Heterogeneous manufacturing is a topic that continues to receive attention.As an emerging manufacturing technology,additive manufacturing can provide strong technical support for heterogeneous manufacturing.In this st...Heterogeneous manufacturing is a topic that continues to receive attention.As an emerging manufacturing technology,additive manufacturing can provide strong technical support for heterogeneous manufacturing.In this study,both homogeneous and heterogeneous composite tubular bionic components were fabricated based on the cold metal transition technology,and the influence of deposition current on the microstructure and mechanical properties of the components was studied.The results show that the interface of the as-deposited heterogeneous composite component is well bonded,and there is an obvious mechanical interlocking structure.The compressive yield strength and elongation of the heterogeneous composite components are higher than those of the homogeneous components,and are positively correlated with the deposition current.Due to the fluctuation of element content,there are a large number of fine grain structures at the interface of the heterogeneous composite components,which increases the mechanical properties.展开更多
Polarization curves and mass losses of SAF3207 hyper-duplex stainless steel under various conditions were measured.The damaged surfaces after erosion–corrosion tests were characterized by scanning electron microscopy...Polarization curves and mass losses of SAF3207 hyper-duplex stainless steel under various conditions were measured.The damaged surfaces after erosion–corrosion tests were characterized by scanning electron microscopy.The results showed that an increase in flow velocity could enhance the electrochemical corrosion and consequently decrease the passivation properties of the steel.The erosion–corrosion damage of the samples increased substantially when the flow velocity exceeded the critical value of 4 m·s^-1.The mass loss rate increased as the sand content increased,reaching a maximum at 7 wt%sand content,corresponding to the most severe electrochemical corrosion damage.When the sand content was increased further,however,the mass loss rate decreased and then tended stable.The mass loss was divided into incubation,sustained,and stationary periods,with a maximum mass loss rate of 12.97 g·h^-1·m^-2 after an erosion period of 2.5 h.The erosion–corrosion mechanism was investigated in detail.展开更多
The thermal fatigue behaviour of an air plasma sprayed thermal barrier coating was investigated. And also the interfacial strengths of thermal barrier coated specimens subjected to thermal fatigue, as well as a retire...The thermal fatigue behaviour of an air plasma sprayed thermal barrier coating was investigated. And also the interfacial strengths of thermal barrier coated specimens subjected to thermal fatigue, as well as a retired TBC vane were also evaluated by means of an instrumented indentation machine. The results indicated that, (1) the TGO grew at the interface during thermal fatigue cycle as a function of the exposure time at elevated temperature; (2) the microcracks were initiated in the top coating and at the interface after thermal cycle tests; (3) the interfacial strength of TBC, which was evaluated by the indentation method, increased with the thermal cycles; (4) the interfacial strength of the retired TBC vane was almost equal with that of the as-sprayed TBC specimen.展开更多
A Cr-Ni-Mo overlayer was deposited on the surface of compacted graphite iron(CGI)by the plasma transferred arc(PTA)alloying technique.The microstructure of Cr-Ni-Mo overlayer was characterized by optical microscop...A Cr-Ni-Mo overlayer was deposited on the surface of compacted graphite iron(CGI)by the plasma transferred arc(PTA)alloying technique.The microstructure of Cr-Ni-Mo overlayer was characterized by optical microscopy(OM),scanning electron microscopy(SEM)equipped with energy dispersive spectroscopy(EDS),and X-ray diffractometer(XRD).Results show that the cross-section consists of four regions:alloying zone(AZ),molten zone(MZ),heat affected zone(HAZ),and the substrate(SUB).The microstructure of AZ mainly consists of cellularγ-(Fe,Ni)solid solution,residual austenite and a network of eutectic Cr7C3 carbide while the MZ area has a typical feature of white cast iron(M3C-type cementite).The martensite/ledeburite double shells are observed in the HAZ.With decreasing the concentration of Cr-Ni-Mo alloys,the fracture mode changes from ductile in the AZ to brittle in the MZ.The maximum hardness of the AZ(450 HV0.2)is lower than that of the MZ(800 HV0.2).The eutectic M3 C and M7C3 carbides increase the microhardness,while the austenite decreases that of the AZ.展开更多
