Using a biologically mimicking climbing robot to explore the performance landscape of climbing in lizards

Beck, Hendrik; Haagensen, Tina; Proost, Tasmin; Clemente, Christofer J.

doi:10.1101/2021.01.12.426469

“…After importing, the corresponding connection, force contact, and drive will appear in order to lay the foundation for simulation and postprocessing. ADAMS then verifies that the model can move in accordance with the movement of the designed tube-climbing robot [11]. The ADAMS virtual prototype model of the established tubeclimbing robot is shown in Figure 8.…”

Section: Virtual Prototype Creationmentioning

confidence: 91%

Kinematics Analysis of Magnetic Adsorption Tube Climbing Robot Based on Adams

2021

IJOMAM

0

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An articulated tube climbing robot with an adsorption device is designed to address the needs of the working environment outside pipeline tubes. The robot can perform actions such as walking on the tube, crossing obstacles, and rotating. A mechanism model is first established using SOLIDWORKS, and mechanical and finite element analyses are carried out to check the strength of the key parts and verify the rationality of the structure. ADAMS dynamics simulation of the tubeclimbing robot outside the tube is then carried out, and the kinematic characteristics and data of the robot performing various actions through different pipelines are analyzed, providing a reference for the development of the prototype machine. The research results show that the mechanism design scheme of the tube climbing robot outside the tube is effective and reasonable.

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Optimizing Current Injection Technique for Enhancing Resistivity Method

Nurpadillah,

Cahyadi,

Mukhtar

et al. 2024

IJEER

0

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Geo-electrical resistivity methods are widely used in various fields and have significant applications in scientific and practical research. Despite the widespread use of resistivity methods, current injection is a critical step in the process of resistivity methods, and the quality of current injection significantly impacts the accuracy of the resistivity measurements. One primary challenge is optimizing current injection techniques to enhance resistivity methods. The developed current injector model for the resistivity meter instrument enhances performance by increasing the voltage source to 400 Volts, extending measurement coverage. It provides three injection current options, 0.5A, 0.8A, and 1A, for efficient accumulator use, considering electrode distances and estimating earth resistance using Contact Resistance Measurement (CRM) to estimate the earth resistance. CRM mode ensures proper electrode connection before injection, thus improving measurement efficiency. The embedded TTGO LoRa ESP32 SX1276 facilitates wireless communication over 1.5 km, addressing challenges in remote and internet-limited areas. The model demonstrates reliability, validity, and durability in CRM mode and current injection measurement. Regarding reliability, we determine the relative error of the model by carrying out measurements repeatedly. In lab-scale testing, the average Relative Error in CRM mode is 0.65%, and in earth resistance measurement testing, it is 1.58%. These relative errors are below the 2% maximum error applied in the “Supersting”, a commercial resistivity instrument. The model's validity is defined by comparing the model with the measuring instrument; we have absolute error. In lab scale testing, the average Absolute Error in CRM mode is 3.08%, and in earth resistance measurement testing, it is 3.73%. The model's durability is tested by injecting current for a minute. After one minute of current injection, the power resistor component's temperature is stable at 30°C.

show abstract

Optimizing Current Injection Technique for Enhancing Resistivity Method

Nurpadillah,

Cahyadi,

Mukhtar

et al. 2024

IJEER

0

View full text Add to dashboard Cite

Geo-electrical resistivity methods are widely used in various fields and have significant applications in scientific and practical research. Despite the widespread use of resistivity methods, current injection is a critical step in the process of resistivity methods, and the quality of current injection significantly impacts the accuracy of the resistivity measurements. One primary challenge is optimizing current injection techniques to enhance resistivity methods. The developed current injector model for the resistivity meter instrument enhances performance by increasing the voltage source to 400 Volts, extending measurement coverage. It provides three injection current options, 0.5A, 0.8A, and 1A, for efficient accumulator use, considering electrode distances and estimating earth resistance using Contact Resistance Measurement (CRM) to estimate the earth resistance. CRM mode ensures proper electrode connection before injection, thus improving measurement efficiency. The embedded TTGO LoRa ESP32 SX1276 facilitates wireless communication over 1.5 km, addressing challenges in remote and internet-limited areas. The model demonstrates reliability, validity, and durability in CRM mode and current injection measurement. Regarding reliability, we determine the relative error of the model by carrying out measurements repeatedly. In lab-scale testing, the average Relative Error in CRM mode is 0.65%, and in earth resistance measurement testing, it is 1.58%. These relative errors are below the 2% maximum error applied in the “Supersting”, a commercial resistivity instrument. The model's validity is defined by comparing the model with the measuring instrument; we have absolute error. In lab scale testing, the average Absolute Error in CRM mode is 3.08%, and in earth resistance measurement testing, it is 3.73%. The model's durability is tested by injecting current for a minute. After one minute of current injection, the power resistor component's temperature is stable at 30°C.

show abstract

Using a biologically mimicking climbing robot to explore the performance landscape of climbing in lizards

Cited by 4 publications

References 37 publications

Kinematics Analysis of Magnetic Adsorption Tube Climbing Robot Based on Adams

Kinematics Analysis of Magnetic Adsorption Tube Climbing Robot Based on Adams

Optimizing Current Injection Technique for Enhancing Resistivity Method

Optimizing Current Injection Technique for Enhancing Resistivity Method

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