PRE2016 3 Groep19: Difference between revisions

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'''1. Suicide at end of life'''
'''1. Suicide at end of life'''
One option is to have the device, at the end of its life, send itself to either the graveyard belt in space or the spacecraft cemetery on Earth. So basically, after it has done its duty cleaning debris from space, it will clean the space from itself. This way, there will not be created any new space debris in LEO. However, one could argue that this is a bit of a waste of material investment.  
One option is to have the device, at the end of its life, send itself to either the graveyard belt in space or the spacecraft cemetery on Earth. So basically, after it has done its duty cleaning debris from space, it will clean the space from itself. This way, there will not be created any new space debris in LEO. However, one could argue that this is a bit of a waste of material investment.  


'''2. Recycling'''
'''2. Recycling'''
Another option could therefore be to recycle (parts of) the device. This can be done in space, so for example by sending incomplete satellites into space and then finishing them in space, like for example the DAPRA project (see section “Getting rid of space debris”, subsection “Recycling of space debris”).
Another option could therefore be to recycle (parts of) the device. This can be done in space, so for example by sending incomplete satellites into space and then finishing them in space, like for example the DAPRA project (see section “Getting rid of space debris”, subsection “Recycling of space debris”).


'''3. A space docking and repair station'''
'''3. A space docking and repair station'''
The last option is having a space docking and repair station. This is a bit of an ‘in- between’ option, since eventually the device is just not repairable anymore. At this point one of the two option above needs to be combined with the repair station.
The last option is having a space docking and repair station. This is a bit of an ‘in- between’ option, since eventually the device is just not repairable anymore. At this point one of the two option above needs to be combined with the repair station.


== References ==
== References ==

Revision as of 15:23, 16 March 2017

Space Debris

Group members

  • Jeanpierre Balster - 0864027
  • Mike Beckers - 0943224
  • Elise Levert - 0883583
  • Joël Peeters - 0939193
  • Kady Schotman - 0958295
  • Elise Verhees - 0950109

Planning

A rough planning of the whole project containing the milestones in the process:

Week 1: Decide on the subject by brainstorming.

Week 2: Do some basic research about the chosen subject and make a presentation about it (including objectives and approach).

Week 3: Create a planning (inclusive a presentation about it), finalize definition deliverables, define milestones. Start working on specific tasks of the literature research.

Week 4: State-of-the-art literature research. Decide solution on Thursday.

Week 5: Do further more detailed literature. Begin Netlogo simulation.

Week 6: Refine solution based on literature. Continue on Netlogo simulation.

Week 7: Finalize NetLogo deliverable.


A Gantt chart of the planning is given below. LR is literature research. SR is solution research, so combining the knowledge from the literature research to find the best solutions. For more detailed explanation on the different tasks, see section 'Approach'.

GanttChartGroup19.jpg

Case study

Group 19 will work on researching a space cleaning robot. This is currently a relevant problem; millions of pieces of space debris are orbiting the Earth. These pose a threat to satellites and spacecrafts which can collide with the debris (forming even more debris). Even if from now on nothing would be shot into space anymore, the amount of space debris would still increase, since pieces of debris can collide with each forming new pieces of debris. The problem needs to be solved using an Artificial Intelligent autonomously functioning device, since it is not possible to control the device from Earth, due to the time it would take to receive and send information from and to space (the debris would already be out of reach before the information is send back to Earth). The robot should be able to autonomously complete the following tasks: locate the debris, either collect and store the debris or push it in the right direction, return to Earth. Furthermore, research should be done on how to get rid of the debris. Will the robot burn the debris upon reentering of the Earth's atmosphere or will it bring he debris back to Earth (for the use of recycling).

Objectives

The objectives are answering the following research questions through literature research:

Furthermore, a NetLogo simulation will be made.

