Physics master unit with hydrodynamics, sensors and software

Function

Intended for experimental study, physics laboratory and carrying out physics experiments on: movements and trajectories, scalar and vector quantities, MRU, MRUV, free fall, projectile launches, MCU, centripetal force, MHS, pendulum motion, damped MH, collisions, momentum, Newton's laws, forces, retropropulsion, Varignon's theorem, levers, gears, pulleys, belts and their combinations, conservation of mechanical energy, ballistic pendulum, moment of inertia, center of oscillation of physical pendulums, transmission and propagation of heat, heat capacity, specific heat, water equivalent, dimensional change as a function of temperature, thermal comfort, black body, thermal radiation, one-dimensional, two-dimensional and three-dimensional waves, parameters associated with the wave, Kepler's laws of planetary motion, mass-helical spring system, Hooke's law, elastic torsional constant, sound, noise, parameters of a sound wave, reverberation, beat, resonance in sound tubes, speed sound, Doppler effect, geometric and physical optics, Young's interference, continuous spectrum, polarization, color composition, electrical phenomena, discharge in gases under atmospheric pressure, configurations of lines of force, equipotential surfaces, electrostatic shielding, magnetism, magnetic spectrum, DC electric motor, Oersted experiment, electromagnetic phenomena, electric transformer, Faraday and Lenz's law, electrical associations, Kirchhoff's laws, atmospheric pressure, electric discharges in gases, hydrostatics, Pascal's principle, Archimedes' principle, Stevin's principle, flow, Reynolds number, suction-pressing hydraulic pump, hydraulic press, colors by light addition, Boyle-Mariotte's law and Planck's constant.

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Details

Details with the main experiments

Key Experiments

» Significant figures and uncertainties. - 1032.003_0
» Kepler's laws of planetary motion. - 1072.003
» The relativity of motion according to the reference frame. - 1032.002
» What are the characteristics of MRU? - 1032.005B1
» The meeting of two pieces of furniture in MRU with opposite directions. - 1032.005C1
» The MRUV and its characteristics, displacement in one dimension. - 1032.006_D
» Free fall motion with a test specimen of 10 equal intervals. - 1032.010K1
» Free fall motion with test specimens from 10 different intervals. - 1032.010K4
» Horizontal launch, range, uncertainty and impact velocity. - 1032.064A
» The launch speed from range, at a 45 degree launch. - 1032.064A1
» The range of a projectile, while maintaining its initial velocity, as a function of the angle of launch. - 1032.064A4
» Range as a function of initial velocity, for the same launch angle. - 1032.064A2
» The MCU, uniform circumferential motion. - 1032.060_1
» The MCU and its characteristics. - 1032.060B
» Couplings of different pulleys per belt - 1032.041C_0
» Coupling of pulleys by belt and gears. - 1032.041C
» Coupling between several gears. - 1032.041C_2
» The balance of a piece of furniture on a low-friction ramp. - 1032.004
» The equilibrium conditions of a mobile on an inclined plane. - 1032.043
» The composition of concurrent coplanar forces, 90° apart. - 1032.040F1
» The composition of concurrent coplanar forces, with 60 - 1032.040F2
» The composition of concurrent coplanar forces at 120° to each other. - 1032.040F
» The composition of concurrent coplanar forces. - 1032.040F_0
» The equilibrium conditions of a rigid body, Varignon's theorem. - 1032.035F
» Rigid body equilibrium, the interfixed lever, Varignon's theorem. - 1032.035AF
» Equilibrium of a rigid body, the inter-resisting lever, Varignon's theorem. - 1032.035BF
» Equilibrium of a rigid body applied, the interpotent lever, Varignon's theorem. - 1032.035CF
» Coplanar vectors, their properties and operations. - 1032.036A
» Some of the quantities of dynamics represented by vectors. - 1032.036B
» The fixed pulley and its mechanical advantage. - 1032.026AF
» The movable pulley and its mechanical advantage. - 1032.027AF
» The exponential hoist and its mechanical advantage. - 1032.030AF
» The parallel block and its mechanical advantage. - 1032.031F
» Hooke's law and the spring constant of a helical spring, restoring force of a spring. - 1032.052AF
» Hooke's Law, the spring constant in a series combination of helical springs. - 1032.052AF_1
» Hooke's Law, spring constant in a parallel association of helical springs. - 1032.052AF_2
» Experimental determination of the mechanical advantage of the movable pulley. - 1032.027H
» Experimental determination of the mechanical advantage of the movable pulley. - 1032.027G
» Relationship between mass and weight, graph, function and value of local g. - 1032.039
» Exploring the laws of dynamics with the retro-propulsion car - 1032.086
