Methods and techniques for the identification, monitoring and management of natural hazards in high mountain areas are enumerated and described. A case study from the western Himalayan Kullu District in Himachal Prade...Methods and techniques for the identification, monitoring and management of natural hazards in high mountain areas are enumerated and described. A case study from the western Himalayan Kullu District in Himachal Pradesh, India is used to illustrate some of the methods. Research on the general topic has been conducted over three decades and that in the Kullu District has been carried out since 1994. Early methods of hazards identification in high mountain areas involved intensive and lengthy fieldwork and mapping with primary reliance on interpretation of landforms, sediments and vegetation thought to be indicative of slope failures, rock falls, debris flows, floods and accelerated soil surface erosion. Augmented by the use of airphotos and ad hoc observations of specific events over time, these methods resulted in the gradual accumulation of information on hazardous sites and the beginnings of a chronology of occurrences in an area. The use of historical methods applied to written and photographic material, often held in archives and libraries, further improved the resolution of hazards information. In the past two decades, both the need for, and the ability to, accurately identify potential hazards have increased. The need for accurate information and monitoring comes about as a result of rapid growth in population, settlements, transportation infrastructure and intensified land uses and, therefore, risk and vulnerability in mountain areas. Ability has improved as the traditional methods of gathering and manipulating data have been supplemented by the use of remote sensing, automated terrain modeling, global positioning systems and geographical information systems. This paper focuses on the development and application of the latter methods and techniques to characterize and monitor hazards in high mountain areas.展开更多
Forest land including forest protection areas in Indonesia have been degraded due to poverty of local communities who live in the surrounding areas. They tend to destroy the forest and are less attentive to forest con...Forest land including forest protection areas in Indonesia have been degraded due to poverty of local communities who live in the surrounding areas. They tend to destroy the forest and are less attentive to forest conservation causing conflict between local community and government. Forest protection areas are very fragile and at risk from natural disaster, mainly in small islands. Natural resources management in small islands needs to be done properly. Therefore, a research has been done for local communities in the Gunung Sirimau forest protection area, Ambon, with objectives to increase income in local communities and knowledge of forest conservation. This study used the action research method. The results of this study showed that income of local communities in three demplots increased by IDR 3,966,000 (in cycle 1), IDR 20,107,000 (in cycle 2) and IDR 25,897,000 (in cycle 3). Unfortunately, their knowledge regarding forest conservation and tree maintenance, both in theory and practice is still low. A lot of effort is needed to increase their knowledge in the next action research. The effort to increase income of local communities and its knowledge of forest conservation should be done step by step. If their knowledge is sufficient, promotion of the environmental service of forest protection areas through carbon trade implementation can be carried out.展开更多
The expansion of social housing in Brazil is solving the great demand among low-income populations, ltowever, these projects are not considering climatic factors and thermal comfort strategies. There is a standardizat...The expansion of social housing in Brazil is solving the great demand among low-income populations, ltowever, these projects are not considering climatic factors and thermal comfort strategies. There is a standardization of architectural projects, which leads to the user discomfort. Bioclimatic solutions that improve the thermal performance of buildings should be valued in the projects of buildings. This paper presents a comparative study noticing the thermal comfort provided by a earth tube ventilation system with a natural ventilation system based in the opening of the windows. In this study, three Brazilian bioclimatic zones defined by NBR (Brazilian Standard) 15220 (2005), Zone 1 (Curitiba), 2 (Camaqu~,) and 7 (Cuiabfi), were considered. To make this comparison, computer simulation was used to observe the thermal confort conditions in RTQ-R (Quality Technical Standard for Energy Efficiency Level in Residential Buildings) (2010), with the help of Energy Plus software and Schektch Up with the plug in Open Studio for modeling the residence. After the energy modeling, the results were analyzed with the Analisys Bio software in order to obtain the percentage of hours of comfort for the year (8,760 h). The conclusion is drawn that the natural ventilation strategy with the opening and closing of the windows is more efficient in Bioclimatic Zone 1. For the Bioclimatic Zone 2, the earth tubes should be used only in the summer and, in Bioclimatic Zone 7, earth tubes are efficient throughout the year because of the high temperatures in the exterior environment.展开更多
