Shape and volume optimization of industrial parts

In the present time, there are many challenges in the production of industrial parts. Due to the constantly rising prices of materials and energy, it is necessary to constantly look for ways to optimize production costs and optimize material consumption. There is great pressure on economical production, i. to produce products with the lowest costs given the expected and necessary properties. With the introduction of additive manufacturing technologies into practice and the production of parts for end use comes the introduction of methods for optimizing the shape of the part and the required amount of material for its production. We call this method Topological Optimization. The presented article describes the preparation of topologically optimized parts and a comparison of their strength properties with respect to the original and the original part.

A Review on Natural Fibre-Reinforced Biopolymer Composites: Properties and Applications

In ongoing decades, material researchers and scientists are giving more consideration towards the improvement of biobased polymer composites as various employments of items arranged by natural fibres and petrochemical polymers prompt natural awkwardness. The goal of this review paper is to provide an intensive review and applications of the foremost appropriate commonly used biodegradable polymer composites. It is imperative to build up the completely/incompletely biodegradable polymer composites without bargaining the mechanical, physical, and thermal properties which are required for the end-use applications. This reality roused to create biocomposite with better execution alongside the least natural effect. The utilization of natural fibre-reinforced polymer composites is concerned with the mechanical properties that are highly dependent on the morphology, hydrophilic tendency, aspect ratio, and dimensional stability of the natural fibre. With this in-depth consideration of eco-friendly biocomposites, structural application materials in the infrastructure, automotive industry, and consumer applications of the following decade are attainable within the near future.

Application of X-ray computed tomography to analyze the structure of sorghum grain

Background The structural characteristics of whole sorghum kernels are known to affect end-use quality, but traditional evaluation of this structure is two-dimensional (i.e., cross section of a kernel). Current technology offers the potential to consider three-dimensional structural characteristics of grain. X-ray computed tomography (CT) presents one such opportunity to nondestructively extract quantitative data from grain caryopses which can then be related to end-use quality. Results Phenotypic measurements were extracted from CT scans of grain sorghum caryopses. Extensive phenotypic variation was found for embryo volume, endosperm hardness, endosperm texture, endosperm volume, pericarp volume, and kernel volume. CT derived estimates were strongly correlated with ground truth measurements enabling the identification of genotypes with superior structural characteristics. Conclusions Presented herein is a phenotyping pipeline developed to quantify three-dimensional structural characteristics from grain sorghum caryopses which increases the throughput efficiency of previously difficult to measure traits. Adaptation of this workflow to other small-seeded crops is possible providing new and unique opportunities for scientists to study grain in a nondestructive manner which will ultimately lead to improvements end-use quality.

Perspectives on the pervasive energy-systems transformations

Energy is central for the global decarbonization and the achievement of a sustainable future for all. This calls for a fundamental energy-systems transformation that would bring multiple co-benefits for health, climate and other challenges facing humanity and especially those without access to affordable and clean energy services. Pervasive transformation toward zero-carbon electricity and electrification of energy end use are central to achieving higher efficiencies, decarbonization and net-zero emissions. This is not merely a technical and economic issue. It is about people, about societies and about values and behaviors. Technology is an integral part of the society and an expression of collective intentionality through aggregation of sundry individual choices. The next disruptive transformation toward a sustainable future may indeed be powered by the digital revolution. It poses dangers for privacy, dissemination of alternative realities and erosion of evidence-based information but it also offers a great promise of catalyzing the emergence of a sustainable future by augmenting human capabilities by new, more convenient, more efficient and decarbonized goods and services. The key question is whether humanity will have the political will to collectively achieve the energy-systems transformation toward a sustainable future and net-zero emissions in merely three decades.

Tissue specific expression of UMAMIT amino acid transporters in wheat

Wheat grain protein content and composition are important for its end-use quality. Protein synthesis during the grain filling phase is supported by the amino acids remobilized from the vegetative tissue, the process in which both amino acid importers and exporters are expected to be involved. Previous studies identified amino acid importers that might function in the amino acid remobilization in wheat. However, the amino acid exporters involved in this process have been unexplored so far. In this study, we have curated the Usually Multiple Amino acids Move In and out Transporter (UMAMIT) family of transporters in wheat. As expected, the majority of UMAMITs were found as triads in the A, B, and D genomes of wheat. Expression analysis using publicly available data sets identified groups of TaUMAMITs expressed in root, leaf, spike, stem and grain tissues, many of which were temporarily regulated. Strong expression of TaUMAMITs was detected in the late senescing leaves and transfer cells in grains, both of which are the expected site of apoplastic amino acid transport during grain filling. Biochemical characterization of selected TaUMAMITs revealed that TaUMAMIT17 shows a strong amino acid export activity and might play a role in amino acid transfer to the grains.

