Microsoft Word - 計算力学2007有限要素法.doc
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- かつかげ そめや
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1 95 2 x y yz = zx = yz = zx = { } T = { x y z xy } () {} T { } T = { x y z xy } = u u x y u z u x x y z y + u y (2) x u x u y x y
2 x y z xy E( ) = ( + )( 2) 2 2( ) x y z xy (3) E x y z z = z = (3) z x y xy E = 2 ( )/2 x y xy (4) x y z z = z { x, y, xy }{ x, y, xy }(3) x y xy /( ) E( ) = /( ) ( + )( 2) ( 2)/[2( )] x y xy (5) (4)(5) { }= [ ] {} (6) x x + xy y + X x = (7) xy x + y y + X y = (8) X x X y x y ( ) 2
3 S S t S t S u S t {t} T = {t x, t y } S t x xy xy y cos sin = t x t y [ ]{n} = {t} S t (9) x {n} T ={cos, sin}{t} = (9)(Cauchy) ds t {n} {t} x dy t x t y xy dx xy y [ ] (9) x y x dy + xy dx = t x ds t xy dy + y dx = t y ds t cos = dy /ds t sin = dx /ds t (9) 3
4 x cos + xy sin = t x xy cos + y sin = t y [] S u u x = u x u y = u y S u () (2)(7, 8)(6) (9, ) 3 { } x y h x y xy xy dxdy = h { u x u y } X x dxdy + h u X x u y y { } t x ds S t t t () y h { } T { }dxdy = h { u} T { X }dxdy + h { u} T {} t ds t (2) S t h z u x u y S u u x = u y = x y xy u x u y x = (u x) x, y = (u y ) y, xy = (u x ) + (u ) y y x (3) h 4
5 (){ u} (7, 8) h x x + xy y + X x u x + xy x + y y + X y u y dxdy = (a) ( x xu x + xy u y ) + ( y xyu x + y u y ) = x x u x + xy x u y + xy y u x + y y u y u ( x ) + x x ( ) u ( x ) + xy y + u ( ) y y y + u y xy x = x x + xy u x + xy y x + y u y + { x y xy } x y (b) y xy (3)(b)(a) h x x + xy y + X x u x + xy x + y y + X y u y dxdy = h x x + xy u y x + xy x + y u y y dxdy { } x y +h x y xy xy dxdy h { x y xy } x y dxdy + h [ X x u x + X y u y ]dxdy xy = h ( x xu x + xy u y ) + y ( xyu x + y u y ) dxdy h { } T { }dxdy + h { X} T { u }dxdy = (c) (c)( ) 2 (c) = h [ n x ( x u x + xy u y )+ n y ( xy u x + y u y )]ds S 2 5
6 = h { n x n y } x xy u x xy y u y ds = h { n} T [ ] { u }ds (d) S S n x n y (d){} n T [ ]= {} t T (9)S u u x = u y = { u} S u (d)s S t S = S t + S u S t (d) h { n} T [ ] { u }ds = h {} t T { u }ds (e) t S (e)(c) S t h {} t T { u}ds h { } T { }dxdy + h { X} T { u }dxdy = (d) t S t (2) y x 2 6
7 x y U e x, U e y F e x, F e y {U e } T = {U x, U y, U x, U y,, U en x, U en y } (4) {F e } T = {F x, F y, F x, F y,, F en x, F en y } (5) n N I (x J, y J, z J ) = for I = J for I J (I, J =~n) (6) {U}{u} T ={u x, u y } u x u y = N N 2... N n N N 2... N n en en (7) {u} = [N]{U e } (8) u x u y 7
8 x y xy = u x u x x u y y y + u y x N x = N y N y N x N 2 x N 2 y... N 2 y N 2 x N n x N n y N n y N n x en en (9) {} = [B]{U e } (2) (3.7)(3.9){U e }{u}{} {u}{} 2 [N][B] [ N][ B] u x = A+ Bx + Cy (2) u y = + Ex + Fy (22) A F(2) x I y I (I =, 2, 3I ) U ei x U ei y A F U x = A + Bx + Cy (23) U x = A + Bx 2 + Cy 2 (24) U x = A+ Bx 3 + Cy 3 (25) U y = + Ex + Fy (26) U y = + Ex 2 + Fy 2 (27) U y = + Ex 3 + Fy 3 (28) A F(2, 22) 8
