tag:blogger.com,1999:blog-8017670750734633321.post5937350112491423863..comments2024-03-29T01:18:36.311+11:00Comments on new illuminati: The Future of Clean Energy and Overunity Explainednew illuminatihttp://www.blogger.com/profile/17527075249440961813noreply@blogger.comBlogger5125tag:blogger.com,1999:blog-8017670750734633321.post-57360508077781067722017-05-15T17:06:02.744+10:002017-05-15T17:06:02.744+10:00Nice stuff dear. I like to read your post. I found...Nice stuff dear. I like to read your post. I found something to share with you. Check here. <a href="https://goo.gl/eJHF1F" rel="nofollow"><b>commercial solar ppa</b></a> & <a href="https://goo.gl/j0cxKU" rel="nofollow"><b>solar panel installation company</b></a>Anonymoushttps://www.blogger.com/profile/01028545924609892703noreply@blogger.comtag:blogger.com,1999:blog-8017670750734633321.post-42644426390670013442013-05-06T09:03:46.936+10:002013-05-06T09:03:46.936+10:00DENATURATION THE STATE OF THERMODYNAMIC EQUILIBRIU...DENATURATION THE STATE OF THERMODYNAMIC EQUILIBRIUM AND OVERVIEW OF THE OVER-UNITY MODELS SPONTANEOUS AND INDUCED. <br /><br />OVERUNITY PRODUCTION BY DYNAMIC MECHANICAL EQUILIBRIUM<br /><br />CREATING ENERGY TAKING INTO CONSIDERATION THE THERMODYNAMICS<br /><br />HOW TO CREATE ENERGY; The creation of energy, exergy creation (inside, and constant) of a thermodynamic equilibrium:<br /><br />From the viewpoint of classical thermodynamics, the amount of exergy that can produce a system is indicative of the distance at which the system is located his, end Equilibrium. A system in thermodynamic equilibrium state, is unable to experience a change of state spontaneously, (thermal equilibrium, mechanical equilibrium, and Chemical equilibrium) by nature (natural or artificial). Agree with the above, a closed system thermally insulated with a chemical and mechanical equilibrium (thermodynamic equilibrium permanent), the output is zero exergy. However, a system that is in thermodynamic equilibrium (dynamic mechanical) exergy can (continue) producing while staying within their own thermodynamic equilibrium without external power supply to the system continuous production of energy (energy creation) from a dynamic-mechanic Equilibrium system, denaturalizing (altering nature) the concept of the thermodynamic equilibrium.<br /><br />The action-reaction forces are present (in nature and in any device created by man) both in the states of equilibrium and non-equilibrium. In the same way, these action-reaction forces are directly responsible for compliance and non-compliance with the laws of thermodynamics.<br /><br />In a system where a process occurs, from a state of equilibrium-1, into another state of equilibrium-2, generating work and heat, with consumption or power dissipation (due to the shape of the operating mechanism, governed by the design system), then everyone is fulfilled the laws of thermodynamics, using the action-reaction forces only to transmit and transform motion energy (fulfilling the law of conservation of energy).<br /><br />By contrast, when a system is in constant dynamic equilibrium, and also has a design in which it retains the energy of the energy source, and uses the transmission effect of the pairs of action-reaction forces, to produce the propulsion (of bodies, and mobility subcycles), so that continually occur macroscopic forces opposing applied in areas opposite movable (supports mobile) which is part of the body of mobile subcycles , (each with low forces opposition to the motion and low friction), which interact Through half (liquid, solid or gas) so as to generate useful movement (work, and incidentally heat due to friction), keeping constant the amount of energy within the energy source (thermal insulation, constant volume, constant temperature, constant pressure to thermal equilibrium, Equilibrium Dynamic-Mechanical, chemical equilibrium), having a constant thermodynamic equilibrium within the limits of the energy source. Oppositely, outside the boundaries of the energy source for the system (composed subcycle or subsystems), there is a non-equilibrium mechanic, a thermal non-equilibrium production of useful movement (due to work and heat by motion friction), and electrical energy production methods, if fitted an alternator or generator, which transforms the mechanical energy (useful movement) in Electric Power, thus, to produce more energy (keeping constant the amount of Energy Source Energy that produces it, using the action-reaction forces) clearly not fulfilled the first law of thermodynamics, well as most of the postulates of the Second Law of Thermodynamics, (with the exception of decreased the entropy of the universe) if you enter a device that violates the first law (PMM1) inside a refrigerator or heat pump, producing (one PMM2) over unity.<br /><br />New Fourth Law of Thermodynamics; useful movement (work and heat) propelled by iso-energy (isobaric, isothermal, isochoric and adiabatic) or iso-energetically propelled subcycle.<br /><br />http://es.calameo.com/books/001042771b37fe7e3106d<br /><br />Ramiro Augusto Salazar La Rotta, D.Sc.