Due to the rapid development of precision manufacturing technology,much research has been conducted in the field of multisensor measurement and data fusion technology with a goal of enhancing monitoring capabilities i...Due to the rapid development of precision manufacturing technology,much research has been conducted in the field of multisensor measurement and data fusion technology with a goal of enhancing monitoring capabilities in terms of measurement accuracy and information richness,thereby improving the efficiency and precision of manufacturing.In a multisensor system,each sensor independently measures certain parameters.Then,the system uses a relevant signalprocessing algorithm to combine all of the independent measurements into a comprehensive set of measurement results.The purpose of this paper is to describe multisensor measurement and data fusion technology and its applications in precision monitoring systems.The architecture of multisensor measurement systems is reviewed,and some implementations in manufacturing systems are presented.In addition to the multisensor measurement system,related data fusion methods and algorithms are summarized.Further perspectives on multisensor monitoring and data fusion technology are included at the end of this paper.展开更多
Additive manufacturing(AM) technology is considered one of the most promising manufacturing technologies in the aerospace and defense industries. However, AM components are known to have various internal defects, such...Additive manufacturing(AM) technology is considered one of the most promising manufacturing technologies in the aerospace and defense industries. However, AM components are known to have various internal defects, such as powder agglomeration, balling, porosity,internal cracks and thermal/internal stress, which can significantly affect the quality, mechanical properties and safety of final parts. Therefore, defect inspection methods are important for reducing manufactured defects and improving the surface quality and mechanical properties of AM components. This paper describes defect inspection technologies and their applications in AM processes. The architecture of defects in AM processes is reviewed. Traditional defect detection technology and the surface defect detection methods based on deep learning are summarized, and future aspects are suggested.展开更多
As the bed depth increases,sintering yield increases,but the productivity decreases.To reveal the reasons for the decrease in productivity and explore targeted solutions,the bed resistance of mixtures,wet zone,and com...As the bed depth increases,sintering yield increases,but the productivity decreases.To reveal the reasons for the decrease in productivity and explore targeted solutions,the bed resistance of mixtures,wet zone,and combustion zone was analyzed in the laboratory.The results showed that the decreased porosity of mixture resulted in the increased bed resistance by 160.56%when the bed depth increased from 600 to 1000 mm.After improving porosity of 1%by adding loosening bars with optimized size and distribution,the bed resistance decreased,and the productivity increased by 5%.The increase in bed depth increased the thickness of the wet zone from 120 to 680 mm and the resistance from 1.56 to 8.83 kPa.By using a three-stage intensive mixer and pre-adding water for granulation,the moisture of mixture was reduced by 0.6%,and the sintering productivity increased by 4%.Besides,the high bed resistance is mainly caused by the increase in the thickness of the combustion zone from 31.9 to 132.7 mm,and the bed resistance increased from 0.70 to 5.62 kPa.The bed resistance of the combustion zone at 900 mm was increased by 90.51%compared to 700 mm.After optimization of the distribution of coke breeze,the thickness of combustion zone at the lower layer decreased from 132.7 to 106.84 mm and permeability improved significantly.展开更多
Bone tissue relies on the intricate interplay between blood vessels and nerve fibers,both are essential for many physiological and pathological processes of the skeletal system.Blood vessels provide the necessary oxyg...Bone tissue relies on the intricate interplay between blood vessels and nerve fibers,both are essential for many physiological and pathological processes of the skeletal system.Blood vessels provide the necessary oxygen and nutrients to nerve and bone tissues,and remove metabolic waste.Concomitantly,nerve fibers precede blood vessels during growth,promote vascularization,and influence bone cells by secreting neurotransmitters to stimulate osteogenesis.Despite the critical roles of both components,current biomaterials generally focus on enhancing intraosseous blood vessel repair,while often neglecting the contribution of nerves.Understanding the distribution and main functions of blood vessels and nerve fibers in bone is crucial for developing effective biomaterials for bone tissue engineering.This review first explores the anatomy of intraosseous blood vessels and nerve fibers,highlighting their vital roles in bone embryonic development,metabolism,and repair.It covers innovative bone regeneration strategies directed at accelerating the intrabony neurovascular system over the past 10 years.The issues covered included material properties(stiffness,surface topography,pore structures,conductivity,and piezoelectricity)and acellular biological factors[neurotrophins,peptides,ribonucleic acids(RNAs),inorganic ions,and exosomes].Major challenges encountered by neurovascularized materials during their clinical translation have also been highlighted.Furthermore,the review discusses future research directions and potential developments aimed at producing bone repair materials that more accurately mimic the natural healing processes of bone tissue.This review will serve as a valuable reference for researchers and clinicians in developing novel neurovascularized biomaterials and accelerating their translation into clinical practice.By bridging the gap between experimental research and practical application,these advancements have the potential to transform the treatment of bone defects and significantly improve the quality of life for patients with bone-related conditions.展开更多
Thalidomide,an immunomodulatory drug,is widely recommended for the treatment of recurrent aphthous stomatitis(RAS).This review aimed to assess the reliability of thalidomide for managing RAS,oro-genital ulcers associa...Thalidomide,an immunomodulatory drug,is widely recommended for the treatment of recurrent aphthous stomatitis(RAS).This review aimed to assess the reliability of thalidomide for managing RAS,oro-genital ulcers associated with Behçet’s disease(BD),and RAS in individuals with HIV infection.A systematic review was conducted following PICOS(Patient,Intervention,Control,Outcome,Study design)principles.Given the heterogeneity across studies,a qualitative analysis was performed in place of a meta-analysis.Eight randomized controlled trials(RCTs)were deemed eligible for inclusion.In three RCTs focused on RAS,a dosage of thalidomide at 100 mg/d demonstrated efficacy,while a lower dose of 25 mg/d helped prolong the recurrence interval of RAS.For oro-genital ulcers of BD,two RCTs indicated that both 300 mg/d for 24 weeks and 200 mg/d for 28 d,preceded by an initial dose of 400 mg/d for 5 d,were effective.In three RCTs investigating RAS in HIV-infected patients,thalidomide at 200 mg/d for either 4 or 7 weeks,with an initial dose of 400 mg/d for the first week,proved effective.However,a regimen of 100 mg three times per week failed to prevent the recurrence of oral ulcers.Adverse reactions to thalidomide were generally tolerable within the dosage ranges used in these studies.Overall,thalidomide showed promising efficacy for treating RAS,oro-genital ulcers in BD,and RAS in HIV-infected individuals.However,the variability in trial designs,dosages,and treatment durations makes it challenging to recommend an optimal dose and course of therapy.Further high-quality RCTs are necessary to establish more definitive guidelines.展开更多