Approach

The approach is to realize the following deliverables:

1. A literature research on:

  • The current impact of the space debris on society
  • The current impact of the space debris on enterprises
  • The current ways of finding space debris
  • The current ways approaching the debris (to catch it)
  • The current ways of retrieving debris from space (catching and storing or pushing in the right direction)
  • The current ways if getting rid of the debris (burn up/bring back to Earth)
  • The current ways of returning the device to earth

2. A concept for the best solution / improving existing solutions

  • The impact of the solution on society
  • The impact on enterprises of the solution
  • The best way to find debris
  • The best way to approach it
  • The best way to retrieve the debris from space
  • The best way to get rid of it
  • The best way to return to earth

3. A Netlogo simulation

  • Which will simulate the search path
  • Which will simulate transporting the debris

USE aspects of space debris

Society on earth

As long as humans have existed, objects from space have hit the earth’s surface. People even think that it was a meteorite that once killed most of the organisms on Earth, including dinosaurs (Choi). A well-known and recent example is the meteorite that hit Russia in 2013. In this occasion at least 1200 people were injured (Sample). In November 2016, in Myanmar, a mining facility became the crash site of a huge piece of space debris (Galeon, BBC.com). What is special about this particular crash is that the object that crashed was clearly not an object originating from space. Some smaller pieces of debris with Chinese markings on it even destroyed the roof of a house nearby. In fact, NASA estimated that the odds of being hit by space debris is 1 in 3200 (Mortillaro). In comparison, the odds of dying in a car accident is 5000 to 1 while winning the lottery is a chance of 175 million to 1 (Amadeo).

The impact of space debris on society is not limited to debris as projectiles. The debris could hit working satellites, and as our lives revolve around the information they provide, it is important to keep the working satellites working. In February 2009, two communication satellites collided accidentally (Dunbar). Satellites are put in orbits around the Earth in such a way to decrease the chances of them colliding. When a collision occurs between two of them, more debris is created. Imagine all the possible collisions between satellites and space debris that could occur at any moment. Now consider how any one collision multiplies the odds of another collision occurring. These collisions damage the satellites we depend so much on. The BBC wrote an article about what would happen if all satellites would stop working at the same time. Although this is very unlikely, the effect of it would be tremendous. From missing the morning news show at breakfast to not being able to reach your overseas colleagues at work immediately, satellites are an integral part of daily life. GPS would stop working, so you would also be limited to getting around using an old school map. These are small, inconvenient changes, but the missing weather information makes things such as air traffic a lot more difficult. In fact, air traffic could be entirely impossible due to the difficulties faced with limited communication. Satellites are also relevant when considering wars where drones are used to drop bombs; limited communication in this case could also have fatal consequenecs (Hollingham). Clearly, the lives we live today are made possible by the satellites in space. Space debris endangers these satellites and can consequently effect our daily lives.

Society in space

A crack in the window of the International Space Station.

Space debris also leads to danger in space itself. In June 2011, a piece of junk whistled 335 meters past the International Space Station(ISS). In March 2012, NASA ground control did spot another piece of space debris going near the station, but it was simply too late for the station to manoeuvre to a safer orbit. It missed the ISS by 12 km (Weinberger). In May of 2016, Tim Peake (a British astronaut, who was at the ISS at the time) tweeted a picture of one of the ISS windows with a chip in it. It was caused by space debris of only thousands of a millimeter across(Placko). Currently the NASA worries about every piece that is larger than a baseball, however, there are more than 21000 pieces of manmade space debris with this size (Lewis). “Being hit by a ‘sugar-cube’ of space debris is the equivalent of standing next to an exploding hand-grenade” (Clark). But clearly, every piece of space debris poses a threat to life in space.

The impact on people all over the world after each of the space disaster in which people died has been enormous. But people know that the launch and return are dangerous parts of the travel to space. Losing a life within space could lead to an even bigger shock worldwide, and is something we desperately need to prevent.

Enterprises

Back in 2001 Dennis Tito became the first space tourist after paying 20 million pounds (Wall). Since then, 6 more people have made the trip, with the last one going in 2009. One of them event went twice (the Guardian). These days, companies are trying to launch affordable flights to space (Jee). With Virgin Galactic promising to start commercial flights in 2016, and SpaceX wanting to fly passengers on private trips around the moon in 2018, space tourism is really something of the near future (Cofield). Futron, an aerospace and technology consulting firm, predict that space tourism could become a billion-dollar market within 20 years ("The Economic Impact of Commercial Space Transportation on the U.S. Economy in 2009"). Combine this with the 700 tickets sold, as of 2014, by Virgin Galactic(Howell) it is important that space is as clean as possible, to prevent accidents. With 21 people losing their lives due to accidents (Venugopal), failures of technology, design and management are risks of space travel everyone is aware of. Awareness of space junk however is far away. It lead to British scientist and artist creating an online interactive project to raise awareness, about the 27000 pieces larger than 10cm, travelling at 8 kilometers a second (Carpeneti).

