Local head loss caused in connections used in micro-irrigation systems

Bombardelli, Wagner W. Á.; Camargo, Antonio P. de; Frizzone, José A.; Lavanholi, Rogério; Rocha, Hermes S. da

doi:10.1590/1807-1929/agriambi.v23n7p492-498

ABSTRACT

Information about local head loss caused by connections employed in micro-irrigation systems is hard to be found in literature. The objective of this research was to experimentally determine the local head losses in connections commonly used in micro-irrigation and propose mathematical models using the theorem of Buckingham. The methodology of tests was based on international standards. The tests were carried out under controlled inlet pressure, at 150 kPa, and five to ten units of each connection model were tested. The curves relating flow and head losses were drawn based on 15 flow conditions, obtained under increase and decrease of flow rate. For each condition, 30 points were collected resulting in a sample size of 900 points in each test. For each connection model evaluated, the following information was obtained: curves of local head loss as a function of flow rate and of local head loss coefficient (K_L). The obtained values of K_L ranged from 2.72 to 24.16, which become constant for Reynolds number higher than 10,000. The sensitivity of the coefficient related to a ratio of the internal sections in the connections was also verified. The flow exponents presented values close to the one applied by the Darcy-Weisbach equation (m = 2). The models developed for the connections presented a satisfactory performance.

Key words:
hydraulics; dimensional analysis; Buckingham Pi theorem

RESUMO

Informações sobre perda de carga localizada em conexões utilizadas em sistemas de microirrigação são difíceis de serem encontradas na literatura. O objetivo desta pesquisa foi determinar experimentalmente as perdas de carga localizada em conexões comumente empregadas nesses sistemas e propor modelos matemáticos utilizando o teorema de Buckingham. A metodologia dos ensaios foi baseada em recomendações de normas técnicas internacionais. Os ensaios foram realizados sob pressão de entrada controlada em 150 kPa, com cinco a dez unidades testadas para cada modelo de conexão. As curvas relacionando vazão e perda de carga localizada foram plotadas com base em 15 condições de vazão, obtidas sob incremento e decréscimo de vazão. Para cada condição, foram coletados 30 pontos, resultando num conjunto de 900 registros de dados a cada ensaio. Em cada modelo de conexão avaliado, foram obtidas as seguintes informações: curvas de perda de carga localizada em função da vazão e do coeficiente de perda de carga localizada (K_L). Os valores de K_L variaram de 2,72 a 24,16, o qual tornar-se constante para um número de Reynolds acima de 10000. Verificou-se também a sensibilidade do coeficiente KL relacionado com a proporção das seções internas nas conexões. Os expoentes de vazão apresentaram valores próximos ao que é aplicado pela equação de Darcy-Weisbach (m = 2). Os modelos matemáticos desenvolvidos para as conexões apresentaram desempenho satisfatório.

Palavras-chave:
hidráulica; análise dimensional; teorema Pi de Buckingham

Introduction

Omitting local head losses in projects of micro-irrigation systems may substantially compromise their operational characteristics and performance. Increments of 5 to 32% have been reported in the total energy loss caused by the protrusion of online emitters in 13- and 25-mm-diameter polyethylene pipes (Al-Amoud, 1995Al-Amoud, A. I. Significance of energy losses due to emitter connections in trickle irrigation lines. Journal of Agricultural Engineering Research, v.60, p.1-5, 1995. https://doi.org/10.1006/jaer.1995.1090
https://doi.org/10.1006/jaer.1995.1090... ). Neglecting the effect of head losses may induce errors of up to 25% in the estimation of diameters and 7% in the maximum length of laterals (Yildirim, 2007Yildirim, G. An assessment of hydraulic design of trickle laterals considering effect of minor losses. Irrigation and Drainage, v.56, p.399-421, 2007. https://doi.org/10.1002/ird.303
https://doi.org/10.1002/ird.303... ). Considering simulations of two models of pipes with in-line and on-line emitters, head losses contributed with 6.4 and 49.5% of the total energy loss in the project of lateral lines (Provenzano & Pumo, 2004Provenzano, G.; Pumo, D. Experimental analysis of local pressure losses for microirrigation laterals. Journal of Irrigation and Drainage Engineering, v.130, p.318-324, 2004. https://doi.org/10.1061/(ASCE)0733-9437(2004)130:4(318)
https://doi.org/10.1061/(ASCE)0733-9437(... ). In another study, total head loss increased from 24.5 to 50.8% due to local head losses caused by non-coaxial drippers inserted in polyethylene pipes (Rettore Neto et al., 2009Rettore Neto, O.; Frizzone, J. A.; Miranda, J. H. de; Botrel, T. A. Perda de carga localizada em emissores não coaxiais integrados a tubos de polietileno. Engenharia Agrícola, v.29, p.28-39, 2009. https://doi.org/10.1590/S0100-69162009000100004
https://doi.org/10.1590/S0100-6916200900... ).

There is a direct proportion between local head loss and kinetic energy, and that is expressed by a local head loss coefficient (K_L). This value is obtained experimentally, being specific for each type of connection or accessory. However, technical information on connections and accessories, when available, is out of date because of the continuous improvement of production technologies (Kotowski et al., 2011Kotowski, A.; Szewczyk, H.; Ciezak, W. Entrance loss coefficients in pipe hydraulic systems. Environment Protection Engineering, v.37, p.105-117, 2011.) and the changes in the geometry of pieces, which can cause discrepancies compared to the values suggested in hydraulic tables (Prado, 2015Prado, G. Decréscimo da energia de pressão devido a instalação de conexões e peças especiais nas tubulações. Enciclopédia Biosfera, v.11, p.2542-2555, 2015.).

This study aimed to experimentally determine local head losses caused by some connections commonly used in micro-irrigation systems and propose mathematical models, obtained by dimensional analysis and Buckingham Pi theorem.

