RU2387570C1 - Compact remotely-controlled underwater vehicle - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: compact remotely-controlled underwater vehicle contains modular frame, buoyancy unit installed in upper part of underwater vehicle, propellers of horizontal and vertical motion, lamps, observing video camera installed using bracket over surface of floating unit, stationary black-and-white video camera. In the upper part of underwater vehicle coaxially with its vertical axis, perforated container for underwater samples collection is installed. Underwater vehicle also contains manipulator equipped with gripper and leakproof drive, herewith the manipulator is installed on output shaft of the drive. On free end of manipulator drive output shaft video camera is installed in such a manner that its axis of sight is constantly directed to the centre of manipulator reach.

EFFECT: increase in efficiency of underwater samples collection and their lifting on surface without simultaneous deterioration of stability and maneuvering capabilities of the vehicle itself.

4 cl, 4 dwg

Description

The invention relates to underwater shipbuilding, namely to small-sized remote-controlled underwater vehicles. (MTPA), in particular to self-propelled MTPA controlled via a communication cable, intended primarily for inspection of underwater objects and collection of underwater samples.

Known remote-control uninhabited underwater vehicle (TNPA) "Dolphin-3K", developed in Japan by JAMSTEC, with an immersion depth of 3300 m ("Recent developments of Japanese companies in the field of shipbuilding and the creation of equipment for underwater work and research, Technical Bulletin, Tokyo, Trade Representation of the USSR , 1988). TNPA has a frame structure, stereo cameras with lights, a directional sonar, two manipulators equipped with grippers are placed in the bow, and the manipulators have five and seven degrees of freedom, respectively, a hinged container for collecting samples installed in the bow of the underwater vehicle, and a buoyancy unit. Information is controlled and transmitted via a 5000 m cable cable with a fiber-optic communication line. The electro-hydraulic propulsion system includes six propulsors, providing marching, vertical and lag speeds. The underwater vehicle is connected via a cable to the control panel, which is connected to a color monitor.

The underwater vehicle is designed to work at great depths. With it, you can deliver to the bottom or lift loads weighing up to 200 kg. It is mainly used to study the mineral resources of the ocean, including cobalt formations and hydrothermal deposits. This underwater vehicle is technically difficult and economically impractical to use at shallow depths.

Known TNPA "Obzor-600" (www.tetis-pro.ru), containing a frame, propulsors, a circular sonar, video cameras and a gripper. The TNLA is connected to the carrier vessel by a cable through which control commands, information from sensors and a video signal are transmitted. This TNLA allows you to detect underwater objects, transmit video images and perform underwater technical work to the extent of the capabilities of the "gripper" manipulator. The underwater vehicle operates at shallow depths of up to 600 meters.

The disadvantages of the above TNLA should include the fact that it has limited capabilities when performing underwater technical work to collect underwater samples and their rise to the surface. The manipulator of the underwater vehicle can take only one sample and can lift it onto the carrier ship only when lifting the TNLA itself, as its design lacks a container for collecting samples. It is very difficult for the operator to lower the underwater vehicle to the same point behind the next sample again.

Known inspection telecontrolled uninhabited underwater vehicle "Kalan-500", (www.bnti.ru), comprising a housing, propulsors, a sector survey sonar, lamps, video cameras and a small manipulator. The TNLA is connected to the carrier vessel by a cable through which control commands, information from sensors and a video signal are transmitted. This TNLA allows you to conduct inspection and inspection work on underwater objects, transmit video images and carry out the lifting of objects along with the ascent to the surface of the apparatus itself. The underwater vehicle operates at depths of up to 500 meters.

Known miniature remote control underwater vehicle (TPA) "SeaBotix", (www.seabotix.ru), comprising a housing made of high-strength plastic, four propulsors, sonar equipment, a lamp, video cameras and a manipulator. TPA is connected to the carrier vessel by a cable through which control commands, information from sensors and a video signal are transmitted. This TPA allows you to search for underwater objects and perform inspection and survey work underwater in coastal sea or inland waters, transmit video images and lift one object at a time while lifting the underwater vehicle itself. The underwater vehicle operates at shallow depths of up to 300 meters.

The well-known underwater vehicles "Kalan-500" and "SeaBotix" have the same drawback as the well-known "Obzor-600", namely, limited technological capabilities when performing underwater technical work on collecting underwater samples and raising them to the surface, because . in the designs of these known underwater vehicles there are no containers for collecting samples and there is no rotation of the manipulator in a vertical plane.

