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HPV 莖流量傳感器/Sap Flow Sensor

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HPV 莖流量傳感器/Sap Flow Sensor

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HPV莖流量傳感器是一款校準型、低成本的熱脈沖液流傳感器,輸出校準液流量、熱速、莖水含量、莖溫等數(shù)據(jù),功耗低,內(nèi)置加熱控制,同時改善了傳統(tǒng)的加熱方式,其原理采用雙方法(DMA)熱脈沖法,測量范圍:-200~+1000cm/hr(熱流速度)或-100~+2000cm3/cm2/hr (莖流通量密度),可廣泛用于于莖流量監(jiān)測、植物莖流蒸發(fā)計算、植物莖流蒸騰量、植物灌溉等
植物莖流是樹木內(nèi)部的“水"運動,而蒸騰是從葉片通過光合作用蒸發(fā)流出的水分。樹液流量和蒸騰量之間有很強的關聯(lián)性,通常理解是同一回事。但是,嚴格地說,它們是不同的,這體現(xiàn)在它們是如何被測量的。
SAP流量以L/hr(或每天、每周等)為單位進行測量。蒸騰量以每小時、每天、每星期等毫米(mm)為單位測量。
蒸散量=蒸騰量+蒸發(fā)量
蒸騰量以毫米為測量單位,可與降雨量以毫米計作比較。隨著時間的推移,降雨量(水輸入)應與蒸騰量(輸出)相匹配。如果蒸騰作用更高,通常是樹木作物的蒸騰作用,那么這種差異必須通過灌溉來彌補。
蒸發(fā)量(evaporation),蒸發(fā)量是指在一定時段內(nèi),由土壤或水中的水分經(jīng)蒸發(fā)而散布到空中的量。

1mm(降雨量)=1㎡地面1kg水
1mm(蒸騰量)=1㎡葉面積的1升樹液流量(水)

例如:在果園和葡萄園等有管理的樹木作物系統(tǒng)中,蒸發(fā)量與蒸騰量相比非常小。因此,為了簡化測量,通常忽略蒸發(fā)量,將蒸騰量取為平均蒸散量(ETo)。

莖流量傳感器廣泛應用
計算總流量
低液流和零液流速率
反向液流速率
夜間水分損失
根莖液流速度
貧瘠生態(tài)系統(tǒng)及干旱
徑向液體流速
葡萄藤的液流

莖流量傳感器 技術指標
測量范圍:-200~+1000cm/hr(熱流速度)
分辨率:0.001cm/hr
準確度:±0.1cm/hr
探針尺寸:φ1.3mm*L30mm
溫度位置:外10mm,內(nèi)20mm
針距:6mm
探針材質(zhì):316不銹鋼
溫度范圍:-30~+70℃
響應時間:200ms
加熱電阻:39Ω,400J/m
電源:12V DC
電流:空閑5mA, 測量<270mA
線纜:5m,*大60m



莖流量傳感器參考文獻:
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9. Bleby, T.M.; McElrone, A.J.; Burgess, S.S.O. Limitations of the HRM: Great at low flow rates, but no yet up to speed? In Proceedings of the 7th International Workshop on Sap Flow: Book of Abstracts, Seville, Spain, 22–24 October 2008.

10. Pearsall, K.R.; Williams, L.E.; Castorani, S.; Bleby, T.M.; McElrone, A.J. Evaluating the potential of a novel dual heat-pulse sensor to measure volumetric water use in grapevines under a range of flow conditions. Funct. Plant Biol. 2014, 41, 874–883. [CrossRef]

11. Clearwater, M.J.; Luo, Z.; Mazzeo, M.; Dichio, B. An external heat pulse method for measurement of sap flow through fruit pedicels, leaf petioles and other small-diameter stems. Plant Cell Environ. 2009 , 32, 1652–1663.[CrossRef]

12. Green, S.R.; Romero, R. Can we improve heat-pulse to measure low and reverse flows? Acta Hortic. 2012 , 951, 19–29. [CrossRef]

13. Green, S.; Clothier, B.; Perie, E. A re-analysis of heat pulse theory across a wide range of sap flows. Acta Hortic. 2009, 846, 95–104. [CrossRef]

14. Ferreira, M.I.; Green, S.; Concei??o, N.; Fernández, J. Assessing hydraulic redistribution with the
compensated average gradient heat-pulse method on rain-fed olive trees. Plant Soil 2018 , 425, 21–41.
[CrossRef]

15. Romero, R.; Muriel, J.L.; Garcia, I.; Green, S.R.; Clothier, B.E. Improving heat-pulse methods to extend the measurement range including reverse flows. Acta Hortic. 2012, 951, 31–38. [CrossRef]

16. Testi, L.; Villalobos, F. New approach for measuring low sap velocities in trees. Agric. Meteorol. 2009 , 149, 730–734. [CrossRef]

17. Vandegehuchte, M.W.; Steppe, K. Sapflow+: A four-needle heat-pulse sap flow sensor enabling nonempirical sap flux density and water content measurements. New Phytol. 2012, 196, 306–317. [CrossRef] [PubMed]

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19. Vandegehuchte, M.W.; Steppe, K. Improving sap-flux density measurements by correctly determining
thermal diffusivity, differentiating between bound and unbound water. Tree Physiol. 2012 , 32, 930–942.
[CrossRef]

20. Looker, N.; Martin, J.; Jencso, K.; Hu, J. Contribution of sapwood traits to uncertainty in conifer sap flow as estimated with the heat-ratio method. Agric. For. Meteorol. 2016, 223, 60–71. [CrossRef]

21. Edwards, W.R.N.; Warwick, N.W.M. Transpiration from a kiwifruit vine as estimated by the heat pulse
technique and the Penman-Monteith equation. N. Z. J. Agric. Res. 1984, 27, 537–543. [CrossRef]

22. Becker, P.; Edwards, W.R.N. Corrected heat capacity of wood for sap flow calculations. Tree Physiol 1999 , 19, 767–768. [CrossRef]

23. Hogg, E.H.; Black, T.A.; den Hartog, G.; Neumann, H.H.; Zimmermann, R.; Hurdle, P.A.; Blanken, P.D.;
Nesic, Z.; Yang, P.C.; Staebler, R.M.; et al. A comparison of sap flow and eddy fluxes of water vapor from a
boreal deciduous forest. J. Geophys. Res. 1997, 102, 28929–28937. [CrossRef]

24. Barkas, W.W. Fibre saturation point of wood. Nature 1935, 135, 545. [CrossRef]

25. Kollmann, F.F.P.; Cote, W.A., Jr. Principles of Wood Science and Technology: Solid Wood; Springer: Berlin Heidelberg, Germany, 1968.

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32. Cohen, Y.; Fuchs, M.; Falkenflug, V.; Moreshet, S. Calibrated heat pulse method for determining water uptake in cotton. Agron. J. 1988, 80, 398–402. [CrossRef]

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36. Bleby, T.M.; Burgess, S.S.O.; Adams, M.A. A validation, comparison and error analysis of two heat-pulse methods for measuring sap flow in Eucalyptus marginata saplings. Funct. Plant Biol. 2004 , 31, 645–658.[CrossRef]

37. Madurapperuma, W.S.; Bleby, T.M.; Burgess, S.S.O. Evaluation of sap flow methods to determine water use by cted palms. Environ. Exp. Bot. 2009, 66, 372–380. [CrossRef]

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關鍵詞:傳感器
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