The Swiss Space Systems (S3) created the CleanSpace One, which is slated to launch in 2018. The costs of this? About 16 million dollars. Another method, named Laser Orbital Debris Removal (LODR) would cost 1 million dollar per object to be cleaned up (Markham). Astroscale, a Singapore-based company, has secured a 30 million dollar funding, in order to create two pieces of technology(Mckirby), one for finding debris smaller than a millimeter, and the ADRAS1, an adhesive-smeared spacecraft designed to stick onto debris and move it out of harm’s way. These are just a few of the many projects started to clean up space, making it obvious, that cleaning up space is going to cost millions, if not billions. But money is not only involved with the cleaning up of space, and tourism. The satellites getting damaged cost money too. Launching new satellites into space, costs between 11,3 and 34,5 million dollars per ton (Smith). The costs of new satellites, or repairing them, makes it worth to invest into cleaning up space, even though this is very expensive.

Why enterprises are forced to care about space debris by governments

Enterprises will be forced to take into account space debris that orbits Earth in Low Earth Orbit ( LEO). This is both due to explicit regulatory requirements as well as to customer demand. In this section, governments pressure on enterprises will be discussed.

Since the problem of space debris in LEO is increasing, governments like the US government have been introducing regulations to minimize further increment of debris. Elsewhere, in for example Europe, the European Union is doing something similar adopting a Code of Conduct including debris-mitigation measures. All these requirements can be combined to one widely applicable standard, which is expected to happen in the near future. This standard can then be enforced in laws or in a treaty. These requirements have to be followed by governmental organizations, but also by non-governmental ones (enterprises). This way, as the title already states, enterprises are forced to care about space debris by governmental regulations.

At the moment, there are not yet many requirements levied by law or regulation. The following list sums up the current requirements:

  • Commercial space launch operations are not allowed to generate space debris on purpose.
  • Components of the launch system are not allowed to collide with each other (creating space debris).
  • Commercial space launch operations should passivate the launch vehicle. This means they should deplete propellants, pressurant gasses, and batteries.
  • In some regulations, commercial satellites should have end-of-life disposal.

However, no requirements exist for the safe disposal of launch vehicle hardware by commercial launches. So at what time this hardware is left in Earth orbit. Such requirements will probably be included in laws/regulations in the future. If not, commercial launch providers will still have to deal with this, since government customers will have their own internal requirements. Government customers are the main clients of launch providers, so this will lay an increasing pressure on the providers to satisfy the requirements of the customers.

Unfortunately for the enterprises, these requirements will cost the commercial launch providers money. This is in conflict with minimizing costs, which is of great importance in the commercial world. A lot of research will have to be done on low-cost debris mitigation technologies. (Schilling)

Retrieving Mechanisms

Electrodynamic tethers can be used to remove space debris. In this option, the tether attaches itself to a piece of debris and current is induced along the tether. A Lorentz force is created between the tether and Earth’s magnetic field, causing the space debris to accelerate. This can significantly decrease the time needed for the object to de-orbit, particularly for debris close to earth (Barbee).

A momentum exchange tether could also be used to change the path of debris. Here, the tether, moving at high speeds, will attach to a slower moving piece of debris. If the debris is released at its highest retrograde velocity, then it will come closer to the atmosphere (lower perigee) (Barbee).

Lasers for vaporization are rather unfeasible as they require high precision and power. The debris moves quickly and somewhat unpredictably, so the precision is a huge issue. Also, the power requirement is beyond our current capabilities. The object could also potentially explode if it contains some unspent propellent. A laser in space could even infringe upon UN regulations (Barbee).

Surface material could be sent into space and affect the travel path of all objects which hit it. The object would be at risk of breaking and creating more space debris (Barbee).

Reflective Solar Sails are another alternative. They could attach onto debris, and as solar photons strike the sail, the object will in turn accelerate. The issue with solar sails is that it may not significantly alter the acceleration of the orbiting bodies unless it is acting on the body for months. At low altitudes this technology couldn’t be used due to corrosion (Barbee).

