Stanford torus

Stanford torus (the proposed 10,000 people habitat described in the 1975 Summer Study, to be distinguished from other rotating wheel space station designs) consists of a torus, or doughnut-shaped ring, that is 1.8 km in diameter and rotates once per minute to provide between 0.9 g and 1.0 g of artificial gravity on the inside of the outer ring via centrifugal force.^[9]

Sunlight is provided to the interior of the torus by a system of mirrors, including a large non-rotating primary solar mirror.^[10]

The ring is connected to a hub via a number of "spokes", which serve as conduits for people and materials travelling to and from the hub. Since the hub is at the rotational axis of the station, it experiences the least artificial gravity and is the easiest location for spacecraft to dock. Zero-gravity industry is performed in a non-rotating module attached to the hub's axis.^[11]

The interior space of the torus itself is used as living space, and is large enough that a "natural" environment can be simulated; the torus appears similar to a long, narrow, straight glacial valley whose ends curve upward and eventually meet overhead to form a complete circle. The population density is similar to a dense suburb, with part of the ring dedicated to agriculture and part to housing.^[11]

Chosen shape

The 1975 NASA Summer Study evaluated several options for the space habitat design, including spherical and cylindrical shapes, in addition to the toroidal one. The torus was chosen as the best option, among other reasons, because it minimized the amount of mass required to have the same area and radius of rotation.^[3]

General characteristics

Location: Earth–Moon L5 Lagrangian point.
Human population: 10,000.
Total mass: 10 million tons (including radiation shield (95%), habitat, and atmosphere).
Diameter: 1,790 m (1.11 mi).
Circumference: 5,623.45 m (3.49 mi).
Rotation: 1 revolution per minute.
Temperature: 23 ± 8 °C.
Radiation shield: 1.7 meters (5.6 feet) thick raw lunar soil.^[3]

Components

Habitation tube (torus proper), with a diameter of 130 m (430 ft). 2/3 of its surface are made of aluminum plates, and the remaining 1/3 is filled with glass windows mounted on aluminum ribs, to allow sunlight to enter inside the torus.
Non-rotating main mirror, that directs sunlight towards the central hub.
Central hub, with a diameter of 130 m (430 ft). Secondary mirrors around the central hub direct sunlight towards the habitation tube.
Fabrication sphere, connected to central hub's South Pole, with a diameter of 100 m (330 ft). It is also connected to a solar furnace and the habitat radiator.
Docking module, connected to central hub's North Pole, with a diameter of 15 m (49 ft) and a length of 60 m (200 ft).
Spokes: 6 spokes of 15 m (49 ft) diameter, connecting the central hub with the habitation tube. They have elevators, power cables, and heat exchange pipes between the torus and the hub.^[3]

Area and volume allocation

The circumference of the torus proper (about 5,600 m in all) would be divided into 6 sections of equal length. 3 of the sections would be used for agriculture, and the remaining 3 for residential uses. Agricultural and residential sections would alternate. A central plain would run through the full length of the torus. To gain space, structures would be terraced over the curved walls of the torus, while many commercial facilities (such as large shops, light industry or mechanical facilities) would be below the level of the central plain. According to the figures included in the study, the plain's floor would be about 1/4 of tube's diameter over the torus bottom, and each spoke would connect at the center of one of the 6 sections.^[3]

Non-agricultural uses

More information Use, Used land area (m2) ...


