RU2384048C1 - Method for testing of grass cover in floodplain of small river - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the field of landscape science. In method they measure lengths of tributaries and areas of river tributaries catchments and tributaries drop by difference of heights between their heads and mouths, distribution of tributaries into distinctive groups by availability of vegetable cover on territories of river catchment and its tributaries basins. Effect from distinctive orographical features of relief and landscape arranged on the territory of tributaries catchment is estimated. Section of floodplain meadow with grass cover is marked visually on map or in nature on measured area and length of small river or its tributary catchment. Then in this section in specific areas they mark at least three hydraulic sections in transverse direction within the limits of water-protection zone. Along each hydraulic section they mark at least three sample sites on each side of small river or its tributary, after marking they measure distances from accepted point of origin on one side of small river or its tributary to centres of sample sites. They measure height of each sample site centre arrangement from the surface of small river or its tributary, and after grass sample has been taken, it is exposed to tests, results of which detect laws of distance effect along each section, heights of sample sites arrangement over water's edge for biophysical and biochemical indices of grass samples, and also they assess effect of distinctive orographical features of coastal relief and natural and anthropogenic objects located within and beyond the territory of water-protection zone.

EFFECT: method makes it possible to improve accuracy of measurements and to increase chances of relief parametres effect and anthropogenic influence detection at crop capacity of meadow grass and soil productivity.

8 cl, 11 dwg

Description

The invention relates to landscapes of small rivers with natural vegetation and can be used for biotechnological and biochemical assessment of grass cover in floodplain meadows and forest meadows, in particular, within the water protection zone and water protection zone of a small plain river and its tributaries. The technical solution can also be applied when taking into account the influence on the productivity and other properties of grass of the orographic parameters of the riverine relief. At the same time, the effects of anthropogenic factors can be taken into account, for example, hydraulic structures, communication facilities and product pipelines located inside the water protection zone and water protection strip, as well as settlements and agricultural land located outside the water protection zone of the small river.

There is a method of distributing vegetation and testing grass cover on a floodplain according to Academician V. R. Williams [Mosolov V. P. Perennial grasses and agrotechnical basis of crop rotation / V.P. Mosolov. - Works. - Volume III. - M .: Gosselkhozizdat, 1953. - 536 p., P. 68], which includes the correct combination of woody vegetation with perennial herbaceous plants to combat soil erosion. Forest plays an exceptional role in the fight against soil erosion. On afforested slopes, soil erosion is observed to a minimum.

According to the academician V.R. Williams himself [Williams V.R. Collected works. Volume Four: Meadow Cultivation (1901-1933) / V.R. Williams. - M .: State. publishing house of agricultural enterprises. Liters, 1949. - 502 p., p. 91] on natural watersheds, woody vegetation with deep roots will prevail. The middle part of the relief - the elements of the slopes, occupying both the location and the properties of the middle position between the watersheds and the valley, provide the best conditions for the development of steppe vegetation. And the lower parts of the slopes and valleys provide the best conditions for the growth and development of meadow grass. Here it reaches such a degree of development that it completely suppresses the natural regeneration of woody plants of forest plant communities. Due to the predominance of plants of mycotrophic type of nutrition in floodplain meadows, even plants of the steppe herbaceous formation do not find conditions for their growth here.

Thus, on the slopes of the floodplains of small rivers, plants of three formations grow - forest, steppe and meadow. In this case, the soil cover is a function of the vegetation cover, and the ruggedness of the relief affects the variability of the soil and vegetation cover.

According to V.R. Williams [Williams V.R. Collected works. Volume Four: Meadow Cultivation (1901-1933) / V.R. Williams. - M .: State. publishing house of agricultural enterprises. Liters, 1949. - 502 p., pp. 93-94], as soon as the soil as a result of the natural process of evolution of its vegetation cover loses the canopy of perennial herbaceous vegetation of the meadow formation, it immediately acquires two essential features: it becomes structureless and saline . These are two essential features of the desert, and their meaning, from national economic importance, is not in doubt.

The meaning of crop production in agriculture is very simplified by man in comparison with the natural cycle of vegetation and soil. As V.R. Williams points out [ibid., P. 94]: “The middle area of the slopes of the relief, on which, during the normal course of evolution of the meadow-forest era, members of the steppe plant formation only show a tendency to prevail, since the latter is allowed by the presence of conditions that determine the possibility their existence, during culture, it is opened up and forcibly colonized exclusively by plants belonging to the steppe plant formation, which are all our annual cultivated plants. ”

He further notes that under the canopy of cultivated plants, the plowed soils not only cannot accumulate new reserves of organic matter, but inevitably the former reserves are destroyed. This can not be prevented by the introduction of manure or other organic fertilizers, since the newly introduced organic matter is destroyed within no more than two years.

