当社グループは 3,000 以上の世界的なカンファレンスシリーズ 米国、ヨーロッパ、世界中で毎年イベントが開催されます。 1,000 のより科学的な学会からの支援を受けたアジア および 700 以上の オープン アクセスを発行ジャーナルには 50,000 人以上の著名人が掲載されており、科学者が編集委員として名高い
。オープンアクセスジャーナルはより多くの読者と引用を獲得
700 ジャーナル と 15,000,000 人の読者 各ジャーナルは 25,000 人以上の読者を獲得
Chhaya Chaudhary
Internal seawater systems (ISS) are essential to a maritime vessel's efficient operation. On board ships, sea water is pumped for a variety of purposes, notably for water provision, cooling capacity, and temperature control (e.g., air conditioners, and electrical systems) (e.g., drinking, firefighting, steam, and ballast). Even while sea water may only briefly enter a ship's internal space system (ISS), it can spread bacteria and macroorganism larvae throughout the system, causing biofouling accumulation that may compromise system integrity or performance. ISS has the ability to support biological invasions by acting as a sub-vector of species translocations. Reports and studies of ISS biofouling are scarce, and much of the specialized literature is decade’s old, due to the difficulty of accessing ISS interior components. The effects of biofouling on ISS and vessel operations are based on increased pipework and equipment surface roughness, constrained water flow, corrosion and component impingement, decreased surface functional efficiency, and potential pathogen contamination that may be harmful to aquatic life and humans. Antifouling coatings and marine growth prevention systems are the key tools used to regulate biofouling, but there are few reliable and easily accessible studies on how effective these systems are in ISS. The level of biofouling in the ISS of the current commercial fleet and the effectiveness of preventative devices need more investigation. Ultimately, decisions based on this information can help ship operators operate more efficiently and guarantee that any potential biosecurity hazards are properly managed