Practice · Different factor pairs, same product · Sensim Math

Variant 1 answer: 7 triangles

A piece of wire is as long as a $7\ \text{cm}$ stick laid end to end $6$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $2\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 7 cm stick placed end to end 6 times. Each triangle is made of three 2 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 7 cm stick laid end to end 6 times.
Each triangle has three sides, each 2 cm long.

Unknowns

The greatest number of 2 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 2 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 7 cm length repeated 6 times, so multiply 7 by 6.

7 \times 6 = 42

6 equal lengths of 7 cm is just the multiplication fact 7 times 6.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 2 cm sides, so one triangle uses 2 cm three times.

2 \times 3 = 6

Three sides of the same length is simply 2 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 6 cm pieces fit in 42 cm. Because 6 times 7 equals 42, exactly 7 triangles can be made with no wire left over.

42 \div 6 = 7

Finding how many equal groups of 6 make 42 is the same as knowing the factor pair 6 and 7 of 42.

Answer: 7 triangles

Review

7 triangles use 6 times 7 = 42 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 6 cm from 42 cm and count the 7 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 7 by 6 for the total wire length and 2 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 42 splits into equal groups of 6, giving 7 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 2 answer: 4 triangles

A piece of wire is as long as a $8\ \text{cm}$ stick laid end to end $3$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $2\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 8 cm stick placed end to end 3 times. Each triangle is made of three 2 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 8 cm stick laid end to end 3 times.
Each triangle has three sides, each 2 cm long.

Unknowns

The greatest number of 2 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 2 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 8 cm length repeated 3 times, so multiply 8 by 3.

8 \times 3 = 24

3 equal lengths of 8 cm is just the multiplication fact 8 times 3.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 2 cm sides, so one triangle uses 2 cm three times.

2 \times 3 = 6

Three sides of the same length is simply 2 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 6 cm pieces fit in 24 cm. Because 6 times 4 equals 24, exactly 4 triangles can be made with no wire left over.

24 \div 6 = 4

Finding how many equal groups of 6 make 24 is the same as knowing the factor pair 6 and 4 of 24.

Answer: 4 triangles

Review

4 triangles use 6 times 4 = 24 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 6 cm from 24 cm and count the 4 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 8 by 3 for the total wire length and 2 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 24 splits into equal groups of 6, giving 4 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 3 answer: 2 triangles

A piece of wire is as long as a $9\ \text{cm}$ stick laid end to end $2$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $3\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 9 cm stick placed end to end 2 times. Each triangle is made of three 3 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 9 cm stick laid end to end 2 times.
Each triangle has three sides, each 3 cm long.

Unknowns

The greatest number of 3 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 3 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 9 cm length repeated 2 times, so multiply 9 by 2.

9 \times 2 = 18

2 equal lengths of 9 cm is just the multiplication fact 9 times 2.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 3 cm sides, so one triangle uses 3 cm three times.

3 \times 3 = 9

Three sides of the same length is simply 3 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 9 cm pieces fit in 18 cm. Because 9 times 2 equals 18, exactly 2 triangles can be made with no wire left over.

18 \div 9 = 2

Finding how many equal groups of 9 make 18 is the same as knowing the factor pair 9 and 2 of 18.

Answer: 2 triangles

Review

2 triangles use 9 times 2 = 18 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 9 cm from 18 cm and count the 2 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 9 by 2 for the total wire length and 3 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 18 splits into equal groups of 9, giving 2 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 4 answer: 6 triangles

A piece of wire is as long as a $9\ \text{cm}$ stick laid end to end $4$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $2\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 9 cm stick placed end to end 4 times. Each triangle is made of three 2 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 9 cm stick laid end to end 4 times.
Each triangle has three sides, each 2 cm long.

Unknowns

The greatest number of 2 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 2 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 9 cm length repeated 4 times, so multiply 9 by 4.