9 u x u y = N N 2 N 3 N N 2 N 3 = [ N] { U e } (29) N = 2 {(x2 y 3 x 3 y 2 ) + (y 2 y 3 )x + (x 3 x 2 )y} (3) N 2 = 2 {(x3 y x y 3 ) + (y 3 y )x + (x x 3 )y} (3) N 3 = 2 {(x y 2 x 2 y )+ (y y 2 )x + (x 2 x )y} (32) 2 = x y 2 + x 2 y 3 + x 3 y x y 3 x 2 y x 3 y 2 (29)(32) x y xy = u x u x x u y y y + u y x N x = N y N y N x N 2 x N 2 y N 2 y N 2 x N 3 x N 3 y N 3 y N 3 x = y 2 y 3 y 3 y y y 2 x 3 x 2 x x 3 x 2 x 2 x 3 x 2 y 2 y 3 x x 3 y 3 y x 2 x y y 2 = [B]{U e } (33) [ B] 9
10 h { } T { }dxdy = h { u} T { X }dxdy + h { u} T {} t ds t (34) { }= [ ] {}{} = [B]{U e } {} = [B]{U e } h {U e } T B [ ] T [ ] B [ ]{U e }dxdy { } T N = h U e { } T { X }dxdy + h U e { } T {} t ds t (35) S t S t { } T N {U e }{U e } { } T B h U e = h U e ( [ ] T [ ][ B]dxdy ) U e { } T N { } { } T { X}dxdy+ h U e { } T N { } T {} t ds t (36) (36){U e } h( [ B] T [ ][ B]dxdy ){ U e }= h { N} T { X }dxdy + h { N} T {} t ds t (37) S t S t [K e ]{ U e }= { F e } (38) [K e ]= h [ B] T [ ][ B]dxdy (39) { F e }= h N { } T { X }dxdy + h { N} T {} t ds t (4) S t [K e ]{ F e } (39)[ ] [ B]h dxdy = h [K e ]= h[ B] T [ ] [ B] (4)
11 e e e e e K K 2 K 3 K 4 K 5 K 6 e e e e e e e K 2 K 22 K 23 K 24 K 25 K 26 e e e e e e K 3 K 32 K 33 K 34 K 35 K 36 e e e e e e K 4 K 42 K 43 K 44 K 45 K 46 e e e e e e K 5 K 52 K 53 K 54 K 55 K 56 e e e e e e K 6 K 62 K 63 K 64 K 65 K 66 = F x F y F x F y F x F y (42) M N 2 N 2N K K 2 K 3 K 4... K,2N F x K 2 K 22 K 23 K K 2,2N F y K 3 K 32 K 33 K K 3,2N 2 2 F x 2 2 K 4 K 42 K 43 K K 4,2N = F y... K 2N, K 2N,2 K 2N,3 K 2N,4... K N N 2N,2N F y (43) (42) 23i j k
12 [K e ] [ K] 2i 2 2i 3 2 j 4 2 j 5 2k 6 2k (43) [ K] K i N F i x K,2i F i y K 2,2i = i (44) F N i y K 2N,2i U x i = U i x i x U i x U i i x 2i i = U i x i i x = { U} 2
13 CG { U} { U e } { U e } {}= [ B] { U e }, { }= [ ] {} (45) 3 3
14 5 FEM (AINA) AINA AINA PC b) mm mm mm 7 MPa.25 N 5.74mm 4 4(a) 5.733mm 4(b) 2.5mm STRESS-YY RST CALC TIME (a) MAXIMUM 6. MINIMUM -6. STRESS-YY RST CALC TIME (b) MAXIMUM 27.9 MINIMUM
15 STRESS-ZZ RST CALC TIME MAXIMUM MINIMUM c) 5 /
16 6
17 8 7
応力とひずみ.ppt
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9 1 9 9.1 9 2 (1) 9.1 9.2 σ a = σ Y FS σ a : σ Y : σ b = M I c = M W FS : M : I : c : = σ b
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() x + y + y + x dy dx = 0 () dy + xy = x dx y + x y ( 5) ( s55906) 0.7. (). 5 (). ( 6) ( s6590) 0.8 m n. 0.9 n n A. ( 6) ( s6590) f A (λ) = det(a λi)
0. A A = 4 IC () det A () A () x + y + z = x y z X Y Z = A x y z ( 5) ( s5590) 0. a + b + c b c () a a + b + c c a b a + b + c 0 a b c () a 0 c b b c 0 a c b a 0 0. A A = 7 5 4 5 0 ( 5) ( s5590) () A ()
