I see heat transfer as in a super-fluid, that is almost instansious.
*I am confident the there is a global condensation of polariton states in a Ni/H reactor. This general condition of Bose-Einstein condensation means that the micro-powder and perhaps even the hydrogen envelope is a superfluid that conducts heat with little or no resistance.* * * *A superfluid conducts heat better than copper, a 1000 times better, which is yet an excellent conductor in its own right. The reason is that thanks to superfluidity, a perfect liquid can easily move from hot zones to cold zones, enabling a thermal conduction by convection, a phenomenon much more efficient than the usual gradual heat diffusion. * * * *When you put a saucepan of water on a hotplate, the bottom is hotter than the free surface. Bubbles appear in the bottom, get bigger, get loose and spread over the water: the water is boiling. * * * *However, in a superfluid, the great thermal conduction requires a very homogeneous temperature everywhere. In the absence of zones hotter than others, transformation from liquid to vapor can only happen at the free surface where a superfluid evaporates: there are no bubbles. A superfluid vaporizes without boiling. * * * *What concerns many theorists of the Ni/H reactor is how heat produced by a few grams of nickel powder can be transmitted to the walls of the reactor.* * * *The general state of superfluidity keeps the temperature uniform throughout the hydrogen envelop. The walls of the reactor are the same temperature as the micro-powder because of a general state of Bose-Einstein condensation made possible by the polariton.* * * *Do you see any indication of this superfluid in the data from the test?* On Fri, May 24, 2013 at 1:43 AM, Rich Murray <[email protected]> wrote: > can Ethan's hidden double power wires explain almost linear temperature > rises and falls every 6 minutes for 5 days in Rossi HT2: Ethan: Rich Murray > 2013.05.23 > > http://rmforall.blogspot.com/2013/05/can-ethans-hidden-double-power-wires.html > > > > http://rmforall.blogspot.com/2013/05/rossi-e-cat-ht-shows-excess-heat-from-h.html > > > http://scienceblogs.com/startswithabang/2013/05/21/the-e-cat-is-back-and-people-are-still-falling-for-it/ > > comment #103 2013.05.23 Thursday noon PST > > Ethan, I appreciate your spirited critique, especially the simple hidden > double wire scam -- which if power was actually supplied at high voltages, > could be very small in diameter. > > I wonder if this can explain the remarkably constant temperature rises and > falls with almost linear curves shown for runs of up to 5 days? > > within the fellowship of service, Rich Murray > rmforall at gmail.com > > > http://arxiv.org/ftp/arxiv/papers/1305/1305.3913.pdf > > page 25 bottom: > > Remarks on the test > > An interesting aspect of the E-Cat HT2 is certainly its capacity to > operate in self-sustaining mode. > > The values of temperature and production of energy which were obtained are > the result of averages not merely gained through data capture performed at > different times; > they are also relevant to the resistor coils’ ON/OFF cycle itself. > > By plotting the average temperature vs time for a few minutes of test > (Plot 3) one can clearly see how it varies between a maximum and a minimum > value with a fixed periodicity. > > Plot 3. Average surface temperature trend of the E-Cat HT2 over several > minutes of operation. > > Note the heating and cooling trends of the device, which appear to be > different from the exponential characteristics of generic resistor. > > Looking at Plot 3, the first feature one notices is the appearance taken > by the curve in both the heating and cooling phases of the device. > > If we compare these in detail with the standard curves of a generic > resistor (Plot 4 and Plot 5), we see that the former differ from the latter > in that they are not of the exponential type. > > Plot 4. Comparing the typical heating curve of a generic resistor (left, > [Ref. 9]) to the one relevant to one of the E-Cat HT2’s ON states. > > Finally, the complete ON/OFF cycle of the E-Cat HT2, as seen in Plot 3, > may be compared with the typical heating-cooling cycle of a resistor, as > displayed in Plot 6. > > Plot 6. Heating and cooling cycle of a generic resistor [Ref. 9]. > The trend is described by exponential type equations. > > What appears obvious here is that the priming mechanism pertaining to some > sort of reaction inside the device speeds up the rise in temperature, and > keeps the temperatures higher during the cooling phase. > > Another very interesting behavior is brought out by synchronically > comparing another two curves: > power produced over time by the E-Cat HT2, and power consumed during the > same time. > > An example of this may be seen in Plot 7, which refers to about three > hours of test. > The resistor coils ON/OFF cycle is plotted in red, while the > power-emission trend of the device appears in blue. > > Plot 8. Detail taken from Plot 7, reproducing the first two periods of the > cycle. > > The three time intervals in which each period may be divided are labeled > by Roman numerals. > > Further food for thought may be found by analyzing the trend of the ratio > between energy produced and energy consumed by the E-Cat HT2, as referred > to the same time interval dealt with in Plot 7. > > The blue curve in Plot 9 is the result of the analysis, and is reproduced > here together with the red curve of power consumption normalized to 1. > > Basically, for every second taken into account, the corresponding value of > the blue curve is calculated as the ratio between the sum of the power per > second emitted in all the previous seconds, and the sum of the power per > second consumed in all the previous seconds. > > Plot 9. The blue curve is the result of the ratio between energy produced > and consumed by the E-Cat HT2, with reference to the same time instants > dealt with in Plot 7. > > The red curve represents the ON/OFF trend of the resistor coils normalized > to 1. > > All the above trends are remarkable, and warrant further in-depth inquiry. > > > On Thu, May 23, 2013 at 12:45 PM, Rich Murray <[email protected]> wrote: > >> can Ethan's hidden double power wires explain regular exponential >> temperature rises and falls every 6 minutes for 5 days in Rossi HT2: Ethan: >> Rich Murray 2013.05.23 >> >> >> >
