E D U C AT I O N Leeds School of Architecture (Leeds Beckett university) BA(hons) Architecture RIBA ARB - First class honors Cadbury College A level - Photography B - Media studies C - Psychology C Ninestiles School GCSE’s 12 A*-B grades.
J U B A L G R E E N PROFILE I am a very hard working, determined and enthusiastic person. I will always strive to do any task set to the best of my ability. Furthermore, I am a confident and can interact well with other people, including clients, co-workers and the public. I have a high amount of energy and would love to bring that forward. I will be moving to Amsterdam to live for a year in September and I would love to work with your team.
EXPERIENCE Colourblind kid Photography (founder) Started my own events photography company while at university. The collective has grown work with clients in a professional manor Clients include Volkswagen Group The Guardian news paper SKY corporation Red bull Beacons festival Various Club events BM3 architects Internship My first taste of the working architecture industry was a great way to work on real projects and learn the dynamic of an architecture practice. Broadway Malyan architects Internship Working with the team helped me gain valuable experience with CAD programs.
INTERESTS& AC H IE VEMENTS Email Jubalgreen@outlook.com Personal number +447854402332 Address 47 Holders Gardens Moseley Birmingham United kingdom
RIBA president’s award nomination I have been put forward to represent my university in the world renowned presidents medals. I am one of two students from the entire university and I feel honored to represent the prestige of my university Lifeguard qualification After years of swimming and training for my swimming team the opportunity to become a lifeguard was a logical step. The training accentuated the importance of responsibility and teamwork. Leeds Beckett Water-polo Team Becoming part of the University water-polo team has been a greatly rewarding experience. Our team winning the UPolo Cup 2012-13 Photography Photography and graphics have shaped the way I look at space. In my design I like to capture and reflect emotion, just like my photography. 3d Printing club During the year I perused a creativity in new materials and 3d printing, this entailed 3d printing fundamentals and maintenance.
J U B A L G R E E N RIBA ARB Part 1 Architecture Graduate
Name: Jubal Reuben Green Date of birth: 26th February 1993 Address: 47 Holders Gardens, Birmingham B13 8NW Email: Jubalgreen@outlook.com Website: jubalgreen.wix.com/architecture
2015
I have recently graduated with a first class degree in architecture equivalent to a RIBA and ARB part 1 qualification at the Leeds School of Architecture . I have also been nominated to receive the RIBA president’s award. The next stage of my professional development towards full qualification is to work for a year from September 2015 in an architectural practice. I would like to do this outside the United Kingdom in order to expand my horizons, and I particularly want to work in Amsterdam because of the Dutch reputation for design, style and innovation. As part of my course I have experience in a wide array of media both digital and physical including: Rhino Auto-CAD. Technical models. Hand drawn work. 3d printing maintenance and software use. Adobe suite. (Photoshop,InDesign) The Architecture course incorporated design at all levels of construction but also encouraged freethinking and design creativity. I look forward to hearing from you and hopefully meeting you very soon.
Yo u r s s i n c e r e l y Jubal Green
J U B A L G R E E N RIBA ARB Part 1 Architecture Graduate
REFERENCES Professor Teresa Stoppani (DrArch IUAV, Architetto IUAV, PhD Arch&UD Florence) Head of The Leeds School of Architecture 0113 81 21701 T.Stoppani@leedsbeckett.ac.uk
Dr Claire Hannibal (BA H Arch, BArch, PhD, PGCHE, ARB, RIBA, FHEA) Senior Lecturer & personal Tutor 0113 81 24071 C.Hannibal@leedsbeckett.ac.uk
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Spaceport 1:200 section
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- Superconducting orb. - Debris harvester. - Junk satellite 1 [Venus airship]. - Junk trade market. - Captains quarters. - Space elevator. - Droid repair module. - Crew quarters. - Processing Core. - Junk satellite 2 [Communications satellite]. - Junk satellite 3 [Spy satellite].
TITLES Body
TITLES Body
TITLES Body
TITLES Body
TITLES Body
Attached - Welded or tethered. Attached Possible uses - Quantum computing, Communications antennas aand threat or a tool for good. They come in a variety of forms with solid - Involuntary connection. Possible uses - Used for Secretive missions and information relay. Possible uses - weather observation and navigation. liquid and gas cores. Orbit - LEO (low earth orbit) Orbit - MEO (Medium earth orbit) 73 km spacing.
ossible uses - Filled and used for short distance travel and navigation. pulsion.
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G CABLES SPY SATELLITES
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DISUSED SATELLITES DATA RELAY SATELLITES
OBSERVATION SATELLITES
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COMMUNICATION SATELLITES
Mirror based Telescope
ntenna
eo location node
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Attached - Welded. Theuses practical uses of the satellite Possible - Interstellar observatio became a crop to be harvested an mapping, weather. used the port. Orbit - Geoby(Geostationary ea
Anti radar lining External koptan covering
Antenna
Satellite dish
Solar panel
Solar fuel cells
Signal receiver
Information compressor
Quantum Computer, encrypts signals
Geo Synchronous Clock Double walled hull
mount - 2000 units Mass - under 800kg per unit. cooled casing. ttached - Welded orantennas tethered. ng, Communications and ossible uses - Used for Secretive missions and information relay. rbit - LEO (low earth orbit)
Amount Mass Attached Possible uses Orbit
Solar cell
- 416 units - Each unit 2,028kg average. - Involuntary connection. - weather observation and navigation. - MEO (Medium earth orbit) 73 km spacing.
