Difference between revisions of "Cost of transportation"
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[[File:Starship Mars.jpg|thumb|600x600px|SpaceX Starship overflying the Valles Marineris]] | [[File:Starship Mars.jpg|thumb|600x600px|SpaceX Starship overflying the Valles Marineris]] | ||
| − | The cost estimates for transportation to Mars cover a large span. From extremely expensive (200 000$/kg) for one way scientific missions, to a more recent estimate of | + | The cost estimates for transportation to Mars cover a large span. From extremely expensive (200 000$/kg) for one way scientific missions, to a more recent estimate of 130$/kg for the SpaceX Mars plans, and even less for future transportation systems. |
The main cost parameter for launch systems cost is the number of flights per vehicle. Up till recently that number was one, but reusability seems to be achievable soon, and should be expected for any large scale plan for Mars colonization. | The main cost parameter for launch systems cost is the number of flights per vehicle. Up till recently that number was one, but reusability seems to be achievable soon, and should be expected for any large scale plan for Mars colonization. | ||
Revision as of 10:12, 5 August 2019
The cost estimates for transportation to Mars cover a large span. From extremely expensive (200 000$/kg) for one way scientific missions, to a more recent estimate of 130$/kg for the SpaceX Mars plans, and even less for future transportation systems.
The main cost parameter for launch systems cost is the number of flights per vehicle. Up till recently that number was one, but reusability seems to be achievable soon, and should be expected for any large scale plan for Mars colonization.
Contents
Propellant production costs
As far as propellant for launch vehicles is concerned, oxygen, hydrogen, kerosene and methane are all commercially available processes and are considered commodity goods for our purpose. The costs that were considered are in the following table:
| Propellant | Density (kg/m3) | Cost
($/kg) |
References |
| Oxygen | 1140 | 0,16 | NASA paid 67 cents per gallon for the shuttle, so about $0.16 per kg |
| Hydrogen | 70 | 3 | Hydrogen Production Cost Using Low-Cost Natural Gas, DOE projection, 2012 |
| Kerosene | 800 | 0,4 | Commodity price for jet fuel, july 2016 |
| Methane | 420 | 0,2 | 0,1$/kg natural gas + delivery, refining and liquefaction |
| Propellant costs for launch vehicles, 2016 | |||
Cost to LEO
The main cost of transportation is for the phase from Earth surface to LEO. The overall deltaV to orbit is about 9 000 m/s, more than for any other part of the trip. For reusability, the vehicle must be able to return to Earth surface with the minimum amount of damage,
This analysis is done for unmanned vehicles. Use of unmanned vehicles greatly reduces the development costs and gives freedom of experimenting risky maneuvers without dramatic consequences.
The minimum value from the surface to LEO is the energy difference between the two positions: orbital velocity and elevation. With an electrical cost of 0.1$ per kWh, the difference in energy is about 33 MJ/kg, which corresponds to about 1 $ per kg.
Cost may eventually be reduced to nearly the base cost of energy when (and if) geostationary space elevators are finally developed and financed over long periods. Significant access to space based power systems might eventually reduce the cost for moving mass to orbit to a trivial amount.
| Launch cost economics | ||
| Launch cost economics is a complex subject, source of endless debates. We present a simplified analysis here, for transportation to LEO, using the following equation: | ||
| Pc | Payload cost ($/kg) | Pc= (De+Co*Vg+In+Vg*Vf*(Ma+Fu))/Pm*Vg*Vf |
| De | Development | Research, management and testing. Safety requirements for crewed vehicles. Flight proofing. |
| Ma | Materials and manufacturing | person hours, testing. |
| Co | Construction of the vehicle | Materials and manufacturing, person hours, testing. |
| In | Infrastructure | Manufacturing plants, tooling and launch sites for a series of vehicles |
| Ma | Maintenance cost per flight | Clean up, repair, upgrades, fueling, set up on pad. |
| Fu | Fuel cost per flight | |
| Vg | Vehicles per generation | Number of vehicles built per design generation. |
| Vf | Vehicle flights | Number of flights a vehicle can do over its lifetime |
| Pm | Payload mass (kg) | Payload mass per flight |
| Environmental impact is not included as a cost but needs to be taken into account in the overall analysis. This parameter doomed fission pulsed propulsion and exotic fuels using fluorine, and might become an issue at high flight rates.