In this study,we demonstrate the direct in-situ synthesis of NiTi alloys with tunable chemical com-position(Ni/Ti atomic ratio)and corresponding thermomechanical response.This synthesis is achieved by regulating the f...In this study,we demonstrate the direct in-situ synthesis of NiTi alloys with tunable chemical com-position(Ni/Ti atomic ratio)and corresponding thermomechanical response.This synthesis is achieved by regulating the feeding speed ratio of pure Ni and Ti wires during the additive manufacturing pro-cess based on dual-wire-feed electron beam directed energy deposition(EB-DED)technology.Under ap-propriate process conditions,the resulting NiTi alloys exhibit a controllable evolution around the near-equiatomic composition and display a typical columnar grain morphology characteristic of additively manufactured NiTi alloys.With an increase in Ni content(shifting from Ti-rich to Ni-rich),the second phase particles present in the samples change from Ti-rich phase(Ti_(2) Ni)to Ni-rich phases(such as Ni4 Ti3 and Ni3 Ti_(2)).The phase transformation temperatures gradually decrease with increasing Ni content,and the predominant matrix phase transitions from martensite to austenite.The as-built NiTi alloy exhibits a typical tensile curve with a good tensile elongation of 11%,fabricated under suitable composition and microstructure conditions.This result surpasses values reported in current in-situ synthesized NiTi alloys through additive manufacturing methods.Moreover,it almost reaches the levels achieved by additively manufactured NiTi alloys using pre-alloyed raw materials.Furthermore,this study reports,for the first time in the field of in-situ synthesized NiTi alloys,a good tensile shape memory effect,achieving an im-pressive recovery rate of up to 70%under a tensile strain of 6%.This investigation provides a meaningful theoretical perspective and technical strategy for the integrated customization of NiTi alloy components in structure,composition,and function.This low-cost and high-efficiency approach is particularly attrac-tive for the preparation of functional graded,large-scale and disposable NiTi components.展开更多
Leveraging surface texturing to realize significant friction reduction at contact interfaces has emerged as a preferred technique among tribology experts,boosting tribological energy efficiency and sustainability.This...Leveraging surface texturing to realize significant friction reduction at contact interfaces has emerged as a preferred technique among tribology experts,boosting tribological energy efficiency and sustainability.This review systematically demonstrates optimization strategies,advanced manufacturing methods,typical applications,and outlooks of technical challenges toward surface texturing for friction reduction.Firstly,the lubricated contact models of microtextures are introduced.Then,we provide a framework of state-of-the-art research on synergistic friction optimization strategies of microtexture structures,surface treatments,liquid lubricants,and external energy fields.A comparative analysis evaluates the strengths and weaknesses of manufacturing techniques commonly employed for microtextured surfaces.The latest research advancements in microtextures in different application scenarios are highlighted.Finally,the challenges and directions of future research on surface texturing technology are briefly addressed.This review aims to elaborate on the worldwide progress in the optimization,manufacturing,and application of microtexture-enabled friction reduction technologies to promote their practical utilizations.展开更多
On-chip devices for generating pre-designed vectorial optical fields(VOFs)under surface wave(SW)excitations are highly desired in integrated photonics.However,conventional devices are usually of large footprints,low e...On-chip devices for generating pre-designed vectorial optical fields(VOFs)under surface wave(SW)excitations are highly desired in integrated photonics.However,conventional devices are usually of large footprints,low efficiencies,and limited wave-control capabilities.Here,we present a generic approach to design ultra-compact on-chip devices that can efficiently generate pre-designed VOFs under SW excitations,and experimentally verify the concept in terahertz(THz)regime.We first describe how to design SW-excitation metasurfaces for generating circularly polarized complex beams,and experimentally demonstrate two meta-devices to realize directional emission and focusing of THz waves with oppo-site circular polarizations,respectively.We then establish a systematic approach to construct an integrated device via merging two carefully designed metasurfaces,which,under SW excitations,can separately produce pre-designed far-field patterns with different circular polarizations and generate target VOF based on their interference.As a proof of con-cept,we demonstrate experimentally a meta-device that can generate a radially polarized Bessel beam under SW excita-tion at~0.4 THz.Experimental results agree well with full-wave simulations,collectively verifying the performance of our device.Our study paves the road to realizing highly integrated on-chip functional THz devices,which may find many ap-plications in biological sensing,communications,displays,image multiplexing,and beyond.展开更多
Modern industrial equipment is increasingly characterized by miniaturization,integration,and high performance,necessitating the production of complex structural parts with exceptionally high internal surface quality.D...Modern industrial equipment is increasingly characterized by miniaturization,integration,and high performance,necessitating the production of complex structural parts with exceptionally high internal surface quality.Direct manufacturing often leads to high internal surface roughness,which traditional finishing and measuring methods cannot adequately address due to the decreasing size and increasing complexity of internal structures.This is especially true for components like pipes with large aspect ratios,extremely small deep holes,multi-stage bends,cross pipes,and array holes.To meet the high-performance manufacturing demands of these parts,advanced internal surface finishing and roughness measurement technologies have gained significant attention.This review focuses on the challenges and solutions related to internal surface parts with various apertures and complex structures.Internal surface finishing methods are categorized into mechanical finishing,fluid-based finishing,and energy-field-based finishing based on their characteristics.Roughness measurement technologies are divided into tool-probing and non-probing methods.The principles,required equipment,and key parameters of each finishing and measurement approach are discussed in detail.Additionally,the advantages and limitations of these methods are summarized,and future trends are forecasted.This paper serves as a comprehensive guide for researchers and engineers aiming to enhance the internal surface quality of complex structure parts.展开更多
