moon_camp

Landing on the moon – Planning and designing a lunar lander

Brief description:

In this set of activities, students will plan, design and build a landing module to secure the survival of the crew (in the form of an egg-naut) landing on the Moon.

They will explore which factors should be considered when landing on the Moon, in comparison to landing on Earth.

In the design of the lunar lander, students must take risk factors and budgeting into account.
Subject: Science, Physics, Mathematics, Economics
Learning Objectives

  • Identify the forces involved in landing on the Earth and Moon surfaces.
  • Understand the relationship between mass and gravitational forces.
  • Solve a problem using Newton’s second law of motion.
  • Design a project taking into account a budget and risk management.
  • Work in a team under time and money constraints.
  •  
    Age range:
    14 – 16 years old
     
    Time
    Preparation: 1 hour
    Lesson: 2 hours and 30 minutes
     
    Resource available in:
    Activity 1: Design and build a lunar landing module

    In this activity, students will design and build a lunar landing module using simple materials. The objective is to design a lander that can safely land an egg-naut on the surface of the Moon. In their planning, students must consider the risks involved in a manned lunar lander mission and perform a risk assessment and a design study.
    Equipment

  • Student worksheet printed for each group
  • Paper
  • Straws
  • Marshmallows
  • Cotton-balls
  • Popsicle sticks
  • Plastic bag
  • String
  • Sellotape
  • Scissors
  • Balloons
  • Eggs – 1 per group
  • Scales
  • Activity 2: Test your landing module

    In this activity, students will test if their landers survive a vertical drop, keeping the egg-naut safe. They will describe the landing conditions and keep track of other factors that can influence the results. Optionally, students can film the drop and later use a video analysing tool to examine the acceleration.
    Equipment

  • Student worksheet printed for each group
  • Self-built landing modules including egg-nauts from Activity 1
  • Camera/camera-phone and tripod (Optional – see Annex 3)
  • Video tracking programme ( Optional – see Annex 3)
  • Computer or smartphone (Optional)
  • Activity 3: Landing on the Moon

    In this activity, students will compare landing on Earth with landing on the Moon. They will investigate the different factors influencing the landing in both locations and the forces diagram. Further, the students will re-iterate the design of their lander on what they have learned during the testing.
    Equipment

  • Student worksheet printed for each student
  • Pen/pencil
  • Calculator
  • Did you know?

    The total cost of the Apollo space programme that took humans to the Moon was $25.4 billion – that is more than $200 billion in today’s currency, adjusted for inflation. In 2018, ESA’s total budget was 5.6 billion Euros.

    Currently, space agencies and industry are working together to develop a more sustainable Moon exploration program. It should be noted that today we will still use part of the infrastructure created in the 1960s: test chambers, launch pads, mission control centres, ground stations, engineering knowledge, technology, materials and thus a lunar exploration program will be much more sustainable from the beginning.

    Buzz Aldrin at work at the Eagle landing module on the Moon