CZ31389U1 - A device for field measurement of real loss of soil by wind erosion - Google Patents

Description

BACKGROUND OF THE INVENTION

Direct and indirect methods are used to determine the real soil loss due to wind. The technical solutions of direct methods include the construction of sediment traps (passive and active) and wind tunnels. There are two different types of wind tunnels - field mobile and stationary laboratory. Despite the possibility of standardization of the measurement process in the laboratory, the disadvantage of the laboratory tunnels is their size and demands on space and operation, and especially the work with soil in non-original storage (the need to prepare the measured area in the laboratory). Consequently, field wind tunnel constructions are better suited for describing the real impact of soil condition on soil soil removal by wind and hence for erosion hazard. These are divided according to the way of air supply to the working space into the pressure and suction tunnels (VAN PELT AND ZOBECK, 2013). Two types of devices (blowers) can be used to obtain an air flow (wind). It is either an axial fan or a centrifuge. Centrifuges produce a homogeneous flow of air with the character of laminar flow, but there is a problem with the technical design of the tunnel construction requiring more complex equipment and the resulting size of the equipment at the required power. The axial fan, on the other hand, is simple to install and can produce a relatively large amount of air. The air flow tends to rotate into a spiral shape and there is a disordered air movement that approaches the turbulent flow. Many technical solutions of wind tunnels with axial fan transform the turbulent air flow by means of baffles to the laminar flow. The reason is, according to the authors, uncertainty of measurement and incomparability of results (FISTER 2005, 2010; MANSHADI 2011). However, from the point of view of approximation to real conditions in the field, it is appropriate to maintain a certain degree of air flow instability, where the current is further transformed by the surface roughness of the soil and other soil parameters related to soil management and quality. These measurements give more realistic information about soil drift and provide important data on the impact of soil quality and soil management as factors that significantly affect soil resistance to wind erosion on actual soil loss by wind erosion.

The essence of the technical solution

The above mentioned shortcomings of laboratory and field devices are eliminated by a device for field measurement of real soil loss by wind erosion, according to the technical solution, which consists in that it consists of a fan, which is controlled by the control unit and on the inlet and outlet side air is provided with covering grilles. The fan is built into a movable structure, into which stabilizing supports are inserted, between which a spacer plate is inserted during measurement. The front of the ventilator consists of a circular flange on which a flexible duct is attached to direct the air flow to the measuring part of the device, or the circular flange is attached to a transition duct which is rigidly connected to the measuring part itself. . Its open portion is embedded at the ground measurement site to precisely delineate the area to be measured by the flow of air at a defined velocity, during measurement the top of the measuring portion is covered with plexiglass to form a viewing hole that is stabilized by clamping points, and the end part of the measuring part is provided with a flange, as well as the adjoining transition pipeline with the lower recessed edge and the soil particle collector. The two flanges are connected at the point of measurement, with flange slots for bolts in the flange at the pipeline transition, and flange on the measuring portion for point bolts where the transition pipe is connected to a flexible pipe that is connected by a pipe transition to a cyclone flange. separator and tightened with a clamping sleeve. The cyclone separator is provided with a transport axle and at the point of measurement the cyclone separator is erected in a vertical position and stabilized by supports, while a collecting vessel for fine soil particles blown by the wind is placed under the bottom outlet of the cyclone separator. The whole device is mobile.

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The device according to the invention operates in such a way that air is blown into the boundary measuring part defined on the area of the agricultural land by means of an electric axial fan, whose power and thus the air flow rate is controlled by means of a regulator. The fan is connected to a mobile power generator of the required output. The air stream blown into the system by the ventilator acts on soil particles on the soil surface that raises, shifts or causes them to hop. All these sediment components are collected and weighed at the end of the measurement for evaluation of real soil loss by wind erosion. The fan is fixed in an iron construction with protective elements and stabilizing supports limiting negative vibrations, preventing injury to the operator and allowing comfortable transport of this part of the device to the measuring point. This part of the device also enables the measurement of pressure differences before and after the fan. The measuring part, provided with Plexiglas from the top for monitoring the measurement progress, is connected to the fan by a flexible duct and is fixed by straps to the transition duct so that all the blown air acts on the soil surface and is not lost by blowing. The apparatus according to the invention is further characterized in that a further transition pipe is connected to the end of the measuring part. This is made of sheet metal and the sliding connection with the measuring part allows it to be embedded under the measured soil surface in order to prevent the formation of a mechanical barrier against which soil particles bouncing or moving on the surface by the action of blown air are hampered. The device according to the technical solution with this solution achieves versatility and flexibility when measuring in terrain conditions, where it is possible to measure on soil with smooth surface, but also on soils with management, where agricultural tools working tools disturb a greater depth of soil profile. The transition duct is shaped to allow the collection of coarser particles that are not withdrawn into the cyclone separator and form a weight part of the resulting amount of absorbed soil at its bottom. The transition pipe at its outlet further continues through a flexible pipe leading to the top of the cyclone separator to which it is connected by means of shrink sleeves. The fine particles entrained in the air stream are separated in the separator, when they lose their velocity in the tapered part of the separator by gravity and fall into the orifice under which the collecting vessel is placed. The size of the cyclone separator is designed to separate 16 µm particles. Due to the size requirements of the particles to be separated, the separator is equipped with two wheels for the transport to the measuring point. The cyclone separator is brought to the site in a horizontal position and then is built and stabilized by supports for safe operation during measurement. Easy mobility of the whole device according to the technical solution is its great advantage.