Material and Methods

The experimental procedures were carried out in the Laboratory of Irrigation Material Tests (22° 42’ S; 47° 37’ W) of the Departamento de Engenharia de Biosistemas da Escola Superior de Agricultura Luiz de Queiroz - ESALQ/USP in Piracicaba, SP state, Brazil. The test bench used operates in a hydraulically closed circuit, supplied by a tank connected to a motor pump set. The arrangement of the instruments and of the test bench itself was based on international standards ISO/TR 15155; ISO 9644 (ISO, 2005ISO - International Organization for Standardization. ISO/TR 15155 - Test facilities for agricultural irrigation equipament. Genebra: International Organization for Standardization, 2005. 24p., 2008ISO - International Organization for Standardization. ISO 9644 - Pressure losses in irrigation valves: Test method. Genebra: International Organization for Standardization , 2008. 11p.).

Flow rate was monitored using an electromagnetic flowmeter, with resolution of 0.01 m³ h^-1, measuring range from 0 to 4 m³ h^-1 and expanded uncertainty of 0.5% of the full scale (FS). This instrument was installed upstream the connection under evaluation. The pressure drop due to local head loss was measured by a differential pressure transmitter, with resolution of 0.01 kPa, measuring range from 1 to 100 kPa, precision of 0.075% FS, as informed by the manufacturer. Water temperature was monitored by a temperature transmitter, with resolution of 0.1 ºC, measuring range from 0 to 50 ºC, with uncertainty of 0.5% FS. Test pressure was monitored by a pressure transmitter, with resolution of 0.001 bar, measuring range from 0 to 5 bar, with uncertainty of 0.1% FS.

Test pressure was adjusted by an electronically controlled proportional valve (½ inch), installed upstream the test connection. The valve drive control (VDC) is operated through electrical signals in the range from 2 to 10 VDC. The motor pump rotation as well as the test pressure were controlled by a variable frequency drive. The test pressure was controlled by a Proportional-Integrative-Derivative (PID) controller. The use of PID controller aims to ensure accuracy and stability in the control of test pressures. Details on the test bench and its validation are presented by Bombardelli et al. (2017Bombardelli, W. W. A.; Camargo, A. P. de; Lavanholi, R.; Araújo, A. C. S.; Talamini Junior, M. V.; Frizzone, J. A. Projeto e validação de uma bancada para ensaios de perda de carga localizada. Irriga, v.edição especial, p.1-10, 2017. https://doi.org/10.15809/irriga.2017v1n1p1-10
https://doi.org/10.15809/irriga.2017v1n1... ) and Bombardelli (2018)Bombardelli, W. W. A. Perda localizada de carga em conexões utilizadas em sistema de microirrigação. Piracicaba: USP, 2018. 81p. Dissertação Mestrado.

The connections tested are produced by the Brazilian Company RSB Plásticos Ltda. and are used in micro-irrigation systems. The connection models evaluated are used in pipes with nominal diameter of 13 and 16 mm. Figure 1 illustrates the models of connections, which were grouped into the following categories: union connectors (ID: 0038 and 0081, Figure 1A), start connectors (ID: 0046 and 0057, Figure 1B), union valves (ID: 0151 and 0153, Figure 1C) and start valves (ID: 0150 and 0152, Figure 1D).

Figure 1
Models of connections tested, grouped by (A) union connectors, (B) start connectors, (C) union valves and (D) start valves

Local head loss assumes a close relationship with the geometric characteristics of the singularities (Azevedo Neto & Fernández y Fernández, 2015Azevedo Netto, J. M.; Fernández y Fernández, M. Manual de hidráulica. 9.ed. São Paulo: Edgard Blucher, 2015. 631p.). Figure 2 illustrates the longitudinal cut of the tested connections, naming their dimensions.

Figure 2
Longitudinal cut of the tested connections representing the characteristic dimensions

The geometric characteristics of the pieces were obtained using a digital caliper, with resolution of 0.01 mm and measuring ranging from 0 to 150 mm, by sampling 10 units. In the categories of pieces belonging to the group of valves, the dimensions of the narrowest internal section (throat) were measured using an optical profile projector. Table 1 presents the dimensions of the tested groups.

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Table 1
Mean (x) and standard deviation (s) of the characteristic dimensions of the evaluated models of connections

The local head loss caused by the flow through the evaluated connections was measured with a differential pressure transmitter, by installing pressure taps upstream and downstream in the connection (Bombardelli et al., 2017Bombardelli, W. W. A.; Camargo, A. P. de; Lavanholi, R.; Araújo, A. C. S.; Talamini Junior, M. V.; Frizzone, J. A. Projeto e validação de uma bancada para ensaios de perda de carga localizada. Irriga, v.edição especial, p.1-10, 2017. https://doi.org/10.15809/irriga.2017v1n1p1-10
https://doi.org/10.15809/irriga.2017v1n1... ). The distance of the pressure taps from the connection is an important detail in this type of tests, because very short distances may cause excessive instability in the indications of differential pressure, whereas very long distances cause considerable major loss. The standard ISO 9644 (ISO, 2008ISO - International Organization for Standardization. ISO 9644 - Pressure losses in irrigation valves: Test method. Genebra: International Organization for Standardization , 2008. 11p.), for the test of irrigation valves, recommends that pressure taps are installed at distances corresponding to two pipe diameters upstream the connection and 10 diameter downstream the connection. These distances were adopted in all tests, because this technical information is the closest one to the test conditions.

Given the distances of the pressure taps, preliminary estimates of the major loss in the segment where the connection was installed were carried out. Local head loss under each test condition was obtained by subtracting the major loss from the total head loss.

For each model of connection, 5 to 10 units of a same lot were tested. The models of connections were tested with fully open angle, as recommended by the standard ISO 9644 (ISO, 2008ISO - International Organization for Standardization. ISO 9644 - Pressure losses in irrigation valves: Test method. Genebra: International Organization for Standardization , 2008. 11p.). A flow-pressure drop curve with at least 5 flow conditions is recommended ISO 9644 (ISO, 2008ISO - International Organization for Standardization. ISO 9644 - Pressure losses in irrigation valves: Test method. Genebra: International Organization for Standardization , 2008. 11p.). The curves relating flow rate and local head loss were constructed with at least 15 pairs of points, under controlled inlet pressure of 150 kPa, and also under increasing and decreasing pressure conditions to include possible effects of hysteresis in the control and measurement system. Since the data were electronically acquired, for each test pressure 30 readings were taken by the transmitters, in order to increase the reliability of the measurements. Additionally, water temperature was continuously monitored during the tests.