» Under constant force, the average speed depends on the mass transported. - 1032.087
» The fundamental law of dynamics, Newton's second law, force and acceleration. - 1032.079_A1A
» Centripetal force as a function of angular velocity, keeping m and R constant, sensor. - 1032.060A3
» Centripetal force as a function of frequency. - 1032.060C3
» Centripetal force as a function of mass. - 1032.060A_4
» Centripetal force as a function of the radius of the trajectory. - 1032.060A_5
» A freight elevator system with fixed pulleys and platform. - 1032.040E
» Applications of fixed and mobile pulleys in a freight elevator system. - 1032.040E2
» The helical spring and Hooke's law. - 1032.052B_3
» Association of helical springs in series. - 1032.053B_3
» Association of coil springs in parallel. - 1032.053C_3
» Two-thread torsion pendulum, torsion spring constant, dynamic method. - 1032.090B4
» Coefficient of restitution, momentum and kinetic energy in an inelastic collision. - interface. - 1032.005_M
» Coefficient of restitution, momentum and kinetic energy in an elastic collision - interface. - 1032.005_N
» The principle of conservation of mechanical energy in a falling cylinder. - 1032.010K3_1
» Work and energy in a system of mass and helical spring, conservation of mechanical energy. - 1032.056B_3
» Conservation of angular momentum, with sensor and multichronometer. - 1032.060C6
» Conservation of mechanical energy in an oblique throw. - 1032.064D
» The determination of the initial velocity of a projectile, considering the amount of linear movement. - 1032.065A
» The initial velocity of a projectile considering the amount of angular momentum. - 1032.065B
» Determining the moment of inertia of the pendulum plus projectile assembly, from the period of oscillation. - 1032.065C
» Conservation of mechanical energy, moment of inertia. - 1032.072A1
» Coefficient of restitution, momentum and kinetic energy in an elastic collision. - 1032.078_A1
» Experimental determination of the moment of inertia of a bar, parallel axis theorem, Steiner's theorem or Huygens-Steiner theorem, with sin - 1032.088E_1
» Work and mechanical energy in a mass and helical spring system. - 1032.056AF
» Torsion pendulum, elastic constant of torsion of a string, dynamic method. - 1032.090B1
» Torsion pendulum, torsion spring constant and its relation to period and length, dynamic method. - 1032.090B3
» Calibrating the two-wire torsion pendulum to function as a torsion balance. - 1032.090B2A
» The moment of inertia of a bar, parallel axis theorem. - 1032.088E
» The Magdeburg Hemisphere Experiment and Atmospheric Pressure. - 1032.093
» Inflating a balloon, decreasing the external pressure. - 1032.094C
» Archimedes' principle. - 1042.032
» Pascal's Principle - 1042.024_2
» The thrust, experimental proof. - 1042.028
» Pressure at a point in a liquid in equilibrium - Stevin's principle. - 1042.008B
» The fundamental principle of hydrostatics Stevin's principle with tube pressure gauge. - 1042.101A
» The fundamental principle of hydrostatics Stevin's principle with differential pressure sensor. - 1042.102A
» Velocity of fluids through a small orifice. - 1042.103A
» Fluid flow through three small vertically positioned orifices. - 1042.103B
» Volumetric flow rate in incompressible fluids. - 1042.104A
» Calculation and analysis of Reynolds number. - 1042.105A
» Determination of thrust by apparent decrease in weight force. - 1042.028C2
» The operation of a suction-pressure hydraulic pump. - 1042.024B2_1
» The hydraulic press: an application of Pascal's principle - 1042.024B3_1
» The heat capacity and specific heat of copper, dry. - 1052.007A
» The water equivalent and heat capacity of a calorimeter. - 1052.003E
» Specific heat of copper, dry. - 1052.007D
» The variation in the length of a metal as a function of temperature. - 1052.021F1
» The variation in the length of a metal as a function of its initial length. - 1052.021F2
» Determination of the coefficient of linear expansion of a metal. - 1052.021F3
» The influence of color on thermal insulation. - 1052.024A3
» Isothermal transformation, Boyle-Mariotte. - 1052.032Q1
» Conduction, a means of propagation of heat means of transmission, transfer of heat. - 1052.024A
» Convection, a means of propagation of heat means of transmission of heat, heat transfer - 1052.024A1
» Radiation, a means of propagation of heat, means of transmission of heat, heat transfer. - 1052.024A2
» Some electrical, light, thermal and mechanical energy transformations. - 1052.026A
» The heat capacity and specific heat of aluminum, dry. - 1052.007B
» The heat capacity and specific heat of brass, dry. - 1052.007C
» Specific heat of aluminum, dry. - 1052.007E
» Specific heat of brass, dry. - 1052.007F
» The mass and spring oscillator, dynamic determination of the spring constant. - 1032.012AF
