File: EnergySavingTips.txt Dates: 12 Jul 2008 - 14 Jul 2008 To view this file, right click -> View source, then use Notepad to Format -> Word Wrap Here are some tips to save energy that we can begin to invoke, using the Bessler principle, even before the low friction Orffyrean roller bearing is developed. Energy collected from gravitons is energy saved from that energy source. AEP - 12 Jul 2008 (1) Reduce friction for rotations about horizontal axes, as not only is the energy saved that would have been lost to friction but also it allows more energy to be picked up from the two-part gravitons. See the Caution below. As a side note, the Takahashi, Kawai, and Gray over-unity electromagnetic engines previously happened to use rotations about horizontal axes. That rotation axis directionality should not be changed. The friction in their bearings should be reduced as much as practical so that they will operate even more efficiently. AEP - 12-14 July 2008 (2) One could heat water by physically stirring it. By stirring it about a vertical axis and one could get approximately an equal amount of heat out for each amount of mechanical energy expended. The word "approximately" is used since there could be some gravitons traveling in a horizontal direction that could provide some slight extra energy, which we now ignore. Consider instead, rotating the water in a cylinder about a horizontal axis of rotational symmetry with the water divided into two compartments (after the manner of the ancient oriental yin-yang symbol). Keep the cylinder well balanced with equal loads in the two compartments. Keeping the compartments full will reduce tumbling friction of the water, provide extra rotating mass, and allow the cylinder to be rotated faster by some external mechanical power source. Extra energy will be picked up from gravitons as the water rotates. Heating in bearings can be arranged such that much of it shows up as heat in the water. This heated water could also be used as a heating or cooking system where more heat is produced than the mechanical energy input. I don't know if this method of extracting heat from gravitons would be better than using a heat pump, but it is a route that was apparently used anciently, so we ought to at least consider it as an option. See the Caution below. Also as another safety issue, a confined heated container could explode, so means needs to be provided in the pressure containing compartment(s) to release dangerous pressure. Water could be allowed to slightly flow between the two compartments as a safety precaution. AEP - 12-14 July, 31 Oct 2008 (3) Increase the mass in wheels and/or axles that are rotating about horizontal axes. This will cause extra energy to be extracted from the two-part gravitons. The energy lost in the bearings due to friction must be considered. Practically a point would need to be found where the extra energy picked up by the larger mass needs to be larger than the extra energy lost to friction in the bearings (with the excess energy showing up as additional rotational kinetic energy). Other types of friction (such as friction with the air for high angular speeds) may be needed for the system to reach equilibrium and not be runaway. Consider the examples of the railroads and of Coral Castle, which examples typically used ordinary bearings but compensated for some friction in the bearings by using extra rotating mass. See the Caution below. AEP - 12-14 July 2008 The placement of extra mass should generally done at the least distance from the axis of rotation, so as to use the least relative speed between the air and the extra mass and thus have less friction between the additional mass and the air, assuming smooth wheel/axle surfaces. With regard to the energy picked up from gravitons, the thing that counts is the angular speed about internal horizontal axes of the rotating ground states, and not the distance of the mass from the macroscopic axis of rotation. AEP - 14 July 2008 (4) Increase the angular speed of the object (wheels and/or axles) being rotated about a horizontal axis. One should use the wheel and/or axle so that there is little air friction or low-radius smooth wheels. Also the bearing efficiency relative to the speed must partly be considered so use the extra angular speed if the wheel/axle/bearing is in a friction region where the extra energy picked up from gravitons is greater than the combined extra energy lost from friction of the wheel/axle/bearings. See the Caution below. The tip applies to molecular or nuclear ground state size wheels, as well as large macroscopic wheels. AEP - 12-14 July 2008 (5) If trying to produce energy somewhat like on the sun, there are many things that must be considered such as: horizontal magnetic fields, types of gas (as deuterium and noble gases), operating temperatures, and means of initially heating the gases. As there are solutions on the sun and solar corona, there should be efficient cost effective solutions on earth. Nature can do it and so can we find suitable solutions. I don't know that we are required to go to plasmas unless we insist on the higher operating temperatures. See the Caution below. The main tip here is that if we are approaching such solutions from a thermo-nuclear or "hot" fusion standpoint, we don't understand the basis of the phenomena and won't be in a good position to make helpful improvements. AEP - 12-14 July 2008 (6) There are solutions associated with the interactions of highly rotating nuclear ground states that can produce a wide variety of phenomena including nuclear fusion (as was the case with "cold" fusion). The word "cold" is put in quotes as from a linear translation perspective such a fusion is cold but from perspectives of highly rotating nuclear ground states such fusion could be considered as hot or operating at much higher temperatures than ordinary hot fusion (which is generally hot from a standpoint of translations but cold from a standpoint of rotations). See the Caution below. The tip here is that we should understand the basis of the phenomena, with regard to the rotating nuclear ground states, for guidance in improving the power production performances. In the case of "cold" fusion, much energy comes from nuclear energy, with the assistance of gravitons for initiating the reaction or creating the highly rotating nuclear ground states that can thereby interact. AEP - 12-14 July 2008 Caution - Though increasing angular speed, increasing rotational mass, and decreasing friction of the rotating bodies allows more kinetic energy of rotation to be picked up from gravitons, there exist points at which many systems can become dangerous or produce runaway situations. Proper safety steps need to be taken to guard against these situations. AEP - 12 July 2008 ---------- Use Back on browser to return to Main or go to http://www1.iwvisp.com/LA4Park/ or http://mysite.verizon.net/aldlin/ (all after exiting, if in "View source" mode).