scholarly journals Incorporating the Work Done by Vertical Density Fluxes in Both Kinetic and Thermal Energy Conservation Equations to Satisfy Total Energy Conservation

2019 ◽  
Vol 58 (2) ◽  
pp. 213-230 ◽  
Author(s):  
Jielun Sun
Keyword(s):  
Thermal Expansion ◽  
Energy Balance ◽  
Kinetic Energy ◽  
Potential Energy ◽  
Energy Conservation ◽  
Total Energy ◽  
Thermal Energy ◽  
Temporal Variations ◽  
Vertical Density ◽  
Total Energy Conservation

AbstractConservation of total, kinetic, and thermal energy in the atmosphere is revisited, and the derived thermal energy balance is examined with observations. Total energy conservation (TEC) provides a constraint for the sum of kinetic, thermal, and potential energy changes. In response to air thermal expansion/compression, air density variation leads to vertical density fluxes and potential energy changes, which in turn impact the thermal energy balance as well as the kinetic energy balance due to the constraint of TEC. As vertical density fluxes can propagate through a large vertical domain to where local thermal expansion/compression becomes negligibly small, interactions between kinetic and thermal energy changes in determining atmospheric motions and thermodynamic structures can occur when local diabatic heating/cooling becomes small. The contribution of vertical density fluxes to the kinetic energy balance is sometimes considered but that to the thermal energy balance is traditionally missed. Misinterpretation between air thermal expansion/compression and incompressibility for air volume changes with pressure under a constant temperature would lead to overlooking important impacts of thermal expansion/compression on air motions and atmospheric thermodynamics. Atmospheric boundary layer observations qualitatively confirm the contribution of potential energy changes associated with vertical density fluxes in the thermal energy balance for explaining temporal variations of air temperature.

scholarly journals On Fulfillment of Energy Conservation Law in Theory of Elastic Waves V. V. Nevdakh1)

2021 ◽  
Vol 20 (2) ◽  
pp. 161-167
Author(s):  
V. V. Nevdakh
Keyword(s):  
Kinetic Energy ◽  
Potential Energy ◽  
Energy Conservation ◽  
Elastic Wave ◽  
Total Energy ◽  
Elastic Deformation ◽  
Sound Wave ◽  
Elastic Waves ◽  
Conservation Law ◽  
Energy Conservation Law

In accordance with the energy conservation law, the total energy of a closed physical system must remain constant at any moment of time. The energy of a traveling elastic wave consists of the kinetic energy in the oscillating particles of the medium and the potential energy of  its elastic deformation. In the existing theory of elastic waves, it is believed that the kinetic and potential energy densities of a traveling wave without losses  are the same at any moment of time and vary according to the same law. Accordingly, the total energy density of such wave is different at various moment of time, and only its time-averaged value remains constant. Thus, in the existing theory of elastic waves, the energy conservation law is not fulfilled. The purpose of this work is to give a physically correct description of these waves. A new description of a sound wave in an ideal gas has been proposed and it is based on the use of a wave equation system for perturbing the oscillation velocity of gas particles, which determines their kinetic energy, and for elastic deformation, which determines their potential energy. It has been shown that harmonic solutions describing the oscillations of the gas particles velocity perturbation and their elastic deformation, which are phase shifted by p/2, are considered as physically correct solutions of such equations system for a traveling sound wave. It has been found that the positions of the kinetic and potential energy maxima in the elastic wave, described by such solutions, alternate in space every quarter of the wavelength. It has been established that every quarter of a period in a wave without losses, the kinetic energy is completely converted to potential and vice versa, while at each spatial point of the wave its total energy density is the same at any time, which is consistent with the energy conservation law. The energy flux density of such traveling elastic wave is described by the expression for the Umov vector. It has been concluded that such traveling sound wave without losses  in an ideal gas can be considered as a harmonic oscillator.

DEVELOPMENT OF CONSTRUCTION OF THREE-INPUT GENERATING INSTALLATIONS ON BASED OF RENEWABLE ENERGY SOURCES

2018 ◽  
Author(s):  
Я.М. КАШИН ◽  
Л.Е. КОПЕЛЕВИЧ ◽  
А.В. САМОРОДОВ ◽  
Ч. ПЭН
Keyword(s):  
Renewable Energy ◽  
Kinetic Energy ◽  
Total Energy ◽  
Thermal Energy ◽  
Output Voltage ◽  
Renewable Energy Sources ◽  
Electrical Energy ◽  
Energy Sources ◽  
Voltage Regulator ◽  
The Sun

