How to Calculate Water Height After Transfer from a Cylindrical to a Cuboidal Tank: A Practical Problem

When managing water storage systems, understanding how volume translates between different tank shapes is crucial. One common scenario involves transferring water from a cylindrical tank to a cuboid (box-shaped) tank. This article explains step-by-step how to calculate the water height in the cuboid tank when the original cylindrical tank holds water to a specified height.

Understanding the Context

Understanding the Problem

We begin with a cylindrical tank with:

  • Radius ( r = 3 ) meters
    - Height of water ( h_{\ ext{cyl}} = 10 ) meters
    - Water transferred to a cuboid tank with base area ( A = 45 ) square meters

We need to find the final height of water ( h_{\ ext{cuboid}} ) in the cuboid tank.

Solved 4. A cylindrical tank with height 7 meters and radius | Chegg.com

Image Gallery

Solved 4. A cylindrical tank with height 7 meters and radius | Chegg.com
Solved: A cylindrical water tank has a radius of 4 meters and a height ...
[Solved]: A vertically oriented cylindrical tank with radi
Solved 2. Consider a cylindrical tank with radius R meters, | Chegg.com
Solved: Cylindrical Tank With Radius 5 M Is Being Filled W... | Chegg.com

Key Insights

Step 1: Calculate the Volume of Water in the Cylindrical Tank

The volume ( V ) of a cylinder is given by the formula:

[
V = \pi r^2 h
]

Substituting the known values:

Continue Reading

A health program in rural Appalachia trained 450 community health workers. If 40% spoke Spanish and 30% spoke both Spanish and English, how many spoke only English?
Only Spanish: 180 - 135 = <<180-135=45>>45
Only English: 450 - 180 = <<450-180=270>>270

🔗 Related Articles You Might Like:

📰 List of Pokemon Red Tms 📰 Mangaplus Subscription 📰 Blitzball Ffx 📰 5 Shocked Investors Rok Stocks Explosive Rise Revealedcan You Buy Before It Blows Up 5973227 📰 H Kinetochore Attachment 4450244 📰 Fire Fragrance And Ancient Magicdiscover The True Power Of Genuine Chinese Five Spice 1228587 📰 Nj Parsippany Weather 647619 📰 Software Development Engineer Microsoft 4054534 📰 Secret How One Meltdown Over Lost Windows Password Led To Instant Recovery Hacks 6057404 📰 Finally What Is Single Touch Payroll The Efficient Solution For Modern Payroll 9165621 📰 Apple Ring 9670068 📰 Free Farm Games You Can Play Todayno Cost Maximum Fun 2351430 📰 Linda Hamilton Young 6004815 📰 Does This N64 Console Boost Your Retro Gaming Like Never Before 9568668 📰 Calculate Used Car Payment 7465172 📰 Foot Tenderness Bottom 7531178 📰 Superhero Tycoon In Roblox 276026 📰 Quad City Times Newspaper Obituaries 5476734

Final Thoughts

[
V = \pi (3)^2 (10) = \pi \ imes 9 \ imes 10 = 90\pi \ ext{ cubic meters}
]

Using the approximation ( \pi pprox 3.1416 ):

[
V pprox 90 \ imes 3.1416 = 282.74 \ ext{ cubic meters}
]

Step 2: Relate Volume to Height in the Cuboid Tank

The cuboid tank has a base area (floor area) of ( 45 ) m². The volume of water remains constant during transfer, so:

[
V = \ ext{Base Area} \ imes \ ext{Height}
]

[
90\pi = 45 \ imes h_{\ ext{cuboid}}
]

Solving for ( h_{\ ext{cuboid}} ):

[
h_{\ ext{cuboid}} = rac{90\pi}{45} = 2\pi
]