Neuropathic pain,often featuring allodynia,imposes significant physical and psychological burdens on patients,with limited treatments due to unclear central mechanisms.Addressing this challenge remains a crucial unsol...Neuropathic pain,often featuring allodynia,imposes significant physical and psychological burdens on patients,with limited treatments due to unclear central mechanisms.Addressing this challenge remains a crucial unsolved issue in pain medicine.Our previous study,using protein kinase C gamma(PKCγ)-tdTomato mice,highlights the spinal feedforward inhibitory circuit involving PKCγ neurons in gating neuropathic allodynia.However,the regulatory mechanisms governing this circuit necessitate further elucidation.We used diverse transgenic mice and advanced techniques to uncover the regulatory role of the descending serotonin(5-HT)facilitation system on spinal PKCγ neurons.Our findings revealed that 5-HT neurons from the rostral ventromedial medulla hyperpolarize spinal inhibitory interneurons via 5-HT_(2C) receptors,disinhibiting the feedforward inhibitory circuit involving PKCγ neurons and exacerbating allodynia.Inhibiting spinal 5-HT_(2C) receptors restored the feedforward inhibitory circuit,effectively preventing neuropathic allodynia.These insights offer promising therapeutic targets for neuropathic allodynia management,emphasizing the potential of spinal 5-HT_(2C) receptors as a novel avenue for intervention.展开更多
Periodontal bone defects,primarily caused by periodontitis,are highly prevalent in clinical settings and manifest as bone fenestration,dehiscence,or attachment loss,presenting a significant challenge to oral health.In...Periodontal bone defects,primarily caused by periodontitis,are highly prevalent in clinical settings and manifest as bone fenestration,dehiscence,or attachment loss,presenting a significant challenge to oral health.In regenerative medicine,harnessing developmental principles for tissue repair offers promising therapeutic potential.Of particular interest is the condensation of progenitor cells,an essential event in organogenesis that has inspired clinically effective cell aggregation approaches in dental regeneration.However,the precise cellular coordination mechanisms during condensation and regeneration remain elusive.Here,taking the tooth as a model organ,we employed single-cell RNA sequencing to dissect the cellular composition and heterogeneity of human dental follicle and dental papilla,revealing a distinct Platelet-derived growth factor receptor alpha(PDGFRA)mesenchymal stem/stromal cell(MSC)population with remarkable odontogenic potential.Interestingly,a reciprocal paracrine interaction between PDGFRA^(+)dental follicle stem cells(DFSCs)and CD31^(+)Endomucin^(+)endothelial cells(ECs)was mediated by Vascular endothelial growth factor A(VEGFA)and Platelet-derived growth factor subunit BB(PDGFBB).This crosstalk not only maintains the functionality of PDGFRA^(+)DFSCs but also drives specialized angiogenesis.In vivo periodontal bone regeneration experiments further reveal that communication between PDGFRA+DFSC aggregates and recipient ECs is essential for effective angiogenic-osteogenic coupling and rapid tissue repair.Collectively,our results unravel the importance of MSC-EC crosstalk mediated by the VEGFA and PDGFBB-PDGFRA reciprocal signaling in orchestrating angiogenesis and osteogenesis.These findings not only establish a framework for deciphering and promoting periodontal bone regeneration in potential clinical applications but also offer insights for future therapeutic strategies in dental or broader regenerative medicine.展开更多
Peri-implant keratinized mucosa(PIKM)augmentation refers to surgical procedures aimed at increasing the width of PIKM.Consensus reports emphasize the necessity of maintaining a minimum width of PIKM to ensure long-ter...Peri-implant keratinized mucosa(PIKM)augmentation refers to surgical procedures aimed at increasing the width of PIKM.Consensus reports emphasize the necessity of maintaining a minimum width of PIKM to ensure long-term peri-implant health.Currently,several surgical techniques have been validated for their effectiveness in increasing PIKM.However,the selection and application of PIKM augmentation methods may present challenges for dental practitioners due to heterogeneity in surgical techniques,variations in clinical scenarios,and anatomical differences.Therefore,clear guidelines and considerations for PIKM augmentation are needed.This expert consensus focuses on the commonly employed surgical techniques for PIKM augmentation and the factors influencing their selection at second-stage surgery.It aims to establish a standardized framework for assessing,planning,and executing PIKM augmentation procedures,with the goal of offering evidence-based guidance to enhance the predictability and success of PIKM augmentation.展开更多
Polymers are widely used materials in aerospace,automotive,construction,medical devices and pharmaceuticals.Polymers are being promoted rapidly due to their ease of manufacturing and improved material properties.Resea...Polymers are widely used materials in aerospace,automotive,construction,medical devices and pharmaceuticals.Polymers are being promoted rapidly due to their ease of manufacturing and improved material properties.Research on polymer processing technology should be paid more attention to due to the increasing demand for polymer applications.Selective laser sintering(SLS)uses a laser to sinter powdered materials(typical polyamide),and it is one of the critical additive manufacturing(AM)techniques of polymer.It irradiates the laser beam on the defined areas by a computer-aided design three-dimensional(3D)model to bind the material together to create a designed 3D solid structure.SLS has many advantages,such as no support structures and excellent mechanical properties resembling injection moulded parts compared with other AM methods.However,the ability of SLS to process polymers is still affected by some defects,such as the porous structure and limited available types of SLS polymers.Therefore,this article reviews the current state-of-the-art SLS of polymers,including the fundamental principles in this technique,the SLS developments of typical polymers,and the essential process parameters in SLS.Furthermore,the applications of SLS are focused,and the conclusions and perspectives are discussed.展开更多
The electrochemical behavior of silicon wafer in alkaline slurry with nano-sized CeO2 abrasive was investigated.The variations of corrosion potential(φcorr)and corrosion current density(Jcorr)of the P-type(100)silico...The electrochemical behavior of silicon wafer in alkaline slurry with nano-sized CeO2 abrasive was investigated.The variations of corrosion potential(φcorr)and corrosion current density(Jcorr)of the P-type(100)silicon wafer with the slurry pH value and the concentration of abrasive CeO2 were studied by polarization curve technologies.The dependence of the polishing rate on the pH and the concentration of CeO2 in slurries during chemical mechanical polishing(CMP)were also studied.It is discovered that there is a large change of φcorr and Jcorr when slurry pH is altered and the Jcorr reaches the maximum(1.306 μA/cm2)at pH 10.5 when the material removal rate(MRR)comes to the fastest value.The Jcorr increases gradually from 0.994 μA/cm2 with 1% CeO2 to 1.304 μA/cm2 with 3% CeO2 and reaches a plateau with the further increase of CeO2 concentration.There is a considerable MRR in the slurry with 3% CeO2 at pH 10.5.The coherence between Jcorr and MRR elucidates that the research on the electrochemical behavior of silicon wafers in the alkaline slurry could offer theoretic guidance on silicon polishing rate and ensure to adjust optimal components of slurry.展开更多
