Level(redirected from leveling out)
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(gorizont, horizon), in mining, the totality of mining developments located at one level and designed for carrying on mining work. By their purpose in the mine the following levels are distinguished: the hauling level (for transporting loads and moving people), the airway level (for ventilating the mine), the discharge level (for discharging broken-up ore), the cutting level (for opening up a rock mass from below in order to cave it in or break it up), and the scraper level (for scraper delivery of broken-up minerals to the loading point). For open-pit extraction of minerals the primary mining equipment for working one bench is installed on a level (the so-called work level of the quarry).
a geodetic instrument used for measurement of the elevation of points on the earth’s surface (leveling) and for establishing horizontality during erection and installation operations. The most common levels are opticomechanical levels, which have a sighting tube that is used for readings from a rod. Before taking the reading, the sight line of the sighting tube is set on the horizontal by means of the spirit level; in levels with self-leveling sight lines, this is done automatically.
Leveling instruments with spirit levels are mainly required to provide a near-parallel relative position of the sight line and the axis of the spirit level that must remain sufficiently stable over time and upon changes in temperature. Such a relationship is achieved through adjustment of the instrument, which must be done frequently. Many types of leveling instruments have been built, primarily to simplify adjustment; they differ in the type of interconnection of their three basic parts (the sighting tube, the spirit level, and the stand). For example, the spirit level may be mounted on the tube, which is laid across the stand, or it may be mounted on the stand. However, dumpy levels, in which both the spirit level and the tube are rigidly connected to the stand, have proved most stable and become most common. Dumpy levels are often made with lifting screws, or elevation screws, to
make it easier to set the spirit-level bubble at the zero point and to increase the precision of the instrument (see Figure 1). In this type of arrangement, all the parts that connect the sighting tube to the horizontal axis form the stand. A distinction is made among high-precision, precision, and engineering levels, which produce errors not greater than 0.5–1.0 mm, 5–8 mm, and 15 mm, respectively, per kilometer of level line.
Hydrostatic levels, based on the principle of communicating vessels, are sometimes used. There have been many attempts to make automatic levels, which determine elevation by integrating the angles of dip along a route traveled across the terrain by bicycle, motor vehicle, or other vehicle; however, as of 1974 the results have not been acceptable.
REFERENCESGOST 10528–69, Niveliry.
Gusev, N. A. Marksheidersko-geodezicheskie instrumenty ipribory, 2nd ed. Moscow, 1968.
Deimlikh, F. Geodezicheskoe instrumentovedenie. Moscow, 1970.
G. G. GORDON
in linguistics, any one of the basic planes of a language system—phonemes, morphemes, words (lexemes), and phrases (tagmemes)—considered as objects of linguistic analysis and constituting the province of phonology, morphology, lexicology, and syntax. Levels of language are determined by the characteristics of units isolated in the continuous articulation of running speech. Some scholars seek to increase the number of levels by raising to the status of a separate level any of the complex units capable of isolation; others consider only two levels to be significant—the differential and the semantic.
On the differential level, language appears only as a system of contrasting signs that include, besides the natural sounds of speech, the written signs that distinguish units on the semantic level. On the semantic level, morphemes, words, and combinations of words are distinguished as two-sided units, that is, with regard to their acoustic aspect, or expression, and to their internal, semantic, aspect, or content.
REFERENCESUrovni iazyka i ikh vzaimodeistvie: Tezisy nauchnoi konferentsii (Apr. 4–7, 1967). Moscow, 1967.
Martinet, A. “Arbitraire linguistique et double articulation.” Cahiers Ferdinand de Saussure, 1957, no. 15.
Benveniste, E. “Les Niveaux de l’analyse linguistique.” In Proceedings of the Ninth International Congress of Linguists. The Hague, 1964.
Buyssens, E. “La Sextuple Articulation du langage.” Ibid.
O. S. AKHMANOVA
an instrument for checking the horizontal position of planes and for measuring small angles. A level consists of a bar with a vial located inside; the vial is filled with alcohol or ether, except for a small gas bubble. If the lower plane of the level is positioned horizontally, the bubble will rest in the center of the vial. Levels with two vials can be used simultaneously to check the horizontal position of two planes that are mutually perpendicular. Some levels have the shape of a cylinder, the top of which is hermetically sealed by glass. The inside of the glass is spherically ground, and the box is filled with a fluid with a gas bubble. If the base of the box is positioned on a true horizontal, the bubble will rest in the center of the glass cover.
Levels used in machine building include mechanic’s levels and frame levels. In the former, the leveling vial is equipped with a scale and mounted within the housing. The level also has a fixture that adjusts the location of the vial with respect to the base of the housing. The position of the end of the bubble on the scale defines the inclination angle of the plane on which the level is placed. A prismatic recess in the base makes it possible to mount the level on cylindrical surfaces. A frame level consists of a four-sided frame with precise right angles; the leveling vial and the adjusting fixture are located in the lower part of the frame. Frame levels can be used on horizontal or vertical surfaces.
Levels with one or two leveling vials are used in construction work to check the correct location of parts of the buildings and structures being erected.
Levels are an important tool in astronomy, geodesy, and physics. They are used in leveling, in determining the inclination angles of horizontal axes, and in measuring the change of the angle between the vertical axis and a sighting line. Levels used in astronomy have a scale for angle measurements marked on the vial; the scale divisions are usually in units between 1 minute and 1 second.
REFERENCESGorodetskii, Iu. G. Konstruktsii, raschet i ekspluatatsiia izmeritel’nykh instrumentov ipriborov. Moscow, 1971.
Blazhko, S. N. Kursprakticheskoi astronomii, 3rd ed. Moscow, 1951.
ii. To bring an aircraft into a horizontal line of flight, such as in to level off or level out.