Design and Underwater Tests of Subsea Walking Hexapod MAK-1

Chernyshev, V. V.; Arykantsev, V. V.; Гаврилов, А. Е.; Kalinin, Ya. V.; Sharonov, N. G.

doi:10.1115/omae2016-54440

Cited by 11 publications

(4 citation statements)

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“…Underwater experiments were carried out in the conditions of real water bodies of the Volga-Akhtuba floodplain on the basis of a prototype of a walking device (modular hardware complex) with hydromechanical equipment installed on it for eroding bottom soil (Figure 1). The walking apparatus was specially designed to test methods for controlling the movement of walking robotic systems designed to work on water-saturated soils or in underwater conditions [8]. The walking device includes bearing beams on the right and left sides, connected by a frame.…”

Section: Methodsmentioning

confidence: 99%

“…Communication between the computer and the surface control unit is carried out via RS-485 protocol or Ethernet. The walking mechanisms of the underwater vehicle are cyclic, λ-shaped, with hingedly attached replaceable feet [9]. The walking mechanisms of each side are kinematically connected and work in antiphase (2 walking mechanisms work in same phase, and the middle one in antiphase).…”

Section: Methodsmentioning

confidence: 99%

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Practice of methods for remote control of walking robotic mini-dredgers moving along the bottom

Arykantsev,

Kalinin,

Chernyshev

2024

E3S Web Conf.

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The results of experimental testing of methods for remote control of underwater walking mini-dredgers are discussed. Tests were carried out in real water conditions on the basis of a prototype of a 6-legged underwater walking vehicle. During the tests, technological operations for clearing and deepening small channels and eriks, as well as the extraction of sapropel from the bottom of the lake, were simulated. During the experiments, a mini-dredger has been controlled using video information of on-board video cameras. Due to poor visibility in the zone of hydraulic erosion of bottom soil, management was carried out in conditions of an incomplete and ambiguous understanding of the external environment. Local positioning was carried out according to natural landmarks. It is shown that fairly accurate remote control of the movement of a mini-dredger can be organized on the basis of public satellite maps of the area, even in conditions of a lack of sensory information. Moreover, the operation of an underwater dredger can be realized with minimal external control influences. The research results may be demanded in the development of walking robotic systems intended for the rehabilitation of degrading small water bodies and for other underwater technical work.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Practice of methods for remote control of walking robotic mini-dredgers moving along the bottom

Arykantsev,

Kalinin,

Chernyshev

2024

E3S Web Conf.

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“…Всемирно известная компания Boston Dynamics создает различные типы шагающих машин [14; 15]. Исследователи сталкиваются с проблемами механики, электроники, вопросами сенсоров [16; 17], а также со сложностью алгоритмов управления движением [18][19][20]. В настоящее время и в нашей стране ведутся научные исследования шагающих машин [21][22][23].…”

Section: Introductionunclassified

Modeling Movement of Supports of Walking Machines with Dynamic Stability by Using a Stand

Aleynikov

Didmanidze

2021

Engineering Technologies and Systems

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Introduction. Walking machines have been interesting for decades. Modern technologies make it possible to create new designs with digital control. Creating software that allows a walking machine to move independently is a difficult task. Walking machine onboard computer needs to process data from sensors in real time. The article demonstrates design and algorithms used to control the motion of an experimental walking machine. Materials and Methods. To simulate the motion of a walking machine and experimental studies, a stand replicating all the electronic systems of the machine was made. The order of rearrangement of the supports during the motion and the trajectory of the support movement are shown. The design of sensors and their principle of operation are considered. The simulation bench with a description of its electronic components is demonstrated. Results. The optimal parameters of the support motion are determined. A cyclic algorithm for specifying the motion of a support along a trajectory consisting of rectilinear segments is described. The problem of synchronization of motion of a set of supports using multithreaded asynchronous programming adapted for multidimensional processors has been solved. The process of lowering the support to the surface and the response of the cyclic algorithm to changes in the shock and load sensor readings are simulated. Discussion and Conclusion. An algorithm for propulsion with reaction to changes in sensor readings has been developed. The conducted research allowed us to obtain an optimal algorithmic model of motion, to which it is easy to add new reactions of the automatic motion control system based on sensor readings.

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“…In the study of the mobile underwater robot motion which moves along the reservoir's bottom, one of the urgent tasks is to study the translational motion of such robot with walking movers [1,2,3], in particular, the movement of an underwater platform-pontoon using anchor-cable propulsion devices. The principle of moving the underwater platform-pontoon with anchorcable propulsion devices [4,5] is presented in Figure 1.…”

Section: Introductionmentioning

confidence: 99%

On the stability of mobile robots movement with cable propulsion devices

2020

Robots in Human Life

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Design and Underwater Tests of Subsea Walking Hexapod MAK-1

Cited by 11 publications

References 0 publications

Practice of methods for remote control of walking robotic mini-dredgers moving along the bottom

Practice of methods for remote control of walking robotic mini-dredgers moving along the bottom

Modeling Movement of Supports of Walking Machines with Dynamic Stability by Using a Stand

On the stability of mobile robots movement with cable propulsion devices

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