CS271429B1 - Sampler from underground waters - Google Patents

Abstract

Device for subterranean water sampling is intended for the monitoring of substance migration into these subterranean waters and consists of a lysimeter (1) and a collecting container (3). The collecting container (3) is adjusted in a ditch (6) made in a manipulation space (7). The collecting container (3) is connected via a hose (2) with the lysimeter (1), adjusted under a non-corrupted soil profile in the side space (5) superposed to the ditch (6). In the ditch (6) an outlet hose is placed in the direction to the surface from the collecting container (3). The device for subterranean water sampling is intended and will be in preference used in agriculture, mainly in areas, where fast and frequent subterranean water sampling is necessary<IMAGE>

Description

(57) The groundwater sampling device is designed to monitor the migration of substances into these groundwater and consists of a lysimeter (1) and a collection vessel (3). The collecting vessel (3) is provided in a pit (6) formed in the handling space (7). The collecting vessel (3) is connected by a tube (2) to 8 with a lysimeter (1), arranged underneath the intact soil profile in the side space (5), perpendicular to the pit (6). A drain tube (4) is located in the pit (6) towards the surface of the collecting container (3). Groundwater sampling equipment is designed and will be mainly used in agriculture, especially where groundwater sampling is often needed.

The invention relates to a device for taking a sample from groundwater.

The migration of substances to groundwater is still monitored by lysimeters fixed in the fall # These lysimeters are intricately removed at least once from the ground and samples from you. evaluated # these lysimeters are built in the fall so that the fall cannot be cultivated in a large-scale production # In laboratories are often used Miteoherlich vessels, into which it is taken.

the sample falls and is subjected to experimental observations. This investigation disrupts soil structure and does not respect the objectivity of the soil conditions of the habitat, such as climatic and soil factors.

The above-mentioned drawbacks are eliminated by a groundwater sampling device for monitoring the migration of substances into these groundwater, consisting of a lysimeter and a collecting vessel treated in a fall, according to the invention, the principle being that the collecting vessel is arranged in a pit formed in and a collecting vessel is connected by a tubing to a lysimeter provided beneath the intact soil profile in a lateral space perpendicular to the pit, and a collecting tubing is provided from the collecting vessel towards the surface. ~

The advantage of the device according to the invention is that the sampling can be carried out while cultivating and utilizing agricultural land. The amount of flooded nutrients and other substances such as fertilizers and chemical preservatives can be objectively evaluated and determined by the device according to the invention and subsequent chemical analysis. Since sampling can easily be carried out at any time, depending on precipitation and growing season, it is possible to determine the optimum fertilizer rates according to the measured values and chemical analysis so that on the one hand there is no leakage, ie losses, into the groundwater. protect water purity. On the other hand, it is possible to determine the optimal usable fertilizer rate for the individual plants in the crop rotation. Thus, the use of the device according to the invention does not compromise the soil profile and also maintains the objectivity of the natural and soil conditions of the habitat #

BRIEF DESCRIPTION OF THE DRAWINGS The invention and its effects are explained in greater detail in the description of the accompanying drawings, in which: FIG. 1 schematically shows one possible placement of a lysimeter in a groundwater sampler according to the invention # FIG. a variant of the storage of the lysimeter in the groundwater sampling device according to the invention # Fig. 3 then schematically shows the layout of the lysimeters throughout the agricultural land using the groundwater sampling device according to the invention, including indicating the dimensions between the lysimeters #

The groundwater sampling device according to the invention has been constructed such that it is below the topsoil on agricultural land at the boundary between the topsoil and subsoil layer, i.e. below.

soil cultivation and exploitation in the hole 6 of the collecting vessel 3, connected to the lysimeters £, moderating _w Nym in side space # £ £ lysimeters and the collecting vessel 3 are supported so as to avoid damage к plow bodies during cultivation of falls with regard to Root systems of cultivated crops # Lyzimeter 1 It is therefore connected by a hose 2 to a collecting container 3,

Woman in pit 6 _F at cultivation and exploitation soil, especially Interlinear space 7 # collecting vessel 3 is provided with a discharge tube 4, whose other end is positioned above the soil surface and secured plug £ · When verifying device according to the invention, in practice it has been found it is advantageous to arrange the pits 6 into the handling space 7, in particular the inter-row space, as indicated in Fig. 3 # The side spaces 5 and the lysimeters 1 can be supported perpendicularly to the pit 6 or according to Fig. 2. again in the side space 5, perpendicular to the pit 6 # The lysimeter 1 and the drain hose 4 must ** be made of plastic, as otherwise the soil would create an electric cell and the nutrients would not float and fall or be contaminated with heavy metals #

The groundwater sampling device according to the invention thus formed works by passing water through the surface and capturing the intact soil profile to a lysimeter 1 located downstream of the topsoil on agricultural land # This water enriched with unused nutrients and other substances from the soil Lysimeter 1 flows through tubing 2 into

CS 271429 B1 of the collecting vessel 3, located in the pit 6, perpendicular to the lateral space jj, in which the lysimeter 1 is stored and located below the level of the lysimeter L · From the collecting vessel 3 the collected water is then pumped to the surface and submitted to subsequent chemical analysis.

