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The Hybrid ROV Freedom is an innovative underwater vehicle developed to cover the functions of work class ROV, observation ROV & survey AUV. It combines the capabilities of both ROVs and AUVs, offering versatility and efficiency in underwater operations. Here's an overview of its features and capabilities: Hybrid Design: The Freedom ROV is designed to operate both as a traditional tethered ROV and as an autonomous underwater vehicle (AUV). This hybrid functionality allows it to perform a wide range of tasks in various underwater environments. Tethered ROV Mode: In tethered mode, the Freedom ROV can be controlled remotely by operators on the surface using a tether cable. This mode provides real-time control and feedback, making it suitable for tasks that require precise maneuvering and manipulation, such as inspection, maintenance, and repair operations. Autonomous Mode: The Freedom ROV can also operate autonomously, following pre-programmed missions or conducting surveys without the need for a tether cable. In this mode, it utilizes onboard sensors and navigation systems to navigate underwater environments and collect data. Versatile Applications: The Hybrid ROV Freedom is suitable for a wide range of applications, including offshore oil and gas exploration, marine research, underwater inspection, search and rescue operations, environmental monitoring, and underwater mapping. Advanced Features: The Freedom ROV is equipped with advanced imaging systems, sensors, and manipulator arms to facilitate its various tasks. It may include high-definition cameras, sonars, navigation systems, and tools for sample collection or manipulation. Efficiency and Cost-Effectiveness: By combining the capabilities of both ROVs and AUVs, the Freedom ROV offers increased flexibility, efficiency, and cost-effectiveness in underwater operations. It can perform tasks that would typically require multiple vehicles or equipment, streamlining operations and reducing overall costs.

Remotely Operated Vehicles (ROVs) are underwater robots used for various applications, including ocean exploration, scientific research, and underwater inspections. Here are the main types of ROVs: 1. Observation Class ROVs These are small, lightweight ROVs primarily used for visual inspection and monitoring tasks. They are equipped with cameras and basic sensors and are often used in underwater archaeology, biological studies, and pipeline inspections.Key Features:Compact and portable Equipped with cameras and lights Limited payload capacity Operated at shallow to moderate depths 2. Inspection Class ROVs Slightly larger and more capable than observation class ROVs, inspection class ROVs are used for more detailed inspections and surveys. They are commonly employed in the oil and gas industry, offshore wind farms, and underwater infrastructure inspections.Key Features:Higher payload capacity than observation class Equipped with high-definition cameras and advanced sensors Can be fitted with additional tools like sonar and manipulators Operated at greater depths. 3. Work Class ROVs These ROVs are larger and more powerful, designed to perform heavy-duty tasks underwater. They are commonly used in the oil and gas industry for construction, maintenance, and repair of underwater structures.Key Features:High payload Capacity Equipped with manipulators, cutting tools, and welding Equipment Can operate at significant depths (up to 3000 meters or more)Often require a dedicated support vessel for deployment. 4. Light Work Class ROVs A subset of work class ROVs, these are smaller and less powerful but still capable of performing a variety of tasks. They are used when full-sized work class ROVs are not necessary but more capability than inspection class ROVs is required.Key Features:Intermediate payload Capacity Equipped with basic manipulators and Tools Suitable for moderate-depth operations. 5. Micro and Mini ROVs These are the smallest class of ROVs, designed for very shallow and confined space operations. They are often used for inspecting pipelines, water tanks, and small underwater structures.Key Features:Extremely compact and Lightweight Easy to deploy and Operate Limited operational depth and payload Capacity Equipped with basic cameras and lights 6. Hybrid ROVs These are versatile ROVs that can operate both autonomously (like Autonomous Underwater Vehicles or AUVs) and be remotely controlled. They are used in applications requiring both automated surveys and detailed inspections or interventions. Key Features: Dual operation modes (autonomous and a variety of or complex missions requiring from the ocean floor, studying marine life, and monitoring environmental conditions.Oil and Gas Industry: Inspecting and maintaining underwater pipelines, rigs, and other infrastructure.Underwater Construction...

𝗜𝗡𝗗𝗨𝗦𝗧𝗥𝗜𝗔𝗟 𝗗𝗥𝗢𝗡𝗘 𝗢𝗣𝗘𝗥𝗔𝗧𝗜𝗢𝗡𝗦 𝗯𝘆 𝗦𝗔𝗙𝗘𝗧𝗬 𝗪𝗢𝗥𝗞𝗦 Suitable for all personnel who are involved in the use of Drones in an industrial/commercial environment. An excellent course for OIMs, HSE Specialists, Permit to Work Coordinators, Operations Superintendents, Asset Integrity Engineers, Planning Engineers etc to take in order to better understand the planning, risk assessments and other safety aspects of Industrial Drone Operations within O&G Assets Worldwide. OEUK Recommend that Drone Pilots are trained over and above the commercial pilot licenses that are gained for ‘normal’ commercial work. The Industrial Drone Operations Training Course ensures the duty of care and responsibility that the major energy and utility companies require are met, in order to prove that drone pilots can perform to the highest levels required in challenging conditions. Contact us on enquiries@safety.works for more information. #DroneTraining #IndustrialDrones #ECITB #DroneCertification #Elearninng #SafetyTraining #UKCertification #DroneOperations #ProfessionalDevelopment #DroneSafety #DroneTechnology #RemoteSensing #WorkplaceSafety #AviationSafety #DroneSkills #TrainingAndDevelopment #SafetyStandards #DronesInIndustry #DigitalLearning #IndustrialTech