In this work,we report a class of wearable,stitchable,and sensitive carbon nanofiber(CNF)-polydimethylsiloxane(PDMS)composite-based piezoresistive sensors realized by carbonizing electrospun polyacrylonitrile(PAN)nano...In this work,we report a class of wearable,stitchable,and sensitive carbon nanofiber(CNF)-polydimethylsiloxane(PDMS)composite-based piezoresistive sensors realized by carbonizing electrospun polyacrylonitrile(PAN)nanofibers and subsequently embedding in PDMS elastomeric thin films.Electro-mechanical tactile sensing characterization of the resulting piezoresistive strain sensors revealed a linear response with an average force sensitivity of~1.82 kN−1 for normal forces up to 20 N.The real-time functionality of the CNF-PDMS composite sensors in wearable body sensor networks and advanced bionic skin applications was demonstrated through human motion and gesture monitoring experiments.A skin-inspired artificial soft sensor capable of demonstrating proprioceptive and tactile sensory perception utilizing CNF bundles has been shown.Furthermore,a 16-point pressure-sensitive flexible sensor array mimicking slow adapting low threshold mechanoreceptors of glabrous skin was demonstrated.Such devices in tandem with neuromorphic circuits can potentially recreate the sense of touch in robotic arms and restore somatosensory perception in amputees.展开更多
This work demonstrates the application of electrospun single and bundled carbon nanofibers(CNFs)as piezoresistive sensing elements in flexible and ultralightweight sensors.Material,electrical,and nanomechanical charac...This work demonstrates the application of electrospun single and bundled carbon nanofibers(CNFs)as piezoresistive sensing elements in flexible and ultralightweight sensors.Material,electrical,and nanomechanical characterizations were conducted on the CNFs to understand the effect of the critical synthesis parameter—the pyrolyzation temperature on the morphological,structural,and electrical properties.The mechanism of conductive path change under the influence of external stress was hypothesized to explain the piezoresistive behavior observed in the CNF bundles.Quasi-static tensile strain characterization of the CNF bundle-based flexible strain sensor showed a linear response with an average gauge factor of 11.14(for tensile strains up to 50%).Furthermore,conductive graphitic domain discontinuity model was invoked to explain the piezoresistivity originating in a single isolated electrospun CNF.Finally,a single piezoresistive CNF was utilized as a sensing element in an NEMS flow sensor to demonstrate air flow sensing in the range of 5-35 m/s.展开更多
基金supported by the National Natural Science Foundation of China(52375372)the National Key Laboratory of Particle Transport and Separation Technology(KWKF-2024-3).
文摘Heterogeneous manufacturing is a topic that continues to receive attention.As an emerging manufacturing technology,additive manufacturing can provide strong technical support for heterogeneous manufacturing.In this study,both homogeneous and heterogeneous composite tubular bionic components were fabricated based on the cold metal transition technology,and the influence of deposition current on the microstructure and mechanical properties of the components was studied.The results show that the interface of the as-deposited heterogeneous composite component is well bonded,and there is an obvious mechanical interlocking structure.The compressive yield strength and elongation of the heterogeneous composite components are higher than those of the homogeneous components,and are positively correlated with the deposition current.Due to the fluctuation of element content,there are a large number of fine grain structures at the interface of the heterogeneous composite components,which increases the mechanical properties.
基金supported by the Major Special Program of Fujian Province, China (No. 2017HZ0001-2)the Joint Innovative Project for Industrial Technology of Fujian Province, China (No. FG-2016001)+1 种基金the Special Funds for Marine High-Tech Industry Development of the Fujian Province of China (High-Tech of Ocean and Fisheries of Fujian Province 2014 No. 14)the Scientific Research Projects for Young Teachers of Education Department of Fujian Province, China (No. JAT160066)
文摘Polarization curves and mass losses of SAF3207 hyper-duplex stainless steel under various conditions were measured.The damaged surfaces after erosion–corrosion tests were characterized by scanning electron microscopy.The results showed that an increase in flow velocity could enhance the electrochemical corrosion and consequently decrease the passivation properties of the steel.The erosion–corrosion damage of the samples increased substantially when the flow velocity exceeded the critical value of 4 m·s^-1.The mass loss rate increased as the sand content increased,reaching a maximum at 7 wt%sand content,corresponding to the most severe electrochemical corrosion damage.When the sand content was increased further,however,the mass loss rate decreased and then tended stable.The mass loss was divided into incubation,sustained,and stationary periods,with a maximum mass loss rate of 12.97 g·h^-1·m^-2 after an erosion period of 2.5 h.The erosion–corrosion mechanism was investigated in detail.
