Specification for Earthworks (KCS 20 20 : 2016).

Park, K.B. and Kim, J.H. (2012), Application of the New Degree of Compaction Evaluation Method, Journal of the Korean Geotechnical Society, Vol.28, No.2, pp.5-14. 10.7843/kgs.2012.28.2.5

Poulos, H.D. and Davis, E.H. (1974), Elastic solutions for soil and rock mechanics: John Wiley and Sons, New York. 10.1016/0148-9062(74)91768-9

Research Society for Road and Traffic (1994), ZTVE StB/TP BF-StB: Surface covering dynamic compaction control methods, German specifications and regulations (Additional technical contractual conditions and guidelines for earthwork in road construction/ Technical testing instructions for soil and rock in road construction).

RVS 8S.02.6. (1999), Continuous compactor integrated compaction - Proof (proof of compaction), Technical contract stipulations RVS 8S.02.6 - Earthworks. Vienna: Federal Ministry for Economic Affairs.

Sandstrom, A. and Pettersson, C. (2004), Intelligent Systems for QA/QC in Soil Compaction, Proceedings of Annual Transportation Research Board Meeting, Transportation Research Board, Washington, D.C., CD- ROM.

Thurner, H. and Sandstrom, A. (1980), A New Device for Instant Compaction Control, Proceedings of International Conference on Compaction, Vol. II, Assoc. Amicale de Ingenieus, Paris, pp.611-614.

Thurner, H. and Sandstrom, A. (2000), Continuous Compaction Control, CCC, Workshop on Compaction of Soils and Granular Materials, Modeling of Compacted Materials, Compaction Management and Continuous Control, International Society of Soil Mechanics and Geotechnical Engineering (European Technical Committee), Paris, France, pp.237-246.

Vagverket (Swedish Road Administration) (1994), Road 94: General Technical Construction Specification for Roads, Road and Traffic Division, Stockholm, Sweden, Publication 1994: 25(E).

White, D. J. and Thompson, M. (2008), Relationships Between In-situ and Roller-Integrated Compaction Measurements for Granular Soils, Journal of Geotechnical Geoenvironmental Engineering, ASCE, Vol.134, No.12, pp.1763-1770. 10.1061/(ASCE)1090-0241(2008)134:12(1763)

White, D. J., Thompson, M., and Vennapusa, P. (2007), Field Validation of Intelligent Compaction Monitoring Technology for Unbound Materials, Final Report, Minnesota Department of Transportation, Maplewood, Minnesota.

Information

Publisher :The Korean Geotechnical Society
Publisher(Ko) :한국지반공학회
Journal Title :Journal of the Korean Geotechnical Society
Journal Title(Ko) :한국지반공학회 논문집
Volume : 36
No :12
Pages :45-56
Received Date : 2020-11-10
Revised Date : 2020-11-20
Accepted Date : 2020-11-21
DOI :https://doi.org/10.7843/kgs.2020.36.12.45

Journal of the Korean Geotechnical Society ISSN:1229-2427(Print) 2288-646X(Online) 한국지반공학회 논문집

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