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Mechanical Physics Set

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Intended for experimental study, physics laboratory and carrying out physics experiments on: Metrology. Significant digits and uncertainty. Kinematics. Reference frame, position, movement and trajectory. Uniform rectilinear motion, MRU. Uniformly varied rectilinear motion, MRUV. Range, uncertainty and speed in a horizontal launch. ...horizontal launch of a projectile from its launch speed. Determination of the impact speed, from the measurement of the horizontal launch speed. ...impact speed. ... Oblique launches with different flight times and initial speeds, keeping the angle constant. The maximum height in an oblique launch of a projectile. Oblique launch, the range as a function of the launch angle. The free fall movement with a test specimen of 10 equal intervals. Free fall movement with a sphere. The principle of conservation of mechanical energy. The acceleration in an MRUV in the Atwood machine. Dynamics. The fundamental law of dynamics, Newton's second law. Friction forces and Newton's first law of motion. The equilibrium condition of a mobile on an inclined plane. Determination of the mechanical advantage of the inclined plane, a simple machine. Hooke's law in a helical spring. Association of helical springs. Understanding the fixed pulley and the movable pulley, simple machine. The exponential pulley. The parallel block. The characteristic curve of the elongation of a helical spring and a rubber belt, elastic hysteresis. Hooke's law in a helical spring. The centripetal force as a function of mass, as a function of the radius of the trajectory, as a function of frequency, as a function of angular velocity and as a function of mass, tangential velocity and radius in a MCU. Statics. Mass, weight and determination of the value of local g. The composition and decomposition of concurrent coplanar forces. The equilibrium conditions of the rigid body, Varignon's theorem. The conditions of stable, unstable and indifferent static equilibrium for a supported spherical rigid body. The equilibrium conditions for a suspended rigid body. Conservation of Energy. The principle of conservation of mechanical energy. Work and energy in a system of oscillating mass and spring. Vertical and oblique launch. Conservation of momentum, kinetic energy and coefficient of restitution in an elastic and inelastic collision. Mechanical work, potential energy and kinetic energy. Momentum. Discussing the conservation of mechanical energy in a loop. The Magdeburg hemispheres experiment and atmospheric pressure. Hydrostatics. The hydrostatic buoyancy force, a quantity with direction, sense and module (value). Archimedes' principle and buoyancy. Pascal's principle, the hydraulic elevator. The free surfaces of a liquid inside communicating vessels. Stevin's principle. The density of a liquid as a function of the known density of another liquid. Determining the density of a solid in steel, through buoyancy. Determining the density of an irregular solid through buoyancy. The fall in a viscous medium, Stokes' law, Reynolds number. Wave. The Laws of the Simple Pendulum. Dynamic determination of the spring constant in a mass-and-spring oscillator. The relationship between the period and the square root of the length of the pendulum. Dynamic determination of the spring constant of a helical spring. The SHM in an oscillating mass-and-helical spring system. Laws of the Simple Pendulum. Observing the oscillating motion, SHM, in a mass-and-helical spring system. Dynamic determination of the spring constant in an oscillating mass-and-helical spring system, SHM. Determination of the spring constant of a mass-and-spring system, SHM. Properties of materials. Determining the density of a liquid using an aerometer, etc.