9 \times 4 = 36

4 equal lengths of 9 cm is just the multiplication fact 9 times 4.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 2 cm sides, so one triangle uses 2 cm three times.

2 \times 3 = 6

Three sides of the same length is simply 2 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 6 cm pieces fit in 36 cm. Because 6 times 6 equals 36, exactly 6 triangles can be made with no wire left over.

36 \div 6 = 6

Finding how many equal groups of 6 make 36 is the same as knowing the factor pair 6 and 6 of 36.

Answer: 6 triangles

Review

6 triangles use 6 times 6 = 36 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 6 cm from 36 cm and count the 6 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 9 by 4 for the total wire length and 2 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 36 splits into equal groups of 6, giving 6 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 5 answer: 6 triangles

A piece of wire is as long as a $4\ \text{cm}$ stick laid end to end $9$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $2\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 4 cm stick placed end to end 9 times. Each triangle is made of three 2 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 4 cm stick laid end to end 9 times.
Each triangle has three sides, each 2 cm long.

Unknowns

The greatest number of 2 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 2 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 4 cm length repeated 9 times, so multiply 4 by 9.

4 \times 9 = 36

9 equal lengths of 4 cm is just the multiplication fact 4 times 9.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 2 cm sides, so one triangle uses 2 cm three times.

2 \times 3 = 6

Three sides of the same length is simply 2 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 6 cm pieces fit in 36 cm. Because 6 times 6 equals 36, exactly 6 triangles can be made with no wire left over.

36 \div 6 = 6

Finding how many equal groups of 6 make 36 is the same as knowing the factor pair 6 and 6 of 36.

Answer: 6 triangles

Review

6 triangles use 6 times 6 = 36 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 6 cm from 36 cm and count the 6 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 4 by 9 for the total wire length and 2 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 36 splits into equal groups of 6, giving 6 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 6 answer: 3 triangles

A piece of wire is as long as a $6\ \text{cm}$ stick laid end to end $6$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $4\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 6 cm stick placed end to end 6 times. Each triangle is made of three 4 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 6 cm stick laid end to end 6 times.
Each triangle has three sides, each 4 cm long.

Unknowns

The greatest number of 4 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 4 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 6 cm length repeated 6 times, so multiply 6 by 6.

6 \times 6 = 36

6 equal lengths of 6 cm is just the multiplication fact 6 times 6.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 4 cm sides, so one triangle uses 4 cm three times.

4 \times 3 = 12

Three sides of the same length is simply 4 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 12 cm pieces fit in 36 cm. Because 12 times 3 equals 36, exactly 3 triangles can be made with no wire left over.

36 \div 12 = 3

Finding how many equal groups of 12 make 36 is the same as knowing the factor pair 12 and 3 of 36.

Answer: 3 triangles

Review

3 triangles use 12 times 3 = 36 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 12 cm from 36 cm and count the 3 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 6 by 6 for the total wire length and 4 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 36 splits into equal groups of 12, giving 3 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 7 answer: 4 triangles

A piece of wire is as long as a $6\ \text{cm}$ stick laid end to end $4$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $2\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 6 cm stick placed end to end 4 times. Each triangle is made of three 2 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 6 cm stick laid end to end 4 times.
Each triangle has three sides, each 2 cm long.

Unknowns

The greatest number of 2 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 2 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 6 cm length repeated 4 times, so multiply 6 by 4.

6 \times 4 = 24

4 equal lengths of 6 cm is just the multiplication fact 6 times 4.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 2 cm sides, so one triangle uses 2 cm three times.

2 \times 3 = 6

Three sides of the same length is simply 2 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 6 cm pieces fit in 24 cm. Because 6 times 4 equals 24, exactly 4 triangles can be made with no wire left over.

24 \div 6 = 4

Finding how many equal groups of 6 make 24 is the same as knowing the factor pair 6 and 4 of 24.

