Ever since the Pan Am “Space Clipper” first slid into frame in 1968’s “2001: A Space Odyssey”, the world has been waiting for the day that privately funded spaceflight would become as routine as air travel. Unfortunately, it’s a dream that’s taken a bit longer to become reality than many would have hoped. The loss of Challenger and Columbia were heartbreaking reminders that travel amongst the stars is not for the faint of heart or the ill-equipped, and pushed commercial investment in space back by decades.
Although Pan Am has since folded, we now have a number of companies working hard towards making the dream of commercial spaceflight a reality. SpaceX and Rocket Lab have shown private companies developing and operating their own orbital class vehicles is a concept no longer limited to science fiction. Now that private industry has a foot in the door, more companies are coming forward with their own plans for putting their hardware into orbit. In many ways we’re seeing the dawn of a second Space Race.
If all goes according to plan, a new challenger should be entering the ring in the very near future. Scheduled to perform their first test launch before the end of the year, Virgin Orbit (a spin-off of the passenger carrying Virgin Galactic) promises to deliver small payloads to Earth orbit faster and cheaper than their competitors. But while most other commercial space companies are using fairly traditional booster rockets to do their heavy lifting, Virgin Orbit is opting for a the less common air launched approach. Before Virgin joins the ranks of commercial companies exploring the final frontier, lets take a look at their plan for getting into space and the advantages it offers compared to the competition.
Continue reading “Virgin Orbit Readies First Launch”
Rockets with nuclear bombs for propulsion sounds like a Wile E. Coyote cartoon, but it has been seriously considered as an option for the space program. Chemical rockets combust a fuel with an oxidizer within themselves and exhaust the result out the back, causing the rocket to move in the opposite direction. What if instead, you used the higher energy density of nuclear fission by detonating nuclear bombs?
Detonating the bombs within a combustion chamber would destroy the vehicle so instead you’d do so from outside and behind. Each bomb would include a little propellant which would be thrown as plasma against the back of the vehicle, giving it a brief, but powerful push.
That’s just what a group of top physicists and engineers at General Atomic worked on between 1958 and 1965 under the name, Project Orion. They came close to doing nuclear testing a few times and did have success with smaller tests, exploding a series of chemical bombs which pushed a 270-pound craft up 185 feet as you’ll see below.
Continue reading “Project Orion: Detonating Nuclear Bombs For Thrust”
When planning a trip by car these days, it’s pretty much standard practice to spin up an image of your destination in Google Maps and get an idea of what you’re in for when you get there. What kind of parking do they have? Are the streets narrow or twisty? Will I be able to drive right up, or will I be walking a bit when I get there? It’s good to know what’s waiting for you, especially if you’re headed someplace you’ve never been before.
NASA was very much of this mind in the 1960s, except the trip they were planning for was 238,000 miles each way and would involve parking two humans on the surface of another world that we had only seen through telescopes. As good as Earth-based astronomy may be, nothing beats an up close and personal look, and so NASA decided to send a series of satellites to our nearest neighbor to look for the best places to land the Apollo missions. And while most of the feats NASA pulled off in the heyday of the Space Race were surprising, the Lunar Orbiter missions were especially so because of how they chose to acquire the images: using a film camera and a flying photo lab.
Continue reading “The Photo Lab That Flew to the Moon”
The Kepler spacecraft is in the final moments of its life. NASA isn’t quite sure when they’ll say their last goodbye to the space telescope which has confirmed the existence of thousands of exoplanets since its launch in 2009, but most estimates give it a few months at best. The prognosis is simple: she’s out of gas. Without propellant for its thrusters, Kepler can’t orient itself, and that means it can’t point its antenna to Earth to communicate.
Now far as spacecraft failures go, propellant depletion isn’t exactly unexpected. After all, it can’t pull into the nearest service station to top off the tanks. What makes the fact that Kepler will finally have to cease operations for such a mundane reason interesting is that the roughly $600 million dollar space telescope has already “died” once before. Back in 2013, NASA announced Kepler was irreparably damaged following a series of critical system failures that had started the previous year.
But thanks to what was perhaps some of the best last-ditch effort hacking NASA has done since they brought the crew of Apollo 13 home safely, a novel way of getting the spacecraft back under control was implemented. While it was never quite the same, Kepler was able to continue on with modified mission parameters and to date has delivered so much raw data that scientists will be analyzing it for years to come. Not bad for a dead bird.
