Abstract
Typhoon Hagibis, which occurred at the beginning of October 2019, was one of the largest and most powerful tropical cyclones and was considered to be the most devastating typhoon to hit Japan in recorded history. Extreme heavy rainfall caused massive impacts to Japan in general and to Marumori Town, Miyagi Prefecture in particular. In the present study, the detailed flood characteristics at Marumori Town were investigated by using field observation and numerical simulations. The obtained data immediately after the flood has clearly shown that most levee breaches were caused by the water overflow on the river embankment at the constriction areas such as the tributaries’ junction and the intersection of the river embankment. Numerical simulations were performed to investigate the mechanism of levee breaching in Marumori Town. According to the simulation results, the flooding water from the upstream levee breach locations flowed into the paddy field area and caused the levee to breach at the river embankment interaction in the downstream area. A new levee breach criterion in terms of overflow depth and its duration on the river embankment was proposed. In addition, a sensitivity analysis was also performed to understand the effect of the backwater and phase lag of water level rise between the mainstream and tributaries. Although there have been many studies on flood disasters, the typhoon’s flood-induced disasters on the river and coastal infrastructures have still remained a big challenge. The present study outcomes provide useful information not only to understand how the river embankment of tributaries is vulnerable to water level rise, but also to support the river authorities to prepare better mitigation plans for future flood disasters.
Highlights
According to the typhoon database by the Japan Meteorological Agency (JMA) from 1951 to 2010 [1], an annual average of 26 typhoons have attacked Japan from the NorthwestPacific Ocean, of which three typhoons have caused significant damage and landfall on the main islands of Japan
The EFDC+ (Environmental Fluid Dynamics Code Plus) model was used for flood simulation in the present study [14]
A large of floodwater through the upstream levee breaching locations flowed the field areas, which concentrated at the areas areas downstream, Ininto addition to these two mechanisms, we observed thatconstricted the effects of stagnant flowed into thepaddy paddy field areas, which concentrated atconstricted the downcausing the overflow from the paddy to the river shown in
Summary
According to the typhoon database by the Japan Meteorological Agency (JMA) from 1951 to 2010 [1], an annual average of 26 typhoons have attacked Japan from the Northwest. Pacific Ocean, of which three typhoons have caused significant damage and landfall on the main islands of Japan. The extreme flood disasflood disaster occurred from 28 June to 8 July 2018 during the Praporoon Typhoon, which ter occurred from 28 June to 8 July 2018 during the Praporoon Typhoon, which caused caused many landfalls on the Honshu and Hokkaido main islands. The Izu. The typhoon brought record-breaking rainfall to many areas. Typhoon Hagibis created an extreme storm surge level that caused significant damage. Typhoon Hagibis created an extreme storm surge level that caused significant damto the coastal structures along with the Greater Tokyo and Shizuoka areas, as reported by age to the coastal structures. The post-field survey the severe flood in the Marumori area during Typhoon Hagibis in 2019. The post-field was carried immediately one dayone afterday theafter event onevent
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