Another general concept is to produce streams of air from within the atmosphere that will be directed towards debris to change its travel path. Methods of producing these air streams vary from balloons to high altitude planes. This approach could affect multiple pieces of space debris in one attempt and is at no risk of creating more space debris if it fails (David).

The use of ion beams is also considered to help move debris; one such example is the Ion Beam Shepherd. The concept is to create an ion beam which will produce a force that can propel the debris forward. This also forces the mission to move in the opposite direction with the same force; thus, two beams are necessary in order to move the debris forward and keep the mission in the same position relative to the debris (Zuiani).

A net mechanism could be used. This would consist of four mass which will be shot out with a spring. The masses will pull the net out and surround the debris. The net size can be rather easily adjusted. This net is attached to a tether which is controllable using a reel and a motor. The net, once encompassing the debris, will close behind the target and tighten slightly. The object, now captured, will be slowed down and sent on a new travel path (Bischof).

Considerations for our project

For our purposes, the vaporisation lasers, surface material, and streams of air are almost immediately out of consideration. We plan to create a software that will create a travel path to the debris, so these capture mechanisms would not be of use to us. A solar sail can also be put aside as the concerns for this mechanism seem to be too technical for us to investigate. The amount of drag produced by solar photons may be near impossible for us to learn and estimate in the time needed. This leaves the tethers, ion beams, and nets. The tether seems to be the most popular mechanism used in space debris missions. The electrodynamic tether may be much more efficient than the momentum exchange tether, as the momentum exchange tether requires more control. The net seems a bit difficult to execute, as the encompassing and closing of the object requires even more control than the tether. The ion beam may require less control, since it does not require any contact.

Research has been conducted by F. Zuiani and M. Vasile on the topic of debris removal missions by means of simplified models for low-thrust, many-revolution transfers using the Ion Beam Sheperd (IBS), which is a spacecraft developed both by JAXA and Bombardelli. In this paper it's stated that one could use a concentrated solar beam instead of an ion beam, however this method has various drawbacks compared to the ion beam. They referred to research carried out by M. Vasile, C. Maddock and C. Saunders on the topic of orbital debris removal with solar concentrators. From their research it can be concluded that the most effective way is to use a network of satellites which send a laser towards a reflective disk which concentrates these lasers on the target. This method however is a variation of the vaporisation laser method which we have already ruled out. The other method, which did not use laser satellites, would require a larger reflector and will use sunlight to cause the enhanced Yarkovsky effect. This method in itself is very fuel-efficient since it only uses direct sunlight to work.

Their paper states it will take 3 satellites with each a 5m diameter reflector 1 year to move a 1 ton rocket from GEO orbit to the graveyard orbit, which usually requires around 11 m/s delta-V. To compare, the IBS takes about one month to reduce the altitude from 1000 km to 500 km, assuming an Isp of 2700 s for both thrusters and a beam momentum transfer efficiency of 0.8. This is a significant difference, since this is a lot faster than using the reflectors. The concentrated solar beam is therefore not recommended for larger objects, both because these tend to have a lower AMR and also because they're heavier. Our focus will primarily be on larger objects, so the usage of an ion beam is therefore the best option.

Getting rid of space debris

Burning in atmosphere

Often space junk gets attracted by the Earth and starts to fall down, but most of it burns up in the atmosphere and will never reach the surface (Redd). This could also be used as a method to actively get rid of the space debris through burning the debris in the Earth’s atmosphere on purpose. However, how will this affect the Earth’s atmosphere and to which dimensions of space debris would this physically be possible.

