FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2984942302> ?p ?o ?g. }

• W2984942302 endingPage "218" @default.
• W2984942302 startingPage "206" @default.
• W2984942302 abstract "Manure-drying system using exhausted air from laying hen houses or ambient air has been extensively used in China to dewater the manure for easy transportation and to reduce pathogen levels prior to land application. Due to the climate influence or inappropriate setting of technological parameters, there are some issues in this manure-drying system, such as low dehydration rate, high energy consumption, and high ammonia emission. A purpose-designed experimental drying apparatus was set up to simulate the commercial manure drying system. Drying experiments were carried out to assess the impacts of hot air temperature (15–35°C), air velocity (0.6–1.8 m/s) and manure layer thickness (60–140 mm) on fan’s energy consumption, dehydration rate, and nitrogen loss rate. The response surface analysis method and sub-stepping method was used to analyze the relationships between the response variables and the influence factors. The drying curves were drawn, and the quadratic regression mathematical models that described the relations between the experimental indices and the influence factors were established. The optimal combination of technological parameters for drying laying-hen manure was obtained through conducting a multi-objective function optimization by function-expected optimization. The optimal parameters are as follows: hot air temperature of 35°C, air velocity of 1.60 m/s, and manure layer thickness of 85 mm. The results also indicate that raising the hot air temperature increased the value of synthesis objective function when the hot air temperature was in 26–35°C. The results can provide a theoretical basis for low-temperature drying of laying-hen manure in actual production.Implications: A large amount of poultry manure is produced yearly in China, which has become a tremendous pressure on the environment when it cannot be utilized as resources. A more sustainable solution using the residual heat from the poultry house ventilation or ambient hot air has been widely used in China. This drying method can significantly reduce energy consumption compared to the traditional way. However, due to the influence of climate or inappropriate setting of technological parameters, issues such as high energy consumption and high ammonia emission still exist in this method. It is necessary to optimize the low-temperature drying process of laying-hen manure, to reduce energy consumption and nitrogen loss rate." @default.
• W2984942302 created "2019-11-22" @default.
• W2984942302 creator A5034401649 @default.
• W2984942302 creator A5036157514 @default.
• W2984942302 creator A5052219263 @default.
• W2984942302 creator A5083130257 @default.
• W2984942302 date "2020-01-07" @default.
• W2984942302 modified "2023-09-30" @default.
• W2984942302 title "Optimization of low-temperature drying of laying-hen manure using response surface methodology" @default.
• W2984942302 cites W112646780 @default.
• W2984942302 cites W2006582807 @default.
• W2984942302 cites W2013135841 @default.
• W2984942302 cites W2020004793 @default.
• W2984942302 cites W2024083329 @default.
• W2984942302 cites W2031126242 @default.
• W2984942302 cites W2047477311 @default.
• W2984942302 cites W2056918819 @default.
• W2984942302 cites W2061843485 @default.
• W2984942302 cites W2073238102 @default.
• W2984942302 cites W2083974781 @default.
• W2984942302 cites W2084914418 @default.
• W2984942302 cites W2103780606 @default.
• W2984942302 cites W2113707599 @default.
• W2984942302 cites W2122623982 @default.
• W2984942302 cites W2137210284 @default.
• W2984942302 cites W2151865951 @default.
• W2984942302 cites W2165247775 @default.
• W2984942302 cites W2745832052 @default.
• W2984942302 cites W2799816188 @default.
• W2984942302 cites W2892191116 @default.
• W2984942302 cites W2903981033 @default.
• W2984942302 cites W2937221830 @default.
• W2984942302 cites W2968724213 @default.
• W2984942302 cites W4255287231 @default.
• W2984942302 doi "https://doi.org/10.1080/10962247.2019.1694092" @default.
• W2984942302 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/31738657" @default.
• W2984942302 hasPublicationYear "2020" @default.
• W2984942302 type Work @default.
• W2984942302 sameAs 2984942302 @default.
• W2984942302 citedByCount "5" @default.
• W2984942302 countsByYear W29849423022020 @default.
• W2984942302 countsByYear W29849423022022 @default.
• W2984942302 countsByYear W29849423022023 @default.
• W2984942302 crossrefType "journal-article" @default.
• W2984942302 hasAuthorship W2984942302A5034401649 @default.
• W2984942302 hasAuthorship W2984942302A5036157514 @default.
• W2984942302 hasAuthorship W2984942302A5052219263 @default.
• W2984942302 hasAuthorship W2984942302A5083130257 @default.
• W2984942302 hasBestOaLocation W29849423021 @default.
• W2984942302 hasConcept C105795698 @default.
• W2984942302 hasConcept C119599485 @default.
• W2984942302 hasConcept C127413603 @default.
• W2984942302 hasConcept C150077022 @default.
• W2984942302 hasConcept C153294291 @default.
• W2984942302 hasConcept C185592680 @default.
• W2984942302 hasConcept C205649164 @default.
• W2984942302 hasConcept C2778769901 @default.
• W2984942302 hasConcept C2780165032 @default.
• W2984942302 hasConcept C2780812243 @default.
• W2984942302 hasConcept C2983363897 @default.
• W2984942302 hasConcept C33923547 @default.
• W2984942302 hasConcept C38304854 @default.
• W2984942302 hasConcept C39432304 @default.
• W2984942302 hasConcept C55493867 @default.
• W2984942302 hasConcept C6557445 @default.
• W2984942302 hasConcept C78519656 @default.
• W2984942302 hasConcept C86803240 @default.
• W2984942302 hasConcept C87717796 @default.
• W2984942302 hasConceptScore W2984942302C105795698 @default.
• W2984942302 hasConceptScore W2984942302C119599485 @default.
• W2984942302 hasConceptScore W2984942302C127413603 @default.
• W2984942302 hasConceptScore W2984942302C150077022 @default.
• W2984942302 hasConceptScore W2984942302C153294291 @default.
• W2984942302 hasConceptScore W2984942302C185592680 @default.
• W2984942302 hasConceptScore W2984942302C205649164 @default.
• W2984942302 hasConceptScore W2984942302C2778769901 @default.
• W2984942302 hasConceptScore W2984942302C2780165032 @default.
• W2984942302 hasConceptScore W2984942302C2780812243 @default.
• W2984942302 hasConceptScore W2984942302C2983363897 @default.
• W2984942302 hasConceptScore W2984942302C33923547 @default.
• W2984942302 hasConceptScore W2984942302C38304854 @default.
• W2984942302 hasConceptScore W2984942302C39432304 @default.
• W2984942302 hasConceptScore W2984942302C55493867 @default.
• W2984942302 hasConceptScore W2984942302C6557445 @default.
• W2984942302 hasConceptScore W2984942302C78519656 @default.
• W2984942302 hasConceptScore W2984942302C86803240 @default.
• W2984942302 hasConceptScore W2984942302C87717796 @default.
• W2984942302 hasIssue "2" @default.
• W2984942302 hasLocation W29849423021 @default.
• W2984942302 hasLocation W29849423022 @default.
• W2984942302 hasOpenAccess W2984942302 @default.
• W2984942302 hasPrimaryLocation W29849423021 @default.
• W2984942302 hasRelatedWork W1988375232 @default.
• W2984942302 hasRelatedWork W2383585712 @default.
• W2984942302 hasRelatedWork W2511397206 @default.
• W2984942302 hasRelatedWork W2810110616 @default.
• W2984942302 hasRelatedWork W2965997943 @default.
• W2984942302 hasRelatedWork W2984942302 @default.

• next