Available online Journal of Scientific and Engineering Research, 2016, 3(6): Research Article

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Av www.. Ju St E R, 2016, 3(6):131-138 R At ISSN: 2394-2630 CODEN(USA): JSERBR Cutvt R Au Su H Lv I y t Mt Btt M Zu H Ut, Su, W Hy Dtt Ay Futy Autu, Uvt Tw, J. Tw N. 9 P, 25136,Wt Sut, I, E-: 65@y. Att I 2013 ut 71,279,709 M y (DGM) uvt t 44,528,434 M ut. Dt t Mty Ht, w xty 100 I, u utt ( ) u t ty t u uttu, ut y y t utt. Dy (F) t, w t, ut t, w t, t tu, v u t. I- I ut 30-60% t u v y t w w u t y utt. T v t t ut 137 t -1 y -1, tuty t t utt, y y t t -tt, wt utvt t y w tt (F) u. T tv t utvty t w F, wt tt >7 M -1 wt tt t t vt v wt tt >30-1. T ut w tt t t t ty t ut v wt t t tt, w t ut w: 1) T u t tt t I 29 vty t t ttt, t u 114.69 t; 2) Put t t DGM u M vt wt ut wt ttt, y 7,417.9 M; 3) t v, vt wt PGR ttt, w t ut tw 18.8-36.2-1. It t ty (vt tt + t 10 M -1 + t u [(10 x 10) x 25 x 10x10)] tt u 4 + yu 10 y + PGR) SRI t u t ut tt t y t t -tt z F. Kyw -tt,, Itut R t tt t w', w u u t wt, t tt w tu t t. T t, y y ut (F) ut 2-3 -1 [1]. A t WHO (2000), y 3 t utt, w -I ut 30-60% u v y t w w u t y utt [1]. T v t t ut 137 t - 1 y -1 [2], tuty t v t utt, y y t t tt. Mt -tt t wy utvt tt ut (F), t t tuy y ut v t t z t t, t vt t tt t. H v v F 2+ t t w, tt tt t xt, t vt wt tt y t t -tt. I ut v y Ju St E R 131

Ut MZH t Ju St E R, 2016, 3(6):131-138 t t y t t -tt, ut y ttt wt wt ut ut t ux, u t ty t ut t w Su-S t, ty t t [3-4]. T tt tt u t t ut w Dy wt v 2,691 [5], w u y t uty F 2+ A 3+ [6-8], ut u tt wt v. T v utvty y 2.2-2.5 M -1 w t ut w t 4.75 M -1 [2]. T ut t y xt w t t t tt vy wy vy w t vy, y: N tt (0.11% w), v P (3.29-1 vy w), wt t t t (K + 0.05-1 w, N 0.13-1 w, M 0.20-1 vy w, C 0.08-1 vy w), w A 3+ 4.78-1 u, F 2+ 104.69-1 [9]. Lv u ut t ut F 3+ t F 2+, t t t t tt t t w tty t [8,10], w u t t t wt vt, y t vt w tv t utt t [7, 11-14]. T ut - vt y, utvty vt w wt wt utvt ty t -tt. It t utvt u u t -tt t t wy t y t vtt tt t tuy utvt u u t. T xt ttt t t utvty wt w t t F, wt tt >7 M -1, t t t wt tt >30-1 ; t t t ty t wt ut ux t t t t t. T ut t tuy vy tt t ut, ty vt t t u y w, t utt ty. Mt Mt T xt w ut Fuy t Auut 2014, t w wt t t Sutt Kt Bu, Dtt Dy. T xt u tw-t t Cty Rz D wt t t. T t t w t vty (V) w: V 1 = I 24; V 2 = SBY; V 3 = I 26; V 4 = I 27; V 5 = I 28; V 6 = I 29; V 7 = I 30; V 8 = Cu; V 9 = M; V 10 = A D. T t w t wt ut (Z), y: Z 0 = Ct; Z 1 = Sytt PGR (Aux); Z 2 = Ntu PGR (ut wt). T t ty u t xt, y: (1). tt vt F A; (2). At w 10 M -1 ; (3). S u [(10 x 10 ) x 25 x (10x10 )]; (4). O t t 10 y [8, 13, 15-16]. Ovt t ut t xt u t ut u t t, t u t, u, t, t ty, t wt 1000 ; y (DGM) -1. Lv (F) u wt AA V 240 wt t t SNI 6989.4.2009 t Itt Lty Kt R X P. R, t t ut D, wt tt 3-1 1-1 30 ut, t tuy 2 x 24 u. R wt wt 7 y, t t t t w u 10 M -1 u t. At tt, t t 25-30 y tt, wt t t xt t wt z 6.0 x 3.0 t, tt 60 xt t. T t wt ut 2 w t t SRI t. Gt y tu wt tt v, t y v wt tt t. T t ut t ut 10 y y t t t. T t t t t U tz, SP-36 KC t y t (250 NPK P) 170 U, 36 P 2 O 5 60 K 2 O). A ut v U t t 6 w t t w t t tv. W t 2 w t 6 w t t. Wt tt, t Ju St E R 132

