The proper use of semantic and formal categories in energy accounting

2013 ◽  
pp. 81-111
Keyword(s):  
Energy Accounting

scholarly journals Sensible Energy Accounting with Abstract Metering for Multicore Systems

2016 ◽  
Vol 12 (4) ◽  
pp. 1-26 ◽  
Author(s):  
Qixiao Liu ◽  
Miquel Moreto ◽  
Jaume Abella ◽  
Francisco J. Cazorla ◽  
Daniel A. Jimenez ◽  
...  
Keyword(s):  
Multicore Systems ◽  
Energy Accounting

Study on Energy Conservation and Consumption Reduction

2013 ◽  
Vol 329 ◽  
pp. 36-39 ◽  
Author(s):  
Qiu Hong Wang
Keyword(s):  
Energy Conservation ◽  
Information Disclosure ◽  
Theoretical Foundation ◽  
Emissions Reduction ◽  
Consumption Reduction ◽  
Energy Accounting

In this paper, according to the requirements on energy conservation and emissions reduction, the theoretical foundation for the essence, objective and elements of energy accounting is introduced around energy conservation and consumption reduction, and also energy accounting is elaborated from expenditure expensing and capitalization, recording and accounting, and information disclosure.

scholarly journals Improvement of the regenerating energy accounting system on the direct current railways

2015 ◽  
Vol 36 (4) ◽  
pp. 35-42 ◽  
Author(s):  
Valeriy G. Kuznetsov ◽  
Oleg I. Sablin ◽  
Alenka V. Chornaya
Keyword(s):  
Power Supply ◽  
Practical Importance ◽  
Rolling Stock ◽  
Accounting System ◽  
Quantitative Indices ◽  
Energy Accounting ◽  
Traction Power Supply ◽  
Electric Traction ◽  
Regenerative Energy ◽  
Traction Power

Purpose. Monitoring of current state of quantitative indices of regenerative energy in the suburban movement, the analysis of the factors influencing its volumes and improvement the principles of the train regenerative energy accounting on the basis of it. Relevance. Development of effective measures of increase the regeneration efficiency of the electric power in system of electric traction demands comprehensive completeness of information on quantitative indices of regeneration energy volumes at all possible levels of its analysis, in particular on the corresponding sections of RS movement that will allow to establish the influence on the level of regeneration of various factors, such as parameters of traction power supply and the organization of train service. As the existing system of the regenerative energy accounting does not allow to consider the specified factors, development of the principles for increasing the efficiency of the analysis of volumes of return energy to a contact line during regenerative braking on DC rolling stock is the actual direction of researches. Collective monitoring of regeneration energy volumes by specialists of locomotive service, power supply and traffic operating departments will be essentially new approach to definition of real factors and taking effective decisions for increasing of using of regenerative energy. Scientific novelty. It’s offered to consider the influence on quantitative indices of regenerative energy the parameters of traction power supply and the organization (sizes) of traffic service on sections. Practical importance. Increasing the efficiency of the regeneration energy accounting is an important element in drawing up the balance of energy for electric traction system, development of the effective methods for improvement of the conditions of regeneration in it and in estimation of its power indicators in general.

THE USE OF THE EPIC DATA BANK IN ENERGY ACCOUNTING STUDIES

1981 ◽  
pp. 258-261
Author(s):  
B. Kalitventzeff ◽  
C. Renson ◽  
G. Heyen ◽  
R. Gosset
Keyword(s):  
Data Bank ◽  
Energy Accounting

scholarly journals SOLAR RADIATION ENERGY PULSATIONS IN A PLANT LEAF

2010 ◽  
Vol 18 (3) ◽  
pp. 188-195 ◽  
Author(s):  
Algimantas Sirvydas ◽  
Vidmantas Kučinskas ◽  
Paulius Kerpauskas ◽  
Jūratė Nadzeikienė ◽  
Albinas Kusta
Keyword(s):  
Solar Radiation ◽  
Radiant Energy ◽  
Radiation Energy ◽  
The Sun ◽  
Plant Leaves ◽  
Plant Leaf ◽  
Balance Of Plant ◽  
Plant Uses ◽  
Energy Accounting ◽  
Temperature Pulsations

