Add to ORKGIn this paper an investigation of the feasibility of a new electrochemical micro actuator is presented. The actuator is fabricated using silicon micro-machining techniques. A gas pressure is generated by electrolysis of an aqueous electrolyte solution. The build up pressure is used to change the deflection of a membrane. The actuator has three states: the electrolysis state, in which the pressure is built up; the passive state, in which the circuit is open and the pressure is maintained; and the pressure reduction state, in which the electrodes are short-circuited in order to reduce the pressure. The advantage of this type of actuation is a low energy consumption. The power is required during pressure build up and to change the states. 1
The paper presents two different approaches of utilizing electrolytic micro actuation in liquid envi...
Microfluidic devices providing an accurate delivery of fluids at required rates are of considerable ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Mechanical Engineering, 2016.Ca...
In this paper an investigation of the feasibility of a new electrochemical micro actuator is present...
A novel electrochemical microactuator made with the use of silicon micromachining techniques, and it...
A novel electrochemical microactuator made with the use of silicon micromachining techniques, and it...
In this paper an investigation of the feasibility of a new electrochemical micro actuator is present...
The lack of fast and strong microactuators is a well-recognized problem in the MEMS community. Elect...
The lack of fast and strong microactuators is a well-recognized problem in the MEMS community. Elect...
A novel electrochemical microactuator was developed, which operates as an active valve. The microact...
An actuator based on water electrolysis with a fast change of voltage polarity is presented. It demo...
AbstractThis work concerns the development of a novel actuator based on water electrolysis for use i...
In this paper the theory of water electrolysis in a closed electrochemical cell, that contains two e...
An electro-osmotic actuation mechanism is explored for micropump applications where self contained, ...
Microfluidic systems require a compact, energy-efficient and microtechnology-compatible actuator tha...
The paper presents two different approaches of utilizing electrolytic micro actuation in liquid envi...
Microfluidic devices providing an accurate delivery of fluids at required rates are of considerable ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Mechanical Engineering, 2016.Ca...
In this paper an investigation of the feasibility of a new electrochemical micro actuator is present...
A novel electrochemical microactuator made with the use of silicon micromachining techniques, and it...
A novel electrochemical microactuator made with the use of silicon micromachining techniques, and it...
In this paper an investigation of the feasibility of a new electrochemical micro actuator is present...
The lack of fast and strong microactuators is a well-recognized problem in the MEMS community. Elect...
The lack of fast and strong microactuators is a well-recognized problem in the MEMS community. Elect...
A novel electrochemical microactuator was developed, which operates as an active valve. The microact...
An actuator based on water electrolysis with a fast change of voltage polarity is presented. It demo...
AbstractThis work concerns the development of a novel actuator based on water electrolysis for use i...
In this paper the theory of water electrolysis in a closed electrochemical cell, that contains two e...
An electro-osmotic actuation mechanism is explored for micropump applications where self contained, ...
Microfluidic systems require a compact, energy-efficient and microtechnology-compatible actuator tha...
The paper presents two different approaches of utilizing electrolytic micro actuation in liquid envi...
Microfluidic devices providing an accurate delivery of fluids at required rates are of considerable ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Mechanical Engineering, 2016.Ca...