From the experimental data, power-law equations were fitted for each local head loss. For each model of connection evaluated, the following data were obtained: power-law equation of local head loss as a function of flow rate; and local head loss coefficient (K_L). Friction factor “f” was calculated using Eq. 1 (Swamee, 1993Swamee, P. K. Design of a submarine oil pipeline. Journal of Transportation Engineering, v.119, p.159-170, 1993. https://doi.org/10.1061/(ASCE)0733-947X(1993)119:1(159)
https://doi.org/10.1061/(ASCE)0733-947X(... ), adopting Reynolds number estimated by an average flow velocity of 1.50 m s^-1 with water temperature of 20 °C and polyethylene pipe roughness of 8.116 µm (Rocha et al., 2017Rocha, H. S. da; Marques, P. A. A.; Camargo, A. P. de; Frizzone, J. A.; Saretta, E. Internal surface roughness of plastic pipes for irrigation. Revista Brasileira de Engenharia Agrícola e Ambiental, v.21, p.143-149, 2017. https://doi.org/10.1590/1807-1929/agriambi.v21n3p143-149
https://doi.org/10.1590/1807-1929/agriam... ).

f = {\{{(\frac{64}{R_{e}})}^{8} + 9.5 {[ln (\frac{ε}{3.7 D_{L}} + \frac{5.74}{R_{e}^{0.9}}) - {(\frac{2500}{R_{e}})}^{6}]}^{- 16}\}}^{0.125}

(1)

where:

f - friction factor, dimensionless;

R_e - Reynolds number, dimensionless;

ε - average roughness, m; and,

D_L - internal diameter of lateral line, m.

The combined use of theoretical and experimental methods is usually required in applications involving hydraulic and fluid mechanics (Zitterell et al., 2013Zitterell, D. B.; Frizzone, J. A.; Rettore Neto, O. Dimensional analysis approach to estimate local head losses in microirrigation connectors. Irrigation Science, v.32, p.169-179, 2013. https://doi.org/10.1007/s00271-013-0424-y
https://doi.org/10.1007/s00271-013-0424-... ; Vilaça et al., 2017Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
https://doi.org/10.1007/s00271-017-0534-... ). Dimensional analysis is a useful technique to solve problems related to these fields because it allows grouping and reducing the number of variables necessary for modeling physical processes and it is also useful for developing prediction models (Vilaça et al., 2017).

The present study used the dimensional analysis based on Buckingham Pi theorem (Buckingham, 1914Buckingham, E. On physically similar systems: Illustrations of the use of dimensional equations. Physical Review, v.4, p.345-376, 1914. https://doi.org/10.1103/PhysRev.4.345
https://doi.org/10.1103/PhysRev.4.345... ) and on the method of repeated variables (Freitas et al., 2015Freitas, G. H. S.; Michels, F. S.; Passos, W. E. Análise dimensional e aplicação hidráulica do teorema Pi de Buckingham. Vetor, v.25, p.84-101, 2015.), following the recommendations proposed by Munson et al. (2013Munson, B. R.; Okiishi, T. H.; Rothmayer, A. P.; Huebsch, W. W.; Rothmayer, A. P. Fundamentals of fluid mechanics. 7.ed. Hoboken: John Wiley & Sons , 2013. 795p.) and Fox et al. (2011Fox, R. W.; Pritchard, P. J.; McDonald, A. T. Introduction to fluid mechanics. 8.ed. Hoboken: John Wiley & Sons, 2011. 899p.). Dimensionless Π groups were formed (Eq. 2) based on the number of variables (k) which describe the process and on the number of dimensions referencing these variables (r). For each group of connections, the number of dimensionless groups (Pi terms), n, was obtained by the subtraction k - r.

Π_{1} = ϕ (Π_{2}, Π_{3}, \dots, Π_{n})

(2)

For any of the cases analyzed in the sequence, local head loss was assumed to be influenced by physical properties of water (density and dynamic viscosity), flow velocity, pipe diameter and by geometric characteristics of the evaluated piece (Eq. 3). Thus, the physical process related to the local head loss involves variables characterized by three basic dimensions (r = 3), which are MLT (mass, length and time).

\begin{array}{l} Δ p_{c} & = & (ρ, μ, V_{L}, D_{L}, geometric characteristics \\ of the hydraulic connection) \end{array}

(3)

where:

Δp_c - pressure drop due to the connection, Pa;

ρ - water density, kg m^-3;

µ - water dynamic viscosity, Pa s; and,

V_L - average flow velocity in the lateral line, m s^-1.

The Pi terms defined in the sequence were obtained by combining the repeated variables V_L, D_L and ρ with the remaining variables. The dimensionless groups proposed for the modeling of start connectors were based on the study of Vilaça et al. (2017Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
https://doi.org/10.1007/s00271-017-0534-... ), according to Eq. 4. Union connectors had a simpler geometry and the inlet and outlet diameter terms were reduced to a single term of the internal diameter of the piece, and the lengths were expressed only by the total length of the piece (Eq. 5).

\frac{Δ p_{c}}{ρ V_{L}^{2}} = \emptyset (\frac{ρ V_{L} D_{L}}{μ}, \frac{D_{E}}{D_{L}}, \frac{D_{S}}{D_{L}}, \frac{L_{E}}{D_{L}}, \frac{L_{S}}{D_{L}})

(4)

where:

D_E - inlet internal diameter, m;

D_S - outlet internal diameter, m;

L_E - inlet length of the connections, m; and,

L_S - outlet length of the connection, m.

\frac{Δ p_{c}}{ρ V_{L}^{2}} = \emptyset (\frac{ρ V_{L} D_{L}}{μ}, \frac{D_{i}}{D_{L}}, \frac{L_{C}}{D_{L}})

(5)

where:

D_i - average internal diameter of union connectors, m; and,

L_C - total length of the connection, m.

For union valves (Eq. 6), six dimensionless groups were proposed, including a relationship of the throat internal diameter with pipe diameter (D_G/D_L) and its corresponding length (L_G) deduced by the difference of L_C with L₁ and L₂. Lastly, for the valves of start connectors (Eq. 7), all expected dimensionless intervals were considered, which led to an eight-term expression.