The table below gives the results for the above equation. It is based on the transportation of 100 000 tonnes to LEO. | ||
Comparison of various launch systems:
| Vehicle | Development (De) | Construc-
tion (Co) |
Infra-
structure (In) |
Flights (Vf) | Fuel cost
per flight (Fu) |
Mainten-
ance/flight (Ma) |
Vehicles per generation (Vg) | Payload (Pm) | Payload cost (Pc) |
| Billions | millions | billions | millions | millions | kg | $/kg | |||
| Delta IV | 0,5 | 300 | 0,2 B$ | 1 | 0,5 | 2 | 20 | 22 000 | 15 000 |
| Falcon Heavy | 0,3 | 70 | 0,2 B$ | 5 | 0,5 | 0,5 | 20 | 54 000 | 1 700 |
| Falcon Heavy recoverable | 0,7 | 90 | 0,2 B$ | 5 | 0,5 | 0,5 | 20 | 30 000 | 520 |
| SpaceX Starship | 10 | 600 | 2 B$ | 100 | 1,25 | .5 | 20 | 300 000 | 40 |
| REL Skylon | 12 | 250 | 0,5 B$ | 200 | 0,1 | 0,1 | 200 | 15 000 | 48 |
| Space gun | 0,5 | - | 2 B$ | 20 000 | 0,05 | 0,01 | 20 000 | 1000 | 925 |
| To achieve these figures ITS and Skylon need to transport about 100 000 tonnes. The firing rates requires for the space canon are very high and might not be achievable. These are base costs, without financing, subsidies, insurance or profit.
The recoverable Falcon heavy is entirely speculative. | |||||||||
Cost from LEO to Mars
The same analysis that was used to show the gains of reusability can be used for orbital transfer. Following the radical reduction in cost possible with high volume reusable launchers, the cost of moving cargo to Mars goes down significantly. The solar electric or nuclear electric thrusters are clearly the most economical solution for the volumes needed for the development of a martian settlement, as long as the volumes are
The main parameter for costs from LEO to Mars are deltaV and the use of atmospheric braking. Vehicles such as solar powered OTV's are unable to use either the Oberth effect or atmospheric braking. However, the mass of fuel required is so low that theses loses are offset by the reduced overall mass. Interesting gains might exist with propellant produced on Mars, or in Mars orbit.
| Vehicle | Development | Construction | Infrastructure | Flights per vehicle | Fuel cost per flight | Flights required | Payload per flight | Vehicles required | Total Flight costs | Payload cost
($/kg) |
| Billions$ | millions$ | billions$ | millions$ | billions$ | ||||||
| Chemical one way | 1.0 | 10.0 | 0.0 | 1.0 | 0 | 16 667 | 6 | 16 667 | 2 666 | 26 657 |
| ITS with refuelling | 0.0 | 0.0 | 0.0 | 100.0 | 0 | 556 | 180 | 6 | 39 | 389 |
| Beamed power Skylon() | 0.0 | 0.0 | 1.0 | 200.0 | 0.0 | 6,667 | 15 | 33 | 57 | 567 |
| Solar electric() | 2.0 | 300.0 | 0.2 | 100.0 | 0 | 556 | 180 | 6 | 15 | 151 |
| Nuclear thermal | 4.0 | 300.0 | 0.0 | 20.0 | 0 | 556 | 180 | 28 | 24 | 243 |
| Orbital transfer vehicles
Costs for 100 000 tonnes to high orbit. 2016$. The chemical one way is paired with the Delta IV vehicle. For the purpose of this table solar electric is the same as nuclear electric. The payload cost includes the cost of the Launcher flights required to carry up the propellant. | ||||||||||
As for the launch vehicles, the orbital transfer vehicles are unmanned. This reduces cost and complexity tremendously, since there is no need to transport a crew and their living environment. Docking, fuel and cargo transfer operations may be supervised and teleoperated, and the OTVs are provided with robot arms moving on rails, or similar active elements, that can be used for inspection and repair.
Low thrust vehicles follow very different trajectories than high thrust vehicles. They cannot profit from the Oberth effect, and therefore require much higher deltaV for the same mission. Despite this, their reduced fuel use makes them more economical than high thrust vehicles. At least for most situations that concern the long term occupation of Mars.
| The Oberth effect, the gain from thrust deep in a gravity well | ||
| Δveff= Δv·√(2VE/Δv) where
Δv= ve·ln(mo/mf) | ||
| Δveff | Effective Velocity change (m/s) | |
| VE | Escape velocity (m/s) | Escape velocity of the body around which the vehicle is doing the Oberth maneuver |
| mo | Initial mass (kg) | Propellant, payload and vehicle structure |
| mf | Final mass (kg) | Payload and vehicle structure+remaining propellant |
Cost of Mars landing
Cost to LMO
Propellant production on Mars is mostly a factor of the cost of electrolysis of water.
| Propellant | Density (kg/m3) | Cost
($/kg) |
References |
| Oxygen | 1140 | Oxygen is a byproduct of hydrogen separation | |
| Hydrogen | 70 | Hydrogen from Electrolysis | |
| Methane | 420 | Methane from Sabatier reaction and hydrogen from Electrolysis | |
| Propellant costs for launch vehicles, on Mars | |||
