a challenge for skeptics -- hidden H2 source would have to supply 36--216 kg H2 to make Rossi heat: Rich Murray 2011.01.18

> a challenge for skeptics -- hidden H2 source would have to supply
> 36--216 kg H2 to make Rossi heat: Rich Murray 2011.01.18
>
> [ Rich Murray: "100 to 600 more than the sensitivity of the scale",
> which may be 0.1 gm, gives 10 -- 60 gm/second ranges of H2 used --
> 36,000 -- 216,000 gm = 36 -- 216 kg H2 -- that would be a lot to deliver from a
> hidden source... ]
>
> " The first measurements Levi described were energy measurements to
> determine the
> input of energy inside the reactor and the output of energy of the
> reactor. “I don't have
> conclusive data on radiation but absolutely we have measured ~12 kW
> (at steady state) of
> energy produced with an input of about just 400 watts. I would say
> this is the main result.
> We have seen also this energy was not of chemical origin, by checking
> the consumption
> of hydrogen. There was no measurable hydrogen consumption, at least
> with our mass 2
> measurement.” By measuring with a very sensitive scale, within a
> precision of a 10 th
> of a gram, Levi measured the weight of the hydrogen bottle before and
> after the experiment
> “If the energy was of chemical origin you would have expected to
> consume about 100 to
> 600 more than the sensitivity of the scale. You measure the bottle
> before and after and
> then you see in your measurements there was almost no hydrogen consumed.” "
>
>
>
> http://lenr-canr.org/acrobat/MacyMspecificso.pdf
>
> Macy, M., Specifics of Andrea Rossi's "Energy Catalyzer" Test,
> University of Bologna, January 14, 2011.
> 2011, LENR-CANR.org.
>
> Specifics of Andrea Rossi’s “Energy Catalyzer” Test,
> University of Bologna, 1/14/2001
>
> Marianne Macy
>
> On January 14, 2011, Andrea Rossi submitted his “Energy Catalyzer”
> reactor, which
> burns hydrogen in a nickel catalyst, for examination by scientists at
> the University of
> Bologna and The INFN (Italian National Institute of Nuclear Physics).
> The test was
> organized by Dr. Giuseppe Levi of INFN and the University of Bologna
> and was assisted
> by other members of the physics and chemistry faculties. This result
> was achieved
> without the production of any measurable nuclear radiation. The
> magnitude of this result
> suggests that there is a viable energy technology that uses commonly
> available materials,
> that does not produce carbon dioxide, and that does not produce
> radioactive waste and
> will be economical to build.
>
> The reactor used less than 1 gram of hydrogen, less than 1,000 W of
> electricity to
> convert 292 grams of water per minute at ~20°C into dry steam at
> ~101°C. The unit was
> turned ON and began producing some steam in a few minutes, and once it
> reached steady
> state continued producing steam until it was turned OFF. The amount of
> power required
> to heat water 80°C and convert it to steam is approximately 12,000
> watts. Dr. Levi and
> his team will be producing a technical report detailing the design and
> execution of their
> evaluation.
>
> A representative of the investment group stated that they were looking
> to produce a
> 20 kW unit and that within two months they would make a public announcement. He
> declared that their completed studies revealed a “huge, favorable
> difference in numbers”
> between the cost to produce the Rossi Catalyzer and other green
> technologies. “We had a
> similar demonstration six months ago with the same success we’ve had
> today. We are
> almost ready with the industrialized product, which we think is going
> to be a revolution.
> It is a totally green energy.” The representative offered that the
> company was called
> Defkalion Energy, named for the father of the Greco Roman empire, and
> was based in
> Athens.
>
> Giuseppe Levi, PhD in nuclear physics at the University of Bologna and
> who works at
> INFN, offers exclusive comments on the test, which he deemed “an open
> experiment for
> physicists. The idea was like a conference: to tell everybody what was
> going on and
> eventually to start new research programs on that topic.”