Intervention Techniques Used Underwater 1- How inspection data is gathered underwater One of the first considerations for any underwater IMR program has to be how is the data to be gathered? It is not possible to inspect any item underwater without first determining how to get the inspector and any NDT equipment to the job site. There are several intervention techniques employed offshore which include: x Divers. x Various types of ROV. x Remote sensors and cameras. x Autonomous unmanned vehicles (AUV). x Manned submersibles. These intervention systems will be considered from the perspective of the advantages and disadvantages of each and any restrictions with the particular method. Because they are all means of working underwater, particularly divers and manned submersibles, a review of the more important physics that apply to any underwater intervention technique will be beneficial in understanding the restrictions and safety requirements for the various techniques. 2- Pressure The increase in the pressure exerted on anything that is submerged is quite dramatic, increasing by 0.1b for every 1m descent. The SI unit of measure for pressure is the Bar (b) (1bar = 14.7psi). 2.1 Absolute pressure In physics pressure is measured in terms of absolute (Abs) pressure, which for the practical purposes considered here is atmospheric pressure (1b) plus the relative pressure being exerted by the column of water. 2.2 Gauge or relative pressure In practical everyday measurements of pressure gauge pressure is normally considered. This is a direct reading of the pressure being exerted on the measuring pressure gauge without taking into account the atmospheric pressure. 2.3 Pressure increase with water depth For every 10m descent into the ocean the pressure will increase is 1 bar. Table below illustrates this. #subsea #oilandgas #offshore

Hello, Drone Operator! Want to be a part of the world's largest E-Commerce client? Please share your updated resume @ prince.singh@collabera.com Ph: +1 (973) 381-6816 and I'll be happy to set up some time to chat. #InPursuitofGREATNESS Job Title: Support Engineer II (Drone Operator/ Operator in Commands) Job Location: Seattle, WA Job Duration: 9 Months (Contract to hire) Pay Rate: $30.87/hr to $31.87/hr Schedule: 4-5 days a week M-F. Shift varies - can start as early at 4:00AM and end as late as 10:00PM. 40/hrs + OT potential. Mission: ·      Their work lays the ground work expectations for how the commercialized variant the MK30 will perform given these testing datasets.   What will this person be accomplishing for you in the business? ·      These pilots will be collecting data for the data collections research team. ·      Their data and interactions with the engineers will help push the development toward impactful bug fixes and optimizations for the aircraft.   Day to Day: ·      Data Collection Team flying consumer drones for Data Collection ·      Take In-house Manufacture payload and simulate the data for shipping under different weather conditions or environments. Based off geographic locations -> this is what prompts need for travel. ·      Schedule may change depending on certain daylight conditions ·      Crew sent out in 2 -person teams, each performs their own duties. 1 is Safety Officer and 1 is Pilot   Must Haves: ·      2+ years of commercial drone piloting experience. ·      14 CFR Part 107 Remote Pilot Certificates. ·      Minimum of 200 RPIC Flight Hours Logged. ·      Troubleshooting experience with Windows or Mac ·      Field Experience: able to operate in the field aspect of drone Piloting ·      Understanding of the Drone Industry and how the companies are competing ·      Experience in more commercial types of drones. Knowledge of safety operations around commercial drone piloting ex: weather condition factors, airspace, etc. ·      Ability and willingness to travel (very important) ·      Time management & attendance (HUGE) strict timelines daily ·      Coordination and organization   Plusses: ·      Military drone pilots typically do well.   Leadership Principle: ·      Earn trust ·      Bias for action ·      Ownership