Also known is a small-sized remote-controlled underwater vehicle manufactured by Seaeye "FALCON" (www.seaeye.com, www.tnpa.ru/falkon.htm). The underwater vehicle contains a frame of modular design made of polypropylene, propulsors of horizontal and vertical travel. The electronic components of the underwater vehicle are housed in durable airtight containers. In addition, “FALCON” contains lamps, a survey and stationary black-and-white video cameras, depth and temperature sensors, pressure compensators, a buoyancy unit installed in the upper part of the underwater vehicle, a manipulation module, including a manipulator equipped with a grip and a sealed drive. The manipulator is mounted on the output shaft of the drive. The underwater vehicle is equipped with a surface control module, which consists of a control panel, a power source, and a video information display unit. The underwater vehicle is connected to the surface module via a cable cable (communication cable).

However, the implementation of one of the functional tasks by this underwater vehicle is difficult, namely, carrying out underwater technical work to collect underwater samples and raise them to the surface. The absence of a container for collecting samples in it does not allow multiple collection of underwater samples without lifting the underwater vehicle to the surface. In addition, the lack of a video camera at the manipulator and the insufficient viewing angle of the overview video camera do not allow a detailed overview of the underwater space in a wide range of the angle of view with a simultaneous review of the process of collecting samples at the bottom.

The problem solved by the present invention is to expand the functionality of the MTPA due to design solutions that provide it with additional technological capabilities when conducting underwater technical work, namely, the effective collection of underwater samples and raising them to the surface, without compromising the stability and maneuverability of MTPA.

The task is achieved by the fact that in a small telecontrolled underwater vehicle containing a frame of modular design, horizontal and vertical propulsion, durable airtight containers to accommodate the electronic part of the underwater vehicle, lights, surveillance and stationary cameras, depth and temperature sensors, pressure compensators, buoyancy unit installed in the upper part of the underwater vehicle, a manipulation module, including a manipulator equipped with a grip and a sealed drive, and a nipple is mounted on the output shaft of this drive, a surface control module including a control panel, a power source, a video information display unit, and a communication cable connecting the underwater vehicle to the surface module, an additional video camera is installed on the other end of the manipulator drive output shaft so that its axis of sight constantly directed to the grip center of the manipulator, the underwater vehicle is equipped with a removable perforated container for collecting samples installed in the upper part of the underwater vehicle coaxially with its vertical axis, and the surveillance video camera is installed by means of a bracket above the buoyancy unit in the diametrical plane of the underwater vehicle in its aft.

In a small-sized remote-controlled underwater vehicle, the frame of a modular design is sealed from polypropylene pipes.

In a small remote-controlled underwater vehicle, a removable perforated container for collecting samples is made in the form of an inverted truncated cone.

In a small telecontrolled underwater vehicle, the communication cable is fixed to the frame in the aft of the underwater vehicle in its diametrical plane at the point of its intersection with the plane of the horizontal group of movers.

The problem is solved in that the placement of the perforated container for collecting samples inside the frame coaxially with the vertical axis of the underwater vehicle allows you to maintain its stability and maneuverability when performing specific underwater technical works, such as collecting underwater samples in a container and transporting them in the container to the surface.

The manipulation module and a removable perforated container for collecting samples are structurally installed in the underwater vehicle in such a way that one rotational degree of freedom is sufficient for the manipulator to collect samples and place them in a perforated container.

Installing an additional survey camera on the other end of the manipulator drive output shaft and placing the survey camera through an arm above the buoyancy unit provides a wide range of viewing angle and allows the operator to work effectively with the manipulator. The surveillance video camera mounted on top of the buoyancy unit of the underwater vehicle allows the operator to control the operation of collecting samples into the container or perform surface surveys (when the MTPA is on the surface of the water), and an additional surveillance video camera of the manipulator allows you to control the operation of the manipulator's coverage during the collection process, since it is located in the immediate vicinity of the grip and its axis of sight is constantly directed to the center of the grip. A wide-angle highly sensitive stationary video camera provides the necessary range and viewing angle in low light conditions when searching for bottom objects and performing underwater technical work. This arrangement of the video system provides multifunctional operation of the underwater vehicle.

The given combination of both known and distinctive essential features ensures the achievement of a technical result - the expansion of the functionality of the MTPA without impairing its stability and maneuvering qualities, i.e. Effective operation of the manipulator for collecting underwater samples and transportation of samples to the carrier vessel are ensured, while maintaining the stability and maneuverability of the underwater vehicle and a detailed overview of the underwater space in a wide range of the angle of view with a simultaneous review of the samples located at the bottom.

The invention is illustrated by drawings, where figure 1 shows a front view of an underwater vehicle; figure 2 is a top view of an underwater vehicle; figure 3 is a side view of the underwater vehicle (in transport condition); figure 4 is a side view of the underwater vehicle (in the process of collecting samples).