文摘Methods and techniques for the identification, monitoring and management of natural hazards in high mountain areas are enumerated and described. A case study from the western Himalayan Kullu District in Himachal Pradesh, India is used to illustrate some of the methods. Research on the general topic has been conducted over three decades and that in the Kullu District has been carried out since 1994. Early methods of hazards identification in high mountain areas involved intensive and lengthy fieldwork and mapping with primary reliance on interpretation of landforms, sediments and vegetation thought to be indicative of slope failures, rock falls, debris flows, floods and accelerated soil surface erosion. Augmented by the use of airphotos and ad hoc observations of specific events over time, these methods resulted in the gradual accumulation of information on hazardous sites and the beginnings of a chronology of occurrences in an area. The use of historical methods applied to written and photographic material, often held in archives and libraries, further improved the resolution of hazards information. In the past two decades, both the need for, and the ability to, accurately identify potential hazards have increased. The need for accurate information and monitoring comes about as a result of rapid growth in population, settlements, transportation infrastructure and intensified land uses and, therefore, risk and vulnerability in mountain areas. Ability has improved as the traditional methods of gathering and manipulating data have been supplemented by the use of remote sensing, automated terrain modeling, global positioning systems and geographical information systems. This paper focuses on the development and application of the latter methods and techniques to characterize and monitor hazards in high mountain areas.
文摘Forest land including forest protection areas in Indonesia have been degraded due to poverty of local communities who live in the surrounding areas. They tend to destroy the forest and are less attentive to forest conservation causing conflict between local community and government. Forest protection areas are very fragile and at risk from natural disaster, mainly in small islands. Natural resources management in small islands needs to be done properly. Therefore, a research has been done for local communities in the Gunung Sirimau forest protection area, Ambon, with objectives to increase income in local communities and knowledge of forest conservation. This study used the action research method. The results of this study showed that income of local communities in three demplots increased by IDR 3,966,000 (in cycle 1), IDR 20,107,000 (in cycle 2) and IDR 25,897,000 (in cycle 3). Unfortunately, their knowledge regarding forest conservation and tree maintenance, both in theory and practice is still low. A lot of effort is needed to increase their knowledge in the next action research. The effort to increase income of local communities and its knowledge of forest conservation should be done step by step. If their knowledge is sufficient, promotion of the environmental service of forest protection areas through carbon trade implementation can be carried out.
文摘The expansion of social housing in Brazil is solving the great demand among low-income populations, ltowever, these projects are not considering climatic factors and thermal comfort strategies. There is a standardization of architectural projects, which leads to the user discomfort. Bioclimatic solutions that improve the thermal performance of buildings should be valued in the projects of buildings. This paper presents a comparative study noticing the thermal comfort provided by a earth tube ventilation system with a natural ventilation system based in the opening of the windows. In this study, three Brazilian bioclimatic zones defined by NBR (Brazilian Standard) 15220 (2005), Zone 1 (Curitiba), 2 (Camaqu~,) and 7 (Cuiabfi), were considered. To make this comparison, computer simulation was used to observe the thermal confort conditions in RTQ-R (Quality Technical Standard for Energy Efficiency Level in Residential Buildings) (2010), with the help of Energy Plus software and Schektch Up with the plug in Open Studio for modeling the residence. After the energy modeling, the results were analyzed with the Analisys Bio software in order to obtain the percentage of hours of comfort for the year (8,760 h). The conclusion is drawn that the natural ventilation strategy with the opening and closing of the windows is more efficient in Bioclimatic Zone 1. For the Bioclimatic Zone 2, the earth tubes should be used only in the summer and, in Bioclimatic Zone 7, earth tubes are efficient throughout the year because of the high temperatures in the exterior environment.