LEADER 05822nam  2201033z- 450 
001 9910557113403321
005 20210501
035   $a(CKB)5400000000040912
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/69248
035   $a(oapen)doab69248
035   $a(EXLCZ)995400000000040912
100   $a20202105d2020      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
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200 00$aModelling, Simulation and Control of Thermal Energy Systems
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 online resource (228 p.)
311 08$a3-03943-360-1 
311 08$a3-03943-361-X 
330   $aFaced with an ever-growing resource scarcity and environmental regulations, the last 30 years have witnessed the rapid development of various renewable power sources, such as wind, tidal, and solar power generation. The variable and uncertain nature of these resources is well-known, while the utilization of power electronic converters presents new challenges for the stability of the power grid. Consequently, various control and operational strategies have been proposed and implemented by the industry and research community, with a growing requirement for flexibility and load regulation placed on conventional thermal power generation. Against this background, the modelling and control of conventional thermal engines, such as those based on diesel and gasoline, are experiencing serious obstacles when facing increasing environmental concerns. Efficient control that can fulfill the requirements of high efficiency, low pollution, and long durability is an emerging requirement. The modelling, simulation, and control of thermal energy systems are key to providing innovative and effective solutions. Through applying detailed dynamic modelling, a thorough understanding of the thermal conversion mechanism(s) can be achieved, based on which advanced control strategies can be designed to improve the performance of the thermal energy system, both in economic and environmental terms. Simulation studies and test beds are also of great significance for these research activities prior to proceeding to field tests. This Special Issue will contribute a practical and comprehensive forum for exchanging novel research ideas or empirical practices that bridge the modelling, simulation, and control of thermal energy systems. Papers that analyze particular aspects of thermal energy systems, involving, for example, conventional power plants, innovative thermal power generation, various thermal engines, thermal energy storage, and fundamental heat transfer management, on the basis of one or more of the following topics, are invited in this Special Issue: ? Power plant modelling, simulation, and control; ? Thermal engines; ? Thermal energy control in building energy systems; ? Combined heat and power (CHP) generation; ? Thermal energy storage systems; ? Improving thermal comfort technologies; ? Optimization of complex thermal systems; ? Modelling and control of thermal networks; ? Thermal management of fuel cell systems; ? Thermal control of solar utilization; ? Heat pump control; ? Heat exchanger control.
606   $aHistory of engineering and technology$2bicssc
610   $aactive disturbance rejection control
610   $aair-fuel ratio
610   $aartificial neural network
610   $aboiler-turbine unit
610   $aburning carbon
610   $achemical looping
610   $acoefficient of thermal expansion
610   $acombustion control
610   $acombustion engine efficiency
610   $aCSP plant model
610   $adeep neural network
610   $adynamic matrix control
610   $adynamic modeling
610   $adynamic states
610   $aelectric and solar vehicles
610   $aelectronic device
610   $aenergy storage operation and planning
610   $aexergetic analysis
610   $afilm coefficient
610   $aflip chip component
610   $aforced convection
610   $ageneralized predictive control (GPC)
610   $agenetic algorithm
610   $aheat exchanger
610   $aheat transfer
610   $ahigh temperature low sag conductor
610   $aintegrated energy system
610   $alife prediction
610   $aload dispatch
610   $alow sag performance
610   $amaximum correntropy
610   $amulti-objective
610   $aNARMA model
610   $aoperational optimization
610   $aoverhead conductor
610   $aparameter estimation
610   $apower plant control
610   $apower tracking control
610   $aSingular weighted method
610   $aSolar-assisted coal-fired power generation system
610   $astacked auto-encoder
610   $asteam supply scheduling
610   $asupercritical circulating fluidized bed
610   $athermal fatigue
610   $athermal management
610   $athermal stress
610   $atransient analysis
610   $atwo-tank direct energy storage
610   $aultra-supercritical unit
610   $awater properties
610   $awavelets
610   $a?-constraint method
615  7$aHistory of engineering and technology
700   $aLee$b Kwang Y$4edt$0308549
702   $aFlynn$b Damian$4edt
702   $aXie$b Hui$4edt
702   $aSun$b Li$4edt
702   $aLee$b Kwang Y$4oth
702   $aFlynn$b Damian$4oth
702   $aXie$b Hui$4oth
702   $aSun$b Li$4oth
906   $aBOOK
912   $a9910557113403321
996   $aModelling, Simulation and Control of Thermal Energy Systems$93038143
997   $aUNINA

LEADER 01777nam  2200433z- 450 
001 9910346768003321
005 20210211
010   $a1000058225
035   $a(CKB)4920000000100843
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/51150
035   $a(oapen)doab51150
035   $a(EXLCZ)994920000000100843
100   $a20202102d2017      |y         0
101 0 $ager
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aKonditionierung von biogenen Energietra?gern aus den Produkten der bioliq®-Schnellpyrolyse
210   $cKIT Scientific Publishing$d2017
215   $a1 online resource (XII, 301 p. p.)
311 08$a3-7315-0575-4 
330   $aWithin the bioliq®-process, the organic phase of straw pyrolysis condensates can be gasified directly, while the aqueous phase can be mixed with char to form a slurry, which also can be gasified. For production and storage, several mixers and stirrers are examined. Grinding the porous and elongated char particles decelerates sedimentation and also reduces the viscosity. Thus, higher concentrated slurries can be mixed, which leads to higher stability.
606   $aTechnology: general issues$2bicssc
610   $agasification
610   $aKoks
610   $aMischen
610   $amix
610   $aPyrolysekondensat
610   $apyrolysis condensate
610   $aslurry
610   $aSuspension
610   $aVergasungchar
615  7$aTechnology: general issues
700   $aNicoleit$b Thomas$4auth$01319244
906   $aBOOK
912   $a9910346768003321
996   $aKonditionierung von biogenen Energieträgern aus den Produkten der bioliq®-Schnellpyrolyse$93033671
997   $aUNINA