The global helicopter life raft market is experiencing robust growth, driven by increasing demand for enhanced safety measures in the aviation industry, particularly within civil and military helicopter operations. The market, estimated at $150 million in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of 7% from 2025 to 2033. This growth is fueled by several key factors, including rising helicopter deployments for search and rescue missions, offshore operations, and military applications. Stringent safety regulations implemented by various aviation authorities worldwide further contribute to the market expansion. The increasing prevalence of extreme weather events also necessitates the availability of reliable life-saving equipment like helicopter life rafts, boosting market demand. Market segmentation reveals a preference for larger capacity rafts (6-10 person and above) due to the nature of many helicopter missions, although the smaller capacity rafts remain significant in niche applications. Geographical analysis shows North America and Europe dominate the market currently, but significant growth opportunities exist in the Asia-Pacific region due to its expanding helicopter fleet and infrastructure development. Further market expansion will be propelled by technological advancements leading to lighter, more durable, and easily deployable life rafts. However, factors such as the high initial cost of these rafts and fluctuating raw material prices pose challenges to the market's growth. Competition among established players like Collins Aerospace, Safran, and Survitec Group remains intense, with companies focusing on product innovation and strategic partnerships to enhance their market position. The market is expected to witness further consolidation as companies strive to capitalize on the rising demand and expand their global reach. Continued investment in research and development, aimed at improving raft design and safety features, will be critical for sustained market growth. The integration of advanced technologies, such as GPS tracking systems, and improved materials will be key differentiators.

The global maritime search and rescue (SAR) equipment market is experiencing steady growth, projected to reach a value of $1584 million in 2025, exhibiting a Compound Annual Growth Rate (CAGR) of 4.7% from 2025 to 2033. This growth is fueled by several key factors. Increasing maritime traffic, coupled with stricter international regulations on maritime safety and security, necessitates advanced SAR equipment for effective response to emergencies. Technological advancements, such as the integration of AI and improved sensor technologies in life rafts, personal locator beacons (PLBs), and emergency position-indicating radio beacons (EPIRBs), are enhancing search and rescue operations and driving market expansion. Furthermore, rising awareness of maritime safety and the increasing adoption of comprehensive SAR strategies by coastal nations and international organizations are significantly contributing to market growth. Key players like Thales Group, General Dynamics, and Garmin Ltd. are driving innovation and competition in this sector. The market is segmented based on equipment type (e.g., EPIRBs, PLBs, life rafts, radar systems, underwater search equipment), application (commercial, military, governmental), and geography. While specific regional breakdowns are unavailable, we can anticipate that regions with high maritime activity and stringent safety regulations – such as North America, Europe, and East Asia – will hold significant market shares. Market restraints include the high initial investment costs associated with sophisticated SAR equipment and the challenges in maintaining and updating aging infrastructure. However, ongoing technological advancements, coupled with the imperative for improved maritime safety, are likely to overcome these challenges and further stimulate market expansion throughout the forecast period.

The global maritime search and rescue (SAR) equipment market, valued at $1584 million in 2025, is projected to experience robust growth, driven by increasing maritime traffic, stringent safety regulations, and advancements in SAR technology. A compound annual growth rate (CAGR) of 4.7% is anticipated from 2025 to 2033, indicating a significant market expansion. Key drivers include the growing demand for advanced equipment like AIS (Automatic Identification System) transponders, EPIRBs (Emergency Position Indicating Radio Beacons), and drone-based search technologies. Furthermore, the increasing focus on enhancing maritime safety and security, particularly in high-risk areas and developing economies, is fueling market growth. Government initiatives and international collaborations promoting standardized SAR protocols also contribute to the expanding market. While challenges exist, such as high initial investment costs for advanced technologies and the need for regular maintenance and updates, the overall market outlook remains positive, with significant opportunities for established players and new entrants. The market is segmented by equipment type (e.g., life rafts, life jackets, communication devices, and search and rescue drones), application (commercial, military, and government), and geographic regions. The competitive landscape is characterized by a mix of established players like Thales Group, General Dynamics, and Garmin, alongside regional manufacturers. These companies are actively investing in research and development to enhance their product offerings and expand their market share. Strategic partnerships, mergers, and acquisitions are becoming increasingly common, aiming to achieve technological advancements and broaden geographical reach. The market's future trajectory is shaped by ongoing technological innovation, particularly in areas such as AI-powered search algorithms and autonomous underwater vehicles (AUVs). These technological advancements offer the potential to improve search and rescue efficiency and effectiveness, leading to further market expansion in the coming years. Furthermore, the growing awareness of the environmental impact of maritime accidents and the need for sustainable SAR solutions will drive the adoption of eco-friendly technologies within the market.