When pieces of debris fall down, nearly all thrash bigger than 10 cm will not entirely burn up, but instead be fragmented into smaller pieces. These pieces will fall into water most of the time since about 70% of the Earth’s surface is water (Redd), but when deliberately sending debris into the Earth’s atmosphere one wants to make sure that no large chunks start raining down and damage property. There are two important factors that influence the extent to which a piece of space debris will burn up. First of all, the size; obviously smaller pieces are more likely to burn up entirely then larger ones. Secondly, the speed with which the atmosphere is entered. The Earth’s atmosphere is full of matter, which means that a lot of friction is created when space junk speeds through it with high velocity. Friction creates heat. Heat, when reaching the boiling point of the debris, vaporizes the space debris layer by layer. ("How big does a meteor have to be to make it to the ground?") But even more important, due to the high kinetic energy, the air in front of the debris will get compressed and compressing air means its temperature will increase. However, it is a bit more complicated, since size plays yet another role: smaller pieces slow down more quickly since the friction is very large compared to their mass. Eventually they might just start drifting down. This means that sometimes, very small dust grains will not burn up whereas a bigger piece of debris would’ve melted away. (“Why burn up on entering Earth's atmosphere”)

It is therefore not possible to define one maximum size for a piece of space debris to get burned up in the atmosphere. By controlling the entrance speed of Earth’s atmosphere, it is possible to ‘change’ this maximum size. However, this will only work up to a certain size, so the very large chunks of space debris will never be able to entirely burn up in Earth’s atmosphere.

But what is exactly the (chemical) impact on Earth’s atmosphere of burning up all this space debris in it. In 1994 a study team commissioned by the Environmental Management Division of the Space and Missile Systems Center looked into the impact of burning space debris in the atmosphere on stratospheric ozone. Their findings were that ozone was affected. When space debris travels through the Earth’s atmosphere with high speed, a shock wave is created. This shock wave produces nitric oxide, causing a decrease in stratospheric ozone (known as ozone depletion). However, the impact is not significant on global level. (David)

Still, more research needs to be done on the density of particles, types of particles, and how long they are suspended in the atmosphere to determine the long term effect of actively pushing large amounts of space debris into the Earth’s atmosphere. (David)

Big space junk – burning or pushing away

The section above mainly focused on the smaller debris that is already orbiting the Earth for some time. But what is done with ‘new’ space debris, meaning for example old space stations and satellites that are nearing their end and have not yet been broken down into smaller pieces. These objects will likely be too large to entirely burn up in the Earth’s atmosphere.

At the moment there are two ways of getting rid of these satellites. Which way to go depends on how high the satellite is orbiting Earth.

Satellites closer to Earth will use their last bit of fuel to slow down. They will then fall out of orbit, and burn up in the Earth’s atmosphere. The smaller satellites might burn up to such an extent that they can do no harm anymore. However the bigger ones, like space stations and larger spacecraft in low orbit, will not entirely burn up before reaching the surface. To make sure such a space station does not crash down in for example a big city, space operators plan for their old satellites to crash down in the so-called spacecraft cemetery. This spacecraft cemetery is situated in the Pacific Ocean, as far away from any human civilization as possible.

Spacecraft cemetery in the South Pacific Ocean ("Where do old satellites go when they die?")

Satellites that are further away from Earth, would need more fuel to slow down than those closer to Earth. Most of these high orbiting satellites need less fuel to get farther away from Earth then to get back. Therefore, these satellites will be send even farther away from Earth instead of sending them back to Earth. Similarly to the spacecraft cemetery, these satellites will be send into a graveyard orbit. This orbit is almost 200 miles higher than where the farthest away active satellites are orbiting. Here they will continue orbiting, some of them for a very long time. For now, they will not be able to bump into the intact satellites and therefore will not cause any more debris to form. But may be some time in the future, humans need to send some kind of space cleaning device to get rid of these satellites. ("Where do old satellites go when they die?")

Recycling of space debris

Destroying space debris is one way of getting rid of it. Another option could be collecting reusable junk and recycling it. There is over a $300 billion worth of dead satellites drifting through space (Vijayaraghavan). The United States Department of Defense (DAPRA) is already working on a program called The Phoenix program that aims at recycling space debris (old satellites that stopped working). They are looking into recycling parts of broken satellites that can still be used to incorporate into new space systems. According to DAPRA director Regina Dugan "If this program is successful, space debris becomes space resource". The program wants to use a robot to reclaim still-working antennas from dead satellites which orbit the Earth in the graveyard orbit (see section about big space junk) and attach these antennas to new smaller satellites (satlets) launched from Earth. This would save a lot of launch costs, since antennas are big and bulky and they therefore need a lot of fuel to be send to space. Launching the satlets without antennas is thus much cheaper. (SPACE.com staff)

