Calculus I · 2B · lesson
Volume and Filling Problems
Learn volume and filling problems with clear exposition, guided derivations, worked examples, visuals, checks, and interpretation.
Section overview
Related ratesWhat this section is building
Learn volume and filling problems with clear exposition, guided derivations, worked examples, visuals, checks, and interpretation.
The picture supplies a constraint; implicit differentiation transmits known rates through that constraint to the unknown rate.
Draw and label first, write one relationship, differentiate with time, then substitute the snapshot measurements and rates.
Substituting numerical dimensions before differentiating and thereby erasing the very change the problem asks about.
Learning objectives
Relate volume rates to changing heights or radii, including similar-triangle constraints.
Volumes with Changing Dimensions
Before the formulas
Related-rates work in Volume and Filling Problems becomes manageable when geometry and calculus are kept separate. Geometry supplies an equation such as the Pythagorean theorem, a volume formula, or a similar-triangle proportion. Calculus differentiates that equation. The derivative does not invent the geometry for you.
Before solving, predict the sign of the unknown rate from the picture. That prediction is a powerful error check. If a ladder foot moves away from a wall, the top should move down; a positive answer for its height rate should trigger a review.
Read this graph as text
A conical tank combines volume and similar-triangle relationships. The water volume depends on both radius and depth. Similar triangles provide r/h=R/H , allowing the two changing dimensions to be expressed using one variable before differentiating. The large cone and the water cone have the same shape, so r/h=R/H . That relationship is not optional bookkeeping; it eliminates one changing variable from V=(1/3) r 2h . Only after that substitution is the volume differentiated with respect to time.
Every relationship in a conical tank combines volume and similar-triangle relationships is identified with written labels plus distinct solid, dashed, dotted, double, marker, or pattern cues; color is never the only carrier of meaning.
Why it matters: This visual addresses the two-equation structure of many volume problems. Students often differentiate the volume formula while leaving both r and h unknown, then discover they have too many rates. The similar-triangle labels should make the reduction step visible.
The water volume depends on both radius and depth. Similar triangles provide r/h=R/H, allowing the two changing dimensions to be expressed using one variable before differentiating.
Volume rates depend on both shape and current size
A formula such as contains several quantities that may vary. The problem statement determines which are changing and whether a geometric constraint links them. Differentiation must include every changing factor.
Units provide a strong check: a volume rate is measured in cubic units per unit time. If the final expression has only square units or lacks time, a variable or rate has probably been omitted.
Filling and draining problems combine geometry with rates. In a cylinder, the cross-sectional area is constant, so height changes at a steady rate when volume does. In a cone or pyramid, the cross-section changes with height, so the same inflow produces different height rates at different depths.
Similar triangles are the bridge between changing dimensions. They reduce a two-variable volume formula to one geometric variable before differentiation, turning a messy system into a solvable rate equation.
Water rising in a cylindrical tank
Water enters a cylindrical tank of radius m at m/min. How fast is the water depth increasing?
Worked solution
Write a real attempt before opening the supplied answer.
Water rising in a cone
A conical tank is m high with top radius m. Water enters at m/min. Find when the water is m deep.
Worked solution
Write a real attempt before opening the supplied answer.
In a cone, the water surface radius is not the tank's fixed top radius until the tank is full. Similar triangles eliminate the extra variable.
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