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OPTIKASCIENCE
DATA HARVEST
ERLER-ZIMMER
Maths Education
OPTIKASCIENCE
Section 02 - Physics / Inertia- Collisions - Two-dimension motion
1. OPTIKASCIENCE
1.1. Section 01 - Kits
1.1.1. Physics Laboratory Sets
1.1.2. Basic Kits
1.1.3. Advanced Kits
1.2. Section 02 - Physics
1.2.1. Statics of solids
1.2.2. Dynamics
1.2.3. Translational motion
1.2.4. Rotational motion
1.2.5. Oscillatory motion
1.2.6. Inertia- Collisions - Two-dimension motion
1.2.7. Liquids
1.2.8. Gases and vacuum
1.2.9. Wave's propagation
1.2.10. Sound Waves
1.2.11. Molecular aspect of matter
1.2.12. Temperature and Heat
1.2.13. Geometrical Optics
1.2.14. Wave Optics
1.2.15. Optical Benches
1.2.16. Electrostatics
1.2.17. Electrical conduction
1.2.18. Magnetism and electromagnetism
1.2.19. Atomic Physics
1.3. Section 03 - Technique and Energy
1.3.1. Energy conversions
1.3.2. Renewable energies
1.4. Section 04 - Microscopy
1.4.1. On-field microscopy kits
1.4.2. Biological microscopes
1.4.3. Stereomicroscopes
1.4.4. Multimedia system
1.4.5. Microscopy accessories
1.4.6. Optical magnifiers
1.4.7. Prepared slides for microscopy
1.5. Section 05 - Biology
1.5.1. Botany
1.5.2. Zoology
1.5.3. Experiments on human beings
1.5.4. Human anatomy and DNA models
1.6. Section 06 - Ecology
1.6.1. Kit for environmental analysis
1.6.2. Items for sample's collection
1.6.3. Stations for the detection of air pollution
1.6.4. Digital instruments
1.7. Section 07 - Meterology
1.7.1. Instruments and weather stations
1.8. Section 08 - Astronomy and Earth Science
1.8.1. Rocks, fossils and minerals
1.8.2. Geological models
1.8.3. The Earth and the solar system
1.9. Section 09 – Chemistry
1.9.1. Periodic table of elements
1.9.2. Molecular models and atomic models
1.9.3. PH-meters
1.9.4. Refractometry
1.9.5. Polarimetry
1.9.6. Spectroscopy
1.9.7. Electrology
1.10. Section 10 – On-Line Science
1.10.1. Interfaces
1.10.2. MBL Sensors
1.10.3. USB Sensor
1.11. Section 11 – Drawing and Mathematics
1.11.1. Drawing
1.11.2. Enumeration
1.11.3. Logics
1.11.4. Fractions and percentages
1.11.5. Geometry
1.11.6. Mathematics on magnetic blackboard
1.12. Section 12 – Measurement Instruments
1.12.1. Lengths and angles
1.12.2. Volumes/Time intervals
1.12.3. Temperature
1.12.4. Density/Forces, weights and masses
1.12.5. Electrical devices
1.13. Section 13 – Lab Tools
1.13.1. Items and instruments
1.13.2. Electrical power sources
2. DATA HARVEST
2.1. Data Logging
2.1.1. Data Loggers
2.1.1.1. Data Logging Range
2.1.2. Sensors
2.1.2.1. Sensor Range
2.1.3. Apps
2.1.3.1. Cross-platform software
2.1.4. Accesories
2.1.4.1. All Accessories
2.2. Dynamics
2.2.1. Dynamics System
2.2.2. Software
2.2.2.1. Cross-platform software
2.2.3. Accessories
2.2.3.1. All Accessories
2.3. Teaching
2.3.1. Teaching Packs
2.3.2. Teaching Metarials
2.4. More Science
2.4.1. Smart Microscopes
2.4.2. Genecon Hand-Held Dynamo
2.4.3. Renewable Energy
2.5. Product Brochures
2.5.1. Primary Teaching Brochure
2.5.2. Secondary Teaching Brochure
3. ERLER-ZIMMER
3.1. Anatomical Models
3.1.1. Skeleton Models
3.1.1.1. Pelvises
3.1.1.2. Limbs
3.1.1.3. Full Body
3.1.1.4. Skulls
3.1.1.5. Spines
3.1.1.6. Bones
3.1.2. Organs & Structures
3.1.2.1. Respiratory System
3.1.2.2. Brain & Nerves
3.1.2.3. Urinary System
3.1.2.4. Skin-Hair-Nail
3.1.2.5. Head Models
3.1.2.6. Circulatory System - Blood Vessels
3.1.2.7. Circulatory System - Hearts
3.1.2.8. Circulatory System - Circulation
3.1.2.9. Liver
3.1.2.10. Muscular Models
3.1.2.11. Kidneys
3.1.2.12. Ears
3.1.2.13. Torsos
3.1.2.14. Digestive System
3.1.2.15. Teeth
3.2. 3D Anatomy Series
3.3. Medical Simulators
3.3.1. Auscultation
3.3.2. Endoscopy
3.3.3. Gynaecology
3.3.4. Skin Suture
3.3.5. Injection
3.3.6. Nursing
3.3.6.1. Chronic Wounds
3.3.6.2. Diabetes
3.3.6.3. Catheterisation
3.3.6.4. Nursing Dolls - Baby & Child Dolls
3.3.6.5. Nursing Dolls - Adult Dolls
3.3.6.6. Stoma Care
3.3.7. Cancer Prevention
3.3.8. Emergency
3.3.8.1. Airway
3.3.8.2. CPR - Baby & Child Dolls
3.3.8.3. CPR - Adult Dolls
3.3.8.4. All Dolls - Baby & Child Dolls
3.3.8.5. All Dolls - Adult Dolls
3.3.8.6. Rescue
3.3.8.7. Thorax
3.3.8.8. Trauma Simulation
3.3.9. X-RAY / CT
3.3.10. Pregnancy & Birth
3.3.11. Ultrasound
1079 Mechanical paradox
As the cylinder goes down the inclined plane, the double cone goes up, apparently contravening the laws of mechanics. In reality the center of gravity of both moving bodies goes down. Made entirely of wood. Length of the inclined plane: 50 cm. Double cone dimensions: 35 cm. Cylinder dimensions: 35 cm....