Ut MZH t Ju St E R, 2016, 3(6):131-138 wt w tt. Hvt t t yw 80% t tt ut. Rut Du T xt ut w tt t w vt t wt ut vt tt tt wt wt ut ut ytt tu (ut wt) v t u t t, u t, u, t (T 1), t u t, u -1, wt 1000 ; DGM -1 (T 2), v (F) (T 3). T 1: Pt t, t u, u t v vt utvt y t t -tt Ty R Vty PGR I 24 SBY I 26 I 27 I 28 I 29 I 30 Cu M A D Pt Ht () Ct 105.13 99.53 89.27 93.53 89.31 114.69 85.87 u 92.69 91.33 105.73 (5) 100.43 96.01 89.15 87.65 85.77 u 85.15 v 89.33 92.51 90.43 112.19 Cut Wt 95.99 94.57 89.61 87.27 93.27 82.27 x 84.65 w 92.83 86.73 t 113.35 Σ T () Ct 92.8 94.0 78.4 w 93.0 89.0 J 91.6 88.4 83.6 82.8 86.0 (5) 95.0 91.6 92.4 93.0 90.2 83.0 94.8 85.0 89.4 89.3 Cut Wt 92.8 92.4 80.0 u 81.2 t 78.8 v 75.0 x 87.0 83.8 83.6 86.2 P () Ct 43.3 45.8 37.2 38.7 34.6 23.7 t 28.7 30.6 37.4 28.5 (5) 50.4 34.9 25.5 35.0 37.4 32.2 25.3 31.5 29.9 26.2 Cut Wt 40.3 31.6 28.9 32.0 32.4 35.9 23.1 u 34.5 32.6 25.2 P Lt () Ct 18.69 17.52 24.99 24.63 19.14 21.75 20.04 18.96 10.77 18.42 (5) 18.87 21.03 23.73 24.54 21.48 21.84 19.32 17.52 18.96 15.56 Cut Wt 18.24 23.28 23.28 25.80 18.06 21.39 19.05 17.52 20.04 18.42 M w y t tt t v ttt w ty t t 5% v y Tuy tt. T wt, w t tty t vt t t F. But t vt t w u w, w T 1 2. T t tt t wt t t y t ut ty vt, tu u vt wt Ju St E R 133

Ut MZH t Ju St E R, 2016, 3(6):131-138 ut t t t t t v vt tt t tt tw ty y vt [17], t t t vt wt t ty t t vt ty vty. T t wt wt t t vt I 29 (t) 114.69 tu t wt ut ttt (82.27 ). At t t t t w tt t ttt t wt ut y t vt t, vt u I 24, SBY, I 27 I 29, M ut t vt, ttt PGR t t I 28 A D. H w t t t y t t, w w t t t tyt t wt ut t t t t ut tyt [17]. T u t vt I 24 I 26 I 30 Cu, M A D tt wt PGR, ut t t vt t wt ut ttt t t. T t t u t t ttt wt PGR I 24 ytt, 95 t, w t wt u ttt I 29 wt ut wt, w 75 t. T u t uy u t t u t yt [(10 x 10 ) x 25 x (10x10 )] u u (Fu 2B). Itt wt t t, u u t t wt vt u t t tt y t t utt, wt t. I vt ( ), t u t tt ut 20 t, ty t t ttt t wt ut t t u t 4x t t vt utvt (Fu 1A). D t u t, uy u t u t t t yt utvt. Dt t t y y vu ttut t t u utv t u u 10-20 t [18-20]. A B Fu 1: Gwt t u wt v () u 15-20 t (A), u (4 ) wt [(10x10) x 25 x (10x10)] u 95-105 t (B) T t u u I 24 wt ytt t wt ut ttt, 50.4, w t wt t u I PGR 29 wtut ttt (t) wt 23.7. T t t t utv t [20]. T u u t xt 2-3 t, t t u v t y vt. Nt vt utvt y y u ut 10-20 [21]. T t u t t t wy utvt, t utvt vt u t 4-6 u (w t) t t ut 21 y, w t ty u ut 12 y u 4 (Fu 1B), wt t t t t t w ty tt tt t y t tt t u Ju St E R 134

