EurekaMag.com logo
+ Site Statistics
References:
53,623,987
Abstracts:
29,492,080
+ Search Articles
+ Subscribe to Site Feeds
EurekaMag Most Shared ContentMost Shared
EurekaMag PDF Full Text ContentPDF Full Text
+ PDF Full Text
Request PDF Full TextRequest PDF Full Text
+ Follow Us
Follow on FacebookFollow on Facebook
Follow on TwitterFollow on Twitter
Follow on LinkedInFollow on LinkedIn

+ Translate

A heat transfer model for ice encapsulated apple buds



A heat transfer model for ice encapsulated apple buds



Paper, American Society of Agricultural Engineers (82-4008): 24 pp



A heat transfer model was developed to predict the maximum off-time of a pulsed overhead sprinkler system used for frost protection. The total off-time consists of the periods required to freeze the water and cool the bud to the critical temperature.

(PDF 0-2 workdays service: $29.90)

Accession: 001038129

Download citation: RISBibTeXText



Related references

Prediction of sprinkler off-times during frost protection of apple buds: a heat transfer model. Transactions of the ASAE American Society of Agricultural Engineers 26(5): 1430-1434, 1983

The heat balance of apple buds and blossoms. I. Heat transfer in the outdoor environment. Agricultural and forest meteorology 35(35): 339-352, 1985

The heat balance of apple buds and blossoms part i. heat transfer in the outdoor environment. Agricultural and Forest Meteorology 35(1): 339-352, 1985

Plantlets from encapsulated micropropagated buds of M.26 apple rootstock. Plant Cell, Tissue and Organ Culture 47(3): 255-260, 1997

Plantlets from encapsulated micropropagated buds of M.26 apple rootstock. Plant Cell Tissue and Organ Culture 47(3): 255-260, 1996

Rooting induction in encapsulated buds of M.26 apple rootstock for synthetic seed. Biology of root formation and development 314, 1997

Effect of different treatments on the conversion of M.26 apple rootstock synthetic seeds obtained from encapsulated apical and axillary micropropagated buds. Journal of Horticultural Science and Biotechnology 73(3): 299-305, 1998

Enhancing heat capacity of colloidal suspension using nanoscale encapsulated phase-change materials for heat transfer. Acs Applied Materials & Interfaces 2(6): 1685-1691, 2010

Seasonal changes of asparagine and arginine contents in spur buds leaf buds and flower buds induced by summer pruning in fuji and jonagold apple tree. Hortscience 27(6): 614, 1992

Heat and mass transfer in stored milo. Part I. Heat transfer model. Transactions of the ASAE 35(5): 1569-1573, 1992

Heat and mass transfer in stored milo. I. Heat transfer model. Transactions of the ASAE 35(5): 1569-1573, 1992

The heat balance of apple buds and blossoms. II. The water requirements for frost protection by overhead sprinkler irrigation. Agricultural and forest meteorology 37(2): 159-174, 1986

The heat balance of apple buds and blossoms. III. The water requirements for evaporative cooling by overhead sprinkler irrigation. Agricultural and forest meteorology 37(2): 175-188, 1986

The heat balance of apple buds and blossoms part ii. the water requirements for frost protection by overhead sprinkler irrigation. Agricultural and Forest Meteorology 37(2): 159-174, 1986

The heat balance of apple buds and blossoms part iii. the water requirements for evaporative cooling by overhead sprinkler irrigation. Agricultural and Forest Meteorology 37(2): 175-188, 1986