Answer: 4 triangles

Review

4 triangles use 6 times 4 = 24 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 6 cm from 24 cm and count the 4 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 6 by 4 for the total wire length and 2 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 24 splits into equal groups of 6, giving 4 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 8 answer: 4 triangles

A piece of wire is as long as a $8\ \text{cm}$ stick laid end to end $6$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $4\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 8 cm stick placed end to end 6 times. Each triangle is made of three 4 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 8 cm stick laid end to end 6 times.
Each triangle has three sides, each 4 cm long.

Unknowns

The greatest number of 4 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 4 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 8 cm length repeated 6 times, so multiply 8 by 6.

8 \times 6 = 48

6 equal lengths of 8 cm is just the multiplication fact 8 times 6.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 4 cm sides, so one triangle uses 4 cm three times.

4 \times 3 = 12

Three sides of the same length is simply 4 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 12 cm pieces fit in 48 cm. Because 12 times 4 equals 48, exactly 4 triangles can be made with no wire left over.

48 \div 12 = 4

Finding how many equal groups of 12 make 48 is the same as knowing the factor pair 12 and 4 of 48.

Answer: 4 triangles

Review

4 triangles use 12 times 4 = 48 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 12 cm from 48 cm and count the 4 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 8 by 6 for the total wire length and 4 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 48 splits into equal groups of 12, giving 4 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 9 answer: 4 triangles

A piece of wire is as long as a $12\ \text{cm}$ stick laid end to end $4$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $4\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 12 cm stick placed end to end 4 times. Each triangle is made of three 4 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 12 cm stick laid end to end 4 times.
Each triangle has three sides, each 4 cm long.

Unknowns

The greatest number of 4 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 4 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 12 cm length repeated 4 times, so multiply 12 by 4.

12 \times 4 = 48

4 equal lengths of 12 cm is just the multiplication fact 12 times 4.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 4 cm sides, so one triangle uses 4 cm three times.

4 \times 3 = 12

Three sides of the same length is simply 4 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 12 cm pieces fit in 48 cm. Because 12 times 4 equals 48, exactly 4 triangles can be made with no wire left over.

48 \div 12 = 4

Finding how many equal groups of 12 make 48 is the same as knowing the factor pair 12 and 4 of 48.

Answer: 4 triangles

Review

4 triangles use 12 times 4 = 48 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 12 cm from 48 cm and count the 4 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 12 by 4 for the total wire length and 4 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 48 splits into equal groups of 12, giving 4 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 10 answer: 5 triangles

A piece of wire is as long as a $5\ \text{cm}$ stick laid end to end $6$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $2\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 5 cm stick placed end to end 6 times. Each triangle is made of three 2 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 5 cm stick laid end to end 6 times.
Each triangle has three sides, each 2 cm long.

Unknowns

The greatest number of 2 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 2 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 5 cm length repeated 6 times, so multiply 5 by 6.

5 \times 6 = 30

6 equal lengths of 5 cm is just the multiplication fact 5 times 6.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 2 cm sides, so one triangle uses 2 cm three times.

2 \times 3 = 6

Three sides of the same length is simply 2 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 6 cm pieces fit in 30 cm. Because 6 times 5 equals 30, exactly 5 triangles can be made with no wire left over.

30 \div 6 = 5

Finding how many equal groups of 6 make 30 is the same as knowing the factor pair 6 and 5 of 30.

Answer: 5 triangles

Review

5 triangles use 6 times 5 = 30 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 6 cm from 30 cm and count the 5 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 5 by 6 for the total wire length and 2 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 30 splits into equal groups of 6, giving 5 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 11 answer: 5 triangles

A piece of wire is as long as a $10\ \text{cm}$ stick laid end to end $3$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $2\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 10 cm stick placed end to end 3 times. Each triangle is made of three 2 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 10 cm stick laid end to end 3 times.
Each triangle has three sides, each 2 cm long.

Unknowns

The greatest number of 2 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 2 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 10 cm length repeated 3 times, so multiply 10 by 3.

