Self‐Deployable Self‐Powered Networking Aerostat
Paul Kim
Chief Technology Officer & Assistant Dean
Stanford University School of Education
This apparatus is designed to self‐deploy a network node or network infrastructure for emergencies or special purposes that require an emergency radio service, wireless communication channel, broadcasting station, network relay station, etc. when conventional network services become disabled or damaged.
This apparatus consists of major components such as a self‐deployable compressed helium containers, wind turbine, tethering mechanism, network device, motor controlled winch, and protective eggshell to house the apparatus.
When triggered by a sensor (earth quake, flood, bomb, or any other predefined triggering event), the eggshell hatches itself and compressed helium is deployed into the wind turbine which is made of balloon, it self‐lifts in the air while the winch unrolls the tether mechanism. When the wind turbine positions in a preconfigured high altitude, it harvests electricity from the wind. When it is deployed, it turns on the networking device and starts to function as preconfigured as a wireless network node or station (e.g., self‐broadcasting radio emergency information, cellular network antenna, emergency internet router, network relay station, etc.). The wind turbine recharges the battery on board.
The protective eggshell contains a motorized winch attached to a linear electricity generator and a controlled board. When there is high wind the linear electricity generator generates electricity to recharges the control board.
Self‐Deployable Self‐Powered Networking Aerostat
Self-deployable aerostat helium balloon to steadily position the wind turbine
Wing
Wire connecting power generator and the network device
Helium filled wind turbine aerostat
Network device 1
Broadcasting or relaying radio signal
Electric power generator
(Brushless DC motor type)
Battery
Wind
Network device 2
Tethering mechanism
Helium canister – auto-detaches when the
positioning aerostat is fully inflated
Wind dynamics
Battery
Helium canister – auto-detaches when the
wind turbine aerostat is fully inflated
Linear electric power generator
Self-hatching protective egg
Altitude control board
Winch controlling motor
Winch
Triggering event sensor
Descriptions
Helium filled wind turbine aerostat – when triggered this aerostat self‐inflates. For bigger size wind turbines, the wind turbine wings are covered with solar power cells to supplement the electricity generation.
Linear electric power generator – this recharges the battery on the ground when there is strong wind. It may trigger the winch to lower the aerostats or raise the aerostat when there is not enough wind or it is risky (potentially damaging or losing the aerostat) to operate at the current altitude. It generates electricity as the tether moves or swings according to wind dynamics.
Tethering mechanism – this holds the aerostats, but has no electric wire connecting the ground control board with the aerostats. It is used to positions, raises, or lowers the aerostats.
Network device 1 – it is pre‐configured to perform various wireless networking tasks, but also post‐reconfigurable based on needs. This network device turns it on and off based on the power level of the on‐board battery.
Network device 2 – it can communicate with the network device 1 based on needs. Through Network device 1, controller from a remote location can send a signal to disconnect the tether, unwind the tether, etc. This network device turns it on and off based on the power level of the on‐board battery.
Triggering event sensor – this may be configured to send the hatching signal when there is an event (e.g., 8.0 magnitude earthquake)
Self‐hatching protective egg – Water‐proof sealed. Upon receiving the signal, it deploys the aerostats. It is heavy enough to hold down the aerostats with tethering and is made of floating buoy so it can float on water if the area is flooded.
Relevant Patents
US PATENT 733500B2 – Helium balloon‐based wind turbine
US PATENT 7188808 B1
Wind dynamic‐based power generation
US PATENT 7129596 B2
Floating wind turbine
US PATENT 4073516
Floating wind turbine
US PATENT 4486669
Lowering or raising wind turbine to maximize wind power generation
Most Recent Relevant Research
Most Recent Relevant Research
Most Recent Relevant Research
2009
Most Recent Relevant Research
Most Recent Relevant Research
ABSTRACT
Many rural and remote communities around the world see themselves
on the wrong side of the digital divide. In particular, there is
evidence to suggest that there is a growing digital divide between
urban and rural areas in terms of broadband Internet access with
people living in rural areas having fewer choices and pay higher
prices for slower speeds. This is true even in developed countries.
Motivated by the above observations, there has been an increasing
interest in deploying and researching low cost rural wireless networks
with active community participation. This paper presents an
overview of our efforts in this direction in deploying a rural WiFibased
long distance mesh network testbed in the Scottish Highlands
and Islands. We highlight the unique aspects of our testbed that
differentiate it from other existing rural wireless testbeds. We also
outline some of the research issues that are currently being investigated
in this project.
WiNS-DR’08, September 19, 2008,
San Francisco, California, USA.
ABSTRACT
Self-powered wireless mesh networks have gained popularity as a cheap alternative for
providing Internet access in many rural areas of the developed and, especially, the developing world.
The quality of service that these networks deliver is often bounded by such rudimentary issues as the
unavailability of electrical energy. Dependence on renewable energy sources and variable power
consumption make it difficult to predict the available energy and provide guarantees on
communication performance. To facilitate energy trend estimation we develop an energy flow model
that accounts for communication and energy harvesting equipment hardware specifications; high
resolution, time-varying weather information; and the complex interaction among them. To show the
model’s practical benefits, we introduce an energy-aware routing protocol, Lifetime Pattern-based
Routing (LPR), specifically tailored for self-powered wireless networks. LPR’s routing decisions are
based on energy level estimations provided by the energy flow model. Our protocol balances the
available energy budget across all nodes; as a result, power failures are distributed among all
participating parties. Using traces captured from a live network, we use simulation to show that LPR
outperforms existing work in rural-area wireless network routing.
Most Recent Relevant Research
Applications
Emergency network, rescue mission, resource deployment , critical announcement of safety & health information (e.g., epidemic, impending Tsunami), medical consultation conference, rapid medical training, special training, continuous education, critical wireless communication backbone, point‐to‐
point or relayed network, emergency cellular network, broadcasting, etc.
Benefits
• Quickly deployable from the ground;
• Less susceptible to disasters, disruption, power‐
outage;
• Broadcasting or communication networking capability;
• Airdrop possibility;
• Pre & post configurable;
• Deployable in outer planets;
• When there is no wind by air motion, there could be other hybrid power generation device depending on the given condition.