The Use of Additive Technologies to Create Lightweight Parts for Gas Turbine Engine Compressors

Magerramova, Liubov; Volkov, M. E.; Svinareva, Maria; Siversky, Alex

doi:10.1115/gt2018-75904

Cited by 9 publications

(6 citation statements)

References 0 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…В ЦИАМ проводятся исследования прочностных характеристик ячеистых структур и разрабатываются лёгкие содержащие ячеистые структуры детали для использования в конструкциях лопаток, корпусов [9][10][11][12]. Проводятся расчётные и экспериментальные исследования, на основе которых определены некоторые рациональные структуры с учётом различного вида нагрузок.…”

Section: ячеистые структурыunclassified

Prospects of application of additive technologies to develop parts and components of gas turbine engines and ramjets

Magerramova

Nozhnitsky

Ножницкий³

et al. 2019

VESTNIK of Samara University. Aerospace and Mechanical Engineer

View full text Add to dashboard Cite

The possibility of reducing the weight, simplifying the design, reducing the time and cost of development, production and operation are important advantages in the implementation of additive technologies (AT). The use of AT can significantly improve fuel efficiency, environmental and other characteristics of aircraft engines. The possibility of using AT in the production of various parts and components of engines is being currently investigated at CIAM. Examples of these developments, advantages of the use of AT and problems arising in the implementation of these technologies are presented in this article. Models of turbine blades with a highly efficient cooling system, in particular, with penetration cooling were designed and manufactured using optimization methods and taking into account the capabilities of AT. The possibilities of using AT for the manufacture of elements of molds for precision casting of gas turbine engine (GTE) blades of heat-resistant alloys and ceramic rods are shown. Elements of a two-zone front module of the low-emission combustion chamber of an advanced GTE are designed and manufactured using the AT method. Research of prospective branched tree channels of heat exchangers with mutually porous bodies that can be made only by AT methods and the use of which will make it possible to increase the efficiency of heat exchange in the case of lower weight, than that of the structures made by traditional technologies, is being carried out. The AT was used to manufacture complex elements of a ramjet engine. Fire tests of printed sections of the combustion chamber were carried out successfully. Cellular structures to be used in gas turbine engine parts with the aim of reducing their weight were developed. A hollow blade model with cellular-type core was made using AT. Tests of the designed cellular prototypes were carried out. The possibilities of reducing the mass of structural elements using cellular structures obtained by AT methods are shown. Research of hollow disks of turbines and other engine components produced with the aid of AT are carried out. Despite the fact that experimental studies of structural elements obtained by additive technologies have not been completed yet, these works show the prospects for the use of AT in the development of a wide range of engine parts and components.

show abstract

Section: ячеистые структурыunclassified

Prospects of application of additive technologies to develop parts and components of gas turbine engines and ramjets

Magerramova

Nozhnitsky

Ножницкий³

et al. 2019

VESTNIK of Samara University. Aerospace and Mechanical Engineer

View full text Add to dashboard Cite

show abstract

“…Due to these limitations, designers are exploring non-conventional structural concepts driven by the utilization of advanced optimization methods such as lattice-infill structures and additive manufacturing techniques [24][25][26]. These methodologies present the flexibility to purposefully decide the optimum arrangement of materials within the design area of the wing [27].…”

Section: Introductionmentioning

confidence: 99%

Non-Conventional Wing Structure Design with Lattice Infilled through Design for Additive Manufacturing

Khan,

Acanfora,

Riccio

2024

Materials

View full text Add to dashboard Cite

Lightweight structures with a high stiffness-to-weight ratio always play a significant role in weight reduction in the aerospace sector. The exploration of non-conventional structures for aerospace applications has been a point of interest over the past few decades. The adaptation of lattice structure and additive manufacturing in the design can lead to improvement in mechanical properties and significant weight reduction. The practicality of the non-conventional wing structure with lattices infilled as a replacement for the conventional spar–ribs wing is determined through finite element analysis. The optimal lattice-infilled wing structures are obtained via an automated iterative method using the commercial implicit modeling tool nTop and an ANSYS workbench. Among five different types of optimized lattice-infilled structures, the Kelvin lattice structure is considered the best choice for current applications, with comparatively minimal wing-tip deflection, weight, and stress. Furthermore, the stress distribution dependency on the lattice-unit cell type and arrangement is also established. Conclusively, the lattice-infilled structures have shown an alternative innovative design approach for lightweight wing structures.

show abstract

“…Lattice structures that belong to the cellular structure category are made of repeating unit cells, the smallest element on which the whole lattice is characterised [2]. These structures with tailorable topologies [3] to meet customized requirements have found applications in various domains, such as aerospace [4][5][6] and automotive sectors [7], civil industry [8,9], and the bioengineering field [10][11][12][13][14]. For instance, in the bioengineering sector, lattice unit cells are employed for designing the structure of in-body medical applications such as implants and scaffolds [15][16][17][18][19][20][21][22] as well as wearable ones like orthoses and prostheses [23,24].…”

Section: Introduction 1lattice Structuresmentioning

confidence: 99%

Characterisation of Process-Induced Defects in Polymeric Strut-Based Lattice Structures Produced by Powder Bed Fusion Additive Manufacturing Process

Amirian,

Battley,

Amirpour

2024

Preprint

View full text Add to dashboard Cite

The Use of Additive Technologies to Create Lightweight Parts for Gas Turbine Engine Compressors

Cited by 9 publications

References 0 publications

Prospects of application of additive technologies to develop parts and components of gas turbine engines and ramjets

Prospects of application of additive technologies to develop parts and components of gas turbine engines and ramjets

Non-Conventional Wing Structure Design with Lattice Infilled through Design for Additive Manufacturing

Characterisation of Process-Induced Defects in Polymeric Strut-Based Lattice Structures Produced by Powder Bed Fusion Additive Manufacturing Process

Contact Info

Product

Resources

About