Cryogens are effective thermal storage media which, when used for automotive purposes, offer significant advantages over current and proposed electrochemical battery technologies, both in performance and economy. An automotive propulsion concept is presented which utilizes liquid nitrogen as the working fluid for an open Rankine cycle. Nitrogen propulsive systems can provide automotive ranges of nearly 400 kilometers in the zero emission mode, with lower operating costs than those of the electric vehicles currently being considered for mass production. Some of the advantages of a transportation infrastructure based on liquid nitrogen are that recharging the energy storage system only requires minutes and there are minimal environmental hazards associated with the manufacture and utilization of the cryogenic "fuel."
5. LIQUID NITROGEN VEHICLE….
The liquid nitrogen powered vehicles was independently developed by University of North Texas (UNT)
and University of Washington (UW).
The vehicle (car) was named as LN2000.
The main Scientist behind this discovery is Abraham Hertzberg.
6. MANUFACTURE OF LIQUID NITROGEN
Atmospheric air is passed
through dust precipitator and
pre-cooled.
It is then compressed inside
large turbo pumps.
Air allowed to expand rapidly
through a nozzle into an
insulated chamber.
By running several cycles the
temperature of the chamber
becomes low enough. The air
entering it starts to liquefy.
Liquid nitrogen is removed
and is stored inside well-
insulated Dewar flasks or
Storage vessel.
Atmospheric
Air passes
Fractional
Distillation
Dust
Precipitator
Inter cooler
Nozzle
LN2
Insulated chamber
Expansion
Turbo
pumps
Dewar Flask
7. LIQUID NITROGEN PROPULISION CYCLE
The main parts of a liquid
nitrogen propulsion system are:
1. Cryogen Storage Vessel.
2. Pump.
3. Economizer.
4. Heat Exchanger
5. Expander Engine.
8. PARTS OF LNPC
Cryogen
Storage
Vessel
A pressurized tank to store liquid nitrogen.
Resistance to deceleration forces in the horizontal plane in the event of
traffic accident, Low boil-off rate , minimum size and mass and
reasonable cost.
Pump
The pump is used to pump the liquid nitrogen into the engine. The
pump which are used for this purpose have an operating pressure
ranging between 500 – 600 Psi. As the pump, pumps liquid instead
of gas, it is noticed that the efficiency is high.
9. Economizer
A Preheater, called an economizer, uses left over heat in the
engine’s exhaust to preheat the liquid nitrogen before it enters
the heat exchanger.
Improves efficiency.
PARTS OF LNPC…….
Heat
Exchanger
A primary heat exchanger that heats (using atmospheric heat)
LN2 to form N2 gas, then heats gas under pressure to near
atmospheric temperature
11. Principle of operation
Cryogen
Storage
Vessel
Pump
Economize
r
Heat
Exchanger
Expander
Engine
LN2 at –320oF (-196oC) is pressurized and then vaporized
in a heat exchanger by ambient temperature of the
surrounding air.
This heat exchanger is like the radiator of a car but instead
of using air to cool water, it uses air to heat and boil liquid
nitrogen.
Liquid N2 passing through the primary heat exchanger
quickly reaches its boiling point.
The N2 expands to a gas with a pressure of 150 KPa.
The pressurized N2 gas drives the motor.
The only exhaust is nitrogen, which is major constituent of
our atmosphere.
Energy+N2(l)-->N2(g)
12. EFFICIENCY
The first LN2 car could travel 79 miles (127.58 km) on a full 24 gallon (90 liter)
tank of liquid nitrogen going 32 Kmph.
Its maximum speed was over 56 Kmph.
After further Researches, the Efficiency has improved as follows:
Power : 78KW or 104.5bhp @ 97Kmph
400 Liters (106 gallon) gives a mileage of 560Km and weighs 280Kg
Operating Cost is around 2.4cents per Km( Re 1 per Km)
15. TECHNICAL ISSUES
The N2 passing through the tubes of the heat exchanger is so cold that the
moisture in the surrounding air would condense on the outside of the tubes,
obstructing the air flow.
There's the safety issue. Should a nitrogen car be kept in a poorly ventilated
space and, if the Nitrogen leaks off, it could prove fatal.
Turning N2 gas into a liquid requires a lot of energy. So while cryogenic cars
have zero emissions, they rely on energy produced at emission generating power
plants.
16. CONCLUSION
In a real sense, the more such vehicles are used, the cleaner the air will become
Time to recharge, infrastructure investment and environmental impact are among the
issues to consider , in addition to range and performance , when comparing the relative
merits of different ZEV technologies.
Manufacturing LN2 from ambient air inherently removes small quantities of
atmospheric pollutants and the installation of large-scale liquefaction equipment at
existing fossil-fuel power stations could make flue gas condensation processes
economical.
Extra research work is needed to utilize the most of the available energy
17. REFERENCES
[1] “LN2000”, University of Washington Research Team, Sept. 18, 2007
[2] “Liquid Nitrogen”, Wikipedia Online Encyclopedia.
[3] Proceeding of 18th International Cryogenic Engineering Conference (Edited by K.G
Narayankhedhar, Narosa Publishing House)
[4] AICTE-ISTE Short term Programme on contribution to technology development from
Space Research.
[5] “Cryogenic Chilling and Freezing”, BOC Gases.
[6] “Cryogenic Paint Removal”, Sig Attilio Bernasconi
[7] Processes and Materials of Manufacture by R.A. LINDBERG