A graduated flask is a laboratory glassware commonly used for precise liquid volume measurement and preparation of solutions. Its conical shape with a long, narrow neck and a calibrated scale allows for accurate determination of liquid volumes.
Graduated flasks are typically made of borosilicate glass, a material known for its resistance to chemical corrosion and thermal shock. The shape of the flask is designed to promote accurate readings by minimizing surface tension effects and ensuring the liquid forms a meniscus at the graduation marks.
The long, narrow neck facilitates precise filling and delivery. Graduations are etched or printed on the neck of the flask, representing specific volume increments.
Class A Graduated Flasks:
* Highest accuracy and precision
* Calibrated to contain a specific volume at a specified temperature
* Used for critical applications in analytical chemistry
Class B Graduated Flasks:
* Less precise than Class A flasks
* Used for general laboratory work where accuracy is not crucial
The accuracy of a graduated flask refers to its closeness to the true volume it contains or delivers. Precision refers to the reproducibility of measurements when using the flask multiple times.
Class A graduated flasks meet严格的精度和准确性标准,误差通常在±0.1%以内的标记容量。Class B graduated flasks are less precise, with an accuracy of typically ±0.2% of their marked volume.
Graduated flasks are typically calibrated by the manufacturer to a specific volume at a specified temperature, usually 20°C or 25°C. It is important to use the flask at the calibrated temperature for accurate measurements.
Graduated flasks find applications in various fields, including:
Table 1: Calibration Tolerances for Graduated Flasks
Class | Capacity (mL) | Tolerance (mL) |
---|---|---|
A | 10 | ±0.01 |
A | 50 | ±0.025 |
A | 100 | ±0.04 |
B | 10 | ±0.02 |
B | 50 | ±0.1 |
B | 100 | ±0.2 |
Table 2: Temperature Coefficients of Expansion for Graduated Flasks
Material | Coefficient of Expansion (1/°C) |
---|---|
Borosilicate glass | 0.000005 |
Soda-lime glass | 0.000011 |
Table 3: Graduated Flask Capacity Ranges
Capacity (mL) | Suitability |
---|---|
2-10 | Microanalysis, preparing small solutions |
10-100 | Most common range for analytical work |
100-1000 | Preparing large solutions, diluting stock solutions |
1000-10000 | Industrial applications, environmental monitoring |
1. What is the difference between a graduated cylinder and a graduated flask?
A graduated flask is designed for accurate volume measurement and solution preparation, while a graduated cylinder is used for approximate volume measurements or dispensing liquids.
2. How do I calculate the volume of liquid in a graduated flask?
Read the volume at the lowest point of the meniscus and subtract any empty space below the graduation mark.
3. What is the accuracy of a Class B graduated flask?
Class B graduated flasks are typically ±0.2% accurate of their marked volume.
4. Can I use a graduated flask to measure hot liquids?
No, graduated flasks are designed to measure liquids at calibrated temperatures, usually 20°C or 25°C. Measuring hot liquids can alter the volume due to thermal expansion.
5. How do I calibrate a graduated flask?
Calibration involves comparing the flask's volume to a standard volume using a balance and a high-purity liquid.
6. What are the precautions to take when using a graduated flask?
Avoid drastic temperature changes, use the correct filling technique, and clean the flask thoroughly to ensure accuracy and longevity.
Graduated flasks are essential laboratory glassware for accurate liquid volume measurement and solution preparation. By using the appropriate flask, following proper techniques, and adhering to calibration standards, scientists and technicians can ensure the reliability and reproducibility of their results.
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