x () g(x) = f(t) dt f(x), F (x) 3x () g(x) g (x) f(x), F (x) (3) h(x) = x 3x tf(t) dt.9 = {(x, y) ; x, y, x + y } f(x, y) = xy( x y). h (x) f(x), F (x
[ ] IC. f(x) = e x () f(x) f (x) () lim f(x) lim f(x) x + x (3) lim f(x) lim f(x) x + x (4) y = f(x) ( ) ( s46). < a < () a () lim a log xdx a log xdx ( ) n (3) lim log k log n n n k=.3 z = log(x + y ),
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1/5 ( ) Taylor ( 7.1) (x, y) f(x, y) f(x, y) x + y, xy, e x y,... 1 R {(x, y) x, y R} f(x, y) x y,xy e y log x,... R {(x, y, z) (x, y),z f(x, y)} R 3 z 1 (x + y ) z ax + by + c x 1 z ax + by + c y x +
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yoshi@image.med.osaka-u.ac.jp http://www.image.med.osaka-u.ac.jp/member/yoshi/ II Excel, Mathematica Mathematica Osaka Electro-Communication University (2007 Apr) 09849-31503-64015-30704-18799-390 http://www.image.med.osaka-u.ac.jp/member/yoshi/
x y x-y σ x + τ xy + X σ y B = + τ xy + Y B = S x = σ x l + τ xy m S y = σ y m + τ xy l σ x σ y τ xy X B Y B S x S y l m δu δv [ ( σx δu + τ )
1 8 6 No-tension 1. 1 1.1................................ 1 1............................................ 5.1 - [B].................................. 5................................. 6.3..........................................
1W II K =25 A (1) office(a439) (2) A4 etc. 12:00-13:30 Cafe David 1 2 TA appointment Cafe D
1W II K200 : October 6, 2004 Version : 1.2, kawahira@math.nagoa-u.ac.jp, http://www.math.nagoa-u.ac.jp/~kawahira/courses.htm TA M1, m0418c@math.nagoa-u.ac.jp TA Talor Jacobian 4 45 25 30 20 K2-1W04-00
II (10 4 ) 1. p (x, y) (a, b) ε(x, y; a, b) 0 f (x, y) f (a, b) A, B (6.5) y = b f (x, b) f (a, b) x a = A + ε(x, b; a, b) x a 2 x a 0 A = f x (
II (1 4 ) 1. p.13 1 (x, y) (a, b) ε(x, y; a, b) f (x, y) f (a, b) A, B (6.5) y = b f (x, b) f (a, b) x a = A + ε(x, b; a, b) x a x a A = f x (a, b) y x 3 3y 3 (x, y) (, ) f (x, y) = x + y (x, y) = (, )
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6. Euler x
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i 18 2H 2 + O 2 2H 2 + ( ) 3K
i 18 2H 2 + O 2 2H 2 + ( ) 3K ii 1 1 1.1.................................. 1 1.2........................................ 3 1.3......................................... 3 1.4....................................
6kg 1.1m 1.m.1m.1 l λ ϵ λ l + λ l l l dl dl + dλ ϵ dλ dl dl + dλ dl dl 3 1. JIS 1 6kg 1% 66kg 1 13 σ a1 σ m σ a1 σ m σ m σ a1 f f σ a1 σ a1 σ m f 4
35-8585 7 8 1 I I 1 1.1 6kg 1m P σ σ P 1 l l λ λ l 1.m 1 6kg 1.1m 1.m.1m.1 l λ ϵ λ l + λ l l l dl dl + dλ ϵ dλ dl dl + dλ dl dl 3 1. JIS 1 6kg 1% 66kg 1 13 σ a1 σ m σ a1 σ m σ m σ a1 f f σ a1 σ a1 σ m