This raster file represents land within the Raft River Study Area classified as either “irrigated” with a cell value of 1 or “non-irrigated” with a cell value of 0 at a 10-meter spatial resolution. These classifications were determined at the pixel level by a Random Forest supervised machine learning methodology. Random Forest models are often used to classify large datasets accurately and efficiently by assigning each pixel to one of a pre-determined set of labels or groups. The model works by using decision trees that split the data based on characteristics that make the resulting groups as different from each other as possible. The model “learns” the characteristics that correlate to each label based on manually classified data points, also known as training data.A variety of data can be supplied as input to the Random Forest model for it to use in making its classification determinations. Irrigation produces distinct signals in observational data that can be identified by machine learning algorithms. Additionally, datasets that provide the model with information on landscape characteristics that often influence whether irrigation is present are also useful. This dataset was classified by the Random Forest model using United States Geological Survey (USGS) Landsat 8 and 9 Level 2, Collection 2, Tier 1 data, Harmonized Sentinel-2 Multispectral Instrument Level-2A data, USGS 3D Elevation Program (USGS 3DEP) data, and Height Above Nearest Drainage (HAND) data. Landsat 8, Landsat 9, and HAND data are at a 30-meter spatial resolution, and the Sentinel-2 and USGS 3DEP data are at a 10-meter spatial resolution. Sentinel-2 Normalized Difference Vegetation Index (NDVI) values and National Agriculture Imagery Program (NAIP) imagery from 2021 (the most recent available) were used to determine irrigation status for the manually classified training data points. Irrigated training point locations were first identified by the NAIP 2021 imagery. Those point locations were then used to sample all available Sentinel-2 NDVI images for the 2022 growing season, and the time series at each point location was reviewed. Only points whose NDVI values remained at or above 0.6 for the majority of the growing season retained their irrigation classification. All non-irrigated training points were reviewed with Sentinel-2 NDVI and false-color imagery to ensure no new crop fields had been established in those locations during the previous year.The final model results were manually reviewed prior to release, however, no extensive ground truthing process was implemented. A wetlands mask was applied using the U.S. Fish and Wildlife Service’s National Wetlands Inventory (FWS NWI) data for areas without overlapping irrigation POUs or locations manually determined to have potential irrigation. “Speckling”, or small areas of incorrectly classified pixels, was reduced by using the Boundary Clean smoothing tool in ArcGIS with a descending sorting type.

Helicopter Life Raft Market Outlook

The global helicopter life raft market size is projected to grow significantly from USD 400 million in 2023 to approximately USD 700 million by 2032, with a compound annual growth rate (CAGR) of 6.2%. This substantial growth is primarily driven by the increasing emphasis on safety regulations and the rising number of helicopter operations across diverse sectors such as military, civil, and commercial applications. The demand for helicopter life rafts is expected to soar as safety protocols become more stringent and the number of airborne activities continues to expand.

One of the primary growth factors contributing to the helicopter life raft market is the stringent safety regulations and standards imposed by various aviation authorities worldwide. Organizations like the International Civil Aviation Organization (ICAO) and the Federal Aviation Administration (FAA) have mandated the inclusion of life-saving equipment, including helicopter life rafts, on certain categories of flights. These regulations have necessitated the adoption of high-quality, reliable life rafts, thereby bolstering market growth. Additionally, the rise in offshore oil and gas exploration activities has heightened the need for robust safety measures, including helicopter life rafts, to ensure the safety of crew members during emergencies.

