Failure data of a microgripper for intracorporeal surgeries (2024)

Data creator : Liseth Pasaguayo [1]
Related person : Zeina Al Masry [1], Noureddine Zerhouni [2], Sergio Lescano [3]
[1] : Franche-Comté Electronique Mécanique Thermique et Optique - Sciences et Technologies (UMR 6174) (Université de Franche-Comté)
[2] : Franche-Comté Electronique Mécanique Thermique et Optique - Sciences et Technologies (UMR 6174) (École Nationale Supérieure de Mécanique et des Microtechniques)
[3] : AMAROB Technologies
Description :
Two datasets are provided, the raw data and filtered data of position, velocity, acceleration, and jerk of a microgripper for intracorporeal surgeries. The microgripper was driven by 316L stainless steel wires of 0.08mm in diameter and motors. Raw data was collected using an experimental setup until one of their components failed. The microgripper was tested under five scenarios under the same operating conditions.
Disciplines :
engineering, industrial (engineering science), engineering, manufacturing (engineering science), engineering, mechanical (engineering science), surgery (medical research)
Access details :
To access the data, please contact the scientific data manager.

General metadata

Data acquisition date : from 1 Apr 2023 to 1 Sep 2024
Data acquisition methods :
  • Experimental data :
    The experimental setup is composed of two 316L stainless steel wires, two MF4005V2 brushless motors, two pulleys of 20 mm in diameter assembled to each motor, two 316L stainless steel wires of 0.08 mm in diameter, a 316L stainless steel tube of 2 mm in diameter, three supports to hold the 316L stainless steel tube, two tensioner mechanism for each 316L stainless steel wire, a wires' guide for preventing wire friction in the sharp edge of the steel tube, a mobile jaw made of 316L stainless steel, a fixed jaw made of photopolymer resin, and an opening limitation shaft of the mobile jaw of 0.40 mm in diameter.
    One side of the 316L stainless steel wire (w1) is attached to the bottom of the mobile jaw, and the other side is attached to the pulley (p1) that is coupled to the shaft of the motor (M1). On the other hand, one side of the 316L stainless steel wire (w2) is attached to the top of the mobile jaw, and the other side is attached to the pulley (p2) that is coupled to the shaft of the motor (M2). The two wires are passed through a tube of 2 mm in diameter. A wire guide for preventing wire friction in the sharp edge of the 316L stainless steel tube is placed on one side of this tube. The jaw tested is the mobile jaw, and its opening range of 2 mm is limited by the shaft of 0.40 mm in diameter.
    In addition, to get equal tension in the two 316L stainless steel wires during testing, two tensioner mechanisms are placed close to the motors.
    The brushless motors incorporate a control unit and one encoder in the shaft of each one. The encoders are used to collect data on angular position. The angular velocity, acceleration, and jerk are generated by computing its derivatives. For velocity by deriving position with respect to time, for acceleration by deriving velocity with respect to time, and for jerk by deriving acceleration with respect to time. All are computed at the same time that the encoder collects the data. The derivatives are computed by using numerical differentiation methods.
    The tests consisted of repetitive opening and closing movements controlled by torque. All tests were conducted using a positive and negative trapezoidal input torque signal for motors M1 and M2 with an amplitude of +0.00854 Nm, and −0.00854 Nm respectively, a frequency of 1 Hz and a period T = 1 second.
    The tests were performed considering five scenarios:
    - Scenario 1: Only the mobile jaw manufactured in 316L stainless steel was subjected to cyclical opening and closing movements, with a maximum opening range of 2 mm, and a closing range of 0 mm.
    - Scenario 2: Only the mobile jaw manufactured in 316L stainless steel was subjected to cyclical opening and closing movements, changing the closing range by holding a small object of 0.39 mm.
    - Scenario 3: Only the mobile jaw manufactured in 316L stainless steel was subjected to cyclical opening and closing movements, changing the closing range by holding a small object of 0.65 mm.
    - Scenario 4: Only the mobile jaw manufactured in 316L stainless steel was subjected to cyclical opening and closing movements, changing the closing range by holding a small object of 0.91 mm.
    - Scenario 5: Only the mobile jaw manufactured in 316L stainless steel was subjected to cyclical opening and closing movements, holding small pieces of raw chicken.
    The tests were saved in CSV files and labeled T1001 to T1025, T2001 to T2025, T3001 to T3025, T4001 to 4025, and T5001 to T5025 respectively for scenarios 1, 2, 3, 4 and 5. The first digit represents the scenario, and the last digit represents the number of tests. Each CSV file contains data on variables Time, Torque_output, Torque_input1, Pos_input1, Velocity_input1, Acceleration_input1, Jerk_input1, and Temp_input1 from encoder 1; and Torque_output2, Torque_input2, Pos_input2, Velocity_input2, Acceleration_input2, Jerk_input2, and Temp_input2 from encoder 2.
    A script program performed in Python "Data_Processing.ipynb" is provided for data structuration, visualization, and filtering.
    Data filtering involves extracting the maximum value from the position, velocity, acceleration, and jerk data during one operational cycle. One operational cycle is composed of one opening and closing movement and encompasses 20 data points. The time was converted to cycles using the equation: number of cycles = time*frequency. After filtering, the data were gathered as T1001_max_min for each test.
    The folder "Test_folder" contains raw data, and the folder "Filter_tests" contains the filtered data. The Python script "Data_Processing.ipynb" is for data filtering and visualization of filtered data.
Language : English (eng)
Formats : application/vnd.openxmlformats-officedocument.spreadsheetml.sheet, text/csv, text/x-python
Audience : University: master, Research
Publications :
  • Surgical Microgrippers: A Survey and Analysis. ASME. J. Med. Devices. September 2023; 17(3): 030801. (doi:10.1115/1.4062950)
  • Critical Components’ Selection Methodology of a Microgripper for Intracorporeal Surgery. Annual Conference of the PHM Society, 14(1). (doi:10.36001/phmconf.2022.v14i1.3156)
Project and funder :
Additional information :
Data collected as part of the CIFRE thesis, by Liseth Pasaguayo, co-supervised by Noureddine Zerhouni (professor) and Zeina Al Masry (associated professor) of FEMTO-ST laboratory.

DOI and links

10.25666/DATAUBFC-2024-06-06
https://dx.doi.org/doi:10.25666/DATAUBFC-2024-06-06
https://search-data.ubfc.fr/FR-13002091000019-2024-06-06

Quotation

Liseth Pasaguayo (2024): Failure data of a microgripper for intracorporeal surgeries. FEMTO-ST. doi:10.25666/DATAUBFC-2024-06-06

Record created 6 Jun 2024 by Liseth Pasaguayo.
Local identifier: FR-13002091000019-2024-06-06.

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