Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Structural Design Practices Payload interfaces to launch vehicles.

Slides:

Advertisements

Similar presentations

“Houston: We Are Go For Exploration!”

Advertisements

Concept Overview for 2 mt Case “2 mt case”: integrated payloads of no more than 2 mt can be landed on the surface of Mars; extension of current Mars EDL.

SPACECRAFT ACCIDENTS: EXAMINING THE PAST, IMPROVING THE FUTURE Apollo 13 Bryan Palaszewski working with the Digital Learning Network NASA Glenn Research.

Presented by Marco Christov at the 11th Mars Society Annual Convention, 14 – 17 August 2008, Boulder Colorado. A Mars Heavy Transport.

National Aeronautics and Space Administration Presentation to the NASA Goddard Academy 2. Constellation Overview Ken Davidian Lead, Commercial.

Ares V RFI Point of Departure Information Package

Exploration Launch Office Scope

Lessons from Apollo * Data from NASA Apollo 11 Press Kit Shows spacecraft weight delivered to LEO (Low Earth Orbit) Shows weights for each portion of Apollo.

Delta II –7920 Fitup Study Model TMA-56 f10 optics In-Line configuration Delta II Launch Vehicle 7920 H 10L Composite Fairing.

Design Goals Saturn V Ariane 4 Pegasus Vanguard Bellerophon ? ? ?

The Google Lunar X PRIZE is a competition begun in The first privately funded team to send a robot to the Moon wins $20,000, In order to win.

Science Alan Shephard, Jr. was the first American, and the second man in space to sub-orbit the earth. This was on the Freedom 7 mission He was.

The Lander is at a 25 km Lunar altitude and an orbital period of approximately 110 minutes. After separation occurs the Lander is completely self sufficient.

April, 1981 First Reusable Shuttle October, 1958 Let’s Begin 1960 TRIOS Program October, 1958 Project Mercury July, 1969 Apollo Mission 11 January, 1962.

Traveling in Space 1.The Space Agency 2.Unmanned Space Vehicles 3.Manned Space Vehicles 4.Equipment needed in Space 5.The Future of Space Exploration NASA.

May 01, 2013 Apply (EDP) knowledge to what we learned about space exploration  Remember: Step 1 of the EDP is to identify a need. (1) Identify the needs.

“Fly me to the Moon”. Few can argue there is a more exciting vehicle than the Saturn V One of the most successful craft ever built by NASA, no payload.

The Return to Space Exploration Constellation. NASA Authorization Act of 2005 The Administrator shall establish a program to develop a sustained human.

A3 Altitude Test Facility

Unit 4 vocabulary/ page 44 L.1/ What caused the explosion? 1F. Dwaikat.

Oh, Thank Heaven for 7-Eleven: Fueling Up in Space with In-Situ Resource Utilization ASTE-527 Final Presentation Riley Garrett.

Physics 112 Star Systems Lecture 6 To The Moon Kevin H Knuth University at Albany Fall 2013.

NATIONAL AERONAUTICS & SPACE ADMINISTRATION (NASA)

Mechanical SuperNova/Acceleration Probe SNAP Study Dave Peters George Roach June 28, a man who's willing to make a decision in the first place can.

Race to Space!. Wernher von Braun: Father of Space Exploration Along with other German scientists, developed the first rockets during and after World.

Sputnik On October 4, 1957, the former Soviet Union launched the first artificial satellite into orbit around Earth. It was called “Sputnik”, the Russian.

What to do with Space Station Poo 1. 2 David Heck Advanced Manufacturing Research & Development Boeing – Phantom Works, St. Louis, Mo SEND IT TO THE MOON.

Vibration Isolation Box Design a system for dampening out the vibrations associated with launch and landing for a box that will fit inside a middeck locker.

LAUNCH VEHICLE DOWNSELECT A Wide Variety of Launch Systems Are Available Today Initial Downselect Constraint Based Upon UMRM Requirements Primary Payload.

The exploration of Mars has been an important part of the space exploration programs of the Soviet Union. Dozens of robotic spacecrafts, including orbiters,landers.

Before Shuttles _______________ All space flights were made with a single use craft _______________ Soviet Cosmonaut Yuri Gagarian 1 st human to orbit.

Introduction to the Altair Project

May 01, 2013 Apply (EDP) knowledge to what we learned about space exploration  Remember: Step 1 of the EDP is to identify a need. (1) Identify the needs.

America will send a new generation of explorers to the moon aboard NASA’s Orion crew exploration vehicle. After that, on to MARS!!!

The Moon Landing By; Coleman G. Apollo 11 crew On 16 July 1969, half a million people gathered near Cape Canaveral, Florida. Their attention was focused.

Journey to the Moon Saturn V rocket powers Apollo 11's lift-off from Kennedy Space Centre Journey to the Moon.