\frac{Δ p_{c}}{ρ V_{L}^{2}} = \emptyset (\frac{ρ V_{L} D_{L}}{μ}, \frac{D_{i}}{D_{L}}, \frac{D_{G}}{D_{L}}, \frac{L_{C}}{D_{L}}, \frac{L_{G}}{D_{L}})

(6)

where:

D_G - throat diameter, m; and,

L_G - throat length, m.

\frac{Δ p_{c}}{ρ V_{L}^{2}} = \emptyset (\frac{ρ V_{L} D_{L}}{μ}, \frac{D_{E}}{D_{L}}, \frac{D_{S}}{D_{L}}, \frac{D_{G}}{D_{L}}, \frac{L_{E}}{D_{L}}, \frac{L_{S}}{D_{L}}, \frac{L_{G}}{D_{L}})

(7)

A power-law multiple regression equation (Eq. 8) was fitted to each of the data sets using the Least Squares Method. This form of equation has been successfully used to model similar hydraulic phenomena (Vekariya et al., 2010Vekariya, P. B.; Subbaiah, R.; Mashru, H. H. Hydraulic of microtube emitters: A dimensional analysis approach. Irrigation Science, v.29, p.341-350, 2010. https://doi.org/10.1007/s00271-010-0240-6
https://doi.org/10.1007/s00271-010-0240-... ; Zitterell et al., 2013Zitterell, D. B.; Frizzone, J. A.; Rettore Neto, O. Dimensional analysis approach to estimate local head losses in microirrigation connectors. Irrigation Science, v.32, p.169-179, 2013. https://doi.org/10.1007/s00271-013-0424-y
https://doi.org/10.1007/s00271-013-0424-... ; Perboni et al., 2015Perboni, A.; Frizzone, J. A.; Camargo, A. P. de; Pinto, M. F. Modelling head loss along emitting pipes using dimensional analysis. Engenharia Agrícola, v.35, p.442-457, 2015. https://doi.org/10.1590/1809-4430-Eng.Agric.v35n3p442-457/2015
https://doi.org/10.1590/1809-4430-Eng.Ag... ; Vilaça et al., 2017Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
https://doi.org/10.1007/s00271-017-0534-... ).

Π_{1} = β_{1} Π_{2}^{β_{2}} Π_{3}^{β_{3}} \dots Π_{n}^{β_{n}}

(8)

where:

β_n - empirical coefficient, dimensionless.

The models were assessed by the root mean square error (RMSE) and analysis of cumulative frequency distribution of errors. RMSE is commonly used and represents the dispersion between the observed values and those estimated by mathematical models (Willmott et al., 2012Willmott, C. J.; Robeson, S. M.; Matsura, K. A refined index of model performance. International Journal of Climatology, v.32, p.2088-2094, 2012. https://doi.org/10.1002/joc.2419
https://doi.org/10.1002/joc.2419... ; Ali & Abustan, 2014Ali, M. H.; Abustan, I. A new novel index for evaluating model performance. Journal of Natural Resources and Development, v.4, p.1-9, 2014. https://doi.org/10.5027/jnrd.v4i0.01
https://doi.org/10.5027/jnrd.v4i0.01... ). The analysis of cumulative frequency distribution of errors is also useful for estimating errors of prediction because it provides a distribution of the relative errors associated with the cumulative frequency.

The experimental data set corresponding to each group of connections was randomized and segmented into two subgroups: calibration data (70% of the data) and validation data (30% of the data).

The mathematical models presented were simplified considering the gravitational acceleration as 9.81 m s^-2 and water temperature of 20 ºC, and are representative for the range of lateral line diameter (D_L) from 13.70 to 16.39 mm. The model for start connectors was compared with the simplified model (Eq. 9) proposed by Vilaça et al. (2017Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
https://doi.org/10.1007/s00271-017-0534-... ), which was calibrated for 3026 ≤ Re ≤ 94536; 0.4147 ≤ D_E/D_L ≤ 0.7672; 0.5721 ≤ D_S/D_L ≤ 0.8538; 1.9435 ≤ L_C/D_L ≤ 4.3765. The obtained data set is met for the conditioned input ranges of both models. The input terms of Eq. 9 are hf_L (m); ν (m² s^-1); V_L (m s^-1); D_L (m); D_E (m).

{hf}_{L} = 0.0190 \frac{V_{L}^{2.0632} D_{L}^{4.5565}}{ν^{0.0632} D_{E}^{4.4933}}

(9)

where:

ν - water kinematic viscosity, m² s^-1.

Results and Discussion

Figure 3 illustrates the collected data and the analyses carried out for the connection ID: 0046, which is one of the models of start connector evaluated and that showed the highest indicators of local head loss. The same procedure was adopted for all connections evaluated. Figure 3A presents the local head loss in function of flow rate. This curve is obtained by the difference between total head loss and major loss, and a power-law equation was fitted to this data. Figure 3B presents the local head loss as a function of kinetic head, and the local head loss coefficient (K_L) corresponds to the angular coefficient of the line illustrated in this figure. Lastly, Figure 3C indicates how much K_L varies as the Reynolds number increases.