Ut MZH t Ju St E R, 2016, 3(6):131-138. Su vt u v, wt t ut tt t t tt - zt vt t tt tyt u t t tu. R t t xt w t ttt PGR ut wt, w 25.80 I 27, t t wt t ut t ytt t wt ut ttt t t vty, t t t I 26 24.99. W t tt vt A D wt ytt t wt ut ttt, 15.56 (T 2). T u ty I 24 wt t ytt t wt ut ttt (47.8 ), w t t u I 30 wt PGR ttt ut wt 20.1 ut. T ut vt ( tu) w tt t u t t, ty w t u 5-10. T 2: Nu t, u, 1000 wt, DGM -1 v vt utvt y t t -tt. Ty R Vty PGR I 24 SBY I 26 I 27 I 28 I 29 I 30 Cu M A D St () Ct 6.3 6.9 9.5 9.60 6.9 B 10.1 8.8 8.3 11.0 8.8 (5) 7.1 7.6 7.6 8.0 7.3 B 9.9 7.3 8.3 10.9 8.9 A K 6.6 12.2 8.2 9.0 6.8 B 10.3 9.0 8.0 11.0 9.3 G P -1 () Ct 105.77 101.03 138.43 137.58 99.23 118.83 102.83 95.53 141.83 109.83 (5) 104.43 75.53 104.73 112.83 105.13 115.83 85.43 85.67 97.83 105.97 A K 101.03 68.23 112.43 126.73 97.13 122.93 85.43 90.33 89.03 96.63 1.000 G Wt () Ct 25.89 32.57 24.58 29.03 32.35 26.01 24.70 25.62 39.44 24.11 (5) 30.24 26.88 23.47 29.19 25.80 28.14 23.97 27.44 34.13 25.35 A K 25.38 23.82 23.88 28.41 27.12 31.22 30.38 24.72 39.51 21.48 Dy G M Put (DGM M -1 ) Ct 6,767 6,881 5,912 5,418 4,891 6,346 4,404 3,068 5,552 5,606 (5) 5,974 4,375 4,535 3,903 4,170 4,314 2,024 4,444 3,455 4,216 A K 5,262 3,884 3,887 2,751 1,920 3,953 2,850 3,406 7,418 3,266 M w y t tt t v ttt w ty t t 5% v y Tuy tt. St t vt SBY wt ut wt ttt t wt ut tt 12.2, ty t t I 24 28, w t t vt w t ty t (T 2). Ju St E R 135

Ut MZH t Ju St E R, 2016, 3(6):131-138 I t t ttt w, v t w v v tt ut t t ttt t wt ut u ytt ut wt, t t; t t, t, t u -1, t wt 1000. T uy u t ty t u u (w) x wt w u u 10 M -1, ut t t t t utvt. Pt PGR vy utt, w ut -1. Cw u t t wt ut ux t u, w y tut w, t, v, tt [22-24]. M vt (t) w t u -1 141.83 t ty t wt I 26 (t) 138.43, w t u -1 wt t vt SBY-tt wt ut wt, w 68.23 (T 3). R t w w v ut t F, u t vt u tt vt tt t t ut t. I t, ty u u t wt t u t vty utt. At t tu t t (4 t ) t u t y vttv wt tt, t t tt tt t y t [9]. T ty, t u vttv wt tv u t t vy yu. T tv vttv wt, v y t u t wt ut tt t v, t. T 3: Lv (F) vt utvt wt -tt SRI t. Ty R Vty PGR I SBY I I I I I Cu M A 24 26 27 28 29 30 D I Ctt R G ( -1 ) Ct 21.1 26.8 24.1 20.3 22.4 31.1 29.3 20.5 35.7 23.1 24.0 20.3 23.0 22.0 29.0 33.8 23.2 21.0 30.2 20.6 (5) Cut 24.2 26.2 23.8 36.0 36.2 22.1 25.2 20.0 25.8 18.8 Wt M w y t tt t v ttt w ty t t 5% v y Tuy tt. I v vt w utvt y t t -tt w tt vy 18.8 t 36.2-1. I v wt t vt A D y ttt wt ut wt (18.8-1 ), w t v t I 28 (36.2-1 ) w t ty t t I 27 wt wt ttt u ut (36.0-1 ), w vt M t (35.7-1 ), I 29 wt t ttt (33.8-1 ) t (31.1-1 ). I v I 28 (36.2-1 ) w tt wt ut wt y 62% wt t (22.4-1 ), w t vt A D (18.8-1 ) w w tt wt ut wt y 19% wt t (23.6-1). I v vt utvt z y F (T 3) u, w wt t v t t y ut 2-3 -1 (Iz Ayu, 2012). T w tt, uy u vt utvt t wt v v vy w. Cutvt vt (T 3) t-tt vt F [15], t vt t t w. I t, ut utu y y t v ty, t : tt vt F A 3+ t 10 M -1 + S u [(10 x 10 ) x 25 x (10x10) ] + O t t w 10 y [8, 13, 15-16]. Cu T ut w tt t t t ty t ut v wt t t -tt, w w t ut: Ju St E R 136

