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180203s2015 gw o 000 0 eng d |
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|a EBLCP
|b eng
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|a 1022078653
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|a 9783832595203
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|a 3832595201
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|z 9783832538828
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|a (OCoLC)1021809346
|z (OCoLC)1022078653
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|a TK1056
|b .W89 2015
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|a 621.31244
|2 23
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|a UAMI
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|a Wu, Wei.
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|a A Centrifugal Particle Receiver for High-Temperature Solar Applications.
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|a Berlin :
|b Logos Verlag Berlin,
|c 2015.
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|a 1 online resource (204 pages)
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|a text
|b txt
|2 rdacontent
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|a computer
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|2 rdamedia
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|a online resource
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|a Print version record.
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|a Intro; 1 Introduction; 1.1 State of the art; 1.1.1 Falling particle receiver; 1.1.2 Rotary kiln; 1.2 The Centrifugal Particle Receiver; 1.2.1 Concept; 1.2.2 Receiver dimensioning; 1.3 Objective; 2 Convection in Rotating Cavities; 2.1 State of the art; 2.1.1 Convection losses in solar cavity receivers; 2.1.2 Rotating convection; 2.2 Theory; 2.2.1 Convective heat loss mechanisms in cavity receivers; 2.2.2 Characteristic dimensionless parameters; 2.3 Experimental set-up and procedure; 2.3.1 Test receiver; 2.3.2 Instrumentation; 2.3.3 Experimental procedure; 2.3.4 Measuring conduction losses.
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|a 2.3.5 Calculating radiation losses2.3.6 Uncertainty analysis; 2.4 Results and discussion; 2.4.1 Heat transfer; 2.4.2 Temperature distribution; 2.4.3 Comparison to literature; 3 Receiver Prototype; 3.1 Experimental set-up; 3.1.1 Receiver; 3.1.2 Particle feeding; 3.1.3 Insulation; 3.2 Instrumentation; 3.2.1 Temperature measurement; 3.2.2 Mass flow rate measurement; 3.2.3 Input power measurement; 3.2.4 Rotation rate measurement; 3.3 Error analysis; 3.3.1 Temperature uncertainty; 3.3.2 Mass flow rate uncertainty; 3.3.3 Uncertainty of the input power; 3.3.4 Overall uncertainty.
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|a 4 Numerical Receiver Model4.1 Model simplifications; 4.2 Governing equations; 4.2.1 Conduction and convection; 4.2.2 Radiation; 4.3 Numerical method; 4.3.1 Boundary conditions; 4.3.2 Material properties; 4.3.3 Finite element approximations; 4.4 Discretization; 4.4.1 Particle trajectory; 4.4.2 Cavity; 4.5 Incoming heat flux; 4.6 Grid study and validation; 5 Experiments; 5.1 Feasibility study; 5.1.1 Dense particle film; 5.1.2 Particle movement; 5.1.3 Critical rotation speed and retention time; 5.1.4 Discussion; 5.2 High flux tests; 5.2.1 Receiver inclination 45°
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|a 5.2.2 Receiver inclination 90°5.2.3 Discussion; 6 Simulation; 6.1 Temperature profiles; 6.2 Receiver efficiency; 6.3 Sensitivity analysis; 6.3.1 Material properties; 6.3.2 Heat flux distribution; 6.3.3 Conduction effects; 6.3.4 Convection effects; 6.4 Discussion; 7 Conclusions; References; Appdx A; Appdx B.
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|a Annotation
|b The novel concept of a particle receiver for high-temperature concentrating solar applications was developed and investigated in the present work. The so-called Centrifugal Particle Receiver (CentRec) uses small bauxite particles as absorber, heat transfer and storage media at the same time. Due to advantageous optical and thermal properties, the particles can be heated up to 1000 degree Celsius without sintering in the storage. High thermal efficiencies at high outlet temperatures are expected indicating a promising way for cost reduction in solar power tower applications. A prototype in laboratory scale was designed, built and tested in order to demonstrate the feasibility and potential of the proposed concept. The expected simple control capability of the receiver could be verified and the target temperature of 900 degree Celsius successfully demonstrated. A thermal efficiency of >; 85 % is calculated by a validated corresponding numerical model for a particle outlet temperature of 900 degree Celsius and a design power of 1 MW/m^2.
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|a ProQuest Ebook Central
|b Ebook Central Academic Complete
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650 |
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|a Solar power plants
|x Design and construction.
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|a Solar power plants
|x Design and construction
|2 fast
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|i has work:
|a A centrifugal particle receiver for high-temperature solar applications (Text)
|1 https://id.oclc.org/worldcat/entity/E39PCYjQGvQJWThHjtQktpwqW8
|4 https://id.oclc.org/worldcat/ontology/hasWork
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776 |
0 |
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|i Print version:
|a Wu, Wei.
|t A Centrifugal Particle Receiver for High-Temperature Solar Applications.
|d Berlin : Logos Verlag Berlin, ©2015
|z 9783832538828
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856 |
4 |
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|u https://ebookcentral.uam.elogim.com/lib/uam-ebooks/detail.action?docID=5231176
|z Texto completo
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|a EBL - Ebook Library
|b EBLB
|n EBL5231176
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|a YBP Library Services
|b YANK
|n 15138952
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