Figure 3
Experimental data obtained for the model 0046: (A) local head loss as a function of flow rate; (B) local head loss as a function of kinetic head; (C) coefficient K_L as a function of Reynolds number

K_L data usually become stable from a Reynolds number of approximately 10,000, as observed by Rettore Neto et al. (2009Rettore Neto, O.; Frizzone, J. A.; Miranda, J. H. de; Botrel, T. A. Perda de carga localizada em emissores não coaxiais integrados a tubos de polietileno. Engenharia Agrícola, v.29, p.28-39, 2009. https://doi.org/10.1590/S0100-69162009000100004
https://doi.org/10.1590/S0100-6916200900... ) and Zitterell et al. (2009Zitterell, D. B.; Frizzone, J. A.; Rettore Neto, O.; Ullmann, M. N. Perda de carga em microtubos e conectores utilizados em microaspersão. Engenharia Agrícola, v.29, p.591-604, 2009. https://doi.org/10.1590/S0100-69162009000400009
https://doi.org/10.1590/S0100-6916200900... ). Cardoso (2014Cardoso, G. G. de G.; Klar, A. E. Índice geométrico e perda de carga localizada em conexão de emissores "online". Engenharia Agrícola, v.34, p.1114-1127, 2014. https://doi.org/10.1590/S0100-69162014000600008
https://doi.org/10.1590/S0100-6916201400... ) observed stable values of K_L for Reynolds number of 20,000, studying pipe-connection sets. Above these values of Reynolds number, the effect of viscosity forces are assumed to be negligible in the flow and the local head loss coefficient (K_L) becomes almost exclusively dependent on the geometric characteristics of the piece (Rettore Neto et al., 2009). One should pay attention to the impact caused by the increment in the kinetic head. For instance, if the velocity in the line is 2 m s^-¹ (kinetic head of approximately 0.2 m) there will be head loss of almost 5 m, caused by the start connector. This corroborates the fact that the geometry of the irrigation material must be improved in order to reduce these losses. On the other hand, all other models evaluated showed lower values of local head loss, indicating more appropriate shape/geometry (Table 2).

For both pipes tested with reference velocity of 1.50 m s^-1, the mean, standard deviation and the coefficient of variation were calculated for K_L data. Table 2 presents this simple descriptive analysis of the technical data of the lot, in order to demonstrate its sampling variation. The connection 0152 showed higher data dispersion between the units of the same model, perhaps due to irregularities in the narrowest section of the piece (throat) and imperfections in the manufacturing process. Table 2 also presents the power-law equations fitted to local head loss (hf_L) data as a function of the flow rate through the lateral path in the piece (Q), where Q is expressed in m³ h^-1. It can be noted that the exponent applied to the flow rate is close to the coefficient used in the Darcy-Weisbach equation (m = 2).

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Table 2
Experimental data of the local head loss curve and K_L values obtained for the models of connection (UC - Union connector; SC - Start connector; UV - Union valve; SV - Start valve)

Due to its reduced dimensional characteristics and the existence of successive alterations in the flow section (Vilaça et al., 2017Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
https://doi.org/10.1007/s00271-017-0534-... ), the local head loss coefficients in micro-irrigation connections assume discrepant values when compared to hydraulic connections of buildings. The minimum and maximum values of average K_L reached by the evaluated connections are attributed to the models identified as 0038 and 0046. For the D_S/D_E quotient of their dimensions, the maximum K_L (ID: 0046) has a ratio of 1.555, whereas the minimum (ID: 0038) has a ratio of only 1.037 (Table 1). The high head loss observed in the piece 0046 is justified by the large expansion in the flow section. In terms of construction, it would be interesting to design connections in such a way to avoid expansions in the flow section or, in cases where this is necessary, it is essential to design smooth and gradual expansions in order to reduce local head losses.

The mathematical models proposed for the classes of pieces tested are presented hereinafter. These equations can be important for projects of irrigation systems and development of material by industries. For a maximum local head loss allowed in the connection to be designed, the industry can vary the dimensions of the piece to achieve the project goals.

The model proposed for union connectors (Eq. 10) was calibrated for the following ranges: 0.68 ≤ V_L (m s^-1) ≤ 5.59; 64.68 ≤ L_C (mm) ≤ 79.99; 9.43 ≤ D_i (mm) ≤ 11.95. These velocity ranges exceed the practical limits recommended for the project of micro-irrigation systems (lower than 2.0 m s^-1) and are only used to calibrate the model and obtain more comprehensive results.

{hf}_{L} = 0.156 \frac{V_{L}^{2.007} D_{L}^{5.087}}{L_{C}^{0.888} D_{i}^{4.191}}

(10)

where:

hf_L - local head loss in the connection, m.

The model for start connectors (Eq. 11) was calibrated for the following ranges: 0.66 ≤ V_L (m s^-1) ≤ 4.11; 18.47 ≤ L_E (mm) ≤ 21.63; 30.77 ≤ L_S (mm) ≤ 40.83; 7.95 ≤ D_E (mm) ≤ 9.64; 9.66 ≤ D_S (mm) ≤ 12.36.

{hf}_{L} = 0.004 \frac{V_{L}^{1.995} D_{L}^{4.282} D_{S}^{0.179} L_{S}^{10.589}}{L_{E}^{14.801} D_{E}^{0.254}}

(11)

The model for union valves (Eq. 12) was calibrated for the following ranges: 0.76 ≤ V_L (m s^-1) ≤ 2.26; 13.72 ≤ L_G (mm) ≤ 13.86; 100.37 ≤ L_C (mm) ≤ 100.56; 11.54 ≤ D_i (mm) ≤ 11.58; 7.65 ≤ D_G (mm) ≤ 7.98.

{hf}_{L} = 0.179 \frac{V_{L}^{2.008} D_{L}^{3.042}}{D_{i}^{0.967} D_{G}^{1.849} L_{C}^{0.039} L_{G}^{0.179}}

(12)

The model for start valves (Eq. 13) was calibrated for the following ranges: 0.62 ≤ V_L (m s^-1) ≤ 2.19; 33.44 ≤ L_E (mm) ≤ 33.48; 13.41 ≤ L_G (mm) ≤ 14.20; 42.39 ≤ L_S (mm) ≤ 43.14; 9.46 ≤ D_E (mm) ≤ 9.51; 7.55 ≤ D_G (mm) ≤ 7.59; 11.59 ≤ D_S (mm) ≤ 11.61.

{hf}_{L} = 0.105 \frac{V_{L}^{1.971} D_{L}^{3.465} L_{E}^{0.067} L_{S}^{0.350}}{D_{E}^{0.889} D_{S}^{0.762} D_{G}^{1.197} L_{G}^{1.063}}

(13)

RMSE assumes a value of 0.132 in the model proposed for the union valves, followed by 0.181 in the models of union connector. The value obtained in the model proposed for start connectors was 0.313 and is close to that obtained by Vilaça et al. (2017Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
https://doi.org/10.1007/s00271-017-0534-... ), who found RMSE of 0.282 through a simplified model to predict local head loss in the lateral path of start connectors. Lastly, the class of start valves showed RMSE of 0.372.

