HNG® – HydroAtomic Nano Gas | Verification test report June, 2013

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HNG® – HydroAtomic Nano Gas© “Make any fossil fuel climate neutral”
VERIFICATION TEST PROTOCOL
of clean burning diesel fuel
Stockholm, Sweden
June 6, 2013
Detailed explanation of the accredited testing equipment and procedure follows
-----------------------------------------------------------------------------------------------------------
Sulfur
1380ppm
CO
10,000 ppm
O2
1% Sooty Burn Clean burn
Sulfur
-0- ppm
CO
-0- ppm
O2
6%
Palgo AB is specialized in smoke gas air analysis and combusting
monitoring.
“According to our professional experience we have never seen
results like this before” – ceo Olof Sten
Olof Sten CEO-Palgo AB
www.palgo.se
Test and results are witnessed and verified by
the accredited laboratory instrument vendor
Olof Sten, CEO Palgo AB.
Confidential, Patent & Copyright All Rights Reserved and protected to full legal extent.
- HydroAtomic-Institute - HydroInfra Technologies AB Sweden
- Position 1146, 18123 Lidingo, Sweden - 2013-06-18
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Phase HNG HOT scrubber:
SO2 – Sulfur
HNG + Diesel.........................................................0.2
Only Diesel...................................................1384.0
Difference -1383.8
CO – Carbon monoxide
HNG + Diesel............................................................0
Only Diesel.......................over measure limit 5000.0
Difference -5000.0
Oxygen – O2
HNG + Diesel.........................................................6.0%
Only Diesel........................................................0.6%
Difference +5.4%
Phase HNG WET scrubber:
The following values are eliminated from air in the
dry and wet phase of the HNG scrubber system
measured by the electronic water analysis system
.
CO2 – Carbon Dioxide
HNG + Diesel..........................................................8%
Only Diesel.........................................................6%
Difference 2%
Nitric Oxide NO
HNG + Diesel........................................................80 ppm
Only Diesel........................................................61 ppm
Difference 19 ppm
Energy efficient increase
Temp for Energy efficiency is increased by nearly 100%
Drive of HNG gas generation is within 10% of used fuel.
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HNG - scrubber TABLE OF RESULTS:

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ELIMINATION OF SO2
The result of this report shows such remarkable data that it creates a first line of questions:
- As the SO2 (sulfur) disappears from the measurement data, the question is into which form will this become.
Answer:
- In the science research report more details will be explained, but as an initial response by the Universities infraspectrometer
shows no sulfur but sign of ethylene appears.
POSITIVE ENERGY BALANCE
The other question:
- When the HNG and diesel are mixed in the burner what is the energy balance of HNG gas and the gain of higher efficiency and
BTU levels.
Answer:
-  HNG gas in its own is not the energy carrier but as a reaction gas frees the boundary of hydrogen in hydrocarbon.
- it will only require a minimum of the diesel fuel to create the reactive gas. Actually, it is less then 10% but the net BTU value
gained is in the area of 20%. This will further be described in future the science reports.
With this introduction the following pages show the report data.
CONCLUSION
This will give the reader the possibility to imagine the consequences for the climate if the full implementation of the HNG takes
place.
Quest and conclusion of
Verification Report
for the HNG scrubber application
Performed 6 of June, 2013 in HydroAtomic/HydroInfra Laboratory under supervision of authorized
measurement inspectors and the tech staff from the laboratory.
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The diesel
oil flame
with no
gas:
Sooty toxic
emissions
The following data is from the HNG hot scrubber verification procedure.