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Amount - 300 units. Mass - 94kg average. Attached - Welded. The Possible practicaluses uses -ofInterstellar the satellites observation, environmental monitoring, became a cropweather. to be harvested and mapping, port.(Geostationary earth orbit)/LEO (low earth orbit). Orbitused by the- Geo
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OBSERVATION SATELLITES
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COMMUNICATION SATELLITES
Mirror based Telescope
Satellite dish
Solar panel
Solar fuel cells
Information relay node
Information compressor Geo Synchronous Clock Solar cell
Amount - 300 units. Mass - 94kg average. Attached - Welded. Possible uses - Interstellar observation, environmental monitoring, mapping, weather. Orbit - Geo (Geostationary earth orbit)/LEO (low earth orbit).
verage. tion. n and navigation. th orbit) 73 km spacing.
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Informati node
Amount Mass Attached Possible uses
- 534 units. - Various. - Manned docking system. - Communication relay of television and Online data.
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Manual of parts I created a manual to asses the potential parts that could be salvaged from the space debris.
Amount Mass Attached Possible uses
- 534 units. - Various. - Manned docking system. - Communication relay of television and Online
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ProcessT IofT LaEcollision S Body
As two objects collide the parts break down and cause a cascade of debris, known as a debris cloud.
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APAS-89 docking system also used on Mir.
Modern Russian probe and drogue docking system of Salyut-1 type.
APAS-95 docking system manufactured by RKK Energiya.
Common Berthing Mechanism. Used as an international and commercial birthing mechanism.
International Space station.
Voluntary T I T L docking ES Body
The existing inhabitable modules left in space are connected via international birthing and docking mechanisms.
CombinedT Idocking T L E S systems Body
This visualisation shows the possibility of combining voluntary and involuntary docking systems to maximise the use of parts.
Space Debris is attached to an external body of mass such as an asteroid.
Space Debris attached to form a core of inhabitable space.
Space debris is attached as a cloud using bars.
Space debris attached as a core with external network of protective junk.
Sketch variations connection T I of T L Edebris S Body
The Debris can be connected in a multitude of ways, each alteration requires a different method of connection.
TITLES Body
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Spaceport 1:200 section
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- Superconducting orb. - Debris harvester. - Junk satellite 1 [Venus airship]. - Junk trade market. - Captains quarters. - Space elevator. - Droid repair module. - Crew quarters. - Processing Core. - Junk satellite 2 [Communications satellite]. - Junk satellite 3 [Spy satellite].
Inner space port section
Inner space port plan
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T I Tport L E Ssection and plan Inner trade space Body
1:500 A : Junk trade market B : Droid repair module C :Crew quarters
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6 1 - The captain plugged into the machine. 2 - Commercial docking node for client use. 3 - Node leading to crew quarters. 4 - Space elevator shaft leading to Greenwich. 5 - Captains interface, here the crew receive orders to alter the vessel. 6 - Node leading to droid repair module.
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Junk trade T I T market L E S plan 1:100 Body
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1 - Node exit leading to junk trade market. 2 - Droid works on the exterior of the vessel, to construct or reassemble spaceport. 3 - Crew members repair debris damaged drone. 4 - Pressurized exit chamber for droid use.
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Droid repair plan T I T Lmodule ES 1:50 Body
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1 - Node exit leading towards the Junk Trade market. 2 - Hatch leading to washroom and plant room. 3 - Medical/mechanical upgrade chamber. 4 - Hatch leading to traders vault. 5 - Sleeping quarters. 6 - communal node and training capsule.
Crew Tquarters I T L E S plan 1:50
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The captain
The client
The crew
The droids
The captain Is routed within the port itself. When a client purchases a satellite the captain ranges and re ranges the parts accordingly.
The Client Makes their way up the elevator to trade. Once the vessel is created they dock the ship and eject from the port.
The captain is fixed within the heart of the spaceport. More machine than man, the captain communicates the building alterations through the monitors to the crew.
The client arrives in the central chamber and chooses the necessary parts to build the vessel within his budget. Often parting with old or outdated parts as a physical trade. Other forms of trade accepted at the spaceport include precious metals and water.
The crew make adjustments to the programs and software running on the spaceport. They also provide service to the droids and pilot the harvesters.
The crew frequent the extremities of the structure and move between nodes to repair, finally returning back to the quarters.
The droids re arrange the ship into new configurations. They build new elements and spend long amounts of time in a vacuum. Eventually however they will become damaged by debris and require repair.
Movement around the site is mostly external with the occasional return for repairs.
Characters T I T L/Ehierarchy S Body
Communications satellite The Satellite is equipped with high frequency Satellite dishes. The vessel has the ability to reflect and process high levels of encoded information.
Venus atmospheric blimp The Blimp is made using the Kevlar materials used on ISS modules such as the Bigelow. The blimp is equipped with a turbine that extracts CO2 from the atmosphere of Venus.
Spy Satellite The spy satellite is made of a broken solar sail and nuclear core reactors, it has the ability travel great distances while expending little energy. It becomes almost undetectable when powered by solar ions.
VariationsTofI TDebris L E S Satellite Body
Navigating T I the T L Esolar S system Body
This model was created to help develop an understanding of the solar system and map out potential routes that could be taken.
Lagrange points capable of accommodating spaceports. Asteroid clusters Planets & potential resources Launch routes of the highway
Potential T I Ttrade L E S routes Body
The possibility of future growth and expansion of trade means huge potential for future development. This map shows the trade routes and future docking locations available in the near future.