Rocket Propulsion Contents: Review Types of Rockets New concept 1 Example 1 Whiteboards 1,2,3Whiteboards123 Concept 2, Example 2Concept 2Example 2 Whiteboards:

Apollo Program By: Courtney McGrath why did we want to reach the moon?  Compete with the Soviet Union  Space Race vs.

What Makes Up the Space Shuttle? The space shuttle is the most complex machine ever created by human beings. The first shuttle was launched on April 12,

LEO Propellant Depot: A Commercial Opportunity? LEAG Private Sector Involvement October 1 - 5, 2007 Houston, Texas LEAG Private Sector Involvement October.

Rocket Performance Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Parametric Design The Design Process Regression Analysis Level I.

Early Space Flight Sustain Life in Space Passenger versus Pilot Duration (4 days) Return to Earth Spacecraft: Vostok Mercury X-15.

Arkansas Workforce Grant Student Experience Melissa Reed

2 AR Reading until 10:29. Student Planner May 7, 2015 Place this in the proper place Vocabulary Test Monday You need planner, notes, pen/pencil, spacecraft.

May 8, 2014 Apply your engineering design process (EDP) knowledge to what we learned about our space exploration efforts.  Remember: Step 1 of the EDP.

NASA. National Aeronautics and Space Administration Founded in 1958 as a result of the Soviet Unions launch of Sputnik.

China! Sputnik! Early Space Flight Sustain Life in Space Passenger versus Pilot Duration (4 days) Return to Earth Spacecraft: Vostok.

Is There Anybody Out There? Next People in Space People such as Timothy Peake are fixing the I.S.S (International Space Station), which is a well- known.

Preliminary Cost Analysis Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Preliminary Cost Analysis Cost Sources Vehicle-level Costing.

Launch Structure Challenge - Background Humans landed on the moon in 1969 – Apollo 11 space flight. In 2003, NASA started a new program (Ares) to send.

Micro Arcsecond X-ray Imaging Mission Pathfinder (MAXIM-PF) Mechanical George Roach Dave Peters 17 May 2002 “Technological progress is like an axe in the.

Dave McGrath ACM Chief Engineer February 18, 2010

An Earth – Moon Transportation System Patrick Zeitouni Space Technology.

Space Exploration Timeline By: Emily Landers  1900-The scientist Tsiolkolsky started testing rockets.  1914-The scientist Goddard patented.

The word "rocket" can mean different things. Most people think of a tall, thin, round vehicle. They think of a rocket that launches into space. "Rocket"

SLS Derived Vertical Habitat

How Astronauts Got Launched to the Moon Created by: Luke Sharman.

An Insiders View of the US Space Programs Dennis O’Connor, PE.

Nathan Holt & Steve Case April 2006

The Space Race How it all Began.

Space Grant Symposium Presentation

The Space Race How it all Began.

External Relations Office

Pioneering Achievement

Pioneering Achievement

Ares I System Requirements Review (SRR)

Telescopes Telescopes come in several types.

Physics 112 Star Systems Lecture 6 To The Moon Kevin H Knuth

Introduction to the Altair Project

THE MOON LUNA MOND LUNE.

Presentation transcript:

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Structural Design Practices Payload interfaces to launch vehicles Examples of structural design approaches from past space vehicle structural designs © 2002 David L. Akin - All rights reserved

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Shuttle Payload Restraint Configurations

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Orbiter Active Latches

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Orbiter Passive Latches

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Atlas V Payload Fairing Configuration

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Delta IV Bolted Payload Attach Fitting

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Delta IV Pyro Payload Attach Fitting

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Delta IV Marmon Band PAF

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V First Stage (S-IC) Cutaway

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-IC Intertank Fairing

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-IC Intertank Assembly

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-IC Ground Handling

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND N-1 Ground Handling

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Buran Ground Handling

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-II Stage Stacking

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-II LOX Tank Cutaway

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-II Stage Engine Cluster

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-II Thrust Structure Detail

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-II Interstage Jettison

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND N-1 Launch Vehicle Interstages

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Saturn V S-IVB/J-2 Thrust Structure

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Mercury Spacecraft Layout

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Mercury Spacecraft Assembly

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Gemini Spacecraft Equipment Arrangement

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Apollo Spacecraft Components

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Soyuz Spacecraft Design

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Lunar Module Overall Configuration

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Lunar Module Ascent Stage Structure

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Lunar Module Ascent Stage Structure

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Lunar Module Descent Stage Structure

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Lunar Module Descent Stage Structures

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND Soviet Lunar Lander Concepts

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND LK Lunar Landing Vehicle

Structural Practices Principles of Space Systems Design U N I V E R S I T Y O F MARYLAND LK Spacecraft on Moon