Solar radiation energy is used by vegetation, which predetermines the existence of biosphere. The plant uses 1–2% of the absorbed radiant energy for photosynthesis. All the remaining share of the absorbed energy, accounting for 99–98%, converts into thermal energy in the plant leaf. At the lowest wind under natural surrounding air conditions, plant leaves change their position with respect to the Sun. An oscillating plant leaf receives a variable amount of solar radiation energy, which causes changes in the balance of plant leaf energies and a changing emission of heat in the leaf. The analysis of solar radiation energy pulsations in the plant leaf shows that when the leaf is in the edge positions of angles 10°, 20° and 30° with respect to the Sun, 1.5%; 6% and 13% less of radiation energy reach the leaf, respectively. During periodic motion, when the amplitude of leaf oscillation is no bigger than 10°, the plant surface receives up to 1.6% less of solar radiation energy within a certain period of time, and when the amplitude of oscillation reaches 30° up to 14% less of solar radiation energy reach the leaf surface. The total amount of radiant energy received during pulsations of solar radiation energy is not dependent on the frequency of oscillation in the same interval of time. Temperature pulsations occur in the leaf due to solar radiation energy pulsations when the plant leaf naturally changes its position with respect to the Sun. Santrauka Saules spinduliuotes energija būtina augalijai, kuri lemia biosferos egzistavima. Augalas 1–2 % absorbuotos spinduliuotes energijos sunaudoja fotosintezei, o 99–98 % absorbuotos energijos augalo lape virsta šilumine energija. Natūraliomis aplinkos salygomis esant mažiausiam vejui augalo lapu padetis Saules atžvilgiu keičiasi. Taigi augalo svyruojančio lapo gaunamas Saules spinduliuotes energijos kiekis yra kintamas, tai sukelia pokyčius augalo lapo energiju balanse ir kintama šilumos išsiskyrima lape. Analizuojant Saules spinduliuotes energijos pulsacijas augalo lape, nustatyta, kad, lapui esant kraštinese 10°, 20° ir 30° kampu padetyse Saules atžvilgiu, i ji atitinkamai patenka 1,5 %; 6 % ir 13 % mažiau spinduliuotes energijos. Augalo lapui periodiškai svyruojant, kai svyravimo amplitude yra iki 10°, per tam tikra laika i lapo paviršiu patenka iki 1,6 % mažiau Saules spinduliuotes energijos, o kai svyravimo amplitu‐de siekia iki 30°, – iki 14 % mažiau. Saules spinduliuotes energijos pulsaciju metu gautas bendras spinduliuotes energijos kiekis nepriklauso nuo to paties laiko intervalo svyravimo dažnio. Del Saules spinduliuotes energijos pulsaciju, natūraliai keičiantis augalo lapo padečiai Saules atžvilgiu, lape kyla temperatūros pulsacijos. Резюме Растения потребляют солнечную лучевую энергию, которая является основой существования биосферы. 1–2% абсорбированной лучевой энергии они используют на фотосинтез. В натуральных условиях при малейшем дуновении ветра листья растений меняют свое положение относительно Солнца. Колеблющийся лист получает переменное количество лучевой энергии, которое вызывает изменения в энергетическом балансе листа растения, что сказывается на переменном выделении тепла в листе. Анализируя пульсации солнечной лучевой энергии в листе растения, установлено, что при крайних положениях листа относительно Солнца на 10, 20 и 30 градусов на лист попадает соответственно на 1,5%, 6% и 13% меньше лучевой энергии. При периодическом колебании листа, когда амплитуда его колебания составляет 10 градусов, за известный промежуток времени солнечная лучевая энергия, попадающая на поверхность листа, уменьшается до 1,6%, а при амплитуде колебания до 30 градусов соответственно количество лучевой энергии на поверхности листа растения уменьшается до 14%. Установлено, что суммарное количество солнечной лучевой энергии во время пульсации не зависит от частоты колебания листа за одинаковый промежуток времени. Пульсации солнечной лучевой энергии при изменении положения листа растения относительно Солнца вызывают температурные пульсации в листе.

Energy Accounting for Eleven Vegetable Oil Fuels

1982 ◽  
Vol 25 (5) ◽  
pp. 1209-1215 ◽  
Author(s):  
C. E. Goering ◽  
M. J. Daugherty
Keyword(s):  
Vegetable Oil ◽  
Energy Accounting

Comment: Energy Accounting: The Case of Farm Machinery in Maryland

1981 ◽  
Vol 13 (1) ◽  
pp. 155-157
Author(s):  
Garnett L. Bradford
Keyword(s):  
Heating System ◽  
Relative Energy ◽  
Government Policies ◽  
Liquid Fuels ◽  
Energy Accounting ◽  
Energy Ratios ◽  
Oil Embargo ◽  
State Of Affairs ◽  
Industrial Heating ◽  
Orderly State

Prior to the 1970s, energy accounting was the primary domain of physical scientists or engineers. The world of thermodynamics, rigorous concepts of energy ratios and entropy, seemed safe within their laboratories where, for example, the relative energy efficiency of solid and liquid fuels was assessed for powering an industrial heating system. This apparent orderly state of affairs—measurement primarily in controlled laboratory conditions—seemed to change abruptly in 1973 with the OPEC oil embargo. Energy accounting became the chore, if not the mission, of a myriad of scientists, engineers, businessmen, bureaucrats, and politicians. Understandably, the journals and other periodicals of our profession now abound with proposals on how to measure energy and how to employ these measures in making decisions and developing government policies.

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