Another significant driver for the market is the increasing use of helicopters in search and rescue missions, medical evacuations, and disaster relief operations. Helicopters are often deployed in remote or inaccessible areas where conventional means of transportation are not feasible. In such scenarios, the availability of life rafts becomes critical for the safety of both the crew and the individuals being rescued. The growing frequency of natural disasters and the subsequent need for efficient rescue operations have amplified the demand for helicopter life rafts. Moreover, advancements in technology have led to the development of lightweight, compact, and easily deployable life rafts, enhancing their usability and appeal.

The expanding commercial aviation sector, particularly in emerging economies, is also a significant growth factor for the helicopter life raft market. The increasing number of helicopter services for tourism, corporate travel, and transportation of goods has necessitated the adoption of comprehensive safety measures, including life rafts. The surge in helicopter tourism in picturesque and remote locations has further fueled the demand for reliable safety equipment. As the commercial aviation sector continues to grow, the need for helicopter life rafts is expected to rise correspondingly, contributing to the overall market expansion.

From a regional perspective, North America currently holds the largest market share in the helicopter life raft market, driven by the well-established aviation industry and stringent safety regulations. However, the Asia Pacific region is expected to witness the highest growth rate during the forecast period. The increasing investments in aviation infrastructure, coupled with the rising number of helicopter operations in countries like China and India, are expected to drive the demand for helicopter life rafts in this region. Additionally, the growing focus on enhancing safety measures in the aviation sector across various Asian countries is likely to contribute to the market growth.

Product Type Analysis

The helicopter life raft market can be segmented based on product type into single tube and multi-tube life rafts. Single tube life rafts are designed for simpler, smaller-scale operations and are typically used in situations where space and weight are critical factors. These life rafts are favored for their compact design and ease of deployment, making them suitable for personal or smaller commercial helicopter operations. Despite their smaller size, single tube life rafts are built to withstand harsh conditions and provide reliable safety in emergencies.

On the other hand, multi-tube life rafts are designed for larger-scale operations and are commonly used in military and larger commercial applications. These life rafts offer greater capacity and additional safety features, making them ideal for situations where multiple individuals need to be accommodated. The robustness and enhanced safety mechanisms of multi-tube life rafts make them a preferred choice for military missions and commercial helicopter services, where the risk factors are higher, and the safety requirements are more stringent.

The choice between single tube and mu

This dataset was generated to determine a 2017 water budget. The boundary of the study area extends from Idaho into a portion of Utah.This layer depicts polygons representing land within the Raft River Study area boundary classified as either "irrigated", "non-irrigated" or "semi-irrigated", where the semi-irrigated classification typically depicts residential land. Neither Irrigation status nor line work were verified by ground truthing. Field boundaries were refined using the 2017 Idaho National Agriculture Imagery Program (NAIP) imagery, Digital Ortho Photo Quadrangle (DOQQ) imagery, or other high resolution imagery. Attribute assignments for irrigation status (irrigated, non-irrigated, and semi-irrigated) are determined using available Landsat and/or Sentinel satellite imagery as background reference. Landsat imagery is typically 30-meter (Landsat5) or 15-meter (Landsat7) resolution. Sentinel imagery is 10-meter resolution. National Agriculture Inventory Program (NAIP) imagery, Digital Ortho Photo Quadrangle (DOQQ) imagery, and other in-house, scanned aerial imagery is used for determining irrigation status and refining the polygon geometry. The interpretation and classification process is described in detail in the report, "2006 Irrigated Land Classification for the Eastern Snake Plain Aquifer" archived on the IDWR website: Legal Actions > Delivery Call Actions > SWC > Archived Matters > Technical Working Group Documents (https://idwr.idaho.gov/legal-actions/delivery-call-actions/SWC/archived-matters.html#twg-documents).

