Energy Balance

(redirected from Drain spacing)
Also found in: Medical.

energy balance

[′en·ər·jē ‚bal·əns]
The arithmetic balancing of energy inputs versus outputs for an object, reactor, or other processing system; it is positive if energy is released, and negative if it is absorbed.
The relation of the amount of utilizable energy taken into the body to that which is employed for internal work, external work, and the growth and repair of tissues.

Energy Balance


in the USSR, an accounting of the extraction, processing, transporting, conversion, distribution, and consumption of energy and energy sources in the country from the point at which they are obtained to their use by the consumer.

The energy balance expresses a quantitative correspondence between the expenditure of energy and the energy made available (income of energy), including changes in the reserves of energy sources. The income side of the balance is made up of data on the extraction of energy sources; the expenditure side shows the production of the various types of energy and their distribution among consumers. Between 1940 and 1975, the extraction of energy sources in the USSR increased by a factor of 6.7, and the amount of electric energy generated increased by a factor of 21.5. In order to ensure scientific and technological progress, it is of the utmost importance that the country’s fuel and power complex be developed as efficiently, economically, and effectively as possible (see).

The principal method of analyzing the quantitative and qualitative state of the country’s energy facilities (energeticheskoe khoziaistvo) is to develop general energy balances that cover all processes from the useful consumption of all types of energy to the obtaining of the energy sources. Such balances are drawn up in choosing the optimal scheme for the energy supply of an enterprise, region, or the entire country and in determining the trends and proportions in the development of the energy facilities for the long term.

In determining economically justified proportions for the consumption of various forms of energy, special energy balances are used, such as a balance for the extraction, processing, and distribution of fuel, a balance for the consumption and production of heat, and balances for the consumption and generation of electric energy (seeFUEL BALANCE; HEAT BALANCE; and ).

Because of the fundamental importance of electric energy for the country’s economic development, the electric-energy balance is the most important part of the energy balance. Its expenditure side describes the overall demand for electric energy and the distribution of electric energy during a planning period among the various branches of the national economy; losses of electric energy during transport, distribution, and export are taken into account. The income side, which is worked out by determining the demand for electric energy, describes the structure of electric-energy production, as well as the necessary capacities of electric power plants.

The optimum energy balance is arrived at on the basis of overall economic efficiency; in other words, the optimum balance is that which entails the minimum calculated costs. Since the various forms of energy sources and energy are interchangeable, a common value for the standard, or normative, coefficient of the efficiency of capital investment is used when making calculations.

If a value of 100 percent is assigned to the potentially usable energy contained in the energy sources consumed, the energy-producing installations that run directly on fuel account for 52 percent, electric power plants for 36 percent, and boiler plants for 12 percent. Only about 40 percent of the potentially usable energy contained in the resources expended is converted into useful energy. The main losses occur in mobile energy-producing installations, in industrial furnaces, and in electric power plants. For medium- and low-temperature processes, the heat produced by electric power plants, boiler plants of various types, and individual fuel consuming installations is used. These energy-producing installations operate on coal, natural gas, and various petroleum products. For high-temperature processes the same kinds of fuel, as well as electric energy from electric power plants, are used. Stationary power plants generally use electric energy; mobile plants generally use petroleum products.

References in periodicals archive ?
75 m or more and drain spacing more than 50 m were implemented in other parts of Iran.
Comparison of drainage water depth of the subsurface drainage treatments for the rice growing season showed, for the same drain spacing, reduction in drainage water depth as a result of increase in drain spacing so that the drainage water depth of [D.
The approach flow head loss is affected by the physical properties of this disturbed soil which surrounds the drain, the drain spacing and the drainage materials used.
In permeable soils where drain spacing is wide, a system of open ditches can be used in lieu of pipes.
In the design of WTM systems used solely for drainage, both the depth of the drain and the drain spacing must be specified.
Agricultural profits for this alternative are reduced because shallow drains require closer drain spacing, which increases costs.
Annual corn yields and nitrogen losses were predicted for a 40-year period using the model DRAINMOD for a range of drain spacings and depths.
Trade studies can be performed with this notebook to observe the effect of FET cell size or the effects of the source and drain spacing on junction temperature with the ultimate goal of keeping the FET junction temperature as low as possible.
Combinations of strip drain spacing and drainage layer thickness were evaluated to provide an optimal design.
Even using a close drain spacing, it is unlikely that significant depressurisation of the bedrock would have been possible; recharge from the overlying alluvium would have occurred at a rate which was greater than the capacity of the drains
That is, the threshold drainage intensity is the most intensive drainage (narrowest drain spacing for a given surface depressional storage) that will still satisfy the hydrologic criteria in 50% of the years.
The design of the seepage drainage is a continuous operation regime, by establishing the pose depth, the length of the drain, the drain spacing and after that checking the drain in non-permanent function.