--- author: Alvie Rahman date: \today tags: - uni - nottingham - mmme1028 - maths - statics - dynamics title: MMME 1028 // Statics and Dynamics --- # Lecture L1.1, L1.2 ### Lecture L1.1 Exercises Can be found [here](./lecture_exercises/mmme1028_l1.1_exercises_2021-09-30.pdf). ### Lecture L1.2 Exercises Can be found here [here](./lecture_exercises/mmme1028_l1.2_exercises_2021-10-04.pdf) ## Newton's Laws 1. Remains at constant velocity unless acted on by external force 2. Sum of forces on body is equal to mass of body multiplied by acceleration > 1st Law is a special case of 2nd 3. When one body exerts a force on another, 2nd body exerts force simultaneously of equal magnitude and opposite direction ## Equilibrium - Body is in equilibrium if sum of all forces and moments acting on body are 0 ### Example Determine force $F$ and $x$ so that the body is in equilibrium. ![](./images/vimscrot-2021-10-04T09:14:41,378027532+01:00.png) 1. Check horizontal equilibrium $\sum{F_x} = 0$ 2. Check vertical equilibrium $\sum{F_y} = 8 - 8 + F = 0$ $F = 2$ 3. Take moments about any point $\sum{M(A)} = 8\times{}2 - F(2+x) = 0$ $F(2+x) = 16)$ $x = 6$ ## Free Body Diagrams A free body diagram is a diagram of a single (free) body which shows all the external forces acting on the body. Where there are several bodies or subcomponents interacting as a complex system, each body is drawn separately: ![](./images/vimscrot-2021-10-04T09:23:03,892292648+01:00.png) ## Friction - Arises between rough surfaces and always acts at right angles to the normal reaction force ($R$) in the direction to resist motion. - The maximum value of friction $F$ is $F_{max} = \mu{}R$, where $\mu{}$ is the friction coefficient - $F_{max}$ is also known as the point of slip ## Reactions at Supports There are three kinds of supports frequently encountered in engineering problems: ![](./images/vimscrot-2021-10-04T09:41:56,080077960+01:00.png) ## Principle of Force Transmissibility A force can be move dalong line of action without affecting equilibrium of the body which it acts on: ![](./images/vimscrot-2021-10-04T09:43:04,689667620+01:00.png) This principle can be useful in determining moments. ## Two-Force Bodies - If a body has only 2 forces, then the forces must be collinear, equal, and opposite: ![](./images/vimscrot-2021-10-04T09:44:05,581697277+01:00.png) > The forces must be collinear so a moment is not created ## Three-Force Bodies - If a body in equilibrium has only three forces acting on it, then the lines of actions must go through one point: ![](./images/vimscrot-2021-10-04T09:55:59,773394306+01:00.png) > This is also to not create a moment - The forces must form a closed triangle ($\sum{F} = 0$) ## Naming Conventions | Term | Meaning | |----------------------|----------------------------------------------------------| | light | no mass | | heavy | body has mass | | smooth | there is no friction | | rough | contact has friction | | at the point of slip | one tangential reaction is $F_{max}$ | | roller | a support only creating normal reaction | | rigid pin | a support only providing normal and tangential reactions | | built-in | a support proviting two reaction components and a moment | ## Tips to Solve (Difficult) Problems 1. Make good quality clear and big sketches 2. Label all forces, dimensions, relevant points 3. Explain and show your thought process---write complete equations 4. Follow standard conventions in equations and sketches 5. Solve everything symbolically (algebraicly) until the end 6. Check your answers make sense 7. Don't forget the units