66 σ σ (8.1) σ = 0 0 σd = 0 (8.2) (8.2) (8.1) E ρ d = 0... d = 0 (8.3) d 1 NN K K 8.1 d σd σd M = σd = E 2 d (8.4) ρ 2 d = I M = EI ρ 1 ρ = M EI ρ EI
65 8. K 8 8 7 8 K 6 7 8 K 6 M Q σ (6.4) M O ρ dθ D N d N 1 P Q B C (1 + ε)d M N N h 2 h 1 ( ) B (+) M 8.1: σ = E ρ (E, 1/ρ ) (8.1) 66 σ σ (8.1) σ = 0 0 σd = 0 (8.2) (8.2) (8.1) E ρ d = 0... d = 0 (8.3)
W u = u(x, t) u tt = a 2 u xx, a > 0 (1) D := {(x, t) : 0 x l, t 0} u (0, t) = 0, u (l, t) = 0, t 0 (2)
3 215 4 27 1 1 u u(x, t) u tt a 2 u xx, a > (1) D : {(x, t) : x, t } u (, t), u (, t), t (2) u(x, ) f(x), u(x, ) t 2, x (3) u(x, t) X(x)T (t) u (1) 1 T (t) a 2 T (t) X (x) X(x) α (2) T (t) αa 2 T (t) (4)
変 位 変位とは 物体中のある点が変形後に 別の点に異動したときの位置の変化で あり ベクトル量である 変位には 物体の変形の他に剛体運動 剛体変位 が含まれている 剛体変位 P(x, y, z) 平行移動と回転 P! (x + u, y + v, z + w) Q(x + d x, y + dy,
変 位 変位とは 物体中のある点が変形後に 別の点に異動したときの位置の変化で あり ベクトル量である 変位には 物体の変形の他に剛体運動 剛体変位 が含まれている 剛体変位 P(x, y, z) 平行移動と回転 P! (x + u, y + v, z + w) Q(x + d x, y + dy, z + dz) Q! (x + d x + u + du, y + dy + v + dv, z +
y π π O π x 9 s94.5 y dy dx. y = x + 3 y = x logx + 9 s9.6 z z x, z y. z = xy + y 3 z = sinx y 9 s x dx π x cos xdx 9 s93.8 a, fx = e x ax,. a =
[ ] 9 IC. dx = 3x 4y dt dy dt = x y u xt = expλt u yt λ u u t = u u u + u = xt yt 6 3. u = x, y, z = x + y + z u u 9 s9 grad u ux, y, z = c c : grad u = u x i + u y j + u k i, j, k z x, y, z grad u v =
0 1-4. 1-5. (1) + b = b +, (2) b = b, (3) + 0 =, (4) 1 =, (5) ( + b) + c = + (b + c), (6) ( b) c = (b c), (7) (b + c) = b + c, (8) ( + b)c = c + bc (9
1-1. 1, 2, 3, 4, 5, 6, 7,, 100,, 1000, n, m m m n n 0 n, m m n 1-2. 0 m n m n 0 2 = 1.41421356 π = 3.141516 1-3. 1 0 1-4. 1-5. (1) + b = b +, (2) b = b, (3) + 0 =, (4) 1 =, (5) ( + b) + c = + (b + c),
III No (i) (ii) (iii) (iv) (v) (vi) x 2 3xy + 2 lim. (x,y) (1,0) x 2 + y 2 lim (x,y) (0,0) lim (x,y) (0,0) lim (x,y) (0,0) 5x 2 y x 2 + y 2. xy x2 + y
III No (i) (ii) (iii) (iv) (v) (vi) x 2 3xy + 2. (x,y) (1,0) x 2 + y 2 5x 2 y x 2 + y 2. xy x2 + y 2. 2x + y 3 x 2 + y 2 + 5. sin(x 2 + y 2 ). x 2 + y 2 sin(x 2 y + xy 2 ). xy (i) (ii) (iii) 2xy x 2 +
ac b 0 r = r a 0 b 0 y 0 cy 0 ac b 0 f(, y) = a + by + cy ac b = 0 1 ac b = 0 z = f(, y) f(, y) 1 a, b, c 0 a 0 f(, y) = a ( ( + b ) ) a y ac b + a y
01 4 17 1.. y f(, y) = a + by + cy + p + qy + r a, b, c 0 y b b 1 z = f(, y) z = a + by + cy z = p + qy + r (, y) z = p + qy + r 1 y = + + 1 y = y = + 1 6 + + 1 ( = + 1 ) + 7 4 16 y y y + = O O O y = y
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240-8501 79-2 Email: nakamoto@ynu.ac.jp 1 3 1.1...................................... 3 1.2?................................. 6 1.3..................................... 8 1.4.......................................