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DetalhesDetails
Detalhes com Principais ExperimentosDetails with the main experiments

Key Experiments

  • » Significant figures and uncertainty. - 1032.003_1
  • » Reference, position, movement and trajectory. - 1032.001
  • » The rectilinear and uniform motion, MRU, air track. - 1032.005_0C
  • » Uniformly varied rectilinear motion, MRUV, air track. - 1032.007_0C
  • » Range, uncertainty and velocity in a horizontal launch. - 1032.064_1A
  • » The range of a horizontal projectile launch from its launch velocity. - 1032.064_2A_1
  • » Determination of impact velocity from measurement of horizontal launch velocity. - 1032.068_2A_1
  • » Horizontal launch, range, uncertainty and impact velocity. - 1032.064A
  • » The range in an oblique throw, digital multitimer. - 1032.064F1
  • » Oblique launches with different flight times and initial speeds, keeping the angle constant. - 1032.064F2
  • » Maximum height at oblique launch of projectile, sensors. - 1032.064F3
  • » Oblique launch, range as a function of launch angle, sensors. - 1032.064F4
  • » Free fall motion with a test specimen of 10 equal intervals. - 1032.010K1
  • » Free fall movement with sphere and sensors. - 1032.010K1_1
  • » The principle of conservation of mechanical energy. - 1032.010K3_2
  • » Acceleration in a MRUV on the Atwood machine, neglecting the pulley's moment of inertia. - 1032.014_C2
  • » Acceleration in a MRUV on the Atwood machine, considering the moment of inertia of the pulley. - 1032.014_D2
  • » The fundamental law of dynamics, Newton's second law. - 1032.079_C
  • » Frictional forces and Newton's first law of motion. - 1032.046
  • » The equilibrium condition of a mobile on an inclined plane. - 1032.034AB1B
  • » Determination of the mechanical advantage of an inclined plane, a simple machine. - 1032.034AB2B
  • » Hooke's law on a helical spring. - 1032.052B_1
  • » Association of helical springs in series. - 1032.053B_1
  • » Association of coil springs in parallel. - 1032.053C_1
  • » Getting to know the fixed pulley, a simple machine. - 1032.026A_2
  • » Getting to know the mobile pulley, a simple machine. - 1032.027A_2
  • » The exponential hoist, a simple machine. - 1032.030A_2
  • » The parallel notebook, a simple machine. - 1032.031_2
  • » The characteristic curve of elongation of a coil spring and a rubber belt, elastic hysteresis - 1032.022A_2
  • » Hooke's law on a helical spring. - 1032.052A_2
  • » The association of coil springs in series. - 1032.053_2
  • » The association of coil springs in parallel. - 1032.053A_2
  • » The helical spring and Hooke's law. - 1032.052B_3B
  • » Association of helical springs in series. - 1032.053B_3B
  • » Association of coil springs in parallel. - 1032.053C_3B
  • » Centripetal force as a function of mass. - 1032.060A_4
  • » Centripetal force as a function of the radius of the trajectory. - 1032.060A_5
  • » Centripetal force as a function of frequency. - 1032.060C3
  • » Centripetal force as a function of angular velocity, sensor. - 1032.060C2
  • » Centripetal force as a function of mass, tangential velocity and radius in an MCU, with sensor and multitimer. - 1032.060C1
  • » Mass, weight and determination of the local g value. - 1032.039_1
  • » The simple machine called a fixed pulley - 1032.026_1
  • » The simple machine called a movable pulley. - 1032.026_2
  • » The composition and decomposition of concurrent coplanar forces. - 1032.040F_1
  • » The equilibrium conditions of a rigid body, Varignon's theorem. - 1032.035F_1
  • » The conditions of stable, unstable and indifferent static equilibrium for a supported spherical rigid body. - 1032.051_1
  • » The equilibrium conditions for a suspended rigid body. - 1032.050_1
  • » The principle of conservation of mechanical energy in a falling cylinder. - 1032.010K3_1
  • » The principle of conservation of mechanical energy in a falling sphere. - 1032.010K5A
  • » Work and energy exchanges in an oscillating mass and spring system. - 1032.056B_1
  • » Determination of maximum height in a vertical launch from conservation of mechanical energy. - 1032.064F5A
  • » Vertical launch, maximum height and conservation of mechanical energy, sensor. - 1032.064F5
  • » Measuring the initial velocity in an oblique throw and determining the maximum height by conservation of mechanical energy. - 1032.064F6
  • » Conservation of momentum, kinetic energy and coefficient of restitution in an elastic collision. - 1032.064F7
