Opportunities and Challenges of Utilizing Additive Manufacturing Approaches in Thermal Management of Electrical Machines

Ghahfarokhi, Payam Shams; Podgornovs, Andrejs; Kallaste, Ants; Cardoso, António J. Marques; Belahcen, Anouar; Vaimann, Toomas; Tiismus, Hans; Asad, Bilal

doi:10.1109/access.2021.3062618

Cited by 51 publications

(20 citation statements)

References 57 publications

(85 reference statements)

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“…Several methods for improving ferromagnetic part performance through topology optimization are discussed in further detail in [20,21]. For improved heat exchange of the printed transformer, enhanced convective heat transfer can easily be obtained by increasing its outer surface area with different surface relief structures [22].…”

Section: Discussionmentioning

confidence: 99%

Additive Manufacturing and Performance of E-Type Transformer Core

et al. 2021

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Additive manufacturing of ferromagnetic materials for electrical machine applications is maturing. In this work, a full E-type transformer core is printed, characterized, and compared in terms of performance with a conventional Goss textured core. For facilitating a modular winding and eddy current loss reduction, the 3D printed core is assembled from four novel interlocking components, which structurally imitate the E-type core laminations. Both cores are compared at approximately their respective optimal working conditions, at identical magnetizing currents. Due to the superior magnetic properties of the Goss sheet conventional transformer core, 10% reduced efficiency (from 80.5% to 70.1%) and 34% lower power density (from 59 VA/kg to 39 VA/kg) of the printed transformer are identified at operating temperature. The first prototype transformer core demonstrates the state of the art and initial optimization step for further development of additively manufactured soft ferromagnetic components. Further optimization of both the 3D printed material and core design are proposed for obtaining higher electrical performance for AC applications.

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Section: Discussionmentioning

confidence: 99%

Additive Manufacturing and Performance of E-Type Transformer Core

et al. 2021

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“…Their equivalent thermal conductivity can reach 100,000 W/mK [131], making them ideal for thermal management in high-power electric machines. Prototype machines implementing this technology have seen improvements in thermal management and power density [110], [132]- [137]. However, Le and Mueller [110], [136] present the only use in AFPM motors seen in literature.…”

Section: F Heat Pipesmentioning

confidence: 99%

Innovations in Axial Flux Permanent Magnet Motor Thermal Management for High Power Density Applications

Jenkins

Jones-Jackson

Zaher

et al. 2023

IEEE Trans. Transp. Electrific.

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At the forefront is the challenging design of electric motors with high efficiencies, torque, and power capabilities. Due to its high performance, the Axial Flux Permanent Magnet (AFPM) Motor is expected to be one of the leading technologies to meet the demands of these industries. Finding the balance between the cooling system's effectiveness and subsequent parasitic losses is key to utilizing these performance benefits.Single stator double rotor topologies achieve the best torque density and lower stator losses, however are more challenging to cool as the stator is in the center of the motor. Single stator single rotor and double stator machines are less challenging to cool but typically have lower power density. Rotor air cooling is discussed including the effectiveness of blades, meshes, and vents which can be optimized to prevent demagnetization. Stator cooling is critical as many machines maximize current density C. Jenkins,

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“…Moreover, this technology could integrate secondary features, such as mass and material reduction, by replacing solid walls with lattice-style walls. For example, an electronic body fulfils a dual function as a thermal conduit, without any mass penalty, which can be especially beneficial in aerospace applications [16,18,40,41] or electrical rotating machines [3,42]. M c Glen et al constructed a titanium vapour chamber flat shape HP utilising LPBF technology.…”

Section: Axial Groovesmentioning

confidence: 99%

Additive Manufacturing as a Solution to Challenges Associated with Heat Pipe Production

Szymański

Mikielewicz

2022

Materials

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The aim of this review is to present the recent developments in heat pipe production, which respond to the current technical problems related to the wide implementation of this technology. A novel approach in HP manufacturing is to utilise hi-tech additive manufacturing techniques where the most complicated geometries are fabricated layer-by-layer directly from a digital file. This technology might be a solution to various challenges that exist in HP production, i.e., (1) manufacturing of complex or unusual geometries HPs; (2) manufacturing complicated and efficient homogenous wick structures with desired porosity, uniform pore sizes, permeability, thickness and where the pores are evenly distributed; (3) manufacturing a gravity friendly wick structures; (4) high customisation and production time; (5) high costs; (6) difficulties in the integration of the HP into a unit chassis that enables direct thermal management of heated element and decrease its total thermal resistance; (7) high weight and material use of the part; (8) difficulties in sealing; (9) deformation of the flat shape HPs caused by the high pressure and uneven distribution of stress in the casing, among others.

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Opportunities and Challenges of Utilizing Additive Manufacturing Approaches in Thermal Management of Electrical Machines

Cited by 51 publications

References 57 publications

Additive Manufacturing and Performance of E-Type Transformer Core

Additive Manufacturing and Performance of E-Type Transformer Core

Innovations in Axial Flux Permanent Magnet Motor Thermal Management for High Power Density Applications

Additive Manufacturing as a Solution to Challenges Associated with Heat Pipe Production

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