A small telecontrolled underwater vehicle made according to the invention comprises a frame 1 of a modular design, propulsion devices 2 for horizontal travel and propulsors 3 for vertical travel with mounting flanges 4, durable airtight containers 5 for accommodating the electronic part of the underwater vehicle, lamps 6, a surveillance video camera 7 mounted on an arm 8, video camera 9 of the manipulator, stationary video camera 10, sensors for depth 11 and temperature 12, pressure compensators 13, buoyancy unit 14 installed in the upper part of the base the bottom of the apparatus, the manipulator 15 and the sealed drive 16 of the manipulator with the output shaft 17, the gripper 18 of the manipulator, a perforated container 19 for collecting samples, a surface control module (not shown in the drawings) and a communication cable 20 connecting the underwater vehicle to the surface module.

Additionally, the drawing shows: 21 - the bottom of the sea; 22 - underwater samples.

A drive 16 of the manipulator is mounted on the frame 1 of a modular design. A video camera 9 and a manipulator 15 are installed on the output shaft 17 of the drive 16. The axis of sight of the video camera 9 of the manipulator 15 is constantly directed to the center of the gripper 18. Due to the location of the video camera 9 and the manipulator 15 on the common output shaft 17 of the drive 16, the relative position of the video camera 9 of the manipulator 15 and the gripper 18 remains unchanged when the output shaft 17 is driven by the drive 16. A removable perforated container 19 is installed in the upper part of the underwater vehicle coaxially with its vertical axis and is fixed in the buoyancy unit 14. With this design solution uu force vector of gravity Gp placed in a perforated container 19, sample 22 will always be located along the line of action of the vector of gravity P of the underwater vehicle, which eliminates the occurrence of additional disturbing torques acting on a unit roll and / or trim. The removable perforated container 19 is placed in the underwater vehicle in such a way that the stability of the underwater vehicle when collecting samples and lowering them into the container only increases due to the fact that the point of application of the gravity vector of the collected samples Gp is always located below the center of volume V of the underwater vehicle. The surveillance video camera 7 is mounted on the bracket 8 in such a way that it allows the operator to see the tong 18 in the upper (transport) position and control the discharge of samples into the container, view the surface space in the case of the underwater vehicle in the shallow position, as well as view objects located above and in front of frame 1, when the underwater vehicle is under water. By adjusting the position of the overview camera 7 on the bracket 8, you can vary the range of the top view. The location of the gripper 18 in the final position (figure 3) is oriented so that the samples 22 discharged into the perforated container 19 fall into the center of its bottom. The constructive solution of the underwater vehicle allows the collection and folding of underwater samples 22 in a perforated container 19 using a single-stage drive 16 for turning the manipulator 15.

Two LED lights 6 are fixed in front of the frame 1 and provide high-quality operation of the video camera 9 of the manipulator 15 and the stationary video camera 10.

The video system of the underwater vehicle consists of a video camera 9 of the manipulator 15, a surveillance video camera 7, and a stationary wide-angle black-and-white video camera 10. During the operation of the underwater vehicle, the video cameras work, as a rule, in the following combinations. A stationary black and white video camera 10 is the main one when searching for a target and moving under water. When working gripper 18 with the sample, the main working video camera is the video camera 9 of the manipulator 15, as it allows you to always monitor and control the position of the gripper 18 in your field of vision. When lowering underwater samples using the manipulator 15 into the perforated container 19, the main working video camera becomes the overview video camera 7 mounted on the bracket 8, since the other video cameras lose the grip 18 of the manipulator 15 from sight. As well as the surveillance video camera 7 provides a surface survey during transportation of the collected underwater samples over the surface of the water when the underwater vehicle approaches the vessel.

The propulsion and steering complex consists of two groups of propulsors: horizontal and vertical. The horizontal group of movers consists of four movers 2. The axis of rotation of movers 2 are located in the same plane and are at an adjustable angle to the longitudinal axis of the underwater vehicle. Thanks to this arrangement of propulsors, the underwater vehicle is controlled at the heading, as well as marching and lagging of the underwater vehicle are carried out. Adjusting the location of the propulsors allows you to change the total thrust vector in marching and lagging directions. The location of the movers 2 of the horizontal group is symmetrical relative to the longitudinal plane passing through the center of gravity of the MTPA (figure 1). The axis of rotation of the propulsors 3 of the vertical group are parallel to the vertical axis of the underwater vehicle and are located symmetrically relative to the longitudinal and transverse planes of the MTPA (figure 2). The mounting flanges 4 are mounted in the buoyancy unit 14 so that the propulsors 3 are rigidly attached directly to them and have a geometric arrangement that allows you to control the vertical movement of the underwater vehicle, as well as the angular movement along the roll and trim.