» Measuring the speed of propagation of a pulse in a spring, with a multitimer. - 1072.011B
» Formation and propagation of two-dimensional waves on a liquid surface. - 1072.012I
» Determination of the speed of propagation of two-dimensional waves on a liquid surface. - 1072.013I
» The reflection of a two-dimensional wave from a liquid surface. - 1072.016I
» The refraction of two-dimensional waves at a liquid surface. - 1072.020I
» Diffraction of two-dimensional waves at a liquid surface. - 1072.024I
» The interference of two-dimensional waves on a liquid surface. - 1072.029I
» The MHS from the MCU. - 1072.004B
» Underdamped angular harmonic motion. - 1072.037B
» Dynamic determination of the spring constant of a helical spring, sensor. - 1032.012_3
» The SHM in an oscillating mass and coil spring system. - 1072.008B_3
» Underdamped angular harmonic motion, with sensor and software. - 1072.037D
» The behavior of the elastic torsion constant as a function of the yarn length by the dynamic method, with sensor and software - 1032.090D3
» MHS in a mass and coil spring system. - 1072.008_A
» The damped harmonic motion MH in a mass and helical spring system. - 1072.009_A
» The center of oscillation of the physical bar-shaped pendulum with interface. - 1032.013_D
» The center of oscillation of the physical pendulum in the form of a rectangular plate, with interface. - 1032.013_E
» The oscillation center of the pendulum in the form of a circular plate, with interface. - 1032.013_F
» The parameters characterizing the simple pendulum. - 1032.013_H3
» Frequency, period and critical angular velocity of the conical pendulum, with sensor and multitimer. - 1032.060C7
» The standing wave on a string. - 1072.032E_1
» Comparing standing waves on two different strings. - 1072.032E_2
» The standing wave on a compound string. - 1072.032E_3
» Taylor's expression applied to a vibrating string, with tensiometer. - 1072.032E_4
» Taylor's expression on vibrating strings of different linear densities, with tensiometer. - 1072.032E_5
» Standing wave along a helical spring. - 1072.032E_6
» Standing waves along helical springs, with tensiometer. - 1072.032E_7
» Sound sources, sound, noise and physiological qualities of sound. - 1072.067B
» The reverberation of sound. - 1072.069B
» Sound beats, the result of superimposed waves with a small difference in frequencies. - 1072.072B
» Standing sound waves in an open tube, resonance. - 1072.074B
» Standing sound waves in a closed tube, resonance. - 1072.078B
» The apexes and nodes of the standing wave inside an open tube, with sensor. - 1072.079B
» The phenomenon of beating, with sensor. - 1072.080B
» Sound, phenomena of interference, resonance and beat. - 1072.060
» Sound, Doppler effect. - 1072.061
» Figures on Chladni resonant plates, mechanics of vibrations. - 1072.090A
» The principles of geometrical optics. - 1062.004S01
» Solar eclipse simulation and identification of umbra and penumbra. - 1062.004S02
» Reflection in a plane mirror. - 1062.004S03
» An application of multiple reflections between plane mirrors. - 1062.004S04
» Reflection in concave and convex spherical mirrors. - 1062.004S05
» The refraction of light and its laws, the diopters. - 1062.004S06
» Refraction and dispersion of light in optical prisms. - 1062.004S07
» Spherical lenses and their main characteristics. - 1062.004S08
» The relationship between the object, the lens and the image generated by the lens. - 1062.004S09
» Defects of vision, correction of hyperopia and myopia with lenses. - 1062.004S10
» The measure of the average wavelength of the colors in the continuous spectrum of light, interference. - 1062.004S11
» Total reflection, optical fibers. - 1062.004S12
» Simulation of the solar eclipse and the lunar eclipse, the umbra and the penumbra, with reflective mirrors. - 1062.052B
» The number of images formed between two plane mirrors at an angle to each other. - 1062.004E
» The image formed in a plane mirror and its characteristics. - 1062.004D
» Comparing polarization between diode laser and polychromatic light. - 1062.003N
» Rayleigh scattering. - 1062.003N2
» Laser diffraction by diffraction grating, lattice constant 1.00 x 10 - 1062.003M1
» The measurement of the thread diameter of a laser-opaque fabric. - 1062.003M2
» The composition of colors derived by light superposition. - 1062.052A
» The construction of some optical instruments. - 1062.004P
» Absorption spectra of filters and light-transparent materials, projectable. - 1062.005B
» Additive color combinations - 1062.051
» Discharge into air under atmospheric pressure. - 1082.012
» The principle of operation of the foil electroscope and the distribution of charges in a conductor. - 1082.004
» Turning on a fluorescent lamp with an electrostatic generator. - 1082.026
