Design and analysis of a polymeric photo-thermal microactuator

This paper presents the modeling, simulation and characterization of a photo-thermally actuated bent-beam microactuator. The microactuator consists of a single polymeric layer (SU-8) fabricated with conventional photolithography techniques. The principle of operation is based on the thermal expansion of the bent-beams that absorb the required heat by laser illumination. This provides an effective non-contact actuation mechanism by laser beam focusing. A theoretical model of the microactuator is derived and verified by finite element simulations and experiments. The experiments show that a bent-beam actuator with 800 m long, 40 m wide, 100 m thick and 6° bent arms achieves a tip displacement of 16 m with an incident laser beam of 50 mW power while keeping the maximum temperature less than 125 °C. This study merges the advantages of photo-thermal actuation with practicality of polymeric materials. To verify the effectiveness of the proposed microactuator mechanism, a microgripper with bent-beam actuator was fabricated and characterized. It has been demonstrated that the opening of the gripping fingers can be increased from 20 to 50 m for a microgripper with 1000 m long fingers with an incident laser power of 50 mW. This polymeric microgripper with photo-thermal actuation provides a way of gentle grasping with electrical isolation, high repeatability and low temperature operation that is particularly crucial for biomanipulation applications. The polymeric photo-thermal actuator described in this study expands the practical applications of microactuators/microgrippers which are critical tools in bioMEMS devices.     

A new multi-objective approach in order to balancing and sequencing U-shaped mixed model assembly line problem: a proposed heuristic algorithm

The International Journal of Advanced Manufacturing Technology - Mixed model production is the practice of assembling different and distinct models in a line without changeovers responding to...     

Beneficial Reuse of FGD Material in the Construction of Low Permeability Liners: Impacts on Inorganic Water Quality Constituents

In this paper, we examine the water quality impacts associated with the reuse of fixated flue gas desulfurization (FGD) material as a low permeability liner for agricultural applications. A 0.457-m-thick layer of fixated FGD material from a coal-fired power plant was utilized to create a 708?m2 swine manure pond at the Ohio Agricultural Research and Development Center Western Branch in South Charleston, Ohio. To assess the effects of the fixated FGD material liner, water quality samples were collected over a period of 5?years from the pond surface water and a sump collection system beneath the liner. Water samples collected from the sump and pond surface water met all Ohio nontoxic criteria, and in fact, generally met all national primary and secondary drinking water standards. Furthermore it was found that hazardous constituents (i.e., As, B, Cr, Cu, and Zn) and agricultural pollutants (i.e., phosphate and ammonia) were effectively retained by the FGD liner system. The retention of As, B, Cr, Cu, Zn, and ammonia was likely due to sorption to mineral components of the FGD liner, while Ca, Fe, and P retention were a result of both sorption and precipitation of Fe- and Ca-containing phosphate solids.     

Electromagnetic micro energy harvester for human locomotion

This paper reports the design and characterization of a proposed electromagnetic harvester. The harvester is made of permanent magnets and the overall size is of AA battery. Using Faraday’s law of induction, the harvester is capable of producing vibrational energy into electrical energy at low frequencies. The proposed harvester is to be used for bio-medical devices such as pacemakers and hearing aids. Human locomotion is the main source of vibrational energy that will be harnessed. Magnetic harvester can be attached anywhere on the human body in presence of motion such as mounting on the boot when walking. For low frequencies of 0–35 Hz and displacement of 0–7.2 mm, the micro harvester is capable of producing power anywhere from 0 to 38 mW at 0–35 Hz with power density of $4.44 \times 10^{ - 4} {\text{W}}/{\text{cm}}^{3}$ 4.44 × 10 ? 4 W / cm 3 .     

A part-level learning strategy for JPEG image recompression detection

Multimedia Tools and Applications - Recompression is a prevalent form of multimedia content manipulation. Different approaches have been developed to detect this kind of alteration for digital...