Figure 4 presents the graphical analysis of the errors for union connectors. Figure 4A compares observed and estimated values of local head loss. Figure 4B shows the relative error of the data estimated by the cumulative frequency.

Figure 4
Representation of the simplified dispersion model proposed for union connectors, where (A) local head loss values (observed and simulated), and (B) relative error by cumulative frequency

The same process of error analysis was carried out for the class of start connectors, union valves and start valves, and relative errors of up to 10% were observed respectively at approximately 46.46, 63.33 and 18.95% of the cumulative frequency of the estimated values.

It was observed that the simplified model of Vilaça et al. (2017Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
https://doi.org/10.1007/s00271-017-0534-... ) underestimated the local head losses caused by the start connectors evaluated in the present study. The relative errors of the model of Vilaça et al. (2017) were calculated with the start connectors. In the proposed model, the errors for the cumulative frequencies of 100, 90 and 50% were respectively 22.1, 14.7 and 10.7%, and for the model of Vilaça et al. (2017), they were 44.8, 40.0 and 34.6%. The maximum absolute deviation observed between the two models was 1.92 m, which represents a percentage error of 24.5%.

The model for union valve showed the lowest RMSE among all connections tested. For cumulative frequencies of 100, 90 and 50% the relative errors were 32.3, 14.3 and 6.7%, respectively. For the start valves, the corresponding relative errors were 30.0, 25.5 and 16.7%.

Conclusions

Local head loss values were expressed by the local head loss coefficient (K_L), with values from 2.719 to 24.164, and are sensitive to the ratio of the internal sections of the connection.
Local head loss coefficient was constant for Reynolds numbers above 10,000.
Flow rate exponents assume values close to the one applied in the Darcy-Weisbach equation (m = 2).
The experimental results and the mathematical models developed are useful for hydraulic projects of micro-irrigation systems and projects of hydraulic connections with better geometry, i.e., which cause lower local head loss.

Acknowlegments

The authors thank the RSB Plásticos Ltda. for providing the material used in the experiments.

Literature Cited

Al-Amoud, A. I. Significance of energy losses due to emitter connections in trickle irrigation lines. Journal of Agricultural Engineering Research, v.60, p.1-5, 1995. https://doi.org/10.1006/jaer.1995.1090
» https://doi.org/10.1006/jaer.1995.1090
Ali, M. H.; Abustan, I. A new novel index for evaluating model performance. Journal of Natural Resources and Development, v.4, p.1-9, 2014. https://doi.org/10.5027/jnrd.v4i0.01
» https://doi.org/10.5027/jnrd.v4i0.01
Azevedo Netto, J. M.; Fernández y Fernández, M. Manual de hidráulica. 9.ed. São Paulo: Edgard Blucher, 2015. 631p.
Bombardelli, W. W. A. Perda localizada de carga em conexões utilizadas em sistema de microirrigação. Piracicaba: USP, 2018. 81p. Dissertação Mestrado
Bombardelli, W. W. A.; Camargo, A. P. de; Lavanholi, R.; Araújo, A. C. S.; Talamini Junior, M. V.; Frizzone, J. A. Projeto e validação de uma bancada para ensaios de perda de carga localizada. Irriga, v.edição especial, p.1-10, 2017. https://doi.org/10.15809/irriga.2017v1n1p1-10
» https://doi.org/10.15809/irriga.2017v1n1p1-10
Buckingham, E. On physically similar systems: Illustrations of the use of dimensional equations. Physical Review, v.4, p.345-376, 1914. https://doi.org/10.1103/PhysRev.4.345
» https://doi.org/10.1103/PhysRev.4.345
Cardoso, G. G. de G.; Klar, A. E. Índice geométrico e perda de carga localizada em conexão de emissores "online". Engenharia Agrícola, v.34, p.1114-1127, 2014. https://doi.org/10.1590/S0100-69162014000600008
» https://doi.org/10.1590/S0100-69162014000600008
Fox, R. W.; Pritchard, P. J.; McDonald, A. T. Introduction to fluid mechanics. 8.ed. Hoboken: John Wiley & Sons, 2011. 899p.
Freitas, G. H. S.; Michels, F. S.; Passos, W. E. Análise dimensional e aplicação hidráulica do teorema Pi de Buckingham. Vetor, v.25, p.84-101, 2015.
ISO - International Organization for Standardization. ISO/TR 15155 - Test facilities for agricultural irrigation equipament. Genebra: International Organization for Standardization, 2005. 24p.
ISO - International Organization for Standardization. ISO 9644 - Pressure losses in irrigation valves: Test method. Genebra: International Organization for Standardization , 2008. 11p.
Kotowski, A.; Szewczyk, H.; Ciezak, W. Entrance loss coefficients in pipe hydraulic systems. Environment Protection Engineering, v.37, p.105-117, 2011.
Munson, B. R.; Okiishi, T. H.; Rothmayer, A. P.; Huebsch, W. W.; Rothmayer, A. P. Fundamentals of fluid mechanics. 7.ed. Hoboken: John Wiley & Sons , 2013. 795p.
Perboni, A.; Frizzone, J. A.; Camargo, A. P. de; Pinto, M. F. Modelling head loss along emitting pipes using dimensional analysis. Engenharia Agrícola, v.35, p.442-457, 2015. https://doi.org/10.1590/1809-4430-Eng.Agric.v35n3p442-457/2015
» https://doi.org/10.1590/1809-4430-Eng.Agric.v35n3p442-457/2015
Prado, G. Decréscimo da energia de pressão devido a instalação de conexões e peças especiais nas tubulações. Enciclopédia Biosfera, v.11, p.2542-2555, 2015.
Provenzano, G.; Pumo, D. Experimental analysis of local pressure losses for microirrigation laterals. Journal of Irrigation and Drainage Engineering, v.130, p.318-324, 2004. https://doi.org/10.1061/(ASCE)0733-9437(2004)130:4(318)
» https://doi.org/10.1061/(ASCE)0733-9437(2004)130:4(318)
Rettore Neto, O.; Frizzone, J. A.; Miranda, J. H. de; Botrel, T. A. Perda de carga localizada em emissores não coaxiais integrados a tubos de polietileno. Engenharia Agrícola, v.29, p.28-39, 2009. https://doi.org/10.1590/S0100-69162009000100004
» https://doi.org/10.1590/S0100-69162009000100004
Rocha, H. S. da; Marques, P. A. A.; Camargo, A. P. de; Frizzone, J. A.; Saretta, E. Internal surface roughness of plastic pipes for irrigation. Revista Brasileira de Engenharia Agrícola e Ambiental, v.21, p.143-149, 2017. https://doi.org/10.1590/1807-1929/agriambi.v21n3p143-149
» https://doi.org/10.1590/1807-1929/agriambi.v21n3p143-149
Swamee, P. K. Design of a submarine oil pipeline. Journal of Transportation Engineering, v.119, p.159-170, 1993. https://doi.org/10.1061/(ASCE)0733-947X(1993)119:1(159)
» https://doi.org/10.1061/(ASCE)0733-947X(1993)119:1(159)
Vekariya, P. B.; Subbaiah, R.; Mashru, H. H. Hydraulic of microtube emitters: A dimensional analysis approach. Irrigation Science, v.29, p.341-350, 2010. https://doi.org/10.1007/s00271-010-0240-6
» https://doi.org/10.1007/s00271-010-0240-6
Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
» https://doi.org/10.1007/s00271-017-0534-z
Willmott, C. J.; Robeson, S. M.; Matsura, K. A refined index of model performance. International Journal of Climatology, v.32, p.2088-2094, 2012. https://doi.org/10.1002/joc.2419
» https://doi.org/10.1002/joc.2419
Yildirim, G. An assessment of hydraulic design of trickle laterals considering effect of minor losses. Irrigation and Drainage, v.56, p.399-421, 2007. https://doi.org/10.1002/ird.303
» https://doi.org/10.1002/ird.303
Zitterell, D. B.; Frizzone, J. A.; Rettore Neto, O. Dimensional analysis approach to estimate local head losses in microirrigation connectors. Irrigation Science, v.32, p.169-179, 2013. https://doi.org/10.1007/s00271-013-0424-y
» https://doi.org/10.1007/s00271-013-0424-y
Zitterell, D. B.; Frizzone, J. A.; Rettore Neto, O.; Ullmann, M. N. Perda de carga em microtubos e conectores utilizados em microaspersão. Engenharia Agrícola, v.29, p.591-604, 2009. https://doi.org/10.1590/S0100-69162009000400009
» https://doi.org/10.1590/S0100-69162009000400009