Описаны конструктивные особенности трехвходовой аксиальной генераторной установки (ТАГУ), преобразующей кинетическую энергию ветра и световую энергию солнца и суммирующей механическую, световую и тепловую энергию с одновременным преобразованием полученной суммарной энергии в электрическую. Показаны преимущества ТАГУ перед двухвходовыми генераторными установками. Дополнительное включение стабилизатора напряжения в схему ТАГУ позволило расширить область применения стабилизированной трехвходовой аксиальной генераторной установки за счет стабилизации ее выходного напряжения. The design features of the three-input axial generating installation (TAGI), which converts the kinetic energy of wind and light energy of the sun and sums the mechanical, light and thermal energy with the simultaneous conversion of the total energy into electrical energy, are described. The benefits of TAGI in front of the two-input generating installation shown. The additional introduction of a voltage regulator into the TAGI scheme allowed to expand the scope of the stabilized three-input axial generating installation by stabilizing its output voltage.

scholarly journals GRAVITY HEATS THE UNIVERSE

2009 ◽  
Vol 18 (14) ◽  
pp. 2201-2207
Author(s):  
ADAM MOSS ◽  
DOUGLAS SCOTT
Keyword(s):  
Kinetic Energy ◽  
Potential Energy ◽  
Energy Conservation ◽  
Cosmic Microwave Background ◽  
Initial Conditions ◽  
Gravitational Instability ◽  
Simplified Model ◽  
Microwave Background ◽  
Average Temperature ◽  
The Universe

Structures in the Universe grew through gravitational instability from very smooth initial conditions. Energy conservation requires that the growing negative potential energy of these structures be balanced by an increase in kinetic energy. A fraction of this is converted into heat in the collisional gas of the intergalactic medium. Using a toy model of gravitational heating, we attempt to link the growth of structure in the Universe with the average temperature of this gas. We find that the gas is rapidly heated from collapsing structures at around z ~ 10, reaching a temperature > 106 K today, depending on some assumptions of our simplified model. Before that there was a cold era from z ~ 100 to ~10 in which the matter temperature was below that of the cosmic microwave background.

Total energy conservation and the symplectic algorithm

2002 ◽  
Vol 19 (3) ◽  
pp. 459-467 ◽  
Author(s):  
Ji Zhongzhen ◽  
Wang Bin ◽  
Zhao Ying ◽  
Yang Hongwei
Keyword(s):  
Energy Conservation ◽  
Total Energy ◽  
Symplectic Algorithm ◽  
Total Energy Conservation

Total energy conservation in ALE schemes for compressible flows

2010 ◽  
Vol 19 (4) ◽  
pp. 337-363 ◽  
Author(s):  
Alain Dervieux ◽  
Charbel Farhat ◽  
Bruno Koobus ◽  
Mariano Vázquez
Keyword(s):  
Energy Conservation ◽  
Total Energy ◽  
Compressible Flows ◽  
Total Energy Conservation

scholarly journals Modeling of Energy Release at the Final Stage of the Meteoroid Movement

2016 ◽  
Vol 27 (1) ◽  
pp. 290-293
Author(s):  
Lidia A. Egorova ◽  
Valery V. Lokhin
Keyword(s):  
High Temperature ◽  
Kinetic Energy ◽  
Energy Conservation ◽  
Thermal Energy ◽  
Final Stage ◽  
Physical Theory ◽  
Cosmic Body ◽  
Gas Volume ◽  
Gas Cloud ◽  
Explosive Destruction

Abstract The paper continues to build upon the author’s previous research on fireballs fragmentation. A model of the sudden explosive destruction of the cosmic body at the height of the maximum flash is used. After the fragmentation, the kinetic energy of the moving particles of a meteoroid passes into the thermal energy of the gas volume inwhich their motion takes place. The temperature of a gas cloud calculated analytically using energy conservation lawand equations of physical theory of meteors. The mass distribution of fragments was taken from the literature. The high temperature of the gas in a cloud allows us to talk about the phenomenon of a "thermal explosion".

Inverting DAS data using energy conservation principles

2021 ◽  
pp. 1-32 ◽  
Author(s):  
Vladimir Kazei ◽  
Konstantin Osypov
Keyword(s):  
Kinetic Energy ◽  
Potential Energy ◽  
Energy Conservation ◽  
Energy Balancing ◽  
Seismic Profiling ◽  
Vertical Seismic Profiling ◽  
Conservation Principles ◽  
Distributed Acoustic Sensing ◽  
To Come ◽  
Seismic Wavefield

