Astronomy Lab Kit STEM Lab Manufacturer,Supplier and Exporter in India
Product Code : SCL-MH-12524
Bring the majesty of celestial mechanics down to Earth with the Astronomy Lab Kit STEM Lab, meticulously engineered by Educational Instrument India. Understanding spatial geography, orbital dynamics, and optical physics can be incredibly challenging when limited to flat textbook pages.
This professional-grade educational setup functions as a fully interactive tactical space observatory. It empowers students to map star systems, measure the moon's phases, and construct functional telescopes, transforming complex astrophysics into an intuitive, hands-on learning adventure.
Product Description & Scientific Principles
The Astronomy Lab Kit STEM Lab by Educational Instrument India is a multi-modular laboratory ecosystem designed to teach foundational space science. The kit features an adjustable celestial sphere dome, a functional multi-lens optical telescope assembly, a modular solar system orrery, and a precision sun-tracking sundial.
Rather than simply viewing star charts passively, students actively manipulate real physical models to track shadows, redirect light rays, and calculate angular distances across the sky.
Astrophysics in Action (E-A-T Authoritative Overview)
The kit allows instructors to cleanly isolate and demonstrate three core scientific principles:
- Keplarian Orbital Geometry & Scale
Using the modular orrery, students model planetary periods around a central light source. They can calculate elliptical paths and orbital configurations based on Kepler's Third Law:
- Optical Refraction & Focal Mechanics
By assembling the internal objective and eyepiece glass elements inside the telescope module, students learn how light rays bend as they cross different mediums. This demonstrates how a telescope gathers light and focuses it to magnify distant objects based on the lens maker's equation.
- Solar Apparent Motion & Altitude Tracking
Using the high-contrast sundial module, students map the Earth's daily rotation. By calculating the shadow length cast by the central gnomon indicator rod, they can dynamically deduce the sun's apparent angular elevation relative to the horizon:
Product Specifications
|
Parameter |
Technical Specification |
|
Brand Name |
Educational Instrument India |
|
Lab Purpose |
Modular Celestial Mechanics, Solar Tracking, & Practical Lens Optics |
|
Telescope Aperture |
50mm Objective Lens with matching multi-coated glass elements |
|
Magnification Scale |
Interchangeable Eyepiece assemblies (providing 15x and 30x power) |
|
Orrery Mechanism |
Manual multi-gear planetary model with a central LED sun star sphere |
|
Mapping Hardware |
3D Translucent Star Finder Dome with printed coordinate constellations |
|
Chassis Framework |
High-impact ABS polymer with integrated degree protractors |
|
Target Application |
Middle School Science, High School Physics, STEM Space Academies |
How to Use It: Step-by-Step Guide
Follow these guidelines to maximize data accuracy and protect the delicate optical systems inside the kit:
Map Constellations with the Star Dome: Place the clear constellation dome over a dark tabletop. Use the integrated rotational dial ring to match the current date and hour. Shine a small flashlight up through the bottom of the dome to project major star systems onto the ceiling, demonstrating how Earth's location changes what we see at night.
Assemble the Refractor Telescope: Slide the large 50mm objective lens into the front housing of the optical tube. Secure the smaller 15x eyepiece lens into the opposite viewing end. Adjust the smooth draw-tube focus mechanism back and forth until a sharp, crisp target image forms.
Demonstrate Eclipses & Phases: Turn on the central LED sun bulb on the solar system orrery module. Position the Earth and Moon modules on their respective rotational arms. Rotate the arm to show how the Moon's position relative to the Earth creates distinct crescent and gibbous phases, and align them perfectly to demonstrate solar and lunar eclipses.
Track the Solar Angle: Place the sun-tracking sundial platform on a level surface outdoors during a clear day. Use a compass to align the gnomon indicator rod toward true North.
Calculate the Sun's Angular Height: Every hour, measure the precise length ($L$) of the shadow cast by the rod. Use the mathematical tangent ratio to calculate the sun's changing altitude angle as the day progresses.
Optical Safety Warning: Never look directly at the sun through the assembled telescope or with the naked eye. Doing so can cause immediate, permanent eye damage. Only track the sun using indirect shadow projection methods on the sundial platform.
Frequently Asked Questions (FAQs)
Q1. Can this telescope module be used to look at real stars at night?
Ans: Yes! The optical system features real, polished glass lenses designed to provide clean magnifications of the moon's craters, nearby planets like Jupiter, and prominent star clusters like the Pleiades on a clear night.
Q2. Does the solar system orrery move automatically?
Ans: No, the planetary orrery module uses a precision manual geared system. This is an intentional STEM design choice, allowing students to manually turn the gears to feel and observe the proportional speed differences between inner planets like Mercury and outer planets like Mars.
Q3. Why are the projected stars blurry when using the constellation dome?
Ans: If the projected stars look blurry, adjust the distance between your flashlight light source and the bottom of the dome. Using a single, concentrated LED light source rather than a wide floodlight will produce crisp, high-contrast star projections on your wall or ceiling.
Q4. How should the optical lenses be cleaned and stored?
Ans: Dust can degrade the performance of optical surfaces over time. Gently wipe the lenses with an anti-static microfiber cloth or specialized lens cleaning tissue. When the lab is over, store all components inside the included compartmentalized storage box away from direct heat and moisture.