Publication Dates

Publication in this collection
10 July 2019
Date of issue
July 2019

History

Received
07 May 2018
Accepted
13 May 2019
Published
04 June 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Al-Amoud, A. I. Significance of energy losses due to emitter connections in trickle irrigation lines. Journal of Agricultural Engineering Research, v.60, p.1-5, 1995. https://doi.org/10.1006/jaer.1995.1090
» https://doi.org/10.1006/jaer.1995.1090

[2] Ali, M. H.; Abustan, I. A new novel index for evaluating model performance. Journal of Natural Resources and Development, v.4, p.1-9, 2014. https://doi.org/10.5027/jnrd.v4i0.01
» https://doi.org/10.5027/jnrd.v4i0.01

[3] Azevedo Netto, J. M.; Fernández y Fernández, M. Manual de hidráulica. 9.ed. São Paulo: Edgard Blucher, 2015. 631p.

[4] Bombardelli, W. W. A. Perda localizada de carga em conexões utilizadas em sistema de microirrigação. Piracicaba: USP, 2018. 81p. Dissertação Mestrado

[5] Bombardelli, W. W. A.; Camargo, A. P. de; Lavanholi, R.; Araújo, A. C. S.; Talamini Junior, M. V.; Frizzone, J. A. Projeto e validação de uma bancada para ensaios de perda de carga localizada. Irriga, v.edição especial, p.1-10, 2017. https://doi.org/10.15809/irriga.2017v1n1p1-10
» https://doi.org/10.15809/irriga.2017v1n1p1-10

[6] Buckingham, E. On physically similar systems: Illustrations of the use of dimensional equations. Physical Review, v.4, p.345-376, 1914. https://doi.org/10.1103/PhysRev.4.345
» https://doi.org/10.1103/PhysRev.4.345

[7] Cardoso, G. G. de G.; Klar, A. E. Índice geométrico e perda de carga localizada em conexão de emissores "online". Engenharia Agrícola, v.34, p.1114-1127, 2014. https://doi.org/10.1590/S0100-69162014000600008
» https://doi.org/10.1590/S0100-69162014000600008

[8] Fox, R. W.; Pritchard, P. J.; McDonald, A. T. Introduction to fluid mechanics. 8.ed. Hoboken: John Wiley & Sons, 2011. 899p.

[9] Freitas, G. H. S.; Michels, F. S.; Passos, W. E. Análise dimensional e aplicação hidráulica do teorema Pi de Buckingham. Vetor, v.25, p.84-101, 2015.

[10] ISO - International Organization for Standardization. ISO/TR 15155 - Test facilities for agricultural irrigation equipament. Genebra: International Organization for Standardization, 2005. 24p.

[11] ISO - International Organization for Standardization. ISO 9644 - Pressure losses in irrigation valves: Test method. Genebra: International Organization for Standardization , 2008. 11p.

[12] Kotowski, A.; Szewczyk, H.; Ciezak, W. Entrance loss coefficients in pipe hydraulic systems. Environment Protection Engineering, v.37, p.105-117, 2011.

[13] Munson, B. R.; Okiishi, T. H.; Rothmayer, A. P.; Huebsch, W. W.; Rothmayer, A. P. Fundamentals of fluid mechanics. 7.ed. Hoboken: John Wiley & Sons , 2013. 795p.