Lean manufacturing is often seen as a set of tools that reduce the total cost and improve the quality of manufactured products.The lean management philosophy is one which targets waste reduction in every facet of the ...Lean manufacturing is often seen as a set of tools that reduce the total cost and improve the quality of manufactured products.The lean management philosophy is one which targets waste reduction in every facet of the manufacturing business;however,only recently have studies linked lean management philosophies with improving environmental sustainability.These studies suggest that lean manufacturing is more than a set of lean tools that can optimize manufacturing efficiencies;it is a process and mindset that needs to be integrated into daily manufacturing systems to achieve sustainability.The foundry industry,as well as manufacturing in general,has significant challenges in the current regulatory and political climate with developing an economically and environmentally sustainable business model.Lean manufacturing has proven itself as a model for both economic sustainability and environmental stewardship.Several recent studies have shown that both lean and green techniques and "zero-waste" policies also lead to reductions in overall cost.While these strategies have been examined for general manufacturing,they have not been investigated in detail for the foundry industry.This paper will review the current literature and describe how lean and green can provide a relevant framework for environmentally and economically sustainable foundries.Examples of lean and green technologies and techniques which can be applied to foundries in a global context will be described.展开更多
The effect of iron addition on the microstructure, mechanical and magnetic properties of Al-matrix composite was studied. Mechanical mixing was used for the preparation of 0, 5%, 10% and 15% Fe-Al composites(mass fra...The effect of iron addition on the microstructure, mechanical and magnetic properties of Al-matrix composite was studied. Mechanical mixing was used for the preparation of 0, 5%, 10% and 15% Fe-Al composites(mass fraction). Mixtures of Al-Fe were compacted and sintered in a vacuum furnace at 600 °C for 1 h. X-ray diffraction(XRD) of the samples containing 5% and 10% Fe indicates the presence of Al and Fe peaks, while sample containing 15% Fe reveals Al and Al13Fe4 peaks. The results show that both densification and thermal conductivity of the composites decrease by increasing the iron content. The presence of iron in the composite improves the compressive strength and the hardness. The strengthening mechanism is associated with the grain refinement of the matrix and uniform distribution of the Fe particles, as well as the formation of Al13Fe4 intermetallic. The measured magnetization values are equal to 0.3816×10-3 A·m2/g for 5% Fe sample and increases up to 0.6597×10-3 A·m2/g for 10% Fe sample, then decreases to 0.0702×10-3 A·m2/g for 15% Fe sample. This can be explained by the formation of the diamagnetic Al13Fe4 intermetallic compound in the higher Fe content sample detected by XRD analysis.展开更多
A major dilemma faced in the nuclear industry is repair of stainless steel reactor components that have been exposed to neutron irradiation. When conventional fusion welding is used for repair, intergranular cracks de...A major dilemma faced in the nuclear industry is repair of stainless steel reactor components that have been exposed to neutron irradiation. When conventional fusion welding is used for repair, intergranular cracks develop in the heat-affected zone(HAZ). Friction stir processing(FSP), which operates at much lower peak temperatures than fusion welding, was studied as a crack repair method for irradiated 304 L stainless steel. A numerical simulation of the FSP process in 304 L was developed to predict temperatures and recrystallized grain size in the stir zone. The model employed an Eulerian finite element approach,where flow stresses for a large range of strain rates and temperatures inherent in FSP were used as input. Temperature predictions in three locations near the stir zone were accurate to within 4%, while prediction of welding power was accurate to within 5% of experimental measurements. The predicted recrystallized grain sizes ranged from 7.6 to 10.6 μm, while the experimentally measured grains sizes in the same locations ranged from 6.0 to 7.6 μm. The maximum error in predicted recrystallized grain size was about 39%, but the associated stir zone hardness from the predicted grain sizes was only different from the experiment by about 10%.展开更多
The thermodynamic characterization as well as the rheological characterization of the A201 alloy were conducted.Thermodynamic simulations (CALPHAD method) and calorimetric experiments were performed to determine the s...The thermodynamic characterization as well as the rheological characterization of the A201 alloy were conducted.Thermodynamic simulations (CALPHAD method) and calorimetric experiments were performed to determine the solidus and liquidus temperatures, the melting range and the sensitivity of the solid fraction at the thixoforming temperatures.The rheology of aluminium alloy A201 was examined using a high temperature Searle rheometer.The flow behaviour was analyzed with concentric cylinders of graphite to avoid chemical interactions with the liquid or semi-solid aluminium.The rotational body was grooved to prevent a phenomenon called wall slippage.Continuous cooling experiment was used to observe the shear rate effects on the flow behaviour.It can be seen that the viscosity level decreases at higher shear rates.Shear rate jump experiment was carried out to evaluate the steady state flow curve within the analyzed shear rate range from 60 s-1 to 260 s-1.It is found that the power law indexes are-1.35 and-1.49 for 35% and 45% solid fraction, respectively.Finally, some mechanical property data of as-cast and as-thixoformed A201 alloy are included indicating the potential for high strength applications.展开更多
Ni60-WC particles are used to improve the wear resistance of hard-facing steel due to their high hardness. An emerging technology that combines laser with cold spraying to deposit the hard-facing coatings is known as ...Ni60-WC particles are used to improve the wear resistance of hard-facing steel due to their high hardness. An emerging technology that combines laser with cold spraying to deposit the hard-facing coatings is known as supersonic laser deposition. In this study, Ni60-WC is deposited on low-carbon steel using SLD. The microstructure and performance of the coatings are investigated through SEM, optical microscopy, EDS, XRD, microhardness and pin-on-disc wear tests. The experimental results of the coating processed with the optimal parameters are compared to those of the coating deposited using laser cladding.展开更多
基金the financial support from Shanghai Science and Technology Committee Innovation Grand(Grant Nos.19ZR1404600,17JC1400601)National Key R&D Program of China(Project Nos.2017YFA0701200,2016YFF0102003)Science Challenging Program of CAEP(Grant No.JCKY2016212 A506-0106).
文摘Due to the rapid development of precision manufacturing technology,much research has been conducted in the field of multisensor measurement and data fusion technology with a goal of enhancing monitoring capabilities in terms of measurement accuracy and information richness,thereby improving the efficiency and precision of manufacturing.In a multisensor system,each sensor independently measures certain parameters.Then,the system uses a relevant signalprocessing algorithm to combine all of the independent measurements into a comprehensive set of measurement results.The purpose of this paper is to describe multisensor measurement and data fusion technology and its applications in precision monitoring systems.The architecture of multisensor measurement systems is reviewed,and some implementations in manufacturing systems are presented.In addition to the multisensor measurement system,related data fusion methods and algorithms are summarized.Further perspectives on multisensor monitoring and data fusion technology are included at the end of this paper.