Soil loses its structural properties and nutrient reserves. The population is forced to plow other parts of the territory of the slopes, and in the direction of the rich soils of the lower elements of the slopes and river valleys.

The structure of phytocenoses and the distribution of vegetation across the river and its floodplains were considered by V. R. Williams in detail in the book [V. Williams. Selected Works / V.R. Williams; ed. V.P. Bushinsky. Volume III The scientific basis of meadow farming (1922-1933). - M .: Publishing House of the Academy of Sciences of the USSR, 1955. - 1008 p., P. 734-747, 898-905].

The disadvantage of this method is the low accuracy of assessing the quality of a floodplain meadow, that is, a plant formation along river banks. Moreover, rivers of different sizes have not only differences in hydrometric properties along the slopes, but also different pictures of the biotechnological and biochemical distribution of plant formations. As a result, by analogy, it is not possible to quantify grass cover on the most vulnerable coastal relief of the river valley.

There is also a method of measuring grass cover on the catchment area according to the length and fall of tributaries according to patent No. 2293290, MKI G01C 13/00, including measuring the length of tributaries and the catchment area of river tributaries, as well as the fall of tributaries as the height difference between their sources and estuaries, distribution of tributaries by distinguishing groups on the presence of vegetation in the territories of the river basin and its tributaries, an assessment of the influence of the distinctive orographic features of the relief and landscape located on the territory of the tributary watershed.

The disadvantage is the use of measurements only by visual estimation of the catchment area as a whole for each tributary by the presence of vegetation cover. Therefore, the influx of a small river is considered entirely by the catchment area, without separation according to separate transverse temporary hydrometric gauges. Such an assessment is suitable for large areas of the entire river network, but cannot be used to evaluate each specific floodplain meadow along even one tributary of a small river. Thus, the terrain parameters of an individual section of the river with a floodplain meadow located on the territory of the river’s water protection zone are inaccurately determined. Moreover, the presence of meadow vegetation is in no way associated with grass productivity at permanent or temporary test sites on the territory of the water protection strip and water protection zone of a small river, and this, in turn, does not allow us to determine the statistical patterns of changes in grass productivity and meadow soil productivity due to the influence of hydrological and relief parameters of the river sections.

EFFECT: increased accuracy of measurements based on the results of testing grass samples cut from test sites on the territory of a floodplain meadow, and increased functionality to identify patterns of influence of relief parameters and anthropogenic long-term effects on the productivity of meadow grass and soil productivity on the floodplain of a small river or its individual tributary.

This technical result is achieved by the fact that the method of testing grass cover in the floodplain of a small river, including measuring the length of the tributaries and the catchment area of the river tributaries, as well as the fall of the tributaries as the height difference between their sources and estuaries, the distribution of tributaries according to distinctive groups according to the presence of vegetation cover in the territories basins of the catchment area of the river and its tributaries, the assessment of the influence of the distinctive orographic features of the relief and landscape located on the catchment area of the tributaries is different in that The length and area of the catchment of a small river or its tributary visually identifies a section of a floodplain meadow with the test grass cover on the map or in situ, then at least three hydrometric sections in the transverse direction are marked in characteristic places along this small river or its tributary in the transverse direction within at least three test sites on each side of the small river or its tributary, mark the distances from the accepted beginning of coordinates on one side of a small river or its tributary to the centers of test plots, in addition, the height of the center of each test platform from the surface of a small river or its tributary is measured, and after cutting the grass sample, it is tested and the patterns of the influence of the distance along each section are revealed , the heights of the test sites above the water edge on the biophysical and biochemical parameters of grass samples, and also assess the impact of the distinctive orographic features of the coastal river lefa and located inside and outside of the waterproof strip of natural and man-made objects.

Visually, on a map or in-situ, a section of a floodplain meadow with a test grass cover before haying is distinguished.

Over the course of a small river or its tributary, bends and other forms of channel formation of a small river or its tributary are taken as natural characteristic places.

In the studied floodplain meadow, at least three hydrometric sections are marked in the transverse direction within the water protection strip with the distances between them along the course of the small river or its tributary no more than 100 times the width of the water mirror in the summer low water, and the test sites are located at intervals of at least 10 m from each other and from the edge of the water mirror of coastal test sites.