Clarification of drawings

1 shows a schematic plan view, FIG. 2 shows a schematic cross-section, and FIG. 3 shows a detail of a transition pipe and a legend to the device according to the invention.

The following examples illustrate, but do not limit, the apparatus according to the invention. This device has been successfully verified by the originator in practice in field measurements in the framework of research projects solved by the applicant, which is the Research Institute of Land Amelioration and Protection, v.v.i., Prague - Zbraslav. CZ.

Examples of technical solutions

Example 1

The device according to the technical solution consists of partial components which are transported to the place of measurement on a trailer towed by a passenger car. The device consists of an electric axial fan 1, which is provided with cover grilles 2 and 8 on the air inlet and outlet side. The fan 1 is built into a supporting structure of welded iron prisms. The base of the supporting structure allows insertion of about 1 m long stabilizing supports 4, which prevent unwanted vibrations during the operation of the fan 1. Between stabilizing supports 4 is placed a spacer plate 5 which fills the space behind the fan i and prevents soil sediment from during fan operation i. Fan I is

It is driven by the generator and its operation can be controlled by the control unit 6 so as to achieve the desired speed and corresponding speed of the air blown into the measuring part. The front side of the fan 1 is formed by a circular flange 7, to which a flexible pipe 8a is fixed by means of a strap, which directs the air flow to the measuring part of the device resp. to the transition conduit 9 which is rigidly connected to the measuring part 12a itself. It consists of a 600 x 300 x 2000 mm "U" sheet metal tunnel, where the open part of the tunnel is placed (embedded) in the field measurement site so as to precisely define the measured area, which will be affected by the air flow of defined speed . To control the measurement process and the soil removal rate during measurement, the top of the measuring portion 12a is covered with plexiglass and forms a viewing hole 12. This is stabilized by clamping points 11 that allow removal of the viewing hole 12 and surface treatment - if required the need to dismantle or transport the entire measuring portion 12a. The end portion of the measuring portion 12a is provided with a flange 14, as well as the adjoining transition conduit 16. The two flanges can be screwed together at the measuring point, and the flange 14 of the transition conduit 16 is not slotted, but slotted. This permits a height displacement of the transition conduit 16 into the soil beneath the surface to be measured so that the lower inlet edge 15 of the transition conduit 16, comprising at its bottom a collector of coarse sediments (particles of decanted sediment that jump or move along the surface due to air flow) ), has reached below the level of the deepest mechanical disturbance of the soil surface and has not hindered the movement of soil particles into the manifold 16. Thanks to this possibility, the impact of different soil management methods where the surface is damaged in different ways on the soil loss by wind erosion can be measured. To facilitate the embedding of the transition conduit 16 into the soil, this part is provided with a flushing edge 15. A flexible conduit 17 extracting air with fine sediment is attached to the transition conduit 16 to the cyclone separator 21. This is provided with a transport axle 22 which is used for horizontal transport of the cyclone. separator 21 to the measurement site. At the point of measurement, the cyclone separator 21 is erected in a vertical position and stabilized by supports 23. A collecting vessel 26 is placed under the lower outlet of the cyclone separator 26 into which fine soil particles 25 (sediment) are blown by wind. and fall through the opening into the collecting container 26 by gravity.

Example 2

The equipment according to example 1 was used in the research activities to measure soil erosion on various soils in the Czech Republic. In particular, the simulation of a wind speed of 9 m / s was carried out in the village of Šardice on a slightly light soil (most endangered), when after conversion from arable land 1.8 t of land / ha was extracted. The influence of soil granularity can be demonstrated on another example, where the soil was decanted at 0.6 t / ha in the same village on moderately heavy soil in the same conditions. The results of the measurements were used for the creation of a methodology for the placement and design of species composition of windbreaks in the erosion-threatened landscape with the aim of increasing local protection of arable land.

Industrial applicability

The present invention relates to a new mobile off-road device for measuring real soil loss by wind erosion, where air of a known velocity is blown onto a limited area of soil and the amount of sediment that is removed from the area is collected and determined. The use of the equipment is possible in the scientific fields of soil science, soil contamination (drift contamination from risk areas), erosion and in the formulation of methodological procedures for practical management of soil erosion endangered. The equipment can be manufactured industrially.

List of literature

Fister, W. (2005). Ein mobiler Windkanal zur experimentellen Erfassung von Winderosion. Diplomarbeit Universitaet Trier. 105 s.

Fister, W., Iserloh, T., Ries, J.B. & Schmidt. R.-G. (2010): A portable wind and rainfall simulator for in-situ soil erosion measurements.- CATENA 91, 7284.

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Manