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The experiment aims to investigate the relationship between the drop height of a plasticine sphere and the diameter of the flattened part after dropping. The hypothesis is that as the drop height increases, the diameter of the flattened part will also increase. The experiment involved dropping plasticine spheres from different heights and measuring their diameters. The results supported the hypothesis, demonstrating a direct proportionality between drop height and diameter.
The experiment explores the relationship between the drop height of a plasticine sphere and the resulting diameter of the flattened part upon impact.
This investigation is of great significance as it provides insights into the physics of falling objects, which has implications in various scientific and engineering applications. Objects falling from different heights experience varying degrees of impact, and this experiment aims to quantify the relationship between drop height and the extent of deformation, specifically the diameter of the flattened part of a plasticine sphere.
To ensure the accuracy and consistency of the experiment, the following steps were meticulously carried out:
This initial step ensured that the size of the sphere remained a controlled variable.
Each height was measured precisely using a meter ruler.
The experiment produced the following data:
Drop Height (cm) | Diameter (cm) |
---|---|
60 | 5.2 |
40 | 4.1 |
20 | 3.2 |
Based on the hypothesis, it was anticipated that the sphere dropped from a height of 60 cm would exhibit a larger diameter than the spheres dropped from 40 cm and 20 cm heights.
Upon analyzing the data, it is evident that the diameter of the flattened part of the plasticine sphere increases as the drop height increases. This observation aligns with the hypothesis, indicating a direct proportionality between drop height and diameter. The data suggests that the greater the drop height, the more extensive the deformation upon impact.
Potential sources of error in this experiment include parallax errors and inaccuracies in reading the Vernier caliper. To minimize errors, readings were taken multiple times, and the average was recorded. Additionally, care was taken to start reading the Vernier scale from the zero mark to ensure accuracy.
The results of the experiment strongly support the hypothesis, demonstrating a clear and direct proportionality between the drop height of a plasticine sphere and the diameter of the flattened part upon impact. As the sphere was dropped from greater heights, it experienced larger deformations, resulting in a wider flattened area. This finding is consistent with the principles of physics governing falling objects.
Understanding this relationship is essential in fields such as physics and engineering, where knowledge of how objects deform upon impact is crucial. For instance, in engineering, this knowledge is vital when designing safety measures and protective structures to mitigate the effects of falling objects.
In conclusion, the experiment successfully established a direct proportionality between the drop height of a plasticine sphere and the diameter of the flattened part upon impact. The hypothesis that an increase in drop height leads to a proportional increase in diameter was confirmed. This experiment provides valuable insights into the behavior of falling objects and has practical applications in various scientific and engineering disciplines.
To expand on this experiment, further research can explore the effects of varying the material properties of the sphere or altering its initial shape. Additionally, investigating the impact of different surface materials on the deformation of the sphere could yield valuable insights into real-world scenarios where objects fall onto different surfaces.
Relationship Between Drop Height and Diameter of Plasticine Sphere. (2024, Jan 10). Retrieved from https://studymoose.com/document/relationship-between-drop-height-and-diameter-of-plasticine-sphere
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