The results
from the
insertion of
a thin
1 cm
HNG gas
flame
THE VERIFICATION PROCEDURE
HOT scrubber process
1 cm
The HNG scrubber system includes DRY and WET system which complete the HNG
scrubber functions down to emission neutralization
HNG gasDiesel HNG with Diesel
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Maximum temperature of oil
flame upon metal plate 139c
Temperature increases 100% from same fuel
with insertion of small amount of HNG gas 272c
Oil flame
only
HNG with oil
flame
Heating plate Heating plate
Laser temp
Reader
139 c
Laser temp
Reader
272 c
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Confidential, Patent & Copyright All Rights Reserved and protected to full
legal extent. - HydroAtomic-Institute - HydroInfra Technologies AB
Sweden - Position 1146, 18123 Lidingo, Sweden - 2013-06-18
The testing
facilities
Horiba analyzers are state of the art
and standard equipment used by
accredited inspectors to check that the
emission is within legal standards of
power plants and other emission
outlets.
An overview of the lab
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Confidential, Patent & Copyright All Rights Reserved and protected to full
legal extent. - HydroAtomic-Institute - HydroInfra Technologies AB
Sweden - Position 1146, 18123 Lidingo, Sweden - 2013-06-18
The testing
facilities
These series of gauges measure
the pressure of the gas as it flows
from the generator to the various
burners on the table.
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The gas is sucked through this tube
from the chimney into the analyzer.
This is a real chimney scaled model.
The smoke is running thru the
chimney in a similar way that the
full scale chimney operates.
The diesel is burned with smoke
directly fed into the chimney.
The diesel flame is burning around
the HNG gas injector.
Test 1) The diesel is burned with the gas off.
Test 2) The diesel is burned with the gas on.
The testing
procedures
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THE AUTHORIZED VERIFICATION PROCEDURE
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The verification procedures took place in the
HydroInfra/HydroAtomic institute laboratory during the
date of May 30th 2013 in presence of:
• Olof Sten, CEO of Palgo AB, accredited measurement
systems
•  The verification procedure was overseen by the professional measurement
companies represented by their CEO’s.
•  These representatives are doing accredited official measurements of emission
for the government control of the Swedish industry.
THE VERIFICATION PROCESS UNDER INSPECTION
OF ACCREDITED MEASUREMENT INSPECTORS
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Oxygen (O2))
Gaseous chemical element chemical symbol O, atomic number 8. It constitutes 21%
(by volume) of air and more than 46% (by weight) of Earth's crust, where it is the
most plentiful element. It is a colorless, odorless, tasteless gas, occurring as the
diatomic molecule O. In respiration, it is taken up by animals and some bacteria (and
by plants in the dark), which give off carbon dioxide (CO). In photosynthesis, green
plants assimilate carbon dioxide in the presence of sunlight and give off oxygen. The
small amount of oxygen that dissolves in water is essential for the respiration of fish
and other aquatic life. Oxygen takes part in combustion and in corrosion but does not
itself burn. It has valence 2 in compounds; the most important is water. It
forms oxides and is part of many other molecules and functional groups,
including nitrate, sulfate, phosphate, and carbonate; alcohols, aldehydes, carboxylic
acids, and ketones; and peroxides. Obtained for industrial use by distillation of
liquefied air, oxygen is used in steelmaking and other metallurgical processes and in
the chemical industry. Medical uses include respiratory therapy, incubators, and
inhaled anesthetics. Oxygen is part of all gas mixtures for manned spacecraft, scuba
divers, workers in closed environments, and hyperbaric chambers. It is also used in
rocket engines as an oxidizer (in liquefied form) and in water and waste treatment
processes.
The definition of the various gases analyzed.
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Carbon Monoxide (CO)
Carbon monoxide (CO) is a colorless, odorless, and tasteless gas that is slightly lighter
than air. It is toxic to humans and animals when encountered in higher concentrations,
although it is also produced in normal animal metabolism in low quantities, and is thought to
have some normal biological functions. In the atmosphere it is spatially variable, short lived,
having a role in the formation of ground-level ozone.
Carbon monoxide consists of one carbon atom and one oxygen atom, connected by a triple
bond that consists of two covalent bonds as well as one dative covalent bond. It is the
simplest oxocarbon, and isoelectronic with the cyanide ion and molecular nitrogen.
In coordination complexes the carbon monoxide ligand is called carbonyl.