The engine-steering complex control unit is located in one of the sealed containers 5 located in the lower part of the underwater vehicle frame on the right side. In the second sealed container 5, located in the lower left part of the MTPA, there are the main electronic MTPA control boards, navigation sensors for magnetic heading, roll, trim and angular yaw rate.

The depth sensor 11 and the temperature sensor 12 are separate sealed devices.

The overboard pressure compensation system consists of two compensators 13 located in the lower aft of the MTPA.

The current-carrying communication cable 20 is fixed on the frame 1 in the rear of the MTPA in its diametrical plane at the point of its intersection with the plane of the horizontal group of movers.

The complete set of the underwater vehicle can be changed by additionally installing various equipment.

The work of the underwater vehicle is as follows. Launched on the water MTPA due to positive buoyancy is located on the surface of the water, and a working surveillance camera 7 performs a review of the surface situation. Next include vertical propellers 3 and the MTPA immerses to the depth specified by the operator, while data on the depth of immersion is obtained using the depth sensor 11 integrated in the MTPA design. When reaching the specified depth or simultaneously with the immersion, the underwater vehicle is moved in the horizontal plane using the horizontal mover groups 2. Here the desired movement of the underwater vehicle is set by the operator. Propulsion control commands are calculated in a specialized calculator unit located in the electronics unit. Further, these commands are sent to the control units of the drives of the respective propellers. In accordance with the laws of control developed by the special calculator, the propulsion-steering complex processes them, forming control actions and ensuring the movement of the apparatus along a predetermined path. Due to the selected layout of the horizontal group of movers 2, the following MTPA movements in the horizontal plane are possible: marching motion, lagging motion, heading. The vertical group of movers 3 allows you to dive-surfacing MTPA, as well as stabilize it at the angles of heel and trim. The immersion depth is stabilized by a group of vertical movers 3 according to the readings of the depth gauge 11. In the submerged state, the MTPA makes video recordings using a stationary black and white wide-angle high-sensitivity video camera 10 or using an overview video camera 7 mounted on an arm 8. Lighting is turned on as necessary. Depending on the conditions, the survey camera 7 and the stationary black-and-white video camera 10 are turned on together. When a search object is detected, the MTPA hangs over it or inspects the object from different sides, making a video recording. If necessary, the movable manipulator 15, equipped with a grip 18, at the command of the operator captures the detected underwater object 22. Located on the same axis as the manipulator 15, the video camera 9 makes a video of the processes occurring in the area of the grip 18. Further, the manipulator 15 with the captured underwater object 22 produces rotational movement in the vertical plane of the apparatus around the axis of the shaft 17 of the drive 16 of the manipulator 15 until the tong 18 with the underwater object 22 is above the perforated container 19 p watercraft. The location of the gripper 18 of the manipulator 15 relative to the perforated container 19 is controlled using the survey camera 7. Next, the gripper 18 of the manipulator 15 is decompressed and the underwater object 22 falls into the removable perforated container 19. The underwater vehicle is floated after the mission is completed using vertical propellers 3, the manipulator 15 this is brought into a transport position in which the gripper 18 of the manipulator 15 is located above the perforated container 19 of the underwater vehicle.

Claims (4)

1. Small-sized remote-controlled underwater vehicle containing a modular design frame, horizontal and vertical propulsion engines, durable airtight containers for placing the electronic part of the underwater vehicle, lamps, surveillance and stationary video cameras, depth and temperature sensors, pressure compensators, buoyancy unit installed in the upper part an underwater vehicle, a manipulation module, including a manipulator equipped with a span and a sealed drive, and the manipulator is mounted on the output shaft about the drive, a surface control module including a control panel, a power source, a video information display unit, and a communication cable connecting the underwater vehicle to the surface module, characterized in that a video camera is additionally installed on the other end of the manipulator drive output shaft so that its axis of sight is constantly directed to the grip center of the manipulator, the underwater vehicle is equipped with a removable perforated container for collecting samples mounted in the upper part of the underwater vehicle coaxially with its vertical axle, and the survey video camera is installed by means of an arm above the buoyancy unit in the diametrical plane of the underwater vehicle in its aft part. 2. The small-sized remote-controlled underwater vehicle according to claim 1, characterized in that the modular design frame is sealed from polypropylene pipes. 3. The small-sized remote-controlled underwater vehicle according to claim 1, characterized in that the removable perforated container for collecting samples is made in the form of an inverted truncated cone. 4. The small-sized remote-controlled underwater vehicle according to claim 1, characterized in that the communication cable is fixed to the frame in the stern of the underwater vehicle in its diametrical plane at the point of intersection with the plane of the horizontal group of movers.

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