Ut MZH t Ju St E R, 2016, 3(6):131-138 1. T u t tt t I 29 t t ttt, t u 114.69 t. 2. Put t t DGM u y M vt wt ut wt ttt, 7.418 M -1. 3. T tt, vt wt PGR ttt w t ut tw 18.8-36.2-1. It t ty (vt tt + t 10 M -1 + u [10 x 10) x 25 x 10x10)] + yu 10 y + PGR) wt t SRI t u t ut t tt t y t t -tt z F. Awt T t S-Lt H Eut Mty Nt Eut t t tu D Kt W X 2014 2015, t Ltt At Itt R Cttv Gt Nt Pty F Y 2014 2015. T t M. S K, t Stu IV V t tut u u Nt E Pyt ty ut t w. R [1]. Ayu. 2012. P t, uy t. K, 22 Nv 2012. Jt. H 13. (I I). [2]. BPS. 2015. I D A. B Put Sttt. Jt, I. (I I). [3]. H, W.G. 1995. Itut t Pt Pyy. T Uvty Wt Ot. J Wy S, INC. [4]. Y, J., S. P., Z. Z., Z. W., R.M. V Q. Zu L. Lu. 2002. G y tt y tt t / y. C S. 42:766-772. [5]. BPS. 2007. Kut Dy. B Dy BPS, Sut Bt, I. (I I). [6]. Ut, M.Z.H. 2010. P vt t uu. J. A. I. 38 (3): 163-169. (I I). [7]. Ut, M.Z.H. 2010. Et NC-t t NO 3-, NH 4+ NO 2- t v vt. J. T S. 15 (3):189-194. : 10.5400/t.2010.15.3.189. [8]. Su., I. W., M.Z.H. Ut. 2010. P vt t F 2+ w u u. J.At A. 13 (1):16-23. (I I). [9]. Ut, MZH., Su., W Hy. 2013. Et t v t t ty ut F 2+. J T S. 18 (3): 195-202. : 10.5400/ t.2013.18.3.195. [10]. Swt, K.L. 2004. I txty wt t t utt. J.Pt Nut. 27: 1471-1504. [11]. M, J. F. 2000. R txt uu t. Pt y. 41(4): 383-390. [12]. R, Z. 2000. M utt, ut t. F ut, Bt. [13]. Ut, M.Z.H., W. Hy., R. Mu, Su. 2009. P vt t t w D Kut P St. J. A. I. 37(2):101-106. (I I). [14]. N, A., I. Lu, M. Gu, M.A. Cz, K. Aw, D. W. 2012. Pu t ut t u tuu t. J. A. I. 40 (2): 91-98. (I I). [15]. Ut, M.Z.H., I. W., Su. 2012. R utv z wt F 2+ w tu wt ut ty. J T S. 17 (3): 239-244. : 10.5400/t.2012.17.3.239. Ju St E R 137

Ut MZH t Ju St E R, 2016, 3(6):131-138 [16]. Hy, W., K., I. Suy., A. Sy., T.B. Pty. 2012. T vt w ut u t. J.A. I. 40(2): 112-118. (I I) [17]. Lt, A.P., B. Au, A. Ju, H. Aw. 2010. Y tty tty t w t ty. J. A I. 38:199-204. [18]. Pu, T., S Iy, M. Mu, E.Wt. 2013. Ct yt utu t tuu t. J. A. I 41(3):175-180. (I I). [19]. Putwt, M.D., Suyt, I A. 2013. Pt ut t utu u uu P w. J. A. I 41(3):188-195. (I I). [20]. Ut, MZH., Su., W Hy A A. 2015. Cutu t y F u v wt tt t. Itt x Pt u t. Uvty Buu, Buu, 12-13 Ot 2015. [21]. Ayu. 2014. Dt vt uu. Put Pt T P, B Pt P Pt. tt://www.utt..t/. (I I). [22]. C-U, S., B. S, A. Pu, C. K. 2009. A t u y u ut u t t tu t utu t t (Oyz tv L. u ). I Vt C.Dv.B. Pt 45: 171-179. [23]. Ku, L., R. S, S.M. B, K. Ut, V. Sy. 2014. Et ttt v t utu (Oyz tv L.) J. Ex.B. A. S.2: 233-242. [24]. Gu, C., Puw, B.S., Dw, I.S Syuu M. 2016. Pt t tzt t utu 6 F. J. A. I 44 (2):133-140. Ju St E R 138

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