<br />ramirohttps://www.blogger.com/profile/02855156135496788019noreply@blogger.comtag:blogger.com,1999:blog-8017670750734633321.post-55463844600353781952013-05-06T08:21:46.599+10:002013-05-06T08:21:46.599+10:00This comment has been removed by the author.ramirohttps://www.blogger.com/profile/02855156135496788019noreply@blogger.comtag:blogger.com,1999:blog-8017670750734633321.post-29623361508771872452013-01-24T08:32:25.554+11:002013-01-24T08:32:25.554+11:00In the latter cases, the efficiencies are less tha...In the latter cases, the efficiencies are less than unity, due not only to the energy lost as heat by friction, but mainly because they work processes that produce from a given volumetric expansion, sacrificing both pressure and temperature that is, the process occurring in volumetric dissipation of energy, from a state of high energy concentration within a small volume, to a state of low energy concentration within a larger volume, or large relative to initial state. Eventhough that both states have the same energy, having done work. In other words the energy is not diminished, or lost due to the transformation in work (another kind of energy), but because this initial energy moves from a high concentration to a low concentration energy energy produced energy dissipation, no energy transformation work (another kind of energy), but an energetic (work), proportional to the change in concentration of energy. This would mean that the energy is not converted but is dissipated to perform a work keeping its value constant in the universe, so if you were to control the energy dissipation occurs as you work, it can be said that the same energy, within a device that produces work (without energy dissipation that produces it), could create other types or forms of energy. Without denying that the internal energy in the system is a state function, not being so for the heat and work, both (heat and work) are only effects, directly proportionate to the change in energy concentration. The latter would be a new theory that revoluconaría, new knowledge regarding actual thermodynamics, in order to achieve efficiencies greater than unity, at properly designed systems for such a purpose.ramirohttps://www.blogger.com/profile/02855156135496788019noreply@blogger.comtag:blogger.com,1999:blog-8017670750734633321.post-18576125411468452692013-01-24T08:26:22.357+11:002013-01-24T08:26:22.357+11:00New formulation and thermodynamics equation of ove...New formulation and thermodynamics equation of over-unity:<br />OVER-UNITY = (E2 – E1 + Ws + Qs + W created + Q created –TΔS ) / (We + Qe) ; <br />1 ≤ OVER-UNITY to ∞ (from one up to infinity)<br />Meaning of the small; e = that enters the system, s = exiting the system.<br />COP = (E2 – E1 + Ws + Qs + W free + Q free –TΔS ) / (We + Qe)<br />0 ≤ COP to ∞ (from zero to infinity)<br /><br />Unlike the:<br />http://en.wikipedia.org/wiki/Coefficient_of_performance<br /><br />http://es.wikipedia.org/wiki/Ciclo_de_Carnot<br /><br /><br />En estos últimos casos, las eficiencias son menores a la unidad, debido no solo a la perdida de energía en forma de calor por la fricción, sino principalmente por ser procesos que producen trabajo a partir de una expansión sacrificando tanto la presión como la temperatura, es decir, ocurriendo en el proceso una disipación volumétrica de la energía, al pasar de un estado de concentración de energía alta dentro de un volumen pequeño, a un estado de concentración de energía baja dentro de un volumen mayor, o grande con respecto al estado inicial. A pesar que en ambos estados se tiene la misma cantidad de energía, después de haber realizado un trabajo. En otras palabras la energía no se disminuye, o se pierde debido a la transformación en trabajo (“modo de transformación de energía”), sino debido a que esta energía inicial pasa de una alta concentración energética a una baja concentración energética, produciéndose una disipación de la energía, no una transformación energética en trabajo (“otro modo de transformación de energía”), sino un efecto energético (el trabajo como el calor) proporcional al cambio de concentración de la energía. Esto significaría que la energía no se transforma, sino que se disipa al realizar un trabajo o transmitir calor hacia el exterior o bien la energía se concentra al recibir un trabajo o calor desde el exterior. Entonces si se llegara a controlar la disipación energética a medida que produce trabajo, se podrá decir, que la misma energía, dentro de un dispositivo que produzca trabajo, (sin disipación de la energía que lo produce), podría crear (free Energy) otros “tipos, o formas de energías”. Tanto el calor como el trabajo si entran al sistema sirven para concentrar la energía y si ambos salen del sistema sirven para disipar la energía (disminuir la concentración de la energía) en el sistema. Sin negar que la energía interna del sistema sea una función de estado, no siendo así para el calor y el trabajo, ambos (calor y trabajo) son solo efectos, directamente proporcionales al cambio de la concentración energética. Esto último sería una nueva teoría que revolucionaría, un nuevo conocimiento con respecto a la termodinámica actual, para poder obtener eficiencias superiores a la unidad en sistemas adecuadamente diseñados para tal propósito. http://es.calameo.com/books/001042771b5f782c01f3bramirohttps://www.blogger.com/profile/02855156135496788019noreply@blogger.com