Before Kepler goes dark for good, let’s take a look at how NASA managed to resurrect this planet hunting space telescope and greatly expand our knowledge of the planets in our galaxy.
Continue reading “Kepler Planet Hunter Nears End of Epic Journey”
In families with three kids, the middle child always seems to get the short end of the stick. The first child gets all the attention for reaching every milestone first, and the third child will forever be the baby of the family, and the middle child gets lost in-between. Something similar happened with the U.S. manned space program in the 60s. The Mercury program got massive attention when America finally got their efforts safely off the ground, and Apollo naturally seized all the attention by making good on President Kennedy’s promise to land a man on the moon.
In between Mercury and Apollo was NASA’s middle child, Project Gemini. Underappreciated at the time and even still today, Gemini was the necessary link between learning to get into orbit and figuring out how to fly to the Moon. Gemini was the program that taught NASA how to work in space, and where vital questions would be answered before the big dance of Apollo.
Chief among these questions were tackling the problems surrounding rendezvous between spacecraft. There were those who thought that flying two spacecraft whizzing around the Earth at 18,000 miles per hour wouldn’t work, and Gemini sought to prove them wrong. To achieve this, Gemini needed something no other spacecraft before had been equipped with: a space radar.
Continue reading “Radar in Space: The Gemini Rendezvous Radar”
With all the talk of SpaceX and Blue Origin sending rockets to orbit and vertically landing part or all of them back on Earth for reuse you’d think that they were the first to try it. Nothing can be further from the truth. Back in the 1990s, a small team backed by McDonnell Douglas and the US government vertically launched and landed versions of a rocket called the Delta Clipper. It didn’t go to orbit but it did perform some extraordinary feats.
Origin Of The Delta Clipper
The Delta Clipper was an unmanned demonstrator launch vehicle flown from 1993 to 1996 for testing vertical takeoff and landing (VTOL) single-stage to orbit (SSTO) technology. For anyone who watched SpaceX testing VTOL with its Grasshopper vehicle in 2012/13, the Delta Clipper’s maneuvers would look very familiar.
Initially, it was funded by the Strategic Defence Initiative Organization (SDIO). Many may remember SDI as “Star Wars”, the proposed defence system against ballistic missiles which had political traction during the 1980s up to the end of the Cold War.
Ultimately, the SDIO wanted a suborbital recoverable rocket capable of carrying a 3,000 lb payload to an altitude of 284 miles (457 km), which is around the altitude of the International Space Station. It also had to return with a soft landing to a precise location and be able to fly again in three to seven days. Part of the goal was to have a means of rapidly replacing military satellites should there be a national emergency.
The plan was to start with an “X” subscale vehicle which would demonstrate vertical takeoff and landing and do so again in three to seven days. A “Y” orbital prototype would follow that. In August 1991, McDonnell-Douglas won the contract for the “X” version and the possible future “Y” one. The following is the story of that vehicle and its amazing feats.
Continue reading “Delta Clipper: A 1990s Reusable Single-Stage To Orbit Spaceship Prototype”
There’s an Apollo module on display in Michigan and its cold-war backstory is even more interesting than its space program origins.
Everyone who visits the Van Andel Museum Center in Grand Rapids, Michigan is sure to see the Apollo Command Module flanking the front entrance. Right now it’s being used as a different kind of capsule: a time capsule they’ll open in 2076 (the American tricentennial). If you look close though, this isn’t an actual Command Module but what they call a “boilerplate.”
Technically, these were mass simulators made cheaply for certain tests and training purposes. A full spacecraft costs a lot of money but these — historically made out of boilerplate steel — could be made with just the pieces necessary and using less expensive materials. What you might not know is that the boilerplate at the Van Ardel — BP 1227 — has a cold war spy history unlike any other boilerplate in the fleet.
The early life of BP 1227 is a little sketchy. It appears the Navy was using it for recovery training somewhere between the Azores and the Bay of Biscay in early 1969. We don’t know for sure if the picture to the left is BP 1227 or not. Comparing it to the one at the museum, it probably isn’t, but then again the museum’s does have a fresh paint job and possibly a top cap. Regardless, the picture to the left was from 1966 in the Atlantic, giving us an idea of how boilerplate capsules were put into service.
In those days — the height of the cold war — Naval ships were often followed by Soviet “fishing trawlers.” These were universally understood to be spy ships — Auxiliary, General Intelligence or AGI vessels.
Continue reading “Spy Tech: How an Apollo Capsule Landed in Michigan after a Layover in the USSR”