Example

The equipment, including the lysimeters, was used before setting the sanitary protection zone in order to create a proposal for management in the sanitary protection zone of the water resources for JZD Nové Lány Světlá nad Sázavou. Three years before the sanitary protection zone was defined with regard to rotation of the crop rotation and the need to change the way of management in terms of protection of water and water purity, representative plots were selected directly in the farm operations.

Based on the selection of representative plots after crop harvesting, the test plot according to Fig. 3 was laid out on each of them and the lysimeters of the groundwater sampling method according to the invention and according to Fig. 1 or Fig. 2 were installed thereon. for agricultural machinery. Agrotechnics in the experimental area did not differ from agrotechnics in the remaining part of the plot.

During the ee monitoring, various doses of nitrogen, phosphorus and potassium were tested for fertilizers and protective chemicals. The determination of total and partial doses, form of fertilizers, application dates was based on a comprehensive methodology of plant nutrition, according to ecological production level. A possible dose range was gradually identified in order to find the optimum with regard to yield and protection of water resources.

Based on long-term observation on permanent grassland and now also on arable land with continuous cultivation and crop cultivation, it was verified that on the basis of mathematical evaluation of results achieved in all experimental plots, mutual comparison of individual fertilization variants, yields of monitored crops and other undesirable substances into groundwater with respect to terrain and climatic factors, it is possible to set a limit dose of nutrients, respectively fertilizers, and protective chemicals to individual crops, and in no case will the water be contaminated or exceed the limit given by the ČSN for drinking water. At the same time, nutrients and other substances are maximally used by plants, and there are no unnecessary losses. The concentration of undesirable substances in the plant, such as nitrates, does not exceed a specified limit. There will also be a significant reduction in economic contributions to agricultural production and water treatment.

The experiment was based on a total area of 1 512 m and according to Fig. 3 was divided into three experimental plots, each of which occupied an area of 504 m ² , ie 18 x 28 m.

p Each plot was divided into 24 experimental plots. Each plot occupied an area of 18 m with dimensions of 3 x 6 m, with regard to the seeding of seeding machines and unlimited use of machinery.

Under each plot was built a terrain lysimeter according to Fig. 1 with an area of 0

0,105 m with collection container. Soil probes were dug at the front of the plots. Retaining lysimeters were built into their side walls so that the topsoil profile and topsoil layer were not damaged. Thus, the natural soil conditions of the nutrient and other substances leaching were preserved. Water with flooded substances was pumped off as required and passed on for subsequent chemical analyzes. The drainage tubes 4, through which the pumped water from the collecting vessels 3 to the surface of the soil, topsoil were routed, were properly clogged and marked on two sides, and in the center of the test area were grassy handling belts 2. The bands 7 result in PVC discharge pipes 4 led from the bottom of the collecting containers 3. This eliminates the possibility of their being torn out or damaged by agricultural technology. Grassy handling belts 7 have their merit especially when entering the stand and accessibility for water sampling,

Claims (1)

soil, plants for subsequent analysis. Since the handling belts 7 are only. on two opposite peripheral. 3 and in the middle of the test area, the experiment is freely passable and mechanically accessible. From the operational point of view, there are no changes and the operating conditions are fully maintained. Based on our observations, we conclude that the monitored parcels are pulled in the same way as the surrounding soil during crossings through heavy mechanization, during plowing, harvesting, cultivation and there will be no damage to the whole facility. The method fully fulfills its purpose in continuous operation without limitation. Depending on the rainfall, it is possible at any time to take a sample of the flooded water with the captured substances to ensure the exact application date, the quantity of fertilizer and crop protection product delivered. This method can be implemented anywhere on soils of all production types, not only in the sanitary protection zone, but in any agricultural cooperative or farm for the purpose of optimum nutrition and plant protection while constantly reducing negative environmental impacts. Monitoring of leaching of plant nutrients from soil. Leaching of plant nutrients from the soil up to 0.5 m below the surface in permanent grasslands was monitored using lysimeters and the above mentioned method. The lysimeters allowed the determination of the maximum possible or potential losses below the intact soil profile. This research has been conducted in 6 trials of the basic series since 1975. In summary, nitrate leaching under permanent grassland or meadow grassland, even at extremely high nitrogen doses of up to 400 kg / ha *, is one order of magnitude less than that of arable land fertilization with less than half the rates. The seasonal dynamics of nitrate leaching show two peaks. The first, more pronounced and always higher, occurs in the period of vegetative rest until early spring, the second, less pronounced and quite dependent on precipitation conditions, in June, after the application of a partial dose of nitrogen after the first mowing. The groundwater sampling device according to the invention is intended and will be predominantly used in agriculture, especially wherever there is a need for frequent and rapid sampling of groundwater. The invention Groundwater sampling device for monitoring the migration of substances to these groundwater, consisting of a lysimeter and a collecting vessel treated in the soil, characterized in that the collecting vessel (3) is arranged in a pit (6) formed in the handling space ( 7), and the collecting vessel (3) is connected by a hose (2) in a lysimeter (1) provided below the intact soil profile in the side space (5), perpendicular to the pit (6), and provided with a collecting vessel (3) tubing (4) towards the surface.