The effect of size on efficiency: Power plants and vascular designs

A. Bejan; S. Lorente; B. S. Yilbas; A. Z. Sahin

doi:10.1016/j.ijheatmasstransfer.2010.11.045

The effect of size on efficiency: Power plants and vascular designs

A. Bejan^*
, S. Lorente
, B. S. Yilbas
, A. Z. Sahin

^*Bu çalışma için yazışmadan sorumlu yazar

Duke Univ.
King Fahd University of Petroleum and Minerals
Université de Toulouse

Araştırma sonucu: Dergiye katkı › Makale › bilirkişi

43 Atıf (Scopus)

Özet

In this paper we use thermodynamics to show why larger flow systems are more efficient than smaller flow systems. This trend is visible across the board, from power generation and refrigeration, to vascular design and animal design. The reason is that larger systems have larger flow passages and heat transfer surfaces, and do not strangle the flow of the currents that must flow. Three fundamental examples show how to predict this trend: a power plant with fluid friction and finite heat transfer area, a vascular body with building blocks optimized at every level of assembly, and a vascular body designed based on a duct-pairing algorithm. The examples show that the performance improves as the size increases, and that the architecture changes with the size. These constructal-design features constitute the basis for scaling up and scaling down the configurations of flow systems, from desktop models to life size installations.

Orijinal dil	İngilizce
Sayfa (başlangıç-bitiş)	1475-1481
Sayfa sayısı	7
Dergi	International Journal of Heat and Mass Transfer
Hacim	54
Basın numarası	7-8
DOI'lar	https://doi.org/10.1016/j.ijheatmasstransfer.2010.11.045
Yayın durumu	Yayınlandı - Mar 2011
Harici olarak yayınlandı	Evet

Belgeye Erişim

10.1016/j.ijheatmasstransfer.2010.11.045

Diğer Dosyalar ve Linkler

Link to publication in Scopus

Alıntı Yap

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title = "The effect of size on efficiency: Power plants and vascular designs",

abstract = "In this paper we use thermodynamics to show why larger flow systems are more efficient than smaller flow systems. This trend is visible across the board, from power generation and refrigeration, to vascular design and animal design. The reason is that larger systems have larger flow passages and heat transfer surfaces, and do not strangle the flow of the currents that must flow. Three fundamental examples show how to predict this trend: a power plant with fluid friction and finite heat transfer area, a vascular body with building blocks optimized at every level of assembly, and a vascular body designed based on a duct-pairing algorithm. The examples show that the performance improves as the size increases, and that the architecture changes with the size. These constructal-design features constitute the basis for scaling up and scaling down the configurations of flow systems, from desktop models to life size installations.",

keywords = "Animal design, Constructal law, Economies of scale, River basins, Scaling up, Size effect, Vascular design",

author = "A. Bejan and S. Lorente and Yilbas, \{B. S.\} and Sahin, \{A. Z.\}",

year = "2011",

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T2 - Power plants and vascular designs

AU - Bejan, A.

AU - Lorente, S.

AU - Yilbas, B. S.

AU - Sahin, A. Z.

PY - 2011/3

Y1 - 2011/3

N2 - In this paper we use thermodynamics to show why larger flow systems are more efficient than smaller flow systems. This trend is visible across the board, from power generation and refrigeration, to vascular design and animal design. The reason is that larger systems have larger flow passages and heat transfer surfaces, and do not strangle the flow of the currents that must flow. Three fundamental examples show how to predict this trend: a power plant with fluid friction and finite heat transfer area, a vascular body with building blocks optimized at every level of assembly, and a vascular body designed based on a duct-pairing algorithm. The examples show that the performance improves as the size increases, and that the architecture changes with the size. These constructal-design features constitute the basis for scaling up and scaling down the configurations of flow systems, from desktop models to life size installations.

AB - In this paper we use thermodynamics to show why larger flow systems are more efficient than smaller flow systems. This trend is visible across the board, from power generation and refrigeration, to vascular design and animal design. The reason is that larger systems have larger flow passages and heat transfer surfaces, and do not strangle the flow of the currents that must flow. Three fundamental examples show how to predict this trend: a power plant with fluid friction and finite heat transfer area, a vascular body with building blocks optimized at every level of assembly, and a vascular body designed based on a duct-pairing algorithm. The examples show that the performance improves as the size increases, and that the architecture changes with the size. These constructal-design features constitute the basis for scaling up and scaling down the configurations of flow systems, from desktop models to life size installations.

KW - Animal design

KW - Constructal law

KW - Economies of scale

KW - River basins

KW - Scaling up

KW - Size effect

KW - Vascular design

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U2 - 10.1016/j.ijheatmasstransfer.2010.11.045

DO - 10.1016/j.ijheatmasstransfer.2010.11.045

M3 - Article

AN - SCOPUS:78751643508

SN - 0017-9310

VL - 54

SP - 1475

EP - 1481

JO - International Journal of Heat and Mass Transfer

JF - International Journal of Heat and Mass Transfer

IS - 7-8

ER -

The effect of size on efficiency: Power plants and vascular designs

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