文摘The thermal fatigue behaviour of an air plasma sprayed thermal barrier coating was investigated. And also the interfacial strengths of thermal barrier coated specimens subjected to thermal fatigue, as well as a retired TBC vane were also evaluated by means of an instrumented indentation machine. The results indicated that, (1) the TGO grew at the interface during thermal fatigue cycle as a function of the exposure time at elevated temperature; (2) the microcracks were initiated in the top coating and at the interface after thermal cycle tests; (3) the interfacial strength of TBC, which was evaluated by the indentation method, increased with the thermal cycles; (4) the interfacial strength of the retired TBC vane was almost equal with that of the as-sprayed TBC specimen.
文摘A Cr-Ni-Mo overlayer was deposited on the surface of compacted graphite iron(CGI)by the plasma transferred arc(PTA)alloying technique.The microstructure of Cr-Ni-Mo overlayer was characterized by optical microscopy(OM),scanning electron microscopy(SEM)equipped with energy dispersive spectroscopy(EDS),and X-ray diffractometer(XRD).Results show that the cross-section consists of four regions:alloying zone(AZ),molten zone(MZ),heat affected zone(HAZ),and the substrate(SUB).The microstructure of AZ mainly consists of cellularγ-(Fe,Ni)solid solution,residual austenite and a network of eutectic Cr7C3 carbide while the MZ area has a typical feature of white cast iron(M3C-type cementite).The martensite/ledeburite double shells are observed in the HAZ.With decreasing the concentration of Cr-Ni-Mo alloys,the fracture mode changes from ductile in the AZ to brittle in the MZ.The maximum hardness of the AZ(450 HV0.2)is lower than that of the MZ(800 HV0.2).The eutectic M3 C and M7C3 carbides increase the microhardness,while the austenite decreases that of the AZ.
基金supported by financial support from the University of Groningen’s start-up grant and Dutch Research Council(NWO)through the NWA Idea Generator project(NWA.1228.192.279)。
文摘In this work,we report a class of wearable,stitchable,and sensitive carbon nanofiber(CNF)-polydimethylsiloxane(PDMS)composite-based piezoresistive sensors realized by carbonizing electrospun polyacrylonitrile(PAN)nanofibers and subsequently embedding in PDMS elastomeric thin films.Electro-mechanical tactile sensing characterization of the resulting piezoresistive strain sensors revealed a linear response with an average force sensitivity of~1.82 kN−1 for normal forces up to 20 N.The real-time functionality of the CNF-PDMS composite sensors in wearable body sensor networks and advanced bionic skin applications was demonstrated through human motion and gesture monitoring experiments.A skin-inspired artificial soft sensor capable of demonstrating proprioceptive and tactile sensory perception utilizing CNF bundles has been shown.Furthermore,a 16-point pressure-sensitive flexible sensor array mimicking slow adapting low threshold mechanoreceptors of glabrous skin was demonstrated.Such devices in tandem with neuromorphic circuits can potentially recreate the sense of touch in robotic arms and restore somatosensory perception in amputees.
文摘This work demonstrates the application of electrospun single and bundled carbon nanofibers(CNFs)as piezoresistive sensing elements in flexible and ultralightweight sensors.Material,electrical,and nanomechanical characterizations were conducted on the CNFs to understand the effect of the critical synthesis parameter—the pyrolyzation temperature on the morphological,structural,and electrical properties.The mechanism of conductive path change under the influence of external stress was hypothesized to explain the piezoresistive behavior observed in the CNF bundles.Quasi-static tensile strain characterization of the CNF bundle-based flexible strain sensor showed a linear response with an average gauge factor of 11.14(for tensile strains up to 50%).Furthermore,conductive graphitic domain discontinuity model was invoked to explain the piezoresistivity originating in a single isolated electrospun CNF.Finally,a single piezoresistive CNF was utilized as a sensing element in an NEMS flow sensor to demonstrate air flow sensing in the range of 5-35 m/s.