10 \times 3 = 30

3 equal lengths of 10 cm is just the multiplication fact 10 times 3.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 2 cm sides, so one triangle uses 2 cm three times.

2 \times 3 = 6

Three sides of the same length is simply 2 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 6 cm pieces fit in 30 cm. Because 6 times 5 equals 30, exactly 5 triangles can be made with no wire left over.

30 \div 6 = 5

Finding how many equal groups of 6 make 30 is the same as knowing the factor pair 6 and 5 of 30.

Answer: 5 triangles

Review

5 triangles use 6 times 5 = 30 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 6 cm from 30 cm and count the 5 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 10 by 3 for the total wire length and 2 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 30 splits into equal groups of 6, giving 5 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Variant 12 answer: 8 triangles

A piece of wire is as long as a $9\ \text{cm}$ stick laid end to end $8$ times. Using this wire, what is the greatest number of triangles you can make if each triangle has three sides that are all $3\ \text{cm}$ long?

Show solution

Understand

A wire is as long as a 9 cm stick placed end to end 8 times. Each triangle is made of three 3 cm sides. We want the greatest number of such triangles the wire can make.

Givens

The wire length equals a 9 cm stick laid end to end 8 times.
Each triangle has three sides, each 3 cm long.

Unknowns

The greatest number of 3 cm equilateral triangles the wire can make.

Constraints

Each triangle uses exactly 3 sides of 3 cm.
Whole triangles only (you cannot use part of a triangle).

Plan

#7 Identify Subproblems · also uses: #8 Analyze the Units

Break the problem into small steps: first find the total wire length, then find how much wire one triangle needs, and finally see how many triangles fit. Tracking centimeters keeps the multiplication and division lined up correctly.

Execute

#7 Identify Subproblems 3.OA.B.5

The wire is a 9 cm length repeated 8 times, so multiply 9 by 8.

9 \times 8 = 72

8 equal lengths of 9 cm is just the multiplication fact 9 times 8.

#8 Analyze the Units 3.OA.B.5

Each triangle has three 3 cm sides, so one triangle uses 3 cm three times.

3 \times 3 = 9

Three sides of the same length is simply 3 added three times, an easy times-three fact.

#7 Identify Subproblems 4.OA.B.4

See how many 9 cm pieces fit in 72 cm. Because 9 times 8 equals 72, exactly 8 triangles can be made with no wire left over.

72 \div 9 = 8

Finding how many equal groups of 9 make 72 is the same as knowing the factor pair 9 and 8 of 72.

Answer: 8 triangles

Review

8 triangles use 9 times 8 = 72 cm, which is exactly the whole wire, so the answer fits with nothing wasted and the magnitude is sensible.

You could repeatedly subtract 9 cm from 72 cm and count the 8 subtractions, which is the repeated-subtraction view of the same division.

Standards · min grade 4

3.OA.B.5 Apply properties of operations as strategies to multiply and divide — Multiplying 9 by 8 for the total wire length and 3 by 3 for one triangle's wire.
4.OA.B.4 Find all factor pairs and recognize multiples; determine prime or composite — Recognizing that 72 splits into equal groups of 9, giving 8 triangles.

💡 Find the whole length, find one triangle's length, then split into equal groups -- only Grade 4 grouping you already know!

Different factor pairs, same product · 12 practice problems

Generated variants — 12

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Standards · min grade 4

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Standards · min grade 4

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Execute

Review

Standards · min grade 4

Understand

Plan

Execute

Review

Standards · min grade 4

Understand

Plan

Execute

Review

Standards · min grade 4

Understand

Plan

Execute

Review

Standards · min grade 4

Understand

Plan

Execute

Review

Standards · min grade 4

Understand

Plan

Execute

Review

Standards · min grade 4

Understand

Plan

Execute

Review

Standards · min grade 4

Understand

Plan

Execute

Review

Standards · min grade 4