>
> The first measurements Levi described were energy measurements to determine the
> input of energy inside the reactor and the output of energy of the
> reactor. “I don't have
> conclusive data on radiation but absolutely we have measured ~12 kW
> (at steady state) of
> energy produced with an input of about just 400 watts. I would say
> this is the main result.
> We have seen also this energy was not of chemical origin, by checking
> the consumption
> of hydrogen. There was no measurable hydrogen consumption, at least
> with our mass 2
> measurement.” By measuring with a very sensitive scale, within a
> precision of a 10 th
> of a gram, Levi measured the weight of the hydrogen bottle before and
> after the experiment
> “If the energy was of chemical origin you would have expected to
> consume about 100 to
> 600 more than the sensitivity of the scale. You measure the bottle
> before and after and
> then you see in your measurements there was almost no hydrogen consumed.”
>
> [ Rich Murray: "100 to 600 more than the sensitivity of the scale",
> which may be 0.1 gm, gives 10 -- 60 gm/second ranges of H2 used --
> 36,000 -- 216,000 gm = 36 -- 216 kg H2 -- that would be a lot to deliver from a
> hidden source... ]
>
> The workings of the Rossi reactor was, Levi explained, unknown to them
> because of
> “industry secrets.” He said: “What we've done is to measure the water
> in the flux and we
> are heating and making steam for that water. We are measuring the water flux and
> carefully checking that all the water was converted into steam, then
> it is easy to calculate
> power that was generated. You are measuring the power that was going
> in the system by
> quite a sensitive power meter. Initially the system started up and we
> had 1 kW of input
> and then we reduce the input to just 400 W. The output energy was
> constant at about
> 12 kW.”
>
> The flow rate, Levi continued, was measured with a high precision
> scale. “The flow
> rate was 146 g in 30 seconds. Using a simple measurement gives a
> simple result. There
> was a pump putting in a constant flux and what I have done is – with the reactor
> completely off take measurements – we spent two weeks of the water that flowing
> through the system to be certain of our calibration. After this
> calibration period I have
> checked that the pump was not touched and when we brought it here for
> the experiment it
> was giving the same quantity of water during all the experiment. The
> water was coming
> from an Edison well and the pump was putting it in the system. Then we
> were releasing
> the steam into the atmosphere; there was not a loop.”
>
> To determine if the steam was coming out dry and at atmospheric
> pressure, Professor
> Gallatini, a specialist in Thermochemics and a former head of the
> Chemical Society of
> Italy, verified that all the water came out as steam. “There was no
> water in the steam,”
> Levi certified. “The outer temperature measured was 101° centigrade at
> atmospheric
> pressure.” The instrument he used was a Delta OHM # HD37AB1347 Indoor
> Air Quality
> Monitor. Gallantini inserted the probe inside the exit pipe with the steam.
>
> Levi was asked: How did you compute the thermal energy production by the Energy
> Catalyzer (ECat)?
> He responded, “The calculation is very, very simple. Because you know
> the number of
> grams of water per second delivered to the ECat you know you must
> raise the water to
> 100°C, this is the transient phase of operation. Once the water is at
> 100°C the energy is
> used to make the water into steam. It takes 2272 joules per gram to
> convert water at
> 100°C to steam. Because the ECat provided more energy the steam became hotter,
> 101°C. So our conservative estimate of the steady state thermal output
> of the ECat,
> neglecting thermal radiation and other losses, is just 2272 joules per
> gram multiplied by
> the 4.9 grams per second = 11, 057 joules per second or Watts. When
> you realize that you
> have to add the energy to raise the temperature of the water you get
> by about 80°C and
> the steam by another 1°C the total thermal power the ECat releasing is
> about 12,400
> Watts. These are not our refined estimate but they indicate that the
> input electrical power
> of 400 W produces using an amount of hydrogen less than a gram in a
> couple hours of
> operation we are seeing a system with a power gain = 12,400/400 = 31.”
>
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