Disclosed are a position locking method of an underwater equipment, a terminal device, a system and a medium. The method comprises: acquiring an optical image and a sonar image taken by an underwater equipment; obtaining a target image by synthesizing the optical image and the sonar image, the target image including at least a target object; determining position offset information of the target object according to the target image; and generating position control parameters of the underwater equipment according to the position offset information, and sending position control parameters to the underwater equipment to make the underwater equipment to lock a position according to the position control parameters. The present application greatly reduces operation difficulty of the underwater equipment in turbid or undercurrent water areas.

A novel underwater robot water quality data acquisition device includes a casing, a thruster group, an upper cabin, a lower cabin, a buoy cabin, an upper cabin tray, a lower cabin tray, a power supply assembly, a power conditioning module, a data acquisition control module, a water quality sensor assembly, and a wireless Internet of Things (IoT) module. The device can convert the power supply voltage required by each other module through the power management module. The data acquisition control module transmits signals to the water quality sensor assembly in a set timing sequence, performs real-time reading and processing of water quality data fed back from the sensor, and uploads the processed water quality data to the data platform through the wireless IoT module, thereby achieving the display and preservation of water quality data.

The present invention discloses a modular underwater robot and a control method therefor. The modular underwater robot includes support plates, a first chamber, a second chamber, and a power assembly, where the supporting plates are stacked, and front end edges and rear end edges of the support plates are respectively provided with a first hollow portion and a second hollow portion; the first chamber is disposed in the first hollow portion; the second chamber is disposed in the second hollow portion, and the second chamber and the first chamber are in a same horizontal position; and the power assembly includes fixed vector thrusters and vertical thrusters. As such, the fixed vector thrusters can enable the modular underwater robot to move forward, backward, or rotatably, so that flexibility of the modular underwater robot can be improved.

A field configurable autonomous vehicle includes modular elements and attachable components. The vehicle can be assembled from these modular elements and components to meet desired mission and performance characteristics without the need to purchase specially designed vehicles for each mission. The vehicle can include a modular propulsion system with magnetic drive.

A deep-ocean polymetallic nodule collector is an apparatus that is used to harvest polymetallic nodules and other natural resources from the ocean floor. To do so, the apparatus includes a support frame and a collection mechanism. The support frame is a durable structure designed to withstand the harsh deep-ocean conditions. The support frame keeps the collection mechanism adjacent to the ocean floor for the mining of polymetallic nodules without damage to the underwater ecosystem. In addition, the support frame allows for attachment of mining support vehicles that support the operation of the apparatus. The mining support vehicles can include, but are not limited to, cabled vehicles which are connected to the surface for power, monitoring, and control, wireless submersible vehicles, or ocean-bottom based vehicles that can operate autonomously, semi-autonomously, or by remote control. The collection mechanism enables the collection of polymetallic nodules while minimizing the damage to the underwater ecosystem.

A field configurable autonomous vehicle includes modular elements and attachable components. The vehicle can be assembled from these modular elements and components to meet desired mission and performance characteristics without the need to purchase specially designed vehicles for each mission. The joints connecting the modules are designed such that power and data connections between modules are reliably made.

The invention relates to a system (1, 2) (1, 4) for handling marine (3) or underwater (5) drones, the system (1, 2) (1, 4) comprising a drone interface module (2, 4) and a floating pontoon (1) with two hulls (11) and an arch (10), the pontoon (1) is catamaran-shaped and delimits a downflooded reception space (17), the arch (10) comprises at least one device (12) for attachment to a winch cable, the pontoon (1) comprises devices (13) for detachable attachment to a drone interface module (2, 4) detachably and interchangeably installed in the receiving space (17), the drone interface modules (2, 4) forming an at least partially flooded docking area (23, 42) for the drone (3, 5), the drone interface modules (2, 4) have a lower portion (22, 43) configured to rest stably on a flat surface after the drone interface module (2, 4) has been removed from the pontoon (1).

A self-adjusting band that includes one or more banding segments, one or more buckling assemblies, a pair of one pin and two links for each buckle assembly, a rotary joint base for each pair of one pin and two links, and a high-load, low-deflection compression spring for each section of the buckle assembly.

A mechanical attachment mechanism includes a clamp and a receptacle. The clamp includes a trigger arm and catchment fingers biased to pivot toward the trigger arm. The receptacle includes an aligner and curved grooves. The curved grooves each have open exterior and closed interior ends. The trigger arm of the clamp is biased from a triggered position toward secured and extended positions. The extended position is for the trigger arm beginning and ending contact between the trigger arm and the aligner. The extended position is also for the trigger arm capturing the catchment fingers of the clamp from the open exterior end of the curved grooves of the receptacle. The triggered position is for the trigger arm releasing the catchment fingers into the curved grooves. The secured position is for securing the clamp and the receptacle together with the catchment fingers engaging the closed interior end of the curved grooves.

An omnidirectional underwater vehicle includes an open-frame mechanism including a frame with top thrusters at four corners of a top end of the frame; mechanical arms disposed at a front end of the frame; and a rotary holder disposed in the frame and including a motor fixing plate, an upper bearing fixing plate and a lower bearing fixing plate. A cylindrical roller bearing is fixed between the upper bearing fixing plate and the lower bearing fixing plate, and an inner edge of the cylindrical roller bearing is provided with two bearing clip inner plates from top to bottom. A servo motor is fixed on the motor fixing plate, a bottom end of the bearing clip inner plate at the bottom is fixedly connected to a steering gear fixing plate, and a top end of the steering gear fixing plate is provided with fully waterproof steering gears installed with underwater thrusters.