30 research outputs found
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Transparentization of SLS Processed SMMA Copolymer Parts by Infiltrating a Thermosetting Epoxy Resin with Tuned Refractive Index
Selective laser sintering is quite advantageous to build complicated tubular
structures such as intake manifolds of automotive engines because of its ability of
building undercut structures without using support ribs. On the other hands, inevitable
opacity of the parts obtained from the process is lowering its advantage when we need to
observe inside of the parts. A technology that can transparentize SLS processed parts by
infiltrating curable resin with tuned refractive index was introduced by the authors in
2004, and in this paper, several modifications are added on material, process
parameters and their control accuracies to improve clarity of obtained parts. As a result
of these modifications, haze of the processed part was reduced by a factor of 40%
reaching the lowest value of 20% through a plate with thickness of 5mm.Mechanical Engineerin
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Effective Mechanisms of Multiple LED Photographic Curing
Multiple LED Photographic Curing (MPC) has proven capable of drawing cross sections of
three-dimensional objects like printing a sheet of paper. Using raster scanning, however, simultaneously exposing a photopolymer with 1,024 beams of light involves various unknown issues. The
aim of this research work was to examine the formation of individual strings and the connecting
mechanisms between strings and layers. At light power ranging from 19.0 to 30.3flW and at various scan speeds, string formation perpendicular to scan direction differs greatly from that in scan
direction. Curing of plane layers happens by curing strings side-by-side with a constant spacing of
62.5flm.Mechanical Engineerin
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Laser Sintering Fabrication of Highly Porous Models Utilizing Water Leachable Filler-Experimental Investigation into Process Parameters
The authors are developing a laser sintering process to fabricate highly porous
models with such high porosities as 90% and more. In the process, water-soluble filler is
mixed with designated plastic powder and leached out after laser sintering process is
finished to generate pores where the grains used to exist. Previously, the authors
reported successful application of this technology on a tissue engineering scaffold.
However, relationship between process parameters and obtained results has not been
clarified. This paper reports experimental investigation into effects of optimizing
process parameters such as mixture, grain size of the filler on resultant porosity, pore
size and process resolutionMechanical Engineerin
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Low Temperature Selective Laser Melting of High Temperature Plastic Powder
In a typical plastic laser sintering or melting system, powder bed temperature is
maintained above the recrystallization temperature of the powder material to prevent
the parts under process from warping until the whole layers are processed. Although this
countermeasure can elegantly suppress the part warpage, heating the powder bed to
such a high temperature causes many problems. In case of high temperature plastic such
as polyetheretherketone (PEEK), bed temperature should be more than 300°C. Due to
this requirement, machine cost is extremely high and powder recyclability is very low.
The authors had introduced another countermeasure for the part warpage that anchors
the in-process parts to a rigid base plate instead of heating the powder bed above the
recrystallization temperature. In the current research, application of this method to
PEEK powder is tested, and a simple test piece of which relative density is more than
90% was successfully obtained with preheating temperature of 200°C. In this paper,
mechanical performances of obtained parts are presented, and several problems with the
process of PEEK powder are discussed as well.Mechanical Engineerin
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Effect of Powder Compaction in Plastic Laser Sintering Fabrication
Powder compaction is introduced into plastic laser sintering fabrication. Compaction was
carried out by using a roller of which rotation speed is independently controlled of its
traversing speed. This additional process improved packing density of powder bed by a
factor of 20% and reduced residual porosity of obtained parts by a factor of 30%. As an
advantage, powder compaction can improve mechanical strength of parts of
semi-crystalline powder, but increases excessive sinter to reduce fabrication accuracy
especially in fabrication of amorphous plastic. This paper presents characteristics of the
powder compaction process itself and its effects on performance of obtained parts.Mechanical Engineerin
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SLS Fabrication of Highly Porous Model Including Fine Flow Channel Network Aiming at Regeneration of Highly Metabolic Organs
Fabrication of very porous scaffold for regeneration of highly metabolic organs is
reported. Polycaprolactone (PCL) powder was mixed with fine salt grains as filler and
SLS processed to develop a model including fine flow channel network. The fabricated
model was rinsed with water to dissolve the salt, and high porosity of 90% was
successfully obtained. Additionally, residual powder in the channels was effectively
removed by solution of the filler. Through micro-CT observation, it was confirmed that
channels of which diameter was smaller than 1mm were successfully fabricated and
repeating branching and merging. Result of culture test is also reported.Mechanical Engineerin
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Process Resolution of Laser Sintering Process Using Plastic Powder Containing Inorganic Filler at a High Rate
Research is being performed on a laser sintering process in which inorganic filler is
employed as porogen at a high content to fabricate highly porous three dimensional
tissue engineering scaffold. Previously, the scaffold, which included capillary like flow
channel network, was used in cell culture test, but obtained cell density was limited due
to insufficient fineness of the network structure. In the scaffold fabrication the author
experienced degradation of process resolution when inorganic filler was introduced at a
high content, but reasons for the low resolution has not been cleared. This paper
investigates the dominating cause of the low resolution. Discussion is focused on effect
of optical and thermal properties of filler. Experiments using transparent and opaque
fillers are performed, and existence of dominating effect of difference in the optical
property is denied. Experiments using thermally conductive solid filler and insulating
hollow filler is performed, and it is concluded that temperature conductivity is
dominating on process resolution.Mechanical Engineerin
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DETERMINATION OF INPUT LASER ENERGY FOR MELTING POWDER LAYERS OF VARIOUS THICKNESSES IN HIGH-SPEED PBF-LB/P USING NEARINFRARED LASER AND ABSORBENT
The rate of production of PBF-LB/P can be increased by increasing the layer thickness.
However, this reduces the part resolution in the stacking direction. To obtain both a high rate
of production and high part resolution, layer thickness adjustment in accordance with part
geometry can be effective. Optimizing the input laser energy with respect to the layer thickness
ensures sufficient melting and part strength. According to previous studies, the use of a nearinfrared laser and absorbent can increase penetration depth or depth of fusion. However, the
optical properties of the powder bed can vary significantly depending on the layer thickness,
and, therefore, the input energy that actually contributes to melting also changes with layer
thickness. This study proposes a method for determining the input laser energy for various layer
thickness without trial and error by estimating the amount of energy required to melt the powder
layer while accounting for the optical properties of the bed.Mechanical Engineerin
研究速報 : Making five atomic force microscope for 200,000yen each : A student project
特集2 日仏マイクロメカトロニクス国際共同研究組織(LIMMS
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Implementation of Tophat Profile Laser into Low Temperature of Poly Phenylene Sulfide
Poly Phenylene Sulfide is a high performance plastics that is used in high-value parts. The
most commercially available plastic laser sintering machines employ Gaussian profile CO2 laser.
In this research, low temperature process of the material with tophat profile laser is tested. By
using tophat profile, a tensile strength of 64.5 MPa was obtained. The value is equivalent to 75%
of those from injection molding and 140% of standard laser sintered polyamide. Tophat profile
effectively suppressed sparkling and fuming and improved surface finish decreasing surplus
sintering or sticking powder.Mechanical Engineerin