Use^[3]	Used land area (m²)	Number of levels	Total usable area (m²)^{[Note 1]}	Height per level (m)	Volume (m³)	Notes
Residential	120,000	4	490,000	3	1,470,000	Including dwelling units, private exterior space and pedestrian access space. Modular housing, allowing for one-or two-level clustered homes, as well as grouped apartment buildings with 4 or 5 stories, and terraced homes taking advantage of the edges of the central plain that runs through the torus
Shops	10,000	2	23,000	4	92,000	The authors of the study determined the space use from recommendations that call for 10 shops per 1000 people
Offices	3,300	3	10,000	4	40,000
Schools	3,000	3	10,000	3.8	38,000	With community multimedia center. The authors of the study calculated the space use for a student population of 10% of total population
Hospital	3,000	1	3,000	5	15,000	50-bed hospital with all the different needed facilities
Assembly (churches, community halls, theaters)	15,000	1	15,000	10	150,000
Recreation and entertainment	10,000	1	10,000	3	30,000	All commercial entertainment, including indoor activities and restaurants
Public open space	100,000	1	100,000	50	5,000,000	Parks, zoo, outdoor recreation (swimming, golf, playgrounds)
Service industry	20,000	2	40,000	6	240,000	Light service industry of personal goods, furniture, handicrafts, etc.
Storage	10,000	4	50,000	3.2	160,000	Wholesaling and storage
Transportation	120,000	1	120,000	6	720,000	15 m width for typical streets. Ring road around the torus, at the edge of the central plain. Mass transport system consisting of a moving sidewalk, monorail, and minibus
Communication switching equipment (for 2800 families)	500	1	500	4	2,000	Communication and telephone distribution
Waste and water treatment and recycling	40,000	1	40,000	4	160,000	Including water supply, return and recycling, and sewage treatment
Electrical supply and distribution	1,000	1	1,000	4	4,000	Including transformer substations
Miscellaneous	10,000	2	29,000	3.8	112,000
Total	466,000	-	942,000	-	8,233,000

Agricultural uses

More information Use, Used land area (m2) ...

Use^[3]	Used land area (m²)	Number of levels	Total usable area (m²)^{[Note 1]}	Height per level (m)	Volume (m³)	Notes
Plant growing areas	147,000	3	440,000	15	6,600,000	38,000 m² for sorghum (yield of 83 g/m²/day), 235,000 m² for soybeans (yield of 20 g/m²/day), 72,000 m² for wheat (yield of 31 g/m²/day), 36,000 m² for rice (yield of 35 g/m²/day), 9,000 m² for corn (yield of 58 g/m²/day), 52,000 m² for vegetables (yield of 132 g/m²/day). Part of the plant production is used to feed livestock. Sorghum is used to obtain sugar. Fruit trees are grown in parks and residential areas, providing 250 g of fruit per person each day, and serving at the same time for ornamental purposes.
Animal areas	17,000	3	50,000	15	750,000	Stable herd of animals: 260,000 fish (0.1 m² for each one), 62,000 chicken (0.13 m² for each one), 28,000 rabbits (0.4 m² for each one), 1,500 cattle (4 m² for each one). Flexibility is allowed for other animals to replace parts of these numbers (for example, pigs would have area requirements between those of rabbits and cattle).
Food processing, collection, storage, etc.	13,000	3	40,000	15	600,000
Agriculture drying area	27,000	3	80,000	15	1,200,000

Totals

More information Used land area (m2), Total usable area (m2) ...

Used land area (m²)	Total usable area (m²)	Volume (m³)	Notes^[3]
670,000	1,552,000	17,383,000	Only part of the 678,000 m² of land area and 69,000,000 m³ of volume available in the torus are used

In 2012 paper World Ships - Architectures & Feasibility Revisited, a generation ship (also called world ship) based on Stanford torus was proposed. Stanford torus was chosen over O'Neill colony designs because of its detailed design, that covers in depth aspects such as life support systems and wall thickness.

Four Stanford torus colonies would be stacked together, each with a population of 25,000 (bigger than the population of 10,000 for the original Stanford torus, while keeping the original general design and dimensions, and almost the same mass, that is increased by only 10% to 11 million tones), for a total population of 100,000, that is the minimum population size that the paper considers for a world ship.

For propulsion system, the one designed in Project Daedalus was chosen, to be used in combination with the Stanford torus, being attached to the center of the torus. Daedalus would provide other additional features, such as power generation and a dust shield to protect the Stanford Torus from interstellar dust impacts.^[13]