基金financial support of the National Key R&D Program of China (Project Nos. 2017YFA0701200, 2016YFF0102003)the Shanghai Science and Technology Committee Innovation Grant (Grant Nos. 19ZR1404600, 17JC1400601)the Science Challenging Program of CAEP (Grant No. JCKY2016212A506-0106)。
文摘Additive manufacturing(AM) technology is considered one of the most promising manufacturing technologies in the aerospace and defense industries. However, AM components are known to have various internal defects, such as powder agglomeration, balling, porosity,internal cracks and thermal/internal stress, which can significantly affect the quality, mechanical properties and safety of final parts. Therefore, defect inspection methods are important for reducing manufactured defects and improving the surface quality and mechanical properties of AM components. This paper describes defect inspection technologies and their applications in AM processes. The architecture of defects in AM processes is reviewed. Traditional defect detection technology and the surface defect detection methods based on deep learning are summarized, and future aspects are suggested.
基金supported by the Basic Science Center Project for the National Natural Science Foundation of China(No.72088101)the S&T Program of Hebei(No.23564101D).
文摘As the bed depth increases,sintering yield increases,but the productivity decreases.To reveal the reasons for the decrease in productivity and explore targeted solutions,the bed resistance of mixtures,wet zone,and combustion zone was analyzed in the laboratory.The results showed that the decreased porosity of mixture resulted in the increased bed resistance by 160.56%when the bed depth increased from 600 to 1000 mm.After improving porosity of 1%by adding loosening bars with optimized size and distribution,the bed resistance decreased,and the productivity increased by 5%.The increase in bed depth increased the thickness of the wet zone from 120 to 680 mm and the resistance from 1.56 to 8.83 kPa.By using a three-stage intensive mixer and pre-adding water for granulation,the moisture of mixture was reduced by 0.6%,and the sintering productivity increased by 4%.Besides,the high bed resistance is mainly caused by the increase in the thickness of the combustion zone from 31.9 to 132.7 mm,and the bed resistance increased from 0.70 to 5.62 kPa.The bed resistance of the combustion zone at 900 mm was increased by 90.51%compared to 700 mm.After optimization of the distribution of coke breeze,the thickness of combustion zone at the lower layer decreased from 132.7 to 106.84 mm and permeability improved significantly.
基金supported by the Foundation of National Clinical Research Center for Oral Diseases(LCA202204)the Key Research and Development Program of Shaanxi(2024GH-YBXM-19)+7 种基金the Clinical New Technology Program of Air Force Medical University(LX2023-306)the China Postdoctoral Science Foundation(2019M653969)the Thousand Talents Plan of Shaanxi Province(to Jing Wang)the National Natural Science Foundation of China(82101069,22205257)the Logistics Independent Research Project of PLA(to Yang Jiao)the Beijing Natural Science Foundation(7242279),the Beijing Nova Program(20230484283)the Beijing Municipal Science&Technology Commission(Z221100007422130)the Open Project of State Key Laboratory of Trauma and Chemical poisoning(SKLO202401).
文摘Bone tissue relies on the intricate interplay between blood vessels and nerve fibers,both are essential for many physiological and pathological processes of the skeletal system.Blood vessels provide the necessary oxygen and nutrients to nerve and bone tissues,and remove metabolic waste.Concomitantly,nerve fibers precede blood vessels during growth,promote vascularization,and influence bone cells by secreting neurotransmitters to stimulate osteogenesis.Despite the critical roles of both components,current biomaterials generally focus on enhancing intraosseous blood vessel repair,while often neglecting the contribution of nerves.Understanding the distribution and main functions of blood vessels and nerve fibers in bone is crucial for developing effective biomaterials for bone tissue engineering.This review first explores the anatomy of intraosseous blood vessels and nerve fibers,highlighting their vital roles in bone embryonic development,metabolism,and repair.It covers innovative bone regeneration strategies directed at accelerating the intrabony neurovascular system over the past 10 years.The issues covered included material properties(stiffness,surface topography,pore structures,conductivity,and piezoelectricity)and acellular biological factors[neurotrophins,peptides,ribonucleic acids(RNAs),inorganic ions,and exosomes].Major challenges encountered by neurovascularized materials during their clinical translation have also been highlighted.Furthermore,the review discusses future research directions and potential developments aimed at producing bone repair materials that more accurately mimic the natural healing processes of bone tissue.This review will serve as a valuable reference for researchers and clinicians in developing novel neurovascularized biomaterials and accelerating their translation into clinical practice.By bridging the gap between experimental research and practical application,these advancements have the potential to transform the treatment of bone defects and significantly improve the quality of life for patients with bone-related conditions.
文摘Thalidomide,an immunomodulatory drug,is widely recommended for the treatment of recurrent aphthous stomatitis(RAS).This review aimed to assess the reliability of thalidomide for managing RAS,oro-genital ulcers associated with Behçet’s disease(BD),and RAS in individuals with HIV infection.A systematic review was conducted following PICOS(Patient,Intervention,Control,Outcome,Study design)principles.Given the heterogeneity across studies,a qualitative analysis was performed in place of a meta-analysis.Eight randomized controlled trials(RCTs)were deemed eligible for inclusion.In three RCTs focused on RAS,a dosage of thalidomide at 100 mg/d demonstrated efficacy,while a lower dose of 25 mg/d helped prolong the recurrence interval of RAS.For oro-genital ulcers of BD,two RCTs indicated that both 300 mg/d for 24 weeks and 200 mg/d for 28 d,preceded by an initial dose of 400 mg/d for 5 d,were effective.In three RCTs investigating RAS in HIV-infected patients,thalidomide at 200 mg/d for either 4 or 7 weeks,with an initial dose of 400 mg/d for the first week,proved effective.However,a regimen of 100 mg three times per week failed to prevent the recurrence of oral ulcers.Adverse reactions to thalidomide were generally tolerable within the dosage ranges used in these studies.Overall,thalidomide showed promising efficacy for treating RAS,oro-genital ulcers in BD,and RAS in HIV-infected individuals.However,the variability in trial designs,dosages,and treatment durations makes it challenging to recommend an optimal dose and course of therapy.Further high-quality RCTs are necessary to establish more definitive guidelines.