  • » Work and energy in a system of mass and oscillating helical spring, conservation of mechanical energy. - 1032.056B_3B
  • » Mechanical work, potential energy and kinetic energy in a mass and helical spring system. - 1032.056A_2
  • » The amount of horizontal movement of a sphere in a horizontal throw. - 1032.076_2C
  • » Determining the minimum launch height to complete the loop - 1032.110B
  • » Determining and discussing the conservation of mechanical energy in a loop, not considering the rotation of the sphere. - 1032.110B3
  • » Determining and discussing the conservation of mechanical energy in a loop, considering the rotation of the sphere. - 1032.110B4
  • » Coefficient of restitution, momentum and kinetic energy in an inelastic collision. - 1032.077_C
  • » Coefficient of restitution, momentum and kinetic energy in an elastic collision. - 1032.078_C
  • » The Magdeburg Hemisphere Experiment and Atmospheric Pressure. - 1032.093
  • » The hydrostatic buoyant force, a quantity with direction, sense and module value. - 1042.028A_2
  • » Archimedes' principle, buoyancy and its relation to the volume and density of the displaced liquid. - 1042.032A_2
  • » Pascal's principle, the hydraulic elevator. - 1042.026C
  • » The free surfaces of a liquid within open, noncapillary, communicating vessels. - 1042.004D
  • » The pressure at a point in a liquid in equilibrium, Stevin's principle. - 1042.008C
  • » The density of a liquid as a function of the known density of another liquid, immiscible liquids. - 1042.020C
  • » The hydrostatic buoyant force, a quantity with direction, sense and module value. - 1042.028D
  • » Archimedes' principle, buoyancy and its relation to the volume and density of the displaced liquid - 1042.032D
  • » Determining the density of a steel solid by buoyancy. - 1042.032D1
  • » Determining the density of a brass solid by buoyancy. - 1042.032D2
  • » Determining the density of an aluminum solid by buoyancy. - 1042.032D3
  • » Determining the density of an irregular solid by buoyancy. - 1042.032D5
  • » Falling in a viscous medium, Stokes' law, Reynolds number - 1032.005_50C
  • » The Laws of the Simple Pendulum. - 1032.013_3
  • » The relationship between a pendulum's period, length, and acceleration due to gravity. - 1032.013_4
  • » Dynamic determination of the spring constant in a mass-spring oscillator. - 1032.012_4
  • » The relationship between the period and the square root of the length of the pendulum. - 1032.015A2
  • » Dynamic determination of the spring constant of a helical spring. - 1032.012_5
  • » The SHM in an oscillating mass and coil spring system. - 1072.008B_3B
  • » Laws of the simple pendulum. - 1032.013_2C
  • » Observing the oscillating motion, MHS, in a mass and helical spring system. - 1072.008A_2
  • » Dynamic determination of the spring constant in an oscillating system of mass and helical spring, MHS. - 1032.012A_2
  • » Determination of the spring constant of a mass and spring system, SHM. - 1072.008C
  • » Determining the density of a liquid using an aerometer. - 1042.036_2AK
  • » Resolution: Reference, position, movement and trajectory. - 1032.001_R
  • » Resolution: Range, uncertainty and speed in a horizontal launch. - 1032.064_1A_R
  • » Resolution: The range of a horizontal projectile launch from its launch velocity. - 1032.064_2A_1_R
  • » Resolution: Determination of impact velocity from the measurement of horizontal launch velocity. - 1032.068_2A_1_R
  • » Resolution: Horizontal launch, range, uncertainty and impact velocity. - 1032.064A_R
  • » Resolution: The range at an oblique launch, sensors. - 1032.064F1_R
  • » Resolution: Oblique launches with different flight times, different initial speeds, keeping the angle constant, sensors - 1032.064F2_R
  • » Resolution: Maximum height at oblique launch of projectile, sensors. - 1032.064F3_R
  • » Resolution: Oblique launch, range as a function of launch angle, sensors. - 1032.064F4_R
  • » Resolution: Free fall motion with a test specimen of 10 equal intervals. - 1032.010K1_R
  • » Resolution: Acceleration in a MRUV, disregarding the pulley's moment of inertia. - 1032.014_C2_R
  • » Resolution: Acceleration in a MRUV, considering the pulley's moment of inertia. - 1032.014_D2_R
  • » Resolution: Friction forces and Newton's first law of motion. - 1032.046_R
  • » Resolution: The equilibrium condition of a mobile on an inclined plane. - 1032.034AB1B_R