However, recycling space debris is not as simple as recycling plastic bottles. According to DARPA program manager David Bernhart: “Satellites in orbit are not designed to be disassembled or repaired, so it’s not a matter of simply removing some nuts and bolts. This requires new remote imaging and robotics technology and special tools to grip, cut and modify complex systems.” (Pultarova)

The robot that DAPRA is working on will have grasping arms and remote vision systems. The Phoenix program can make use of some existing ‘Earth technology’ to start with. These technologies include surgery systems that make it possible for doctors to do the surgery from thousands of miles away and remote imaging systems used by oil drillers to view as far as the ocean floor thousands of feet underwater. However, these systems need to be adapted to work in outer space where there will be no gravity, vacuum, and harsh-radiation. (SPACE.com staff)

Spacecraft movement

Right now, once in space, the current method of maneuvering space crafts is very much consistent over almost all devices: steering rockets. However, there are still several other techniques that can be used to achieve the same goal. Below, the two methods most relevant to our case have been explained.

1. Rocket engines or thrusters

Rocket engines work by bringing a gas to high pressure and temperatures, and then burning it in a combustion chamber with a small exhaust nozzle, allowing for a rapid escape of the gas, and causing the vehicle to be thrusted the other way. Because of the high speed build-up, rocket engines can work very efficiently, peaking at around 60 percent.

2. Ion beams

Ion thrusters send large electric currents through ions, allowing them to reach large speeds. The thrust these ions create while being hurled away allows for the movement of the vehicle These types of engines are very effective, requiring op to ten times less fuel than the standard rocket engine, and generally weigh much less. NASA has recently uncovered a system called NEXT, which manages these engines with great success.

Finding Space Debris

SPACETRACK is the current program for worldwide Space Surveillance Network(SSN). It consists of multiple dedicated electro-optical, passive radio frequency and radar sensors. The purpose of the SSN is not only space debris cataloging and identification but also satellite attack warning and space treaty monitoring. In total the SSN tracked 39.000 space objects.

Then there is the Air Force Space Surveillance System (AFSSS). Which is called “space fence” in common tongue. It consists of a network of very high frequency radar network located at multiple locations of south America. The system became operational in 1961 and tracked about 10.000 objects in space.

The United States Department of Defense(DoD) also maintains a space catalog. These catalogs are stored on multiple satellites and is regularly updated by the SSN. In the year 2001 the number of cataloged objects was about 20.000.

Improved tracking systems:

The current big state-of-the-art project for detection of space debris is the Lockheed Martin’s Space Fence Program. The program is currently still focussing on getting the system operational and the initial operational capacity is scheduled for 2018. The machine is constructed on Kwajalein Atoll in the Marshall Islands. There is already a second site planned to go online in 2021. The primary tasks regarding space debris of the system are the following:

  1. Detection
  2. Tracking
  3. Measurement
  4. Catalog

These action are performed for space debris more that 1.5 million times a day to predict and prevent collisions between debris and satellites or space stations. The system will primarily trace space debris at the low-earth orbit where the ISS performs operations for example. The space fence system predicts to simultaneously detect, track and characterize around 200.000 objects anywhere in its field of view. This would be a ten-fold increase in comparison to the current systems.

The improved performance comes from the combination of S-Band radars and Gallium High power amplifiers(GaH HPAs). Older radar system types uses the traditional Gallium Arsenide(GaN) and have approximately 50% less range as the GaH has. GaH is a efficient semiconductor material and outperforms the traditional GaH in the following aspects:

  • Higher Power Density: Increased range and detection sensitivity
  • Efficiency: Less energy consumption and less cooling
  • Operates at higher temperatures: More robust and so applicable in more situations

