Study on development of volume-controllable balloon with pressure sensing function and its application to surgical retractor

制度:新 ; 文部省報告番号:甲2652号 ; 学位の種類:博士(工学) ; 授与年月日:2008/3/24 ; 早大学位記番号:新481

Study on workspace-creation manipulator for minimally invasive surgery

制度:新 ; 文部省報告番号:甲2244号 ; 学位の種類:博士(工学) ; 授与年月日:2006/3/24 ; 早大学位記番号:新426

Design and Testing of a Biomimetic Pneumatic Actuated Seahorse Tail Inspired Robot

The purpose of this study is to build and test a pneumatically actuated robot based on the biomimetic design of a seahorse tail. McKibben muscles, a form of pneumatic actuator, have been previously used to create highly flexible robots. It has also been discovered that the seahorse tail serves as a highly flexible and prehensile, yet armored appendage. Combining these topics, this research aims to create a robot with the mechanical flexibility of a pneumatic actuator and the protection of a seahorse tail. First, the performance of a miniature McKibben muscle design is examined. Then, the artificial muscles are implemented into a 3D-printed seahorse tail-inspired skeleton. The robot\u27s actuation was observed to determine its maximum bending capacities. The results of the experiments revealed that the miniature McKibben muscles performed comparably to larger sized McKibben muscles previously reported in literature. The pneumatically actuated robot achieved a maximum bend angle of ~22°. Further research is recommended to determine the behaviors of similar robots with additional plates or McKibben muscles spanning shorter plate sequences

Finger-attachment device for the feedback of gripping and pulling force in a manipulating system for brain tumor resection

Purpose: Development and evaluation of an effective attachment device for a bilateral brain tumor resection robotic surgery system based on the sensory performance of the human index finger in order to precisely detect gripping- and pulling-force feedback. Methods: First, a basic test was conducted to investigate the performance of the human index finger in the gripping- and pulling-force feedback system. Based on the test result, a new finger-attachment device was designed and constructed. Then, discrimination tests were conducted to assess the pulling force and the feedback on the hardness of the gripped material. Results: The results of the basic test show the application of pulling force on the side surface of the finger has an advantage to distinguish the pulling force when the gripping force is applied on the finger-touching surface. Based on this result, a finger-attachment device that applies a gripping force on the finger surface and pulling force on the side surface of the finger was developed. By conducting a discrimination test to assess the hardness of the gripped material, an operator can distinguish whether the gripped material is harder or softer than a normal brain tissue. This will help in confirming whether the gripped material is a tumor. By conducting a discrimination test to assess the pulling force, an operator can distinguish the pulling-force resistance when attempting to pull off the soft material. Pulling-force feedback may help avoid the breaking of blood pipes when they are trapped in the gripper or attached to the gripped tissue. Conclusion: The finger-attachment device that was developed for detecting gripping- and pulling-force feedback may play an important role in the development of future neurosurgery robotic systems for precise and safe resection of brain tumors. © 2017 CARSEmbargo Period 12 month

Development of novel micropneumatic grippers for biomanipulation

Microbjects with dimensions from 1 μm to 1 mm have been developed recently for different aspects and purposes. Consequently, the development of handling and manipulation tools to fulfil this need is urgently required. Micromanipulation techniques could be generally categorized according to their actuation method such as electrostatic, thermal, shape memory alloy, piezoelectric, magnetic, and fluidic actuation. Each of which has its advantage and disadvantage. The fluidic actuation has been overlooked in MEMS despite its satisfactory output in the micro-scale. This thesis presents different families of pneumatically driven, low cost, compatible with biological environment, scalable, and controllable microgrippers. The first family demonstrated a polymeric microgripper that was laser cut and actuated pneumatically. It was tested to manipulate microparticles down to 200 microns. To overcome the assembly challenges that arise in this family, the second family was proposed. The second family was a micro-cantilever based microgripper, where the device was assembled layer by layer to form a 3D structure. The microcantilevers were fabricated using photo-etching technique, and demonstrated the applicability to manipulate micro-particles down to 200 microns using automated pick-and-place procedure. In addition, this family was used as a tactile-detector as well. Due to the angular gripping scheme followed by the above mentioned families, gripping smaller objects becomes a challenging task. A third family following a parallel gripping scheme was proposed allowing the gripping of smaller objects to be visible. It comprises a compliant structure microgripper actuated pneumatically and fabricated using picosecond laser technology, and demonstrated the capability of gripping microobject as small as 100 μm microbeads. An FEA modelling was employed to validate the experimental and analytical results, and excellent matching was achieved

Design and Analysis of Soft Actuator with Enhanced Stiffness with Granular Jamming

The field of soft robotics has been increasing popularity and importance in last decade with its groundbreaking applications in the field of delicate food handling industry and rehabilitation of limbs and fingers of stroke affected patients. The area of soft robotics seeks to improve robot safety, allowing them to function in circumstances where standard robots cannot. This research is focused on pneumatically actuated soft robots as they are efficient, easily controlled, affordable, and well researched. These robots consist of one or more soft actuators, made of silicone elastomers with low material hardness. Low hardness silicone actuators are structurally weak and cannot generate functional forces, which can be rectified by simply increasing the hardness of the material, resulting in compromising softness of the robot. This research attempts to provide a solution to increase structural stability and force output of soft actuator without compromising softness of the material. These were achieved in two ways; one, by improving the cross-sectional profile of the actuator, with an addition of vacuum functionality which increases degree of freedom by one. Two, by attaching a granular jamming component to the actuator, which can change its stiffness actively based on the vacuum applied to it. In this research, the soft actuator was made of Eco-Flex 00-30 silicone and ground coffee was used as granular material for jamming. The actuator was designed on CATIA, and simulation analysis was carried out in ANSYS. A simulation study is conducted to optimize the design parameters to improve bending angle. The jamming components are attached on either side of the actuator and filled with ground coffee which provides controlled stiffness. The actuator was fabricated by molding, all molds are 3D printed with polylactic acid. The actuator was powered by an electric air pump. The actuator is evaluated for bending angle and blocking force at the tip. 280% more bending was achieved under vacuum when compared to conventional design. The blocking force was increased by 270% upon implementing jamming component. The force output obtained per unit pressure applied when compared to present literature increased by 4 times. Lastly, these methods can be implemented to improve the performance of any soft pneumatic actuators