» Making an “electric fountain” with the electrostatic generator. - 1082.026B
» Paper strips that repel each other, with the electrostatic generator. - 1082.026C
» Hair-raising with the electrostatic generator. - 1082.026E
» Configurations of the lines of force between electrodes, the lightning rod, the Faraday cage and the coaxial cable. - 1082.020A
» The electric potential and the amount of charge accumulated in the generator. - 1082.027
» Lighting a neon lamp without contact with the electrostatic generator. - 1082.026A
» Simulating a lightning rod with the electrostatic generator. - 1082.026D
» The turnstile, the effect of the “electric wind”, with the electrostatic generator. - 1082.026F
» Spark extension in the Van de Graaff generator and dielectric strength. - 1082.027A
» Equipotential surfaces, lines of force and electric field vector between point electrodes. - 1082.029C
» Equipotential surfaces, lines of force and electric field vector, between flat and parallel electrodes. - 1082.030C
» The Faraday cage and electrostatic shielding. - 1082.031C
» Equipotential surfaces, lines of force, electric field and coaxial cable. - 1082.032C
» Electrical resistance, Ohm's law, with sensors - 1082.056B_2
» The association of lamps in series, with sensor - 1082.044_E
» Parallel lamp associations with sensor - 1082.044_E1
» The association of resistors in series. - 1082.076_D
» The association of resistors in parallel. - 1082.076_D1
» The mixed association of resistors. - 1082.076_D3
» A way to measure the internal resistance of a voltmeter. - 1082.053A
» A way to measure the internal electrical resistance of an ammeter. - 1082.054A
» Identification of a non-ohmic resistor, with sensors - 1082.064B_2
» The equivalent of a series association of capacitors. - 1082.076_E0
» The equivalent of a parallel association of capacitors. - 1082.076_E1
» Potentiometer as a voltage divider, with sensor - 1082.076_F2
» Measurements in electrical circuits and electrical power, with sensors - 1082.092B_2
» The function of a diode in a circuit. - 1082.088_D
» Kirchhoff's loop law, with sensor - 1082.088_F
» Kirchhoff's knot law, with sensor - 1082.088_F0
» RC circuit, with sensor - 1082.076_G2
» The lines of force and the magnetic field of the magnet, magnetism. - 1082.120A
» Identifying the Earth's magnetic field with sensor. - 1082.128D_0
» Identification of magnetic poles and field lines using sensor. - 1082.128D_1
» Oersted's experiment and electromagnetism, projectable table. - 1082.128_0
» Faraday's law, Lenz's law, Faraday-Lenz-Neumann law, electromagnetic induction, electromagnetic phenomena. - 1082.128A_2
» Oersted's magnetic sensor experiment. - 1082.128D_2
» The operation of the current meter known as the D’Arsonval ammeter, on the torsion balance. - 1082.180B
» The action of electromagnetic force on a current-carrying conductor immersed in a magnetic field. - 1082.136
» The electromagnetic force acting on a moving conductor carrying electric current immersed in a magnetic field. - 1082.136_A
» The magnetic field generated by an electric current in a straight conductor - 1082.161A
» The magnetic field generated by an electric current in a straight conductor, with sensor. - 1082.128D_4
» The magnetic field between two parallel, straight conductors carrying an electric current. - 1082.161B
» The magnetic field at the center of a circular loop carrying an electric current - 1082.161C
» Magnetic induction between parallel and straight conductors carrying electric current, with sensor. - 1082.128D_5
» Magnetic induction inside a solenoid carrying an electric current. - 1082.161D
» Magnetic induction inside a solenoid carrying an electric current, with sensor. - 1082.128D_7
» Electromagnetic phenomena. - 1082.161E
» Mapping magnetic field lines in a Helmholtz coil. - 1082.128D_6
» A direct current electric motor. - 1082.152
» The step-up and step-down electrical transformer - 1082.161E1
» Electromagnetic phenomena. - 1082.161E2
» The electric step-up transformer, case of 110 VAC mains voltage on the primary. - 1082.161E3
» The step-down electrical transformer, case of 220VAC mains voltage on the primary. - 1082.161E4
» Magnetic induction between two parallel conductors carrying electric current. - 1082.164B
» Influence of surface coating color on thermal comfort, sensor. - 1093.113
» The influence of surface coating on thermal comfort, with interface. - 1121.021
» Blackbody radiation with Leslie's cube. - 1121.020_1
» Determination of Planck's constant with voltage and current sensors. - 1082.182
» Light emission caused by high electrical voltage in a rarefied Geissler tube. - 1121.010_E1
» The interaction of magnetic fields with electric discharge in rarefied gases. - 1121.010_E2
» The color of the light emitted inside the Geissler tube depends on the confined gas. - 1121.010_E3