At least three test sites on each side of the small river or its tributary are marked along each gauge gauge, and the numbering of test sites is carried out from the left bank to the right when the observer is facing the stream of the small river or its tributary.

After marking, the distances from the accepted coordinate origin on one side of the small river or its tributary to the centers of the test sites are measured, while the coordinate origin at all hydrometric gauges from the left edge of the water mirror is set at approximately the same distance around the summer low water, for example, 40-50 or more meters with an accuracy of 0.1 m.

The height of the center of each test site from the surface of a small river or its tributary is measured using geodetic instruments with an accuracy of one centimeter, and measurements of this relief parameter in other seasons of the year are performed using constant reference marks.

The contours of each test site measuring 1.0 × 1.0 or 0.5 × 0.5 m at the place of sampling of grass plants are marked with pegs with a cord stretched between them on the sides of the test site, and for multiple sampling of grass when studying grass yields and hay on several slopes in the summer season, as well as for environmental monitoring of the impact of various natural, natural-anthropogenic and anthropogenic objects on the grass cover, turn the test site into a reference site in that long-term pegs driven into the soil provide Labels with account number and other credentials.

The essence of the invention lies in the fact that from the area of the catchment area of a small river along its separate tributary, they pass to the measurement object in the form of a small section along the tributary on which a separate floodplain meadow is located. In this case, not the entire width of the basin to the border of the watershed of this tributary is taken into account, but only the water protection strip and the water protection zone. Settlements and farmland, as a rule, are located outside the water protection zone. Therefore, they have an indirect effect on the floodplain meadow, and the hydraulic structures and bridges of transport routes and product pipelines have a direct effect. The floodplain meadow may be partly or wholly turned into grassland and / or pasture. As a result, it becomes possible to use an inductive approach in scientific research, compared with the deductive approach of the prototype.

The essence of the invention lies in the fact that the test site becomes one multifactorial observation, and many test sites distributed at least three hydrometric sections of a small river in the floodplain meadow area becomes a temporary test site. In the dynamics of the growing season and the hydrological year, it becomes possible to assess the influence of the hydrological regime of the river on grass productivity from a variety of points measured relative to the water mirror in the river.

The essence also lies in the fact that, in addition to measuring the total length and fall of the inflow, the distances between the hydrometric gauges, the distances between the test sites for each target, and also the height of the center of the test sites from the water surface approximately at the summer low water are additionally measured.

The essence also lies in the fact that the specific grass yield at each test site depends not only on the relief parameters relative to the water edge in the river, but also on the direct and indirect influence of anthropogenic factors.

The positive effect is that as the number of test sites on each floodplain increases along each tributary of a small river, it becomes possible to quantitatively describe the territory of the water protection zone along the entire river network in the form of a digital model. And many digital models based on the results of testing grass on a large set of temporary test sites will allow us to analyze the dynamics of the behavior of the grass cover of the river network in the space of the water protection zone and water protection zone.

Thus, the proposed technical solution has significant features, novelty and a positive effect. In the scientific, technical and patent literature, information materials discrediting the novelty of the invention have not been found.

Figure 1 shows a specific example of the location of the water protection zone (border along the external lines) and the water protection strip (border along the internal lines) of the small river Irovka, which flows into the Ilet river and then into the large Volga, near the village of Yandemirovo, Paranginsky municipal district of the Republic of Mari El; figure 2 shows a map and an arrangement of three hydrometric sections I, II and III in the water protection zone and water protection zone near the village; figure 3 - diagram of the gauge alignment I and the coordinates of the measurement height of the center of the test sites 1 ... 6 above the water edge at distances along the gauge alignment of a small river; figure 4 - the same in figure 3 along the alignment II of the test sites 7 ... 12; in Fig.5 - the same in Fig.3 along the alignment III of the test sites 13 ... 18; figure 6 shows a map of the first alignment within the boundaries of the water protection strip of the Irka River in the upper part of the dam; Fig.7 is a map diagram of the second alignment within the boundaries of the water protection strip near the bend of the river; on Fig - map of the third alignment within the boundaries of the water protection strip after the dam; figure 9 shows a top view of the location of the test sites 1 ... 6 along the first hydrometric gauge relative to the surface lines of the water at approximately summer low water; figure 10 is the same in figure 9, a top view of the location of the test sites 7 ... 12 along the second alignment; in Fig.11 - the same in Fig.9, a top view of the location of the test sites 13 ... 18 along the third river section.