Subsea remotely operated vehicles (ROVs) are equipped with manipulator arms to perform various tasks in underwater environments. These manipulator arms typically have several degrees of freedom (DOF), which refer to the number of independent movements or axes of motion they can perform. The functions and DOF of subsea ROV manipulator arms depend on their design and purpose, but here are some common functions and their associated degrees of freedom: Grasping: Grasping objects is one of the primary functions of ROV manipulator arms. This involves gripping, lifting, and manipulating items underwater. DOF: Generally, grasping manipulator arms have at least 3 DOF: yaw, pitch, and roll. Some may have additional DOF for better dexterity. Cutting: ROVs are often equipped with cutting tools to sever cables, ropes, or other materials underwater. DOF: Cutting manipulator arms typically have 3 DOF for positioning the cutting tool accurately. They may also have rotational DOF for orienting the tool. Manipulating: This involves precise positioning and manipulation of objects for tasks such as assembly, inspection, or repair. DOF: Manipulation arms can vary in DOF depending on the complexity of tasks they are designed for. They commonly have 5 to 7 DOF, including translational and rotational movements. Sampling: ROVs may need to collect samples from the seabed or other underwater surfaces for scientific or environmental monitoring purposes. DOF: Sampling manipulator arms require precise control and often have multiple DOF, typically around 5 to 7, to facilitate accurate sample collection. Tool Handling: ROVs may need to use various tools for specific tasks, such as attaching or detaching equipment. DOF: Tool handling manipulator arms usually have similar DOF to manipulation arms, allowing them to position and operate tools effectively. Inspection: Manipulator arms may be used to deploy cameras or sensors for inspection tasks, such as examining underwater structures or pipelines. DOF: Inspection manipulator arms may have fewer DOF compared to other types, typically around 3 to 5, depending on the range of motion required for deploying inspection equipment. These functions and DOF enable ROV manipulator arms to perform a wide range of tasks in challenging underwater environments, supporting activities such as offshore oil and gas exploration, underwater construction, scientific research, and marine salvage operations.

Ever wondered what it takes to be a professional drone pilot? Let's dive into a typical day and explore the skills and training required for this exciting career! Pre-Flight Preparation: Reviewing flight plans, checking weather conditions, and ensuring equipment is in top shape. Skills in meteorology and technical knowledge of drones are crucial. DGCA certification is MANDATORY. On-Site Operations: Conducting site surveys and risk assessments. Setting up and calibrating the drone. Proficiency in operating various drone models and problem-solving skills are essential. Flight Time: Capturing footage or conducting inspections with precision and focus. Expertise in aerial photography, GIS mapping, or industry-specific applications enhances work quality. Post-Flight and Data Analysis: Analyzing collected data and preparing detailed reports for clients. Knowledge in data analysis and familiarity with tools like Photoshop, AutoCAD, or GIS software are often required. Continuous Learning: The drone industry is rapidly evolving, so continuous education is vital. Attending workshops, obtaining advanced certifications, and staying updated with the latest tech trends keep pilots ahead in the field. Being a professional drone pilot is a dynamic and rewarding career combining technical expertise, creativity, and a passion for innovation. Curious about the drone pilot life or thinking of starting a career in this field? Drop your questions or comments below! #DronePilot #DayInTheLife #DroneTechnology #SkillsAndTraining #ProfessionalDevelopment #Innovation

A test lab for #ROVs (Remotely Operated Vehicles) and other underwater robots is a specialized facility where these machines are tested under controlled conditions. These labs are designed to simulate the marine or aquatic environments in which the ROVs will eventually operate. Here’s how such a lab typically works: 1. Facility DesignTest Pool: Most #ROV test labs have a large tank or pool where the vehicles can be submerged. These tanks often come equipped with systems to control the temperature, salinity, pressure, and sometimes even currents and waves, allowing them to mimic different marine conditions. Cabling and Communication Systems: ROVs are usually connected to a control station via an umbilical cable, which supplies power and allows data transfer. The lab is set up to handle these connections efficiently. Control Stations: These labs feature control stations where operators can pilot the ROVs, monitor real-time #data, and make adjustments as needed. 2. Testing ProceduresFunctional Testing: Before submerging the ROV, its systems are thoroughly checked to ensure everything is working properly—this includes propulsion, cameras, sensors, and any manipulators. Mission Simulations: Once everything checks out, the ROV is submerged for tests that simulate real-world missions. This might involve tasks like object manipulation, inspecting underwater structures, or navigating through obstacles. Durability and Stress Testing: ROVs undergo tests for pressure resistance, performance at different depths, and durability under challenging conditions (like corrosion, high pressure, and impacts). Data Collection: During the tests, data is collected via the ROV’s sensors and analyzed to assess its performance. This might include video footage, temperature readings, depth measurements, and more. 3. Analysis and OptimizationAnalyzing Results: After the tests, the collected data is analyzed to spot any issues or weaknesses. This helps determine whether the ROV is ready for real-world deployment or if it needs further adjustments. Tweaks and Modifications: Based on the test results, engineers may make modifications to improve the ROV’s performance. These changes are then retested in the lab. 4. Safety Protocols: The test lab is designed with safety in mind, both for the operators and the equipment. This includes protocols for handling emergencies, such as an ROV malfunction or a leak in the #tank. 5. Collaboration and TrainingResearch and Development: These labs often play a role in the research and development of new underwater technologies. They may also collaborate with #universities or companies to test prototypes. Training: The labs can also serve as training grounds for ROV operators, giving them hands-on experience in a controlled environment before they head out to the field.In short, an ROV test lab is a critical environment for ensuring these vehicles are ready to operate reliably and effectively in real-world #marine conditions.

It is not just about obtaining the drone license; it is about internalizing the information to ensure safe, legal, and proficient flight operations. https://lnkd.in/gNv3HJJq