1113 Newton’s cradle
It is composed of five steel balls of equal mass, lined up and in contact with each other. Raising the first ball and then releasing it, its energy are trasmitted to the last ball. This phenomenona doesn’t happen if you place a disk of deforming material between the balls....
1325 Two-dimension collision apparatus
A steel ball rolls down a track to finally fall freely, leaving a trace on the fall plane thanks to a carbon-paper sheet.It is possible to do calculations on energy conservation and on motion composition by changing the free fall height and by measuring the range.With two balls, it is also possible to verify the conservation of the motion quantity and of the kinetic energy.The item is supplied with 3 steel balls.Dimensions: 400x100x20 mm....
1364 Downward speed
Two balls with the same diameter roll down at the same time, from the same height difference, but following different trajectories. Departing from the same height, which will be the fist ball to reach the finish point?Base: 600×200 mm.Length of tracks: 600 mm.Starting altitude: 120 mm; Arrival fee: 45 mm....
1422 An historical quest
A hunter wants to shoot a monkey hanging from a tree branch, hence he aims his blowpipe at the animal. As soon as the monkey sees the arrow, it loosens the grip to avoid being shot. The hunter, as the monkey jumps, thinks he missed the target; shortly thereafter, however, he can see with great surprise the arrow hit the free falling animal. It is possible to demonstrate that the monkey would be hit in all cases, whatever the velocity V0 at which the arrow moves, provided that its value is such as to allow the arrow to hit the animal before it reaches the ground. At the very instant in which the projectile exits t...
1431 Parabolic motion apparatus
This simple apparatus let the students study, in a quantitative way, the parabolic motion. This launching system has 5 launch positions, and the projectile is a plastic sphere. The regulation system allows you to vary inclination from 0° to 90°. If you want to know the speed at which the bullet is thrown, we recommend that you buy it:Apparatus to measure launch velocity 9095...
1435 Gyroscope
It has a metallic wheel. If you turn this wheel, using a string, you can study angular momentum conservation. Applying a perpendicular force to a rotation axe, you can observe precession motion, in other words the gyroscopic effect....
1436 Ballistic pendulum
The ballistic pendulum allows to study the laws of conservation of energy and the conservation of momentum in a perfectly inelastic collision. The launching system is removable and suitable to verify the initial speed of a projectile according to the laws of parabolic motion.The cannon is made of anodized aluminum. It is equipped with 5 launching positions and can be dismantled, this also allows an in-depth study of the parabolic motion....
1437 Atwood machine
Atwood’s machine was invented in 1784 by George Atwood as a laboratory experiment to verify the laws of motion uniformly accelerated. With this apparatus it is possible to conduct experiments on the Dynamics of moving bodies and perform accurate measurements.Using the appliance cod. 8107 it is possible to study even the uniform motion. Topics • Newton’s second law • Atwood machine – Theory • Friction force • Newton’s second law in the presence of friction Equipment for online use - not supplied 1 Interface code 9001 1 Distance sensor code 9041 or 1 USB dista...
1438 Apparatus to study the moment of inertia
Thanks to this device, students can delve into complicated concepts such as angular velocity and moment of inertia, based on the fundamental law of rotary motion. The discussion also includes the energy balance of the system, including friction. Topics • Translational motion and rotational motion • Analogies between translational and rotational motions • Definition of rotational motion quantities • How to calculate torque • How to evaluate acceleration • The fundamental law of rotational motion • The moment of intertia • Kinetic energy in rotational motion • How to d...
1439 Apparatus for the verification of the principle of mechanical energy conservation
All the natural phenomena taking place in an isolated system are governed by a property that, until today, has had no exceptions: there is a magnitude whose value remains the same throughout the course of a phenomenon; this magnitude is named as energy.Thanks to this kit, the student can study the concept of energy and go into the meaning of its conservation. Topics • Isolated systems • What energy is? • Principle of mechanical energy conservation • Why mechanical energy is preserved? ...
8107 Uniform linear motion apparatus
This item is composed of a couple of neodymium magnets which are dropped into an aluminium tube. During their fall, the tube is the centre of induced forces which, due to Lenz’s Law, oppose the magnets motion. The kit of magnets is submitted to a force F = – k v, which is proportional and opposite to the speed. Therefore, after a brief transitional phase, the motion of the two magnets becomes uniform thanks to this force. Connecting trolleys or other objects to the magnets through a cord, it is possible to obtain the uniform motion of these objects. Topics • Falling of a magnet in an aluminium ...
9095 Apparatus to measure launch velocity
Looking for the speed of the projectile, launched by the launching system code 1431, we recommend our product code 9095. It consists of a photocell connected to a timer able of evaluating to the millisecond the obscuration time Δt caused by the passage of the projectile....
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