基金the State Key Laboratory of Tribology in Advanced Equipment(Project code:SKLT2022C20)Postdoc Matching Fund Scheme of The Hong Kong Polytechnic University(Project code:1-W283)+3 种基金Research Institute of Advanced Manufacturing at The Hong Kong Polytechnic University(PolyU)(Project code:CD9E,CD8Y)PolyU Research and Inno-vation Office(Project code:BBR5)Departmental General Research Fund of the Department of Industrial and Systems Engineering of The Hong Kong Polytechnic University(Project code:G-UAKX)the funding support for the State Key Laboratories in Hong Kong from the Innovation and Technology Commission of the Govern-ment of the Hong Kong Special Administrative Region,China.
文摘In this study,we demonstrate the direct in-situ synthesis of NiTi alloys with tunable chemical com-position(Ni/Ti atomic ratio)and corresponding thermomechanical response.This synthesis is achieved by regulating the feeding speed ratio of pure Ni and Ti wires during the additive manufacturing pro-cess based on dual-wire-feed electron beam directed energy deposition(EB-DED)technology.Under ap-propriate process conditions,the resulting NiTi alloys exhibit a controllable evolution around the near-equiatomic composition and display a typical columnar grain morphology characteristic of additively manufactured NiTi alloys.With an increase in Ni content(shifting from Ti-rich to Ni-rich),the second phase particles present in the samples change from Ti-rich phase(Ti_(2) Ni)to Ni-rich phases(such as Ni4 Ti3 and Ni3 Ti_(2)).The phase transformation temperatures gradually decrease with increasing Ni content,and the predominant matrix phase transitions from martensite to austenite.The as-built NiTi alloy exhibits a typical tensile curve with a good tensile elongation of 11%,fabricated under suitable composition and microstructure conditions.This result surpasses values reported in current in-situ synthesized NiTi alloys through additive manufacturing methods.Moreover,it almost reaches the levels achieved by additively manufactured NiTi alloys using pre-alloyed raw materials.Furthermore,this study reports,for the first time in the field of in-situ synthesized NiTi alloys,a good tensile shape memory effect,achieving an im-pressive recovery rate of up to 70%under a tensile strain of 6%.This investigation provides a meaningful theoretical perspective and technical strategy for the integrated customization of NiTi alloy components in structure,composition,and function.This low-cost and high-efficiency approach is particularly attrac-tive for the preparation of functional graded,large-scale and disposable NiTi components.
基金the National Natural Science Foundation of China(Award No.07120016)support by the Dalian University of Technology(DUT)(Award Nos.82232022,82232043,and DUT22LAB404)AVIC Shenyang Aircraft Company(Award No.12020641 and 12020642)。
文摘Leveraging surface texturing to realize significant friction reduction at contact interfaces has emerged as a preferred technique among tribology experts,boosting tribological energy efficiency and sustainability.This review systematically demonstrates optimization strategies,advanced manufacturing methods,typical applications,and outlooks of technical challenges toward surface texturing for friction reduction.Firstly,the lubricated contact models of microtextures are introduced.Then,we provide a framework of state-of-the-art research on synergistic friction optimization strategies of microtexture structures,surface treatments,liquid lubricants,and external energy fields.A comparative analysis evaluates the strengths and weaknesses of manufacturing techniques commonly employed for microtextured surfaces.The latest research advancements in microtextures in different application scenarios are highlighted.Finally,the challenges and directions of future research on surface texturing technology are briefly addressed.This review aims to elaborate on the worldwide progress in the optimization,manufacturing,and application of microtexture-enabled friction reduction technologies to promote their practical utilizations.
基金the financial support from National Natural Science Foundation of China (Nos. 62192771, 12374344, 12221004)National Key Research and Development Program of China (2022YFA1204700, 2020YFA0710100)+1 种基金Natural Science Foundation of Shanghai (Grant No. 23dz2260100)China Postdoctoral Science Foundation 2021TQ0077
文摘On-chip devices for generating pre-designed vectorial optical fields(VOFs)under surface wave(SW)excitations are highly desired in integrated photonics.However,conventional devices are usually of large footprints,low efficiencies,and limited wave-control capabilities.Here,we present a generic approach to design ultra-compact on-chip devices that can efficiently generate pre-designed VOFs under SW excitations,and experimentally verify the concept in terahertz(THz)regime.We first describe how to design SW-excitation metasurfaces for generating circularly polarized complex beams,and experimentally demonstrate two meta-devices to realize directional emission and focusing of THz waves with oppo-site circular polarizations,respectively.We then establish a systematic approach to construct an integrated device via merging two carefully designed metasurfaces,which,under SW excitations,can separately produce pre-designed far-field patterns with different circular polarizations and generate target VOF based on their interference.As a proof of con-cept,we demonstrate experimentally a meta-device that can generate a radially polarized Bessel beam under SW excita-tion at~0.4 THz.Experimental results agree well with full-wave simulations,collectively verifying the performance of our device.Our study paves the road to realizing highly integrated on-chip functional THz devices,which may find many ap-plications in biological sensing,communications,displays,image multiplexing,and beyond.
基金the financial supports from National Key R&D Program of China(No.2022YFB3403301)the Funds for International Cooperation and Exchange of the National Natural Science Foundation of China(No.52311530080)。
文摘Modern industrial equipment is increasingly characterized by miniaturization,integration,and high performance,necessitating the production of complex structural parts with exceptionally high internal surface quality.Direct manufacturing often leads to high internal surface roughness,which traditional finishing and measuring methods cannot adequately address due to the decreasing size and increasing complexity of internal structures.This is especially true for components like pipes with large aspect ratios,extremely small deep holes,multi-stage bends,cross pipes,and array holes.To meet the high-performance manufacturing demands of these parts,advanced internal surface finishing and roughness measurement technologies have gained significant attention.This review focuses on the challenges and solutions related to internal surface parts with various apertures and complex structures.Internal surface finishing methods are categorized into mechanical finishing,fluid-based finishing,and energy-field-based finishing based on their characteristics.Roughness measurement technologies are divided into tool-probing and non-probing methods.The principles,required equipment,and key parameters of each finishing and measurement approach are discussed in detail.Additionally,the advantages and limitations of these methods are summarized,and future trends are forecasted.This paper serves as a comprehensive guide for researchers and engineers aiming to enhance the internal surface quality of complex structure parts.