Carbon monoxide is produced from the partial oxidation of carbon-containing compounds; it
forms when there is not enough oxygen to produce carbon dioxide (CO2), such as when
operating a stove or an internal combustion engine in an enclosed space. In the presence of
oxygen, carbon monoxide burns with a blue flame, producing carbon dioxide.[1] Coal gas,
which was widely used before the 1960s for domestic lighting, cooking, and heating, had
carbon monoxide as a significant constituent. Some processes in modern technology, such
as iron smelting, still produce carbon monoxide as a byproduct.[2]
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Sulfur Dioxide (SO2)
Sulfur dioxide (SO2) is one of a group of highly reactive gasses known as “oxides of
sulfur.” The largest sources of SO2 emissions are from fossil fuel combustion at power
plants (73%) and other industrial facilities (20%). Smaller sources of SO2emissions
include industrial processes such as extracting metal from ore, and the burning of high
sulfur containing fuels by locomotives, large ships, and non-road equipment. SO2 is
linked with a number of adverse effects on the respiratory system.
Sulfur dioxide can cause acid rain that seriously affects ecosystems. Acid rain is a major
problem in the northern hemisphere, where trees and whole forests have been affected.
Acid rain does not occur in New Zealand. However, sulfur dioxide deposition can affect
vegetation around industrial discharges and in cities. Lichens are good bio-indicators of
pollution and do not like to grow where there is sulphur dioxide in the air.
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Carbon dioxide (CO2 )
Carbon dioxide (chemical formula CO2) is a naturally occurring chemical
compound composed of two oxygen atoms covalently bonded to a single carbon atom. It is
a gas at standard temperature and pressure and exists in Earth‘s atmosphere in this state, as
a trace gas at a concentration of 0.039 per cent by volume.[1]
As part of the carbon cycle, plants, algae, and cyanobacteria use light energy
to photosynthesize carbohydrate from carbon dioxide and water, with oxygen produced as a
waste product.[2] However, photosynthesis cannot occur in darkness and at night some carbon
dioxide is produced by plants during respiration.[3] Carbon dioxide is produced
by combustion of coal or hydrocarbons, the fermentation of sugars
in beer and winemaking and by respiration of all living organisms. It is exhaled in the breath of
humans and land animals. It is emitted from volcanoes, hot springs, geysers and other places
where the earth's crust is thin and is freed from carbonate rocks by dissolution. CO2 is also
found in lakes at depth under the sea, and commingled with oil and gas deposits.[4]
The environmental effects of carbon dioxide are of significant interest. Carbon dioxide is an
important greenhouse gas, warming the Earth's surface to a higher temperature by reducing
outward radiation. Atmospheric carbon dioxide is the primary source of carbon in life on Earth
and its concentration in Earth's pre-industrial atmosphere since late in the Precambrian eon has
been regulated by photosynthetic organisms. Burning of carbon-based fuels since the industrial
revolution has rapidly increased concentrations of atmospheric carbon dioxide, increasing the
rate of global warming and causing anthropogenic climate change. It is also a major source
of ocean acidification since it dissolves in water to form carbonic acid,[5] which is a weak
acid as its ionization in water is incomplete.
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NOx
NOx is a generic term for mono-nitrogen oxides NO and NO2 (nitric
oxide and nitrogen dioxide). They are produced from the reaction
of nitrogen and oxygen gases in the air during combustion, especially
at high temperatures. In areas of high motor vehicle traffic, such as in
large cities, the amount of nitrogen oxides emitted into the atmosphere
as air pollution can be significant. Nox gases are formed everywhere
where there is combustion – like in an engine. In atmospheric
chemistry, the term means the total concentration of NO and NO2.
NOx react to form smog and acid rain. NOx are also central to the
formation of tropospheric ozone.
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END OF VERIFICATION PROTOCOLL
HydroInfra Industries HIT-I publ. AB
Pos 11 46
Stockholmsvägen 33
181 23 Lidingö, Sweden
www.HydroInfra.com
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HNG® – HydroAtomic Nano Gas | Verification test report June, 2013

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