Trapped Flux and Levitation Properties of Multiseeded YBCO Bulks for HTS Magnetic Device Applications—Part II: Practical and Achievable Performance

Deng, Zigang; Izumi, Mitsuru; Miki, M.; Tsuzuki, K.; Felder, B.; Liu, Weiqun; Zheng, Jun; Wang, S.; Wang, J.; Floegel-Delor, U.; Werfel, F.

doi:10.1109/tasc.2011.2172436

Cited by 27 publications

(12 citation statements)

References 49 publications

(49 reference statements)

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“…Modern high-temperature superconductors (HTSs) exhibit large potential for new technologies. Superconducting trapped-field (TF) magnets could significantly reduce the size and enhance the performance of numerous magnetic devices such as (but not restricted to) motors and wind power generators [1][2][3][4][5][6][7][8], flywheels and maglev trains [1,[9][10][11], and the magnetic resonance imaging [1,[12][13][14][15]. To obtain such a magnet, one needs a method that would, ideally, provide maximum TF of high uniformity with minimum cash and energy cost.…”

Section: Introductionmentioning

confidence: 99%

Thermal behavior of ﬂux jumps and inﬂuence of pulse-shape on the trapped ﬁeld during pulsed magnetization of a high-temperature superconductor

Moroz¹,

Kashurnikov²,

Rudnev³

et al. 2021

J. Phys.: Condens. Matter

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The impact of temperature on the pulsed magnetization of a high-temperature superconductor (HTS) has been numerically studied. The resulting trapped field (TF) and its distribution over the HTS have been calculated for samples with random and periodic pinning (a regular triangular lattice). The increasing ambient temperature (within the considered values) has been shown to improve the field-trapping efficiency and lead to the possibility of pumping more flux into the sample with each consecutive pulse (contrary to the low-temperature case). Various pulse shapes produced different results at high temperatures. Trapezoidal pulses showed the highest efficiency owing to the constant-field segments during which the vortices continued to enter the sample. The critical (activation) field of flux jumps has been shown to decrease with the rising temperature. At the highest considered temperature (30 K), the flux jumps occurred during the TF relaxation. To the best of our knowledge, such calculations have been done for the first time.

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Section: Introductionmentioning

confidence: 99%

Thermal behavior of ﬂux jumps and inﬂuence of pulse-shape on the trapped ﬁeld during pulsed magnetization of a high-temperature superconductor

Moroz¹,

Kashurnikov²,

Rudnev³

et al. 2021

J. Phys.: Condens. Matter

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“…The size of each bulk is 64, 32 and 13 mm in length, width and thickness, respectively. The HTS bulks were manufactured by ATZ GmbH (Germany), which have superior performance across the seeds [13,14]. The permanent magnet guideway (PMG) consists of rectangular NdFeB permanent magnets arranged in a Halbach array.…”

Section: Experimental Descriptionmentioning

confidence: 99%

Levitation performance of an onboard high-temperature superconducting bulk unit with cryocooler direct cooling

Sun¹,

Deng²,

Wang

et al. 2020

Supercond. Sci. Technol.

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High-temperature superconducting (HTS) maglev systems show the intrinsic advantage of self-stabilizing levitation without external control, therefore, they have great potential to be a new type of rail transit. At present, the cryogenic condition (77 K) of HTS bulks is maintained by pouring liquid nitrogen (LN 2 ) into the dewar and supplementing LN 2 at regular intervals, which cannot be maintained for a long period and in a controllable cryogenic environment. This cooling method is easy to realize but not the best approach for future commercial high-speed maglev. It is therefore necessary to try other cooling methods. In this paper, we try the direct cooling method. A cryocooler was used to directly cool a cryogenic unit with eight bulk superconductors which are designed to be close to the practical application. The levitation performance of the cryogenic unit with superconductors is tested on SCML-01. The temperature stability of the cryogenic unit was verified and measurements of levitation force versus temperature and levitation force versus field cooling heights were performed at temperatures from 50 to 90 K. The experimental results show that the HTS bulk unit can obtain a stable and controllable cryogenic environment. By analyzing the experimental data, it is found that decreasing temperature is beneficial to the levitation performance of HTS bulks and as the temperature decreases, the rate of the levitation force increase steps down. Moreover, according to the application environment of the HTS maglev cryogenic unit, 60 K is recommended as its operating temperature. The experimental results provide valuable references for the design of HTS maglev units in the future.

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“…18,19,22 Different studies have been performed to enhance the superconducting material properties in addition to the size of the bulk REBCO, such as using a cylindrical 23,24 or pyramid-like 25 buffer layer between the seed and the main material. Notwithstanding the numerous number of studies done so far, the most commonly used bulk YBCO in Maglev studies of laboratory scale 14,15,26 or real-scale prototypes 5,27 are the ones fabricated by ATZ GmbH 8,22,[28][29][30] in a rectangular prism shape with three seeds.…”

Section: Introductionmentioning

confidence: 99%

Enhancing magnetic levitation and guidance force and weight efficiency of high‐temperature superconducting maglev systems by using sliced bulk YBCO

Abdioglu

Öztürk

Güner

et al. 2023

Int J Applied Ceramic Tech

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We aimed to enhance the magnetic force efficiency of Maglev systems without increasing total weight. For this aim, we divided YBCO bulks into three slices horizontally to utilize the YBCO‐permanent magnetic guideway (PMG) interaction surface as much as possible. We used whole YBCO above PMGs with different magnetic pole directions (PMG‐A and PMG‐B) in two lying positions of transversal and longitudinal and investigated levitation and guidance force performances. It is determined that levitation and guidance forces by using YBCO in transversal lying mode are bigger compared to the longitudinal mode. For sliced YBCO, the maximum levitation force increased by 69% and 78%, while the guidance force enhancements are determined as 212% and 91%, compared to the whole YBCO above PMG‐A and PMG‐B, respectively. The levitation and guidance force density with respect to the total mass of unit a set of slices YBCO increased by 92% and 106%, respectively, compared to the whole YBCO above PMG‐B in transversal mode. Since the higher levitation force and the lower total weight of the onboard unit are important parameters in point of the energy efficiency in Maglev and other levitation applications, the result of this study supplies useful data for the engineers and industrial partners.

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Trapped Flux and Levitation Properties of Multiseeded YBCO Bulks for HTS Magnetic Device Applications—Part II: Practical and Achievable Performance

Cited by 27 publications

References 49 publications

Thermal behavior of ﬂux jumps and inﬂuence of pulse-shape on the trapped ﬁeld during pulsed magnetization of a high-temperature superconductor

Thermal behavior of ﬂux jumps and inﬂuence of pulse-shape on the trapped ﬁeld during pulsed magnetization of a high-temperature superconductor

Levitation performance of an onboard high-temperature superconducting bulk unit with cryocooler direct cooling

Enhancing magnetic levitation and guidance force and weight efficiency of high‐temperature superconducting maglev systems by using sliced bulk YBCO

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