Mathematics • Year 10 • Unit 1 • Lesson 20

Volume of Pyramids, Cones and Spheres — Skill Drill

Build fluency with the three "tapered solid" volume formulas from Lesson 20: pyramid V = ⅓ × A_base × h, cone V = ⅓πr²h, and sphere V = ⁴⁄₃πr³. Plus the one-third rule: a pyramid (or cone) has exactly one-third the volume of a prism (or cylinder) with the same base and height.

Build · I Do / We Do / You Do

1. I do — fully worked example

Read every step. Each one has a short reason on the right so you can see why, not just what.

Problem. A square-based pyramid has base side 6 cm and perpendicular height 10 cm. Find its volume.

Step 1 — Spot the rule.

Pyramid → V = ⅓ × A_base × h.

Reason: every pyramid follows the one-third rule. The base is whatever polygon the pyramid sits on; here it's a square.

Step 2 — Find the base area.

A_base = 6 × 6 = 36 cm²

Reason: square of side 6 has area side² = 36.

Step 3 — Substitute into the formula (use the perpendicular height, not a slant).

V = ⅓ × 36 × 10

Reason: A_base = 36, h = 10. The lesson warns: always use the perpendicular height.

Step 4 — Evaluate.

V = ⅓ × 360 = 120 cm³

Reason: multiply 36 × 10 first, then take a third.

Step 5 — Check with the one-third rule.

A prism with the same base would have V = 36 × 10 = 360 cm³; the pyramid is one-third of that = 120 cm³ ✓

Answer: V = 120 cm³.

Stuck? Revisit lesson § "Volume of Pyramids and Cones" — Worked Example 1.

2. We do — fill in the missing steps

Same structure as Section 1, but with the working faded. Fill in each blank line. 4 marks

Problem. A spherical water balloon has radius 12 cm. Find its volume in litres (to 2 d.p.).

Step 1 — Spot the rule: sphere → V = __________________ πr³.

Step 2 — Cube the radius:

r³ = 12³ = ______ cm³

Step 3 — Substitute into the formula:

V = (4/3) × π × ______ = ______π cm³

Step 4 — Convert to a decimal (1 d.p.):

V ≈ ______ cm³

Step 5 — Convert cm³ to litres (1 cm³ = 1 mL; 1000 mL = 1 L):

V ≈ ______ mL ÷ 1000 ≈ ______ L (2 d.p.)

Stuck? Revisit lesson § "Volume of Spheres" — Worked Example 2. Be careful to cube (not square) the radius.

3. You do — independent practice

Show your working in the space under each problem. Give answers in exact form (in terms of π where appropriate) and as a decimal to 1 d.p. unless told otherwise. The first four are foundation. The middle two are standard. The last two are extension.

Foundation — single-formula tapered solids

3.1 A cone has radius 3 cm and perpendicular height 8 cm. Find its volume in exact form. 1 mark

3.2 A sphere has radius 6 cm. Find its volume in exact form. 1 mark

3.3 A square-based pyramid has base side 8 cm and perpendicular height 6 cm. Find its volume. 1 mark

3.4 A rectangular-based pyramid has base 5 cm × 4 cm and perpendicular height 6 cm. Find its volume. 1 mark

Standard — diameter and the one-third rule

3.5 A sphere has diameter 10 cm. Find its volume in exact form and to 1 d.p. 2 marks

3.6 A cone and a cylinder have the same radius and the same height. The cylinder has volume 60π cm³. Use the one-third rule to find the cone's volume. 2 marks

Extension — push your thinking

3.7 A cone has radius 4 cm and perpendicular height 9 cm. Find its volume in exact form. Then find what fraction of a sphere of the same radius (r = 4 cm) the cone would fill. 3 marks

3.8 A solid metal ball-bearing has radius 0.5 cm. Find its volume in exact form (as a fraction with π) and to 4 d.p. 2 marks

Stuck on 3.7? V_cone = ⅓π(4)²(9) = 48π. V_sphere = (4/3)π(4)³ = 256π/3. Take the ratio.

How did this worksheet feel?

Got it Partly Lost

What I'll revisit before next class:

Answers — Do not peek before attempting

Section 2 — We do (sphere r = 12)

Step 1: V = (4/3) πr³.
Step 2: r³ = 12³ = 1728 cm³.
Step 3: V = (4/3) × π × 1728 = 2304π cm³.
Step 4: V ≈ 7238.2 cm³.
Step 5: V ≈ 7238.2 mL ÷ 1000 ≈ 7.24 L (2 d.p.).

3.1 — Cone (r = 3, h = 8)

V = ⅓ × π(3)²(8) = ⅓ × π(9)(8) = 24π cm³ (≈ 75.4 cm³).

3.2 — Sphere (r = 6)

V = (4/3)π(6)³ = (4/3)π(216) = 288π cm³ (≈ 904.8 cm³).

3.3 — Square pyramid (base 8, h = 6)

A_base = 64 cm². V = ⅓ × 64 × 6 = 128 cm³.

3.4 — Rectangular pyramid (5 × 4 × h = 6)

A_base = 20 cm². V = ⅓ × 20 × 6 = 40 cm³.

3.5 — Sphere (d = 10)

r = 5. V = (4/3)π(5)³ = (4/3)π(125) = 500π/3 ≈ 523.6 cm³ (1 d.p.).

3.6 — Cone vs cylinder (same r, same h, cylinder = 60π)

One-third rule: V_cone = ⅓ × V_cylinder = ⅓ × 60π = 20π cm³.

3.7 — Cone (r = 4, h = 9) vs sphere (r = 4)

V_cone = ⅓π(4)²(9) = ⅓π(16)(9) = 48π cm³.
V_sphere = (4/3)π(4)³ = (4/3)π(64) = 256π/3 cm³.
Fraction = (48π) ÷ (256π/3) = 48 × 3 ÷ 256 = 144/256 = 9/16.
So the cone holds 9/16 of the sphere's volume.

3.8 — Ball bearing (r = 0.5 cm)

V = (4/3)π(0.5)³ = (4/3)π(0.125) = 0.5π/3 = π/6 cm³ ≈ 0.5236 cm³ (4 d.p.).