The ion beam

The ion beam shepherd (IBS) is a satellite that can emit two beams of accelerated quasi-neutral plasma; one beam will be directed towards a target and the second beam is used to keep the satellite within range of the target (typically 5 to 10 meters at least). A controller could be developed to ensure that the target and IBS remain within distance of each other as they move through space. This is especially an issue if the orbit is conical and not circular. In theory, the IBS would be able to hold a following distance in a perfectly circular orbit, but if an orbit is at all elliptical, the following pattern would change. Most orbits in the low earth orbit is quasi-circular, so this area will be most dependable for this technology (Bombardelli). An IBS sends high velocity ions to its target where the ions lose energy and momentum through ionizing collisions up until they abruptly stop nanometers away from the target’s surface. At this point, the surface material rejects the ion from its lattice, although occasionally surface material detaches due to a collision (sputtering). This effect can, however, be neglected. One main concern of the ion beam shepherd is the beam divergence. If this angle is minimal, the ion beam will be able to control the movement of its target from further distances. A higher specific impulse and system mass would allow the beam divergence to lessen, but clearly, this is a trade-off. Although the beam can be assumed to be conical for simplicity, the jet of plasma is not perfectly conical in reality (consider the effects of the magnetic field in space) (Bombardelli). The time needed for the IBS to move a target from a 1000 km orbit to a 300 km orbit using constant tangential thrust and a specific impulse of 2500 seconds is shown for various masses in the figure. For the 5 ton target, this goal is reached within a year. There are two relevant methods of advanced electric propulsion: ion engines and Hall effect thrusters. Although Hall thrusters are more compact and lighter, the ion engines are preferred, largely due to its lower divergence angle. A comparison of specific ion engines is included in these tables (Bombardelli). In order to move on with a representative ion engine, Bombardelli created a list of properties for a standard ion engine: initial radius of 0.1 m, Xenon as a propellant, electron temperature of 5 eV, initial mean plasma density of 2.6 · 1016 m-3, initial ion axial velocity of 38000 m/s, ion kinetic energy of 1 keV, mass flow rate of 6.85 mg/s, ion current of 5 A, initial plasma Mach number of 20, initial beam divergence parameter of 0.2, and a thrust force of 100 mN (Bombardelli).

Time needed to remove space debris of various masses (Bombardelli) Specifications of various ion engines (Bombardelli)

USE aspects of the ion beam

Society on earth

Society in space

Enterprises

As of right now, not much is (publically) known about the costs of the ion beam. The money invested in certain other space cleaning projects are known and to be found in the general enterprise aspect. It can be expected that the costs for the ion beam are not much different, therefore millions, but since ion beams are also used for cancer treatment (Preuss) , creating high quality ion beams for relatively low costs should be possible in the (near) future. Yet, even with minimum costs for the ion beam, the entire operations costs money, as more research is needed, and the ion beam needs to be send to space as well. For enterprises the ion beam may thus not be the greatest solution as it does not cost any less than the other solutions.

However, the money spend on this operation does pay back as well. NASA currently spends almost 7 million dollars a year tracking space junk (Adams). This number should drop once the bigger pieces of junk are cleaned up, as the NASA is currently only tracking the bigger pieces of junk. Since these have the greatest impact, these should be cleaned up first. Although (most likely several) one time investments have to be done, other costs will slowly drop after that. If companies will follow the rules set by governments, this could mean that in the long run, no more money has to be invested in the cleaning up of the LEO. Once the LEO is cleaned up, space tourism will be much more safe, and can really take off. This will eventually pay back the costs made to get rid of the space debris. Thus, the ion beam does provide a solution enterprises should be willing to invest in.

Life-cycle management

To come to the best solution we need to consider the whole life-cycle of our end product. This includes everything from building the device till the end of the life span of it. For this projects purpose, apart from developing the best solution concept for the space debris problem, we will mainly look into what happens after the mission is completed, called the “End of life (EOL) phase”. (Product Lifecycle Management)

End of life (EOL) phase

It is very important to decide on what will happen to the space clean robot at the end of its life because this will influence the choice of material and design. A few option will be discussed below.

1. Suicide at end of life

One option is to have the device, at the end of its life, send itself to either the graveyard belt in space or the spacecraft cemetery on Earth. So basically, after it has done its duty cleaning debris from space, it will clean the space from itself. This way, there will not be created any new space debris in LEO. However, one could argue that this is a bit of a waste of material investment.

2. Recycling

Another option could therefore be to recycle (parts of) the device. This can be done in space, so for example by sending incomplete satellites into space and then finishing them in space, like for example the DAPRA project (see section “Getting rid of space debris”, subsection “Recycling of space debris”).

3. A space docking and repair station

The last option is having a space docking and repair station. This is a bit of an ‘in- between’ option, since eventually the device is just not repairable anymore. At this point one of the two option above needs to be combined with the repair station.

References

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