基金supported by the National Natural Science Foundation of China(81971058,82371226,82101295,82301398)the National Funded Postdoctoral Researcher Program(GZC20233585)The Boost Plan of Xijing Hospital(XJZT24QN25,XJZT25CX22).
文摘Neuropathic pain,often featuring allodynia,imposes significant physical and psychological burdens on patients,with limited treatments due to unclear central mechanisms.Addressing this challenge remains a crucial unsolved issue in pain medicine.Our previous study,using protein kinase C gamma(PKCγ)-tdTomato mice,highlights the spinal feedforward inhibitory circuit involving PKCγ neurons in gating neuropathic allodynia.However,the regulatory mechanisms governing this circuit necessitate further elucidation.We used diverse transgenic mice and advanced techniques to uncover the regulatory role of the descending serotonin(5-HT)facilitation system on spinal PKCγ neurons.Our findings revealed that 5-HT neurons from the rostral ventromedial medulla hyperpolarize spinal inhibitory interneurons via 5-HT_(2C) receptors,disinhibiting the feedforward inhibitory circuit involving PKCγ neurons and exacerbating allodynia.Inhibiting spinal 5-HT_(2C) receptors restored the feedforward inhibitory circuit,effectively preventing neuropathic allodynia.These insights offer promising therapeutic targets for neuropathic allodynia management,emphasizing the potential of spinal 5-HT_(2C) receptors as a novel avenue for intervention.
基金supported by grants from the National Key Research and Development Program of China(2022YFA1104400)the National Natural Science Foundation of China(82170988,82371020,82301028,82401201,82471011)+5 种基金the Young Science and Technology Rising Star Project of Shaanxi Province(2024ZC-KJXX-122)the China Postdoctoral Science Foundation(BX20230485)the Project of State Key Laboratory of Oral&Maxillofacial Reconstruction and Regeneration(2024MS04)the Shaanxi Provincial Health Research and Innovation Platform Construction Plan(2024PT-04)the“Rapid Response”Research projects(2023KXKT017 and 2023KXKT090)the Intramural Research Program project founded by Fourth Military Medical University(2024QMJJ008).
文摘Periodontal bone defects,primarily caused by periodontitis,are highly prevalent in clinical settings and manifest as bone fenestration,dehiscence,or attachment loss,presenting a significant challenge to oral health.In regenerative medicine,harnessing developmental principles for tissue repair offers promising therapeutic potential.Of particular interest is the condensation of progenitor cells,an essential event in organogenesis that has inspired clinically effective cell aggregation approaches in dental regeneration.However,the precise cellular coordination mechanisms during condensation and regeneration remain elusive.Here,taking the tooth as a model organ,we employed single-cell RNA sequencing to dissect the cellular composition and heterogeneity of human dental follicle and dental papilla,revealing a distinct Platelet-derived growth factor receptor alpha(PDGFRA)mesenchymal stem/stromal cell(MSC)population with remarkable odontogenic potential.Interestingly,a reciprocal paracrine interaction between PDGFRA^(+)dental follicle stem cells(DFSCs)and CD31^(+)Endomucin^(+)endothelial cells(ECs)was mediated by Vascular endothelial growth factor A(VEGFA)and Platelet-derived growth factor subunit BB(PDGFBB).This crosstalk not only maintains the functionality of PDGFRA^(+)DFSCs but also drives specialized angiogenesis.In vivo periodontal bone regeneration experiments further reveal that communication between PDGFRA+DFSC aggregates and recipient ECs is essential for effective angiogenic-osteogenic coupling and rapid tissue repair.Collectively,our results unravel the importance of MSC-EC crosstalk mediated by the VEGFA and PDGFBB-PDGFRA reciprocal signaling in orchestrating angiogenesis and osteogenesis.These findings not only establish a framework for deciphering and promoting periodontal bone regeneration in potential clinical applications but also offer insights for future therapeutic strategies in dental or broader regenerative medicine.
基金supported by the Natural Science Foundation of Sichuan Province(grant number:25NSFSC0265).
文摘Peri-implant keratinized mucosa(PIKM)augmentation refers to surgical procedures aimed at increasing the width of PIKM.Consensus reports emphasize the necessity of maintaining a minimum width of PIKM to ensure long-term peri-implant health.Currently,several surgical techniques have been validated for their effectiveness in increasing PIKM.However,the selection and application of PIKM augmentation methods may present challenges for dental practitioners due to heterogeneity in surgical techniques,variations in clinical scenarios,and anatomical differences.Therefore,clear guidelines and considerations for PIKM augmentation are needed.This expert consensus focuses on the commonly employed surgical techniques for PIKM augmentation and the factors influencing their selection at second-stage surgery.It aims to establish a standardized framework for assessing,planning,and executing PIKM augmentation procedures,with the goal of offering evidence-based guidance to enhance the predictability and success of PIKM augmentation.
基金the support from the Shanghai Science and Technology Committee Innovation Grant(Grant No.19ZR1404600)Fudan University-CIOMP Joint Fund(FC2020-006)。
文摘Polymers are widely used materials in aerospace,automotive,construction,medical devices and pharmaceuticals.Polymers are being promoted rapidly due to their ease of manufacturing and improved material properties.Research on polymer processing technology should be paid more attention to due to the increasing demand for polymer applications.Selective laser sintering(SLS)uses a laser to sinter powdered materials(typical polyamide),and it is one of the critical additive manufacturing(AM)techniques of polymer.It irradiates the laser beam on the defined areas by a computer-aided design three-dimensional(3D)model to bind the material together to create a designed 3D solid structure.SLS has many advantages,such as no support structures and excellent mechanical properties resembling injection moulded parts compared with other AM methods.However,the ability of SLS to process polymers is still affected by some defects,such as the porous structure and limited available types of SLS polymers.Therefore,this article reviews the current state-of-the-art SLS of polymers,including the fundamental principles in this technique,the SLS developments of typical polymers,and the essential process parameters in SLS.Furthermore,the applications of SLS are focused,and the conclusions and perspectives are discussed.
