tubenet transit system intro
TRANSCRIPT
Tubenet Transit SystemZhengxian Tubenet Transit
System InstituteFeb 2014
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Metropolitan Transit System Problems
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Problems at a glance
More transit systemWorse pollutionLower efficiencyMore difficult to
travel
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Problematic solutions for traditional metropolitan
transit systems
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Road shared with various transportation vehicles – low efficiency, unsafe
Expensive subway or Bart System – low coverage rate
Driver’s individual decisions – random, traffic jams
Energy and other resource consumption – pollution, unsustainable
Transfer between various transit systems – time consuming, inconvenient
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Tubenet Transit System
Our solution
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Basic concept
Tubenet is a standardized tube-rail public transit system, connecting buildings and communities, driven mainly by solar power, fully computer controlled with cloud technology, using single coach-wagon to carry people or other goods, covering entire city or metropolitan areas, as well as connections between cities
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tube-like structure with upper track and lower rails
Upper tracks controls turning and merging into other branchesLower rails provide support and electricity
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Light-weight single car
Cars can also be in capsule shape, carrying 2 to 3 people
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Terminal – branch – main transit network structure
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Distributed PV solar power source
PV panels and Li-batteries provide most of the electricity to drive the system, double secured by city power lines
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Vertical-integrated terminal hub
Cars are stored in the hubs and ready to be used and scheduling
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Air-gap prevent collisions
Cars and tube wall are loosely sealed to provide an air-cushion to preventhard collisions between cars
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Vertical decent for emergency evacuation
There many lids installed underneath the tube for emergency evacuationEven when power is off there is still a manual mechanism to have people in the car to be decent onto the ground from the car inside the tube-rail
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Intra-computer network with cloud control
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Modulated design, installation and modifications
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Tubenet fully rely-on a smart transit system
Smart management for all parts
• car• road• station• garage
life-cycle simulation and optimization
• Before design
• construction• In operation
Entire system metadata
smart scheduling
• Local network
• Branch network
• Main network
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Advantages of tubenet transit system
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Very Safe
excluding human factors
mono-directional, even speed, continuously moving, no cross pathes
air-buffer due to sealed tube prevent collision between cars
人为因素93%
车辆因素0.0271
道路因素0.0012
其他因素0.042
道路交通安全事故原因
人为因素 车辆因素 道路因素 其他因素
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Near zero pollution discharge Using distributed PV solar panels
Eliminating exhaust, dust and driving noise
A factor of 22 in CO2 discharge
小汽车 管联网 -
30.00
60.00
90.00
120.00
150.00 145.490
6.561
小汽车与管轨网(市电)碳排放比较 (克 CO2/ 人次 · 千米)
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Energy Saving light-rail single car
metal rail, even speed
a factor of 4 better effective load
球形车
小汽车
0 200 400 600 800 1000 1200 1400 1600
150
1000
150
150
小汽车与管轨网有效载重比较
自重 载重(两人)
有效载重 13.04%
有效载重 50%
Kg
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Energy SavingAverage energy consumption is less than 1% of a regular car
小汽车每千米用能 球形车车每千米用能0
500
1000
1500
2000
2500
3000
2939
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设计能耗比较(千焦 / 千米)
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Fast, convenient and optimized traveling efficiency
Non-stop
Non-tranfer
Building to building
Full coverageDefiniteness
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Comfortable and privacy
As confy as
railway
As private
as driving
No tiredness
from driving
Double sound
insulation
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Vast transport volume
管轨网单向干线的设计运力:单车运载能力 = 运力
人 / 小时
Two people per car
50mile/h for main
tube
Distance between
cars 2.5meters
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Very economic
建设成本 建设成本比较 年运营成本 年运营成本比较城市轨道交通系统 63,400 100.0% 7,940 100.0%
新建城市高架道路 + 机动车 14,060 22.2% 1,316 16.6%
新建城市道路 + 机动车 9,060 14.3% 1,316 16.6%
管轨网双线(对开) 4,000 6.3% 500 6.3%
建设成本 年运营成本 -
10,000 20,000 30,000 40,000 50,000 60,000 70,000
经济性比较 (万元 / 千米)
城市轨道交通系统 新建城市高架道路+机动车新建城市道路+机动车 管联网双线(对开)
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Comparing with other types of new transit
systems
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Comparison 1
H-Bahn (Germany)
Monorail ( Germany)Tubenet( China)
Volume ( 10k/h ) Cost($M/mile )H-Bahn 1.2 ( unidirectional,
90s )31.6-39.5
monorail 0.6-2.6 ( unidirectional ) 52.7
tubenet 6.4 ( unidirectional main )4.8 ( unidirectional branch )
5.3
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Comparison 2
Skytran ( US ) VECTUS ( Kerea) Tubenet ( China)Volume ( 10k/h ) Cost($M/mile )
Skytran unknown >30
VECTUS 0.721 ( including standing ) >20
tubenet 6.4 ( unidirectional main )4.8 ( unidirectional branch )
5.3
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Inventor, R&D teamR&D process
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Mr. Nanzheng Yang, BS in operational research, Ph.D in Business Management from Scups University of California, US; research on war game and computer simulation of war; working on transit system solution since 1993
Inventor
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R&D Team
Chief engineer 易政青 Principle engineer
Operational research system engineering
张永光 Sr. Scientist
System simulation 计雷 Sr. scientist Environmental
system 李康 Professor
Control system 王宏安 Sr. scientist Network engineering system
盛兴旺 Professor
Engineering system 殷参 Sr. scientist Station/garage
system 黄鹏志 Sr. Engineer
Aero-dynamics designing 武家陶 Principle
engineerComplex material design
赵京先 Sr. Engineer
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R&D processResearched on various advanced transit system solution in the world
Designed “elevated light-weight automatic rail transit system”
1993
2002
Applied patents for tubenet transit systems
Finished many round of simulations to improve technology
20052012
Established a small testing base for tubenet transit system
2013
Established a real-life
size testing bad
Proposed EHR transportation strategic management theory
Organized a meeting to discuss tubenet transit system
20032004
2014
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IP
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Up to now, the tubenet transit system patents have been allowed by China, USA, EU, Japan, Canada, Australia, Mexico, Korea, Taiwan and Singapore. The patents have also entered the formal evaluation phase for the following countries and areas: Canada (dividing), 7 countries in EU dividing ( Great Britten, Germany, France, Italy, Spain, Turkey, and Poland), Hong Kong, Indonesia, India, Malaysia, Thailand, and Brazil.
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Patent issued
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What is next
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Establish a real-life size testing base - done
Sightseeing model design and operation for large tourist attractions
Last miles to buildings and communities from train stations and airports
Connecting newly developed areas and large communities with city centers
Jam areas for the megacities
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demo system for a Beijing suburb community
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A small demo system for a Beijing suburb community 1.3 miles away from the subway station
terminal network – 1.2 miles; branch network – 1.2 miles; 12 terminal-hubs
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demo system for a mid-size city in Hubei province
沙市中山公园
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demo system for a mid-size city in Hubei province
terminal network – 3.1 miles; branch network – 10 miles; 20 terminal-hubs
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Bright Futures
管轨网可望在中型以上城市做到全覆盖,在较大程度上取代自驾车出行,成为市民出行的主要选择,在非出行高峰期担负电子商务等中小尺寸货物的配送系统功能。
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