Distributed acoustic sensing (DAS) technologies are now becoming widespread, in particular in Vertical Seismic Profiling (VSP). Being a spatially densely sampled recording of seismic wavefield, DAS data provides an extended measurement as compared with point geophone VSP. We developed a basic theory that enables intuitive geophysical understanding of DAS data using the concepts of kinetic and potential energy and their fluxes. We start by relating DAS and geophone measurements to potential energy and kinetic energy, correspondingly. We use this relationship and energy balancing along the well to come up with a scheme for inverting DAS and geophone wavefields for density and velocity simultaneously. Then, recognizing that it may be impractical to have both geophones and DAS, we propose a second inversion scheme that eliminates the need for geophones and uses upgoing and downgoing DAS wavefields instead. There is no need for first-break picking windowing the data and full DAS records can be utilized in both inversion schemes. We test the feasibility of these inversion schemes on 2D elastic synthetics.

scholarly journals Atmospheric Available Energy

2012 ◽  
Vol 69 (12) ◽  
pp. 3745-3762 ◽  
Author(s):  
Peter R. Bannon
Keyword(s):  
Kinetic Energy ◽  
Potential Energy ◽  
Total Energy ◽  
General Circulation ◽  
Total Potential Energy ◽  
Maximum Amount ◽  
Hydrostatic Equilibrium ◽  
Gibbs Function ◽  
Available Energy ◽  
Total Potential

Abstract The total potential energy of the atmosphere is the sum of its internal and gravitational energies. The portion of this total energy available to be converted into kinetic energy is determined relative to an isothermal, hydrostatic, equilibrium atmosphere that is convectively and dynamically “dead.” The temperature of this equilibrium state is determined by minimization of a generalized Gibbs function defined between the atmosphere and its equilibrium. Thus, this function represents the maximum amount of total energy that can be converted into kinetic energy and, hence, the available energy of the atmosphere. This general approach includes the effects of terrain, moisture, and hydrometeors. Applications are presented for both individual soundings and idealized baroclinic zones. An algorithm partitions the available energy into available baroclinic and available convective energies. Estimates of the available energetics of the general circulation suggest that atmospheric motions are primarily driven by moist and dry fluxes of exergy from the earth’s surface with an efficiency of about two-thirds.

scholarly journals CONSEQUENCES FROM THE ENERGY OF THE DIPOLE OR THE RATIONALE FOR THE IDEA OF NIKOLA TESLA

2021 ◽  
Vol 7 (4(40)) ◽  
pp. 11-14
Author(s):  
Evgeny Georgievich Yakubovsky
Keyword(s):  
Gravitational Field ◽  
Kinetic Energy ◽  
Potential Energy ◽  
Total Energy ◽  
Breakdown Voltage ◽  
Virial Theorem ◽  
Experimental Studies ◽  
The Earth ◽  
Nikola Tesla ◽  
Maximum Voltage

According to the virial theorem, a dipole has a small total energy at infinite negative potential energy and infinite positive kinetic energy, see [1] §10. Nikola Tesla was able to realize this energy in the car he built. The fundamental difficulties for creating a machine without an engine on gasoline energy have been overcome. But the experimental studies of Nikola Tesla were much ahead of the existing technologies, and according to my calculations, the breakdown voltage, for example, porcelain should be made orders of magnitude higher. Nikola Tesla could create a voltage of a billion volts, and according to modern data, the maximum voltage is a million volts. Moreover, it is necessary to use towers of great height to avoid breakdown. If we calculate the force created by the potential of the dipole and equate it with the force of attraction, then we will receive compensation for the gravitational field of the Earth.

scholarly journals Gravitational Potential Energy Balance for the Thermal Circulation in a Model Ocean

2006 ◽  
Vol 36 (7) ◽  
pp. 1420-1429 ◽  
Author(s):  
Rui Xin Huang ◽  
Xingze Jin
Keyword(s):  
Energy Balance ◽  
Equation Of State ◽  
Kinetic Energy ◽  
Potential Energy ◽  
Gravitational Potential ◽  
Mechanical Energy ◽  
Vertical Mixing ◽  
Gravitational Potential Energy ◽  
Thermal Circulation ◽  
Model Ocean

Abstract The gravitational potential energy balance of the thermal circulation in a simple rectangular model basin is diagnosed from numerical experiments based on a mass-conserving oceanic general circulation model. The vertical mixing coefficient is assumed to be a given constant. The model ocean is heated/cooled from the upper surface or bottom, and the equation of state is linear or nonlinear. Although the circulation patterns obtained from these cases look rather similar, the energetics of the circulation may be very different. For cases of differential heating from the bottom with a nonlinear equation of state, the circulation is driven by mechanical energy generated by heating from the bottom. On the other hand, circulation for three other cases is driven by external mechanical energy, which is implicitly provided by tidal dissipation and wind stress. The major balance of gravitational energy in this model ocean is between the source of energy due to vertical mixing and the conversion from kinetic energy at low latitudes and the sink of energy due to convection adjustment and conversion to kinetic energy at high latitudes.

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