  • » Resolution:Determination of the mechanical advantage of the inclined plane, a simple machine II. - 1032.034AB2B_R
  • » Resolution: Hooke's law on a helical spring. - 1032.052B_1_R
  • » Resolution: Association of helical springs in series. - 1032.053B_1_R
  • » Resolution: Association of helical springs in parallel. - 1032.053C_1_R
  • » Resolution: Knowing the fixed pulley. - 1032.026A_2_R
  • » Resolution: Understanding the mobile pulley. - 1032.027A_2_R
  • » Resolution: The exponential slope. - 1032.030A_2_R
  • » Resolution: The parallel notebook. - 1032.031_2_R
  • » Resolution: The characteristic curve of the elongation of a helical spring and a rubber belt, elastic hysteresis. - 1032.022A_2_R
  • » Resolution: Hooke's law on a helical spring. - 1032.052A_2_R
  • » Resolution: The association of helical springs in series. - 1032.053_2_R
  • » Resolution: The association of helical springs in parallel. - 1032.053A_2_R
  • » Resolution: Centripetal force as a function of mass. - 1032.060A_4_R
  • » Resolution: Centripetal force as a function of the radius of the trajectory. - 1032.060A_5_R
  • » Resolution: Centripetal force as a function of frequency with sensor and multitimer. - 1032.060C3_R
  • » Resolution: Centripetal force as a function of angular velocity with sensor and multitimer. - 1032.060C2_R
  • » Resolution: Centripetal force as a function of mass, tangential velocity and radius in an MCU, with sensor and multitimer. - 1032.060C1_R
  • » Resolution: Mass, weight and determination of the local g value. - 1032.039_1_R
  • » Resolution: The simple machine called a fixed pulley - 1032.026_1_R
  • » Resolution: The simple machine called a movable pulley. - 1032.026_2_R
  • » Resolution: The composition and decomposition of concurrent coplanar forces. - 1032.040F_1_R
  • » Resolution: Rigid body equilibrium conditions, Varignon's theorem. - 1032.035F_1_R
  • » Resolution: Conditions of stable, unstable and indifferent static equilibrium for a supported spherical body. - 1032.051_1_R
  • » Resolution: The equilibrium conditions for a suspended rigid body. - 1032.050_1_R
  • » Resolution: The principle of conservation of mechanical energy in a falling cylinder. - 1032.010K3_1_R
  • » Resolution: The principle of conservation of mechanical energy in a falling sphere. - 1032.010K5A_R
  • » Resolution: Work and energy in a mass and helical spring system. - 1032.056B_1_R
  • » Resolution: Vertical launch, maximum height through conservation of mechanical energy, sensor. - 1032.064F5A_R
  • » Resolution: Vertical launch, maximum height and conservation of mechanical energy, sensor. - 1032.064F5_R
  • » Resolution: Maximum height by conservation of mechanical energy, oblique launch, sensors. - 1032.064F6_R
  • » Resolution: Conservation of momentum, kinetic energy and coefficient of restitution in an elastic collision. - 1032.064F7_R
  • » Resolution: Work and mechanical energy in a mass and helical spring system. - 1032.056A_2_R
  • » Resolution: The amount of horizontal movement of a ball in a horizontal throw. - 1032.076_2C_R
  • » Resolution: Determining the minimum launch height to complete the loop - 1032.110B_R
  • » Resolution: Discussing the conservation of mechanical energy in a loop, disregarding the rotational motion of the sphere. - 1032.110B3_R
  • » Resolution: Discussing the conservation of mechanical energy in a loop, considering the rotational motion of the sphere. - 1032.110B4_R
  • » Resolution: The hydrostatic buoyant force, a quantity with direction, sense and module value. - 1042.028A_2_R
  • » Resolution: Archimedes' principle, buoyancy and its relation to the volume and density of the displaced liquid - 1042.032A_2_R
  • » Resolution: Falling in a viscous medium, Stokes' law, Reynolds number, 5 sensors, 2 tubes. - 1032.005_50C_R
  • » Resolution: The Laws of the Simple Pendulum. - 1032.013_3_R
  • » Resolution: The relationship between the period and the length of a pendulum, acceleration of gravity. - 1032.013_4_R
  • » Resolution: Dynamic determination of the spring constant in a mass-spring oscillator. - 1032.012_4_R
  • » Resolution: Laws of the simple pendulum. - 1032.013_2C_R
  • » Resolution: Observing the oscillating motion of the mass in a mass and helical spring system. - 1072.008A_2_R
  • » Resolution: Dynamic determination of the spring constant in an oscillating system of mass and helical spring - MHS. - 1032.012A_2_R

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