The global helicopter life raft market is poised for significant growth, driven by increasing demand for enhanced safety measures in the aviation industry, particularly within civil and military sectors. The market's expansion is fueled by stringent regulatory compliance requirements mandating the presence of life-saving equipment on helicopters, coupled with rising helicopter operations across diverse applications like offshore oil and gas exploration, search and rescue missions, and emergency medical services. Technological advancements, leading to the development of lighter, more durable, and technologically advanced life rafts with features like improved buoyancy, enhanced survival gear integration, and GPS tracking capabilities, further stimulate market growth. The market is segmented by raft capacity (4-6 person, 6-10 person, 10-20 person, and over 20 person) allowing manufacturers to target specific needs, with the larger capacity rafts likely to see higher demand in commercial and military applications. Geographic segmentation reveals strong market presence in North America and Europe, owing to established helicopter operations and robust safety regulations. However, Asia-Pacific is projected to witness the fastest growth rate due to increasing investments in infrastructure and aviation sectors, specifically in countries like China and India. While the market faces restraints like high initial investment costs associated with acquiring life rafts and the need for regular maintenance, the overall market outlook remains positive, indicating substantial expansion opportunities for existing and new market players. Despite challenges, the market is characterized by a competitive landscape with both established players and emerging manufacturers. Key players such as Collins Aerospace, Safran, and Survitec Group are driving innovation, consolidating their market share through strategic partnerships and investments in R&D. The growing adoption of advanced materials and technologies, along with a focus on improving the overall user experience, promises to further propel market growth in the coming years. The increasing focus on environmental sustainability will also influence the market, with manufacturers exploring eco-friendly materials and production processes. This commitment to sustainability and technological advancements suggests a dynamic and evolving market with considerable growth potential throughout the forecast period.

Inflatable Rafts Market Outlook

According to our latest research, the global inflatable rafts market size reached USD 1.92 billion in 2024, with a robust year-on-year growth fueled by expanding recreational and rescue applications. The market is expected to advance at a CAGR of 6.1% from 2025 to 2033, propelling the total value to approximately USD 3.26 billion by 2033. This steady growth is primarily driven by increasing consumer interest in outdoor adventure activities, rising investments in safety and rescue operations, and technological innovations in raft materials and design.

One of the primary growth factors for the inflatable rafts market is the surge in demand for recreational water sports and adventure tourism. As disposable incomes rise and urban lifestyles become more stressful, consumers are seeking unique and thrilling experiences such as white-water rafting, river expeditions, and wilderness exploration. The proliferation of adventure tourism operators and the increasing accessibility of remote water bodies have further stimulated the adoption of inflatable rafts. In addition, the versatility and portability of modern inflatable rafts make them attractive to both novice enthusiasts and seasoned adventurers, thereby expanding the market’s consumer base. Enhanced safety features, ease of transport, and improved durability have also contributed to the market’s growth, making inflatable rafts a preferred choice over traditional rigid boats.

Another significant growth driver is the increasing utilization of inflatable rafts in military and rescue operations. Governments and defense agencies across the world are investing in advanced rescue equipment to enhance disaster preparedness and response capabilities. Inflatable rafts are favored for their lightweight construction, rapid deployment, and ability to navigate challenging terrains, including flooded urban areas and swift rivers. These attributes are critical during natural disasters, search and rescue missions, and humanitarian aid operations. The integration of innovative materials such as reinforced PVC, Hypalon, and polyurethane has further improved raft performance, offering greater puncture resistance and longevity, which is essential for demanding rescue environments. This has led to a steady rise in procurement contracts from government agencies and non-governmental organizations.

Technological advancements in raft materials and manufacturing processes have played a pivotal role in shaping the inflatable rafts market. The development of high-performance fabrics and coatings has enabled manufacturers to produce rafts that are not only lightweight and compact but also highly resistant to UV radiation, abrasion, and chemical exposure. Furthermore, the introduction of modular designs, self-bailing mechanisms, and enhanced buoyancy features has broadened the scope of applications, from recreational use to commercial and industrial settings. Manufacturers are also investing in eco-friendly materials and sustainable production practices to address environmental concerns, which is increasingly influencing purchasing decisions among environmentally conscious consumers and organizations.