A method for testing grass cover on a small river floodplain from test plots measuring 1.00 × 1.00 or 0.50 × 0.50 m located across the floodplain meadow of a small flat river includes such actions.

First, the grass cover is visually studied in the given floodplain meadow territory and places with hydrometric gauges and test sites relative to them across the small river are marked. At the same time, at least three sections and at least three test sites are marked on each side of the small river.

Before cutting off the aerial part of the grass as test samples, the contours of each test site measuring 1.0 × 1.0 or 0.5 × 0.5 m at the place of sampling of grass plants are noted.

The contours of a site measuring 1.0 × 1.0 or 0.5 × 0.5 m at the place of sampling of grass plants are marked with pegs with a cord stretched between them on the sides of the test site, and for multiple sampling of grass when studying the yield of grass and hay several slopes in the summer season, as well as for environmental monitoring of the impact of various natural, natural-anthropogenic and anthropogenic objects on the grass cover, turn the test site into a reference site so that the pegs hammered into the soil are long-term, and they are supplied etkami with an area number and other data.

After marking, measure the distance from the accepted coordinate origin on one side of the small river or its tributary to the centers of the test sites, in addition, measure the height of the center of each test site from the surface of the small river or its tributary, and after cutting the grass sample, it is tested and the test results are revealed regularities of the influence of the distance along each alignment, the height of the test sites above the water edge on the biophysical and biochemical parameters of grass samples, and also assess the impact of different Telnyh orographic features of the coastal topography and located inside and outside of the waterproof strip of natural and man-made objects.

Visually, on a map or in-situ, a section of a floodplain meadow with a test grass cover is identified before haymaking.

Over the course of a small river or its tributary, bends and other forms of channel formation of a small river or its tributary are taken as natural characteristic places.

In the studied floodplain meadow, at least three hydrometric sections are marked in the transverse direction within the water protection strip with the distances between them along the course of the small river or its tributary no more than 100 times the width of the water mirror in the summer low water, and the test sites are located at intervals of at least 10 m from each other and from the edge of the water mirror of coastal test sites.

At least three test sites on each side of the small river or its tributary are marked along each gauge gauge, and the numbering of test sites is carried out from the left bank to the right when the observer is facing the stream of the small river or its tributary.

After marking, the distances from the accepted coordinate origin on one side of the small river or its tributary to the centers of the test sites are measured, while the coordinate origin at all hydrometric gauges from the left edge of the water mirror is set at approximately the same distance around the summer low water, for example, 40-50 or more meters with an accuracy of 0.1 m.

The height of the center of each test site from the surface of a small river or its tributary is measured using geodetic instruments with an accuracy of one centimeter, and measurements of this relief parameter in other seasons of the year are performed using constant reference marks.

A method for testing grass cover on a small river floodplain from test sites measuring 1.00 × 1.00 m located across a small river within the boundaries of a water protection strip, taking into account the influence of hydraulic structures and a settlement, includes such actions.

First, grass cover in a floodplain meadow is studied visually or on a map and its location relative to a river and other natural, natural, man-made and anthropogenic objects is noted. Then in the meadow mark out the place of sampling grass. And for grass cover on the territory of the meadow, outlines along the river, located in characteristic places along the course of the river, are designated with trial plots.

After marking, measure the distance from the adopted coordinate origin on one side of the small river or its tributary to the centers of the test sites, in addition, measure the height of the center of each test site from the surface of the small river or its tributary.

Visually, on a map or in-situ, a section of a floodplain meadow with a test grass cover is identified before haymaking.

Over the course of a small river or its tributary, bends and other forms of channel formation of a small river or its tributary are taken as natural characteristic places.

In the studied floodplain meadow, at least three hydrometric sections are marked in the transverse direction within the water protection strip with the distances between them along the course of the small river or its tributary no more than 100 times the width of the water mirror in the summer low water, and the test sites are located at intervals of at least 10 m from each other and from the edge of the water mirror of coastal test sites.

At least three test sites on each side of the small river or its tributary are marked along each gauge gauge, and the numbering of test sites is carried out from the left bank to the right when the observer is facing the stream of the small river or its tributary.

After marking, the distances from the accepted coordinate origin on one side of the small river or its tributary to the centers of the test sites are measured, while the coordinate origin at all hydrometric gauges from the left edge of the water mirror is set at approximately the same distance around the summer low water, for example, 40-50 or more meters with an accuracy of 0.1 m.

