Exercícios - Transporte de Calor

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Nome: César Fernando Souza Savioli RGM:        30200351[pic 43][pic 44][pic 45][pic 46][pic 47][pic 48][pic 49][pic 50][pic 51][pic 52]

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Dados - Condições de Contorno:

𝑊𝑛 =[pic 89]

𝑊𝑛 = 2𝜋 𝑓𝑛

K = m . 𝑊𝑛²

Frequencia Natural →[pic 90]

𝑊𝑛 = 2𝜋 𝑓𝑛        →

𝑊𝑛 = 2𝜋 10

→ Wn = 20𝜋 rad/s

𝑊𝑛 =[pic 91]

→        2 = 𝐾

𝑚[pic 92][pic 93]

→   𝐾 = 𝑚.        2

Temos que, a frequência natural é alterada em 45% (a diferença):

0,55. 𝑊𝑛 =[pic 94]

2 =

→   0,55.20𝜋 =        𝑚[pic 95][pic 96][pic 97]

2 =        1000 +[pic 98][pic 99][pic 100]

𝑚

2 = (20𝜋)² . m

Para calcular o K, temos:

K = m . 𝑊𝑛²        → K = 0,281 . 62,832²

[pic 101]

𝑊𝑛 =[pic 102]

Cc = 𝑊𝑛 . 2𝑚

𝜁 =

𝐶

[pic 103]

[pic 104]

𝐶𝑐

1. Constante de amortecimento crítica (Cc)

𝐶𝑐

C =[pic 105]

2

𝑊𝑑 =

𝛿 = ln[pic 106][pic 107][pic 108]

𝑋1

[pic 109]

𝑋2

𝑊𝑛

Cc = 𝑊𝑛 . 2𝑚

→        Cc =

. 2𝑚

→        Cc =

. 2 . 50

1. Frequência natural amortecida

𝐶𝑐

C =[pic 110]

2

𝐶

[pic 111]

500

C = 500

𝑊𝑑 =

𝑊𝑛[pic 112]

→ 𝑊𝑑 =

𝜁 =[pic 113]

[pic 114]

𝐶𝑐[pic 115]

→ 𝜁 =

[pic 116]

1.000

→   𝜁

= 0,5

𝑊𝑑 =[pic 117][pic 118]

B) Constante de amortecimento crítica

𝑋1

𝛿 = ln        →[pic 119]

𝑋2

8

𝛿 = ln[pic 120]

6

...