From a regional perspective, North America continues to dominate the inflatable rafts market, accounting for a significant share of global revenue in 2024. The region’s leadership can be attributed to its vibrant outdoor recreation culture, well-established adventure tourism infrastructure, and strong presence of leading raft manufacturers. Europe follows closely, driven by growing adventure tourism in countries such as Germany, France, and the United Kingdom. Meanwhile, Asia Pacific is emerging as the fastest-growing market, with rising disposable incomes, expanding tourism sectors, and increasing government focus on disaster management and rescue operations. Latin America and the Middle East & Africa are also witnessing gradual growth, supported by expanding water sports activities and investments in safety infrastructure.

Product Type Analysis

Globally, species distributions are shifting in response to environmental change, and those that cannot disperse risk extinction. Many taxa, including marine species, are showing poleward range shifts as the climate warms. In the Southern Hemisphere, however, circumpolar oceanic fronts can present formidable barriers to dispersal4. Although passive, southward movement of species across this barrier has been considered unlikely, the recent discovery of buoyant kelp rafts on beaches in Antarctica demonstrates that such journeys are possible. Rafting is a key process by which diverse taxa ��� including terrestrial and coastal marine species ��� can cross oceans. Kelp rafts can carry passengers, and thus can act as vectors for long-distance dispersal of coastal organisms. The small numbers of kelp rafts previously found in Antarctica do not, however, shed much light on the frequency of such dispersal events. We here use a combination of high-resolution phylogenomic analyses (>220,000 SNPs) and oceanographic modelling to show that long-distance biological dispersal events in the Southern Ocean are not rare. We document tens of kelp (Durvillaea antarctica) rafting events of thousands of kilometres each, over several decades (1950 ��� 2019), with many kelp rafts apparently still reproductively viable. Modelling of dispersal trajectories from genomically-inferred source locations shows that some distant landmasses are particularly well connected, for example South Georgia and New Zealand, and the Kerguelen Islands and Tasmania. Our findings illustrate the power of genomic approaches to track, and modelling to show frequencies, of long-distance dispersal events.

To determine the proteins in the membrane raft, we used the TMT-labeling and nano-liquid chromatography mass spectrometry (nano-LC-MS/MS) analysis by Creative Proteomics (NY, USA; https://www.creative-proteomics.com/). Rat primary microglia were treated with IL-6 (25 ng/ml) for 15 min. Membrane rafts were obtained by flotation assay. Samples were prepared from three independent experiments. Proteins in equal volumes of raft fractions were digested with trypsin, desalted, and labeled with a TMT reagent (Thermo Fisher Science). The TMT-labeled peptides were fractionated and analyzed by nano-LC-MS/MS. The resulting MS/MS data were analyzed and searched against the rat protein database using Proteome Discoverer 2.1.

We used a process-based water temperature model (RAFT, Pike et al., 2013) to estimate the ability of reservoir discharge to mediate river temperature heating processes impacting downstream locations (i.e., discharge-mediated temperature management) on California's Sacramento River. This was done by modeling water temperatures over the historical record (1990-2020) of model forcings and only perturbing reservoir discharge levels on a daily time step, ranging from 3000 to 15000 cubic feet per second as simulated at the Sacramento River at Wilkins Slough USGS gauging station (https://waterdata.usgs.gov/monitoring-location/11390500). Pike, A., E. Danner, D. Boughton, F. Melton, R. Nemani, B. Rajagopalan, and S. Lindley. 2013. Forecasting river temperatures in real time using a stochastic dynamics approach. Water Resources Research 49:5168-5182.

Report of Raft Fishing Reel is covering the summarized study of several factors encouraging the growth of the market such as market size, market type, major regions and end user applications. By using the report customer can recognize the several drivers that impact and govern the market. The report is describing the several types of Raft Fishing Reel Industry. Factors that are playing the major role for growth of specific type of product category and factors that are motivating the status of the market.