The height of the center of each test site from the surface of a small river or its tributary is measured using geodetic instruments with an accuracy of one centimeter, and measurements of this relief parameter in other seasons of the year are performed using constant reference marks.

Before cutting off the aerial part of the grass, the contours of each test site measuring 1.00 × 1.00 m are marked at the place of sampling of grass plants, for example, with a cord stretched between them along the sides of the test site, oriented along the course of a small river.

Cut grass samples are subjected to weighing and other tests for subsequent biotechnological and / or biochemical evaluation of test sites. According to the totality of the measured properties of grass samples, patterns of their changes are revealed depending on the distance along each alignment and on the height of the center of the test sites from the water edge approximately in the summer low-water season.

The proposed method is simple in practical implementation and allows you to learn about the behavior of the totality of grass samples, and through this about the behavior of the grass cover of the floodplain meadow as a whole, many biotechnical and biochemical phenomena and processes. The properties of grass by samples can be indicators of an effective environmental assessment of any river landscape and coastal topography on which grass grows.

Claims (8)

1. A method of testing grass cover on a floodplain of a small river, including measuring the length of tributaries and the catchment area of river tributaries, as well as the fall of tributaries as the height difference between their sources and mouths, the distribution of tributaries by distinctive groups according to the presence of vegetation in the territories of the river catchment basins and its tributaries, an assessment of the influence of the distinctive orographic features of the relief and landscape located on the catchment area of the tributaries, characterized in that on the small river measured along the length and area of the catchment or its tributary, a plot of a floodplain meadow with the test grass cover is highlighted visually on a map or in-situ, then at least three hydrometric sections in the transverse direction within the water protection strip or water protection zone, along each waterway or water protection zone, are marked along characteristic small river or its tributary in this section along each at least three test sites on each side of a small river or its tributary are marked with a gauging gauge; after marking, the distances from the accepted coordinate origin are measured on one side of a small river or e of the inflow to the centers of the test sites, in addition, the height of the center of each test site from the surface of the small river or its tributary is measured, and after cutting the grass sample, it is tested and the results of the tests reveal patterns of influence of the distance along each section, the height of the test sites above the edge water on the biophysical and biochemical parameters of grass samples, and also assess the impact of distinctive orographic features of the coastal relief located inside and outside the territory waterproof strip of natural and man-made objects. 2. The method of testing grass cover on the floodplain of a small river according to claim 1, characterized in that a plot of a floodplain meadow with the test grass cover before haying is visually highlighted on a map or in situ. 3. The method of testing grass cover on the floodplain of a small river according to claim 1, characterized in that along the course of a small river or its tributary, bends and other forms of channel formation of a small river or its tributary are taken as natural characteristic places. 4. The method of testing grass cover on the floodplain of a small river according to claim 1, characterized in that at least three hydrometric gauges are marked in the transverse direction within the water protection strip with distances between them along the course of the small river or its tributary no more than 100 times wide water mirrors in the summer low water, and test sites are located at intervals of not less than 10 m from each other and from the edge of the water mirror of coastal test sites. 5. The method of testing grass cover on the floodplain of a small river according to claim 1, characterized in that at least three test sites are marked along each hydrometric gauge on each side of the small river or its tributary, and the numbering of test sites is carried out from the left bank to the right bank when located an observer facing the course of a small river or its tributary. 6. The method of testing grass cover on the floodplain of a small river according to claim 1, characterized in that after marking, the distances from the accepted coordinate origin on one side of the small river or its tributary to the centers of the test sites are measured, while the origin of coordinates on all gauging sections from the left the edges of the water mirror are set at approximately the same distance around the summer low water, for example, 40-50 meters or more with an accuracy of 0.1 m. 7. The method of testing grass cover on the floodplain of a small river according to claim 1, characterized in that the height of the center of each test site from the surface of a small river or its tributary is measured using geodetic instruments with an accuracy of one centimeter, moreover, the measurements of this relief parameter to other seasons of the year are carried out by constant reference marks. 8. The method of testing grass cover on the floodplain of a small river according to claim 1, characterized in that the contours of each test site measuring 1.0 × 1.0 or 0.5 × 0.5 m at the place of sampling of grass plants are marked with pegs between them with a cord on the sides of the test site, and for repeated sampling of grass when studying the yield of grass and hay on several mowings in the summer season, as well as for environmental monitoring of the impact of various natural, natural and man-made and man-made objects on the grass cover, turn the test loschadku in an area that hammered into the soil long-term stakes are tagged with an area number and other data.

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