Promising Aspects of Economic Development of Industry in the Siberian Regions of Russia

According to many analysts, the modern digital technological transformation of the economy, both at the macro level and at the level of industrial enterprises, has a deep character and is aimed at establishing a new global economic structure. Programming at the level of international, climate, anti-pandemic, sanctional, technological, military-political and other agreements to reduce the level of production and consumption in accordance with the principles of sustainable development determines the prospect of transformations in industry, including in the raw materials sector. A significant part of the industrial companies of the Siberian regions belongs to the field of raw materials extraction, which forms new guidelines in the new technological conditions, both in personnel and technical areas. Large-scale introduction and application of a new generation of equipment that meets modern environmental standards requires accelerated training of a significant number of professional personnel. In fact, the education system, which should ensure the educational process of a high strategic status, both in scale and in terms of engineering and technical level, requires a systemic transformation based on the principles of digital technological innovations. The release of a significant number of workers, both representatives of the working professions and the intellectuals, which is happening and threatening to intensify, in the light of the ongoing contraction of the economy, will require the formation of millions of new jobs. This fillip, aimed at the development of small industrial forms of production of end-use goods, is able to provide employment for the population, as well as an increase in the level and quality of life in export-raw materials regions with the support from the state. The creation and development of engineering, technical and technological business franchises with the formation of a large retail network representing the goods of "industrial farms" are promising in this aspect. The upcoming steps of digital technological transformation require a comprehensive balanced scientific understanding, the development of appropriate justifications and recommendations.

Powder Surface Roughness as Proxy for Bed Density in Powder Bed Fusion of Polymers

Powder bed fusion of polymers is becoming increasingly adopted by a variety of industries to tailor the strength, weight and functionality of end-use products. To meet the high standards of the modern manufacturing industry, parts built with powder bed fusion require consistent properties and to be free of defects, which is intrinsically connected to the quality of the powder bed prior to melting. The hypothesis of this work is that the roughness of the top surface of an unmelted powder bed can serve as a proxy for the powder bed density, which is known to correlate with final part density. In this study, a laser line scan profilometer is integrated onto the recoater arm of a custom powder test bench, which is able to automatically create layers of powder. A diverse group of polymers was investigated including polyamide 12 (PA12), polyamide 11 (PA11), polypropylene (PP), and a thermoplastic elastomer (TPU) under different recoating speed in order to increase the variance of the dataset. Data analytics were employed to compare roughness to measured powder bed density and a statically significant correlation was established between them.

Standardizing Performance Metrics for Building-Level Electrical Distribution Systems

Building-level electrical distribution systems comprise a myriad of current-carrying equipment, conversion devices, and protection devices that deliver power from the utility or local distributed energy resources to end-use building loads. Electric power has traditionally been generated, transmitted, and distributed in ac. However, the last decade has seen a significant increase in the integration of native dc equipment that has elevated the importance of dc distribution systems. Numerous studies have comparatively examined the performance of various electrical distribution systems in buildings but have failed to achieve uniform conclusions, primarily because of a lack of consistent and analogous performance evaluation methods. This paper aims to fill this gap by providing a standard set of metrics and measurement boundaries to consistently evaluate the performance of ac, dc, or hybrid ac/dc electrical distribution systems. The efficacy of the proposed approach is evaluated on a representative medium-sized commercial office building model with ac distribution and an equivalent hybrid ac/dc and dc distribution model, wherein the ac distribution model is concluded to be the most efficient. The simulation results show variation in computed metrics with different selected boundaries that verify the effectiveness of the proposed approach in ensuring consistent computation of the performance of building-level electrical distribution systems. This paper provides an initial set of guidelines for building energy system stakeholders to adopt appropriate solutions, thus leading to more efficient energy systems.