学生は、物理学Aで習得した質点と剛体の力学に加えて、場の概念と、偏微分による記述法を学ぶ。
1.力学的波動
2.調和波と波のエネルギー
3.弦の振動と波動方程式
4.波の重ねあわせと定在波
5.水面や膜面を伝わる波-空中を伝わる波
6.弾性体の応力と変形
7.Hookeの法則
8.弾性エネルギー
9.弾性体中の音波
10.流体の密度と圧力-浮力
11.表面張力と表面エネルギー
12.流線と連続 の方程式-Bernoulliの定理
13.粘性と抵抗
14.渦と乱流
Students lean the concept of place and the description method by partial differentiation in addition to mass points acknowledged in physics A and rigid body dynamics.
1. Mechanical wave
2. Harmonic wave and energy of wave
3. String vibration and wave equation
4. Wave superposition and standing wave
5. Wave goes through water and membrane surface - wave travels the air
6. Elastic body's practical power and deformation
7.Hook's law
8. Elastic energy
9. Sound wave in the elastic body
10. Fluid density and pressure - buoyancy
11. Surface tension and surface energy
12. Streamline and continuum equation - Bernoulli 's thえおれm
13. Viscosity and resistance
14. Vortex and turbulence
均一相における酸塩基、錯生成、酸化還元などの無機化学反応に対する平衡定数、化学種の分布、およびその計算法を学ぶ。また、多相にわたる平衡関係を学び、相間の分配や物質移動などの基礎的事項と地球における物質の分布や素材の創製との関連について考察する。
Students lean about equilibrium constant of inorganic chemical reactions such as acid-base, complex formation and oxidation-reduction in uniform phase and their calculation methods. In addition, they learn about equilibrium relationship in multi-phases and examine about basic items such as distribution of phases and mass transfer and the relevance between material distribution in the earth and creation of materials.
1.地球と生物活動
2.水圏環境と水の性質
3.酸性度の概念
4.酸塩基平衡の取り扱い
5.雨水のpHと海水のpH
6.金属錯体の形成
7.錯生成平衡の取り扱い
8.多相間の平衡
9.酸化還元反応の特徴
10.平衡の取り扱い:pE/pH図
11.環境中の鉄の移行
12.溶解平衡と溶解度
13.環境中のコロイド
14.相間の分配、物質移動
15.まとめ
1. The earth and biological activities
2. Aquatic Environment and the nature of water
3. Concept of the acidity
4.Handling of acid-base equilibrium
5. ph of the seawater and rainwater
6. Formation of metal complexes
7. Handling of complex formation equilibrium
8. Equilibrim between multiphases
9. Features of the oxidation-reduction reaction
10. Handling of equiliburim :Pe/Ph Figure
1 1. Migration of iron in environment
1 2. Dissolution equilibrium and solubility
1 3. Colloidal in environment
1 4. Distributionphase between multi-phases and material transfer
1 5. Conclusion
機械工学、化学工学、電子工学、環境保全などの幅広い工学分野においてエネルギーを取り扱う際の基本となる、伝熱学について学ぶ。温度差によるエネルギー移動現象の理解を目的として、メカニズムの異なる伝熱現象の基礎式とその応用となる数理解法を、具体的な演習を通して修得する。
基本的な伝熱のメカニズムである熱伝導、対流、放射について、物理現象と工学設計との関わりを含めて学ぶ。伝熱に関わる無次元数を整理するとともに、相変化を伴う熱伝達、熱交換器設計への伝熱学の応用について修得する。
Learn about heat transfer which become the basis when to handle with energy in a wide range of such as mechanical engineering, chemical engineering, electronic engineering and environment conservation. To aim at understanding energy transfer by different temperature, we learn basic equation of mechanically different heat transfer phenomenon and numerical understanding method heat transfer through concrete practices.
As for heat transfer, convection and radiation which are basic heat transfer mechanism, we learn them including connection to physical phenomena and engineering design. As well as arranging dimensionless numbers related with heat transfer, we learn about heat transfer's practical use for heat transfer with phase change and heat exchange design.