[14] Perboni, A.; Frizzone, J. A.; Camargo, A. P. de; Pinto, M. F. Modelling head loss along emitting pipes using dimensional analysis. Engenharia Agrícola, v.35, p.442-457, 2015. https://doi.org/10.1590/1809-4430-Eng.Agric.v35n3p442-457/2015
» https://doi.org/10.1590/1809-4430-Eng.Agric.v35n3p442-457/2015

[15] Prado, G. Decréscimo da energia de pressão devido a instalação de conexões e peças especiais nas tubulações. Enciclopédia Biosfera, v.11, p.2542-2555, 2015.

[16] Provenzano, G.; Pumo, D. Experimental analysis of local pressure losses for microirrigation laterals. Journal of Irrigation and Drainage Engineering, v.130, p.318-324, 2004. https://doi.org/10.1061/(ASCE)0733-9437(2004)130:4(318)
» https://doi.org/10.1061/(ASCE)0733-9437(2004)130:4(318)

[17] Rettore Neto, O.; Frizzone, J. A.; Miranda, J. H. de; Botrel, T. A. Perda de carga localizada em emissores não coaxiais integrados a tubos de polietileno. Engenharia Agrícola, v.29, p.28-39, 2009. https://doi.org/10.1590/S0100-69162009000100004
» https://doi.org/10.1590/S0100-69162009000100004

[18] Rocha, H. S. da; Marques, P. A. A.; Camargo, A. P. de; Frizzone, J. A.; Saretta, E. Internal surface roughness of plastic pipes for irrigation. Revista Brasileira de Engenharia Agrícola e Ambiental, v.21, p.143-149, 2017. https://doi.org/10.1590/1807-1929/agriambi.v21n3p143-149
» https://doi.org/10.1590/1807-1929/agriambi.v21n3p143-149

[19] Swamee, P. K. Design of a submarine oil pipeline. Journal of Transportation Engineering, v.119, p.159-170, 1993. https://doi.org/10.1061/(ASCE)0733-947X(1993)119:1(159)
» https://doi.org/10.1061/(ASCE)0733-947X(1993)119:1(159)

[20] Vekariya, P. B.; Subbaiah, R.; Mashru, H. H. Hydraulic of microtube emitters: A dimensional analysis approach. Irrigation Science, v.29, p.341-350, 2010. https://doi.org/10.1007/s00271-010-0240-6
» https://doi.org/10.1007/s00271-010-0240-6

[21] Vilaça, F. N.; Camargo, A. P. de; Frizzone, J. A.; Mateos, L.; Koech, R. Minor losses in start connectors of microirrigation laterals. Irrigation Science, v.35, p.227-240, 2017. https://doi.org/10.1007/s00271-017-0534-z
» https://doi.org/10.1007/s00271-017-0534-z

[22] Willmott, C. J.; Robeson, S. M.; Matsura, K. A refined index of model performance. International Journal of Climatology, v.32, p.2088-2094, 2012. https://doi.org/10.1002/joc.2419
» https://doi.org/10.1002/joc.2419

[23] Yildirim, G. An assessment of hydraulic design of trickle laterals considering effect of minor losses. Irrigation and Drainage, v.56, p.399-421, 2007. https://doi.org/10.1002/ird.303
» https://doi.org/10.1002/ird.303

[24] Zitterell, D. B.; Frizzone, J. A.; Rettore Neto, O. Dimensional analysis approach to estimate local head losses in microirrigation connectors. Irrigation Science, v.32, p.169-179, 2013. https://doi.org/10.1007/s00271-013-0424-y
» https://doi.org/10.1007/s00271-013-0424-y

[25] Zitterell, D. B.; Frizzone, J. A.; Rettore Neto, O.; Ullmann, M. N. Perda de carga em microtubos e conectores utilizados em microaspersão. Engenharia Agrícola, v.29, p.591-604, 2009. https://doi.org/10.1590/S0100-69162009000400009
» https://doi.org/10.1590/S0100-69162009000400009

ID	D_E or D₁	D_S or D₂	D_G	L_E or L₁	L_S or L₂	L_C
ID	x (mm) ± s (mm)
0038	11.74 ± 0.06	12.17 ± 0.05	-	-	-	79.99 ± 0.10
0046	7.95 ± 0.03	12.36 ± 0.03	-	21.63 ± 0.23	40.83 ± 0.27	62.46 ± 0.07
0057	9.64 ± 0.02	9.66 ± 0.03	-	18.47 ± 0.22	30.77 ± 0.26	49.24 ± 0.10
0081	9.66 ± 0.05	9.19 ± 0.02	-	-	-	64.68 ± 0.12
0150	9.51 ± 0.04	11.59 ± 0.01	7.55 ± 0.16	33.44 ± 0.48	43.14 ± 0.80	89.99 ± 0.12
0151	11.53 ± 0.04	11.64 ± 0.01	7.65 ± 0.39	43.67 ± 0.97	43.17 ± 1.41	100.56 ± 0.09
0152	9.46 ± 0.02	11.61 ± 0.06	7.59 ± 0.08	33.48 ± 0.89	42.39 ± 0.52	90.06 ± 0.10
0153	11.50 ± 0.12	11.58 ± 0.11	7.98 ± 0.11	43.16 ± 0.62	43.35 ± 0.65	100.37 ± 0.05

ID	Class/D_L (mm)	Equations of hf_L (m)	K_L
ID	Class/D_L (mm)	Equations of hf_L (m)	x	s	CV (%)
0038	UC 16	0.3 Q^2.0	2.719	0.151	5.554
0046	SC 16	2.1 Q^2.0	24.164	1.420	5.877
0057	SC 13	1.0 Q^2.0	5.721	0.103	1.800
0081	UC 13	0.6 Q^2.0	3.625	0.240	6.621
0150	SV 16	2.0 Q^2.0	22.288	0.866	3.886
0151	UV 16	1.4 Q^2.0	15.776	1.131	7.169
0152	SV 13	2.0 Q^2.0	11.086	1.220	11.005
0153	UV 13	1.5 Q^2.0	8.487	0.746	8.790

Brasil

Brasil

Local head loss caused in connections used in micro-irrigation systems

Perda de carga localizada em conexões utilizadas em sistemas de microirrigação

ABSTRACT

RESUMO

Introduction

Material and Methods

Results and Discussion

Conclusions

Acknowlegments

Literature Cited

Publication Dates

History