Description
Atomfair-OICP682 Optical Self-Assembled Innovation Cloud Platform
Product Overview
The Atomfair-OICP682 is a self-assembled comprehensive optical experiment kit that breaks the limitations of traditional integrated experimental equipment. Adopting a portable, functional, and modular design, it provides a variety of standardized components with unique functions. Users can freely design experimental schemes, flexibly select, match, and assemble components to complete experiments. It not only helps students cultivate active thinking, hands-on operation, and divergent thinking abilities but also offers convenient support for teachers’ scientific research. Combined with the Internet + experiment sharing platform, it realizes resource sharing, process sharing, and result comparison, making the experimental process more interactive and interesting.
Core Product Features
Modular and Standardized Design: Accessories adopt standardized and generalized specifications with unified sizes, allowing for easy replacement to meet the needs of different experimental combinations.
Free Matching and Arbitrary Combination: Supports arbitrary splicing of T-shaped and parallelogram angle rails, paired with dozens of functional accessories to achieve diverse experimental setups.
Portable and Easy to Store: The overall design is lightweight with streamlined accessories, facilitating carrying and storage while ensuring excellent experimental results.
Rich Experimental Content: Covers a wide range of experimental projects from basic to advanced levels, adapting to the needs of different learning and research stages.
Intelligent Experiment Support: Provides functions such as experiment reservation, preview, micro-class appreciation, experimental video viewing, and virtual experiment operation to assist in efficiently completing experiments.
Interactive Sharing of Achievements: Supports functions including experimental result upload and comparison, experimental video upload, global comparison of experimental results, micro-class upload, score checking, and click count statistics, enabling extensive exchange of experimental achievements.
Main Configurations and International Standard Specifications
| No. | Name | Specifications (International Standards) |
|---|---|---|
| 1 | Optical Components | Material: BK7; Focal Length Tolerance: ±2%; Diameter Tolerance: +0.0/-0.1mm; Effective Aperture: >80%; Eccentricity: 3′; Surface Quality: 60/4; Surface Figure Accuracy: λ/4@632.8nm |
| 2 | Guide Rail Slides | Material: High-strength lightweight aluminum alloy; Structural Design: Profile structure; Surface Treatment: Matte finish |
| 3 | Light Sources | (1) Solid-state Laser: Central wavelength 532nm, TEM mode, power 3-5mW, powered by a DC stabilized current power supply to ensure power stability and prevent light spot flicker; (2) Low-pressure Mercury/Sodium Lamp: Injection-molded modular power supply, electronic ballast, no noise, high working efficiency; (3) Tungsten Bromide Lamp: Adjustable brightness, maximum power 35W, spectral range 300nm-2500nm |
| 4 | Adjustment Frames | Material: High-strength hard aluminum alloy, featuring high strength, heat resistance, and low internal stress; Surface Treatment: Matte finish with low reflectivity; Adjustment Knob: High-stability design, pitch 0.25mm, high adjustment precision |
Usable Experimental Projects
(I) Lens-Related Experiments
- Focal Length Measurement of Thin Lenses by Autocollimation Method
- Focal Length Measurement of Thin Lenses by Bessel Method (Double Imaging Method)
- Focal Length Measurement of Eyepieces by Object-Image Magnification Method
- Focal Length Measurement of Concave Lenses by Object-Image Distance Method
- Determination of Nodes and Focal Length of Lens Systems
- Self-Assembled Projector
- Magnification Measurement of Self-Assembled Telescope
- Self-Assembled Telescope with Erecting Prism
- Magnification Measurement of Self-Assembled Microscope
(II) Interference Experiments
- Young’s Double-Slit Experiment
- Fresnel Double Prism Interference
- Fresnel Double Mirror Interference
- Lloyd’s Mirror Interference
- Newton’s Rings Experiment
- Determination of Air Refractive Index by Interference Method
- Optical Path Construction of Mach-Zehnder Interferometer
- Optical Path Construction of Sagnac Interferometer
- Measurement of Refractive Index and Thickness of Media by Laser Interference
(III) Diffraction Experiments
- Fraunhofer Single-Slit Diffraction
- Fraunhofer Circular Aperture Diffraction
- Fresnel Single-Slit and Circular Aperture Diffraction
- Fresnel Diffraction at a Straight Edge
- Grating Diffraction
- Grating Monochromator Experiment
(IV) Other Optical Experiments
- Generation and Inspection of Polarized Light
- Holography
- Holographic Grating Fabrication
- Abbe Imaging Principle and Spatial Filtering
- θ Modulation Experiment
- Observation of 6 Types of Lens Aberrations
- Optical Image Addition and Subtraction Experiment
- Optical Image Differentiation Experiment
- Convolution Theorem Experiment
- Crystal Birefringence Experiment
- Wave Plate-Related Experiments
- Dispersion Prism Spectroscopy Experiment
Advantages of Featured Experiments
Holographic Experiment: Adopts green laser and green-sensitive photographic plates, reducing experimental costs while achieving novel and excellent experimental results.
Interference and Diffraction Experiments: Relying on standardized accessories and flexible rail splicing design, the experiments are easy to set up with reliable data accuracy, fully meeting the needs of teaching and basic scientific research.
If you’re interested, have any questions, or have specific customization requirements, please feel free to contact us at inquiry@atomfair.com.
