A robotic fish includes a front body, a rear body that includes a first segment and a second segment, and a driving unit. The first segment has a front engaging portion projecting toward and pivotally connected to the front body, and a rear engaging portion formed with a recess that recedes toward the front body and pivotally connected to the second segment. The driving unit includes a motor disposed in the front engaging portion, and a shaft extending along a dorsoventral axis and connecting the motor and the rear connecting portion. A ratio of a distance between the shaft and a foremost edge of the front engaging portion to a distance between the foremost edge and an extreme point of the recess ranges from 0.075 to 0.75.

A lift and drive unit for an aircraft or submarine vehicle may include a hydrogen based drive component for providing a forward drive force to move the aircraft or vehicle over ground, and a hydrogen-based lift component for providing an upward drive force to move the aircraft or vehicle upward. An onboard hydrogen generating apparatus is connectable to both the drive component and the lift component, for providing the drive and lift components with hydrogen.

Implementations described and claimed herein provide an underwater vehicle includes a vehicle body having a frame enclosed by a fairing. The vehicle body extends between a proximal end and a distal end and defining an interior. A nose is disposed at the proximal end of the vehicle body. The nose has a tow system configured to move between a tow position and a stow position. A propulsion system is disposed at the distal end of the vehicle body. The propulsion system includes a plurality of control fins and a thruster. A power distribution system is housed in the interior of the vehicle body. The power distribution system includes a first power system housed in a first pressure vessel and a second power system housed in a second pressure vessel. The first pressure vessel is isolated from the second pressure vessel.

Performing a seismic survey in an aqueous medium is provided. A system can include a transfer device with a first vertical side and a second vertical side. The transfer device can include a chute to receive units. The chute extends from the first vertical side to the second vertical side. The chute has a first end at the first vertical side that is higher than a second end at the second vertical side opposite the first end to establish a first slope for the chute, which causes the units to slide from the first end towards the second end via gravity. The transfer device includes a retainer at the second end of the chute to be actuated by an arm of a first underwater vehicle that mates with the chute. The transfer device can be towed by a marine vessel via an unpowered rope.

A method of generating electricity in a body of water includes providing a colony of sulfur-reducing bacteria, a colony of sulfur-oxidizing bacteria, and a colony of denitrifying bacteria submerged in the body of water. The colony of sulfur-reducing bacteria can be used to convert at least a portion of sulfates present in the body of water to hydrogen sulfide. The colony of sulfur-oxidizing bacteria can be used to convert the hydrogen sulfide to sulfuric acid, which can react with manganese to produce hydrogen gas. The colony of denitrifying bacteria can be used to convert at least a portion of nitrogen oxides in the body of water to nitrogen gas, which can be bubbled through a portion of water from the body of water to remove dissolved oxygen gas. The hydrogen gas and oxygen gas can be combined in a fuel cell generator to generate electricity.

In order to meet the objectives described above, the present invention provides a robot for detecting breakdown of NORM (Naturally Occurring Radioactive Materials) in a production system, in order to plan operations to remove scale containing radioactive material, and for decommissioning subsea system operations. The fields of application are the area of flow assurance and reservoir management, using operations to chemically remove scale containing NORM in the production system, and to improve the safety of the decommissioning processes of production systems. The invention allows the position of the scale inside the production system to be safely detected, such as, for example, the beginning of the deposit inside a production line, the extension of the deposit, and the end of the deposit, as well as whether the deposit occurred at different points along the production line.

A subsurface diver transport vehicle includes a vehicle body and at least one propulsion device. The vehicle body incorporates a number of individual mission modules mechanically assembled together to define a substantially continuous hull and deck of the vehicle. The mission modules include at least one battery module adapted for supplying electrical current to electrical subsystems of the vehicle. The propulsion device is attached to the vehicle body and capable of propelling the vehicle through a body of water.

A flexible underwater robot, a control method and a device is provided with at least one movable joint and a control module. A flexible joint module of the movable joint comprises a first connecting plate, a second connecting plate, a first spring, several second springs, several third springs, several first pulling ropes, several second pulling ropes and a pulling module. The first spring, the second springs and the third springs are arranged from inside to outside in sequence with gradually decreased rigidities correspondingly to form a gradual rigidity structure, so that it is more flexible to adjust a posture. When the robot is impacted, it may absorb and release energy to ensure the integrity of the flexible joint module, so that the stability is improved.

Techniques are disclosed for providing retractable control fins on an underwater vehicle. The retractable control fins can be extended away from a main hull portion of the underwater vehicle and retracted inwards to a stowage region within the hull portion to protect the fins from damage and reduce an overall outer diameter (e.g., in the case of a cylindrical body) of the underwater vehicle. In some embodiments, the control fins are folded inwards to reduce the vehicle diameter. In other embodiments, the control fins are pulled inwards using a rotating structure designed to slide the control fins through an opening and into an inner portion of the hull to reduce the vehicle diameter. The retraction of the fins through the various retraction mechanisms reduces the envelope diameter of the underwater vehicle.

Provided are an underwater robot and a method and apparatus for controlling an underwater robot. The underwater robot includes a robot body and at least three groups of thruster arrays disposed on sides of the robot body. Each group of thruster array includes two thruster components, each of the two thruster components includes a housing and a propelling mechanism, the two thruster components in each group of thruster array are symmetrically disposed on two sides of the robot body about a central axis of the robot body, and at least three values of included angles between propelling directions of at least three thruster components located on a same side of the central axis, and the central axis are formed. The control method includes: acquiring coordinates of a target position point and enabling a robot body to arrive at the target position point by using at least three groups of thruster arrays disposed on sides of the robot body.