( ) sin 1 x, cos 1 x, tan 1 x sin x, cos x, tan x, arcsin x, arccos x, arctan x. π 2 sin 1 x π 2, 0 cos 1 x π, π 2 < tan 1 x < π 2 1 (1) (
6 20 ( ) sin, cos, tan sin, cos, tan, arcsin, arccos, arctan. π 2 sin π 2, 0 cos π, π 2 < tan < π 2 () ( 2 2 lim 2 ( 2 ) ) 2 = 3 sin (2) lim 5 0 = 2 2 0 0 2 2 3 3 4 5 5 2 5 6 3 5 7 4 5 8 4 9 3 4 a 3 b
5. [1 ] 1 [], u(x, t) t c u(x, t) x (5.3) ξ x + ct, η x ct (5.4),u(x, t) ξ, η u(ξ, η), ξ t,, ( u(ξ,η) ξ η u(x, t) t ) u(x, t) { ( u(ξ, η) c t ξ ξ { (
![5. [1 ] 1 [], u(x, t) t c u(x, t) x (5.3) ξ x + ct, η x ct (5.4),u(x, t) ξ, η u(ξ, η), ξ t,, ( u(ξ,η) ξ η u(x, t) t ) u(x, t) { ( u(ξ, η) c t ξ ξ { (](/thumbs/92/107866626.jpg "5. [1 ] 1 [], u(x, t) t c u(x, t) x (5.3) ξ x + ct, η x ct (5.4),u(x, t) ξ, η u(ξ, η), ξ t,, ( u(ξ,η) ξ η u(x, t) t ) u(x, t) { ( u(ξ, η) c t ξ ξ { (")
5 5.1 [ ] ) d f(t) + a d f(t) + bf(t) : f(t) 1 dt dt ) u(x, t) c u(x, t) : u(x, t) t x : ( ) ) 1 : y + ay, : y + ay + by : ( ) 1 ) : y + ay, : yy + ay 3 ( ): ( ) ) : y + ay, : y + ay b [],,, [ ] au xx
Acrobat Distiller, Job 128
(2 ) 2 < > ( ) f x (x, y) 2x 3+y f y (x, y) x 2y +2 f(3, 2) f x (3, 2) 5 f y (3, 2) L y 2 z 5x 5 ` x 3 z y 2 2 2 < > (2 ) f(, 2) 7 f x (x, y) 2x y f x (, 2),f y (x, y) x +4y,f y (, 2) 7 z (x ) + 7(y 2)
( ) x y f(x, y) = ax
013 4 16 5 54 (03-5465-7040) nkiyono@mail.ecc.u-okyo.ac.jp hp://lecure.ecc.u-okyo.ac.jp/~nkiyono/inde.hml 1.. y f(, y) = a + by + cy + p + qy + r a, b, c 0 y b b 1 z = f(, y) z = a + by + cy z = p + qy
. p.1/14
. p.1/14 F(x,y) = (F 1 (x,y),f 2 (x,y)) (x,y). p.2/14 F(x,y) = (F 1 (x,y),f 2 (x,y)) (x,y) (x,y) h. p.2/14 F(x,y) = (F 1 (x,y),f 2 (x,y)) (x,y) (x,y) h h { F 2 (x+ h,y) F 2 2(x h,y) F 2 1(x,y+ h)+f 2 1(x,y
II No.01 [n/2] [1]H n (x) H n (x) = ( 1) r n! r!(n 2r)! (2x)n 2r. r=0 [2]H n (x) n,, H n ( x) = ( 1) n H n (x). [3] H n (x) = ( 1) n dn x2 e dx n e x2
![II No.01 [n/2] [1]H n (x) H n (x) = ( 1) r n! r!(n 2r)! (2x)n 2r. r=0 [2]H n (x) n,, H n ( x) = ( 1) n H n (x). [3] H n (x) = ( 1) n dn x2 e dx n e x2](/thumbs/101/149159646.jpg "II No.01 [n/2] [1]H n (x) H n (x) = ( 1) r n! r!(n 2r)! (2x)n 2r. r=0 [2]H n (x) n,, H n ( x) = ( 1) n H n (x). [3] H n (x) = ( 1) n dn x2 e dx n e x2")
II No.1 [n/] [1]H n x) H n x) = 1) r n! r!n r)! x)n r r= []H n x) n,, H n x) = 1) n H n x) [3] H n x) = 1) n dn x e dx n e x [4] H n+1 x) = xh n x) nh n 1 x) ) d dx x H n x) = H n+1 x) d dx H nx) = nh
B line of mgnetic induction AB MN ds df (7.1) (7.3) (8.1) df = µ 0 ds, df = ds B = B ds 2π A B P P O s s Q PQ R QP AB θ 0 <θ<π
8 Biot-Svt Ampèe Biot-Svt 8.1 Biot-Svt 8.1.1 Ampèe B B B = µ 0 2π. (8.1) B N df B ds A M 8.1: Ampèe 107 108 8 0 B line of mgnetic induction 8.1 8.1 AB MN ds df (7.1) (7.3) (8.1) df = µ 0 ds, df = ds B
(u(x)v(x)) = u (x)v(x) + u(x)v (x) ( ) u(x) = u (x)v(x) u(x)v (x) v(x) v(x) 2 y = g(t), t = f(x) y = g(f(x)) dy dx dy dx = dy dt dt dx., y, f, g y = f (g(x))g (x). ( (f(g(x)). ). [ ] y = e ax+b (a, b )
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