基金Project(2005DFBA028)supported by the International Cooperation of Science and Technology Ministry of ChinaProject(LA07023)supported by the National Undergraduate Innovative Experiment Plan
文摘The electrochemical behavior of silicon wafer in alkaline slurry with nano-sized CeO2 abrasive was investigated.The variations of corrosion potential(φcorr)and corrosion current density(Jcorr)of the P-type(100)silicon wafer with the slurry pH value and the concentration of abrasive CeO2 were studied by polarization curve technologies.The dependence of the polishing rate on the pH and the concentration of CeO2 in slurries during chemical mechanical polishing(CMP)were also studied.It is discovered that there is a large change of φcorr and Jcorr when slurry pH is altered and the Jcorr reaches the maximum(1.306 μA/cm2)at pH 10.5 when the material removal rate(MRR)comes to the fastest value.The Jcorr increases gradually from 0.994 μA/cm2 with 1% CeO2 to 1.304 μA/cm2 with 3% CeO2 and reaches a plateau with the further increase of CeO2 concentration.There is a considerable MRR in the slurry with 3% CeO2 at pH 10.5.The coherence between Jcorr and MRR elucidates that the research on the electrochemical behavior of silicon wafers in the alkaline slurry could offer theoretic guidance on silicon polishing rate and ensure to adjust optimal components of slurry.
文摘Lean manufacturing is often seen as a set of tools that reduce the total cost and improve the quality of manufactured products.The lean management philosophy is one which targets waste reduction in every facet of the manufacturing business;however,only recently have studies linked lean management philosophies with improving environmental sustainability.These studies suggest that lean manufacturing is more than a set of lean tools that can optimize manufacturing efficiencies;it is a process and mindset that needs to be integrated into daily manufacturing systems to achieve sustainability.The foundry industry,as well as manufacturing in general,has significant challenges in the current regulatory and political climate with developing an economically and environmentally sustainable business model.Lean manufacturing has proven itself as a model for both economic sustainability and environmental stewardship.Several recent studies have shown that both lean and green techniques and "zero-waste" policies also lead to reductions in overall cost.While these strategies have been examined for general manufacturing,they have not been investigated in detail for the foundry industry.This paper will review the current literature and describe how lean and green can provide a relevant framework for environmentally and economically sustainable foundries.Examples of lean and green technologies and techniques which can be applied to foundries in a global context will be described.
文摘The effect of iron addition on the microstructure, mechanical and magnetic properties of Al-matrix composite was studied. Mechanical mixing was used for the preparation of 0, 5%, 10% and 15% Fe-Al composites(mass fraction). Mixtures of Al-Fe were compacted and sintered in a vacuum furnace at 600 °C for 1 h. X-ray diffraction(XRD) of the samples containing 5% and 10% Fe indicates the presence of Al and Fe peaks, while sample containing 15% Fe reveals Al and Al13Fe4 peaks. The results show that both densification and thermal conductivity of the composites decrease by increasing the iron content. The presence of iron in the composite improves the compressive strength and the hardness. The strengthening mechanism is associated with the grain refinement of the matrix and uniform distribution of the Fe particles, as well as the formation of Al13Fe4 intermetallic. The measured magnetization values are equal to 0.3816×10-3 A·m2/g for 5% Fe sample and increases up to 0.6597×10-3 A·m2/g for 10% Fe sample, then decreases to 0.0702×10-3 A·m2/g for 15% Fe sample. This can be explained by the formation of the diamagnetic Al13Fe4 intermetallic compound in the higher Fe content sample detected by XRD analysis.
基金supported by the National Science Foundation grant CMMI-1405508
文摘A major dilemma faced in the nuclear industry is repair of stainless steel reactor components that have been exposed to neutron irradiation. When conventional fusion welding is used for repair, intergranular cracks develop in the heat-affected zone(HAZ). Friction stir processing(FSP), which operates at much lower peak temperatures than fusion welding, was studied as a crack repair method for irradiated 304 L stainless steel. A numerical simulation of the FSP process in 304 L was developed to predict temperatures and recrystallized grain size in the stir zone. The model employed an Eulerian finite element approach,where flow stresses for a large range of strain rates and temperatures inherent in FSP were used as input. Temperature predictions in three locations near the stir zone were accurate to within 4%, while prediction of welding power was accurate to within 5% of experimental measurements. The predicted recrystallized grain sizes ranged from 7.6 to 10.6 μm, while the experimentally measured grains sizes in the same locations ranged from 6.0 to 7.6 μm. The maximum error in predicted recrystallized grain size was about 39%, but the associated stir zone hardness from the predicted grain sizes was only different from the experiment by about 10%.
基金the "Ministerio de Ciencia e Innovación" and to the "Fondos FEDER",project "Integrauto" PSE-370000-2008-03the Basque Government,project "ETORTEK, Manufacturing 0.0 II",for their financial support
文摘The thermodynamic characterization as well as the rheological characterization of the A201 alloy were conducted.Thermodynamic simulations (CALPHAD method) and calorimetric experiments were performed to determine the solidus and liquidus temperatures, the melting range and the sensitivity of the solid fraction at the thixoforming temperatures.The rheology of aluminium alloy A201 was examined using a high temperature Searle rheometer.The flow behaviour was analyzed with concentric cylinders of graphite to avoid chemical interactions with the liquid or semi-solid aluminium.The rotational body was grooved to prevent a phenomenon called wall slippage.Continuous cooling experiment was used to observe the shear rate effects on the flow behaviour.It can be seen that the viscosity level decreases at higher shear rates.Shear rate jump experiment was carried out to evaluate the steady state flow curve within the analyzed shear rate range from 60 s-1 to 260 s-1.It is found that the power law indexes are-1.35 and-1.49 for 35% and 45% solid fraction, respectively.Finally, some mechanical property data of as-cast and as-thixoformed A201 alloy are included indicating the potential for high strength applications.
基金sponsored by the Centre for Industrial Photonics, Institute for Manufacture, Department of Engineering, University of Cambridgethe Natural Science Foundation of China (51271170)+1 种基金China International Science and Technology Cooperation Project (2011DFR50540)Major Scientific and Technological Special Key Industrial Project of Zhejiang Province (2012C11001)
文摘Ni60-WC particles are used to improve the wear resistance of hard-facing steel due to their high hardness. An emerging technology that combines laser with cold spraying to deposit the hard-facing coatings is known as supersonic laser deposition. In this study, Ni60-WC is deposited on low-carbon steel using SLD. The microstructure and performance of the coatings are investigated through SEM, optical microscopy, EDS, XRD, microhardness and pin-on-disc wear tests. The experimental results of the coating processed with the optimal parameters are compared to those of the coating deposited using laser cladding.