This raster file represents land within the Raft River Study Area classified as either “irrigated” with a cell value of 1 or “non-irrigated” with a cell value of 0 at a 30-meter spatial resolution. These classifications were determined at the pixel level by a Random Forest supervised machine learning methodology. Random Forest models are often used to classify large datasets accurately and efficiently by assigning each pixel to one of a pre-determined set of labels or groups. The model works by using decision trees that split the data based on characteristics that make the resulting groups as different from each other as possible. The model “learns” the characteristics that correlate to each label based on manually classified data points, also known as training data. A variety of data can be supplied as input to the Random Forest model for it to use in making its classification determinations. Irrigation produces distinct signals in observational data that can be identified by machine learning algorithms. Additionally, datasets that provide the model with information on landscape characteristics that often influence whether irrigation is present are also useful. This dataset was classified by the Random Forest model using Level 2 (surface reflectance), Collection 2, Tier 1 data from Landsat 7 and Landsat 8, Mapping Evapotranspiration with Internalized Calibration (METRIC) data produced by IDWR, United States Geological Survey National Elevation Dataset (USGS NED) data, and Height Above Nearest Drainage (HAND) data. Landsat 7, Landsat 8, METRIC, and HAND data are at a 30-meter spatial resolution, and the USGS NED data are at a 10-meter spatial resolution. The Cropland Data Layer (CDL) from the United States Department of Agriculture (UDSA) National Agricultural Statistics Service (NASS), National Agriculture Imagery Program (NAIP) data from the USDA Farm Service Agency (FSA), Utah Water Related Land Use data from the Utah Division of Water Resources, and water rights data from IDWR were also used in determining irrigation status for the manually classified training data points but were not used for the machine learning model predictions. The final model results were manually reviewed prior to release, however, no extensive ground truthing process was implemented. “Speckling”, or small areas of incorrectly classified pixels, was reduced by masking all pixels with a slope value of 10% or greater as “non-irrigated”, regardless of the status they were assigned by the Random Forest model. Speckling within irrigated areas was reduced by a majority filter smoothing technique using a kernel of 8 nearest neighbors. A limited amount of manual corrections were also made to the final results.

Euro Raft Srl Company Export Import Records. Follow the Eximpedia platform for HS code, importer-exporter records, and customs shipment details.

9412 Global exporters importers export import shipment records of Life raft and Hsn Code 89071000 with prices, volume & current Buyer's suppliers relationships based on actual Global export trade database.

Data generated from laboratory experiments that investigated the influence of fluctuating environmental conditions on the attachment strength of byssal threads as they aged. Mussels (M. trossulus) were collected from Penn Cove Shellfish, Quilcene Bay, Quilcene, Washington, USA Penn Cove Shellfish hatchery, Quilcene Bay, Quilcene, Washington, USA [47°47’48.0” N, 122°51”16.6” W] and held in experimental aquaria at the University of Washington in Seattle, Washington, USA for up to 14 days. Mussels produced threads over the course of 4 hrs that were aged in fluctuating oxygen and pH conditions for up to 20 days. Adhesive plaques were then pulled to failure to determine adhesion strength. A second cohort of mussels was placed in static pH and Oxygen treatments, recording the number of threads produced by each over one week.

Access Life Raft import export data of global countries with importers' & exporters' details, shipment date, price, hs code, ports, quantity etc.

Japan SPPI: OFT: Railroad freight transportation (RAFT) data was reported at 102.600 2010=100 in Jun 2018. This records a decrease from the previous number of 103.100 2010=100 for May 2018. Japan SPPI: OFT: Railroad freight transportation (RAFT) data is updated monthly, averaging 101.750 2010=100 from Jan 2010 (Median) to Jun 2018, with 102 observations. The data reached an all-time high of 105.300 2010=100 in Sep 2016 and a record low of 97.100 2010=100 in May 2011. Japan SPPI: OFT: Railroad freight transportation (RAFT) data remains active status in CEIC and is reported by Bank of Japan. The data is categorized under Global Database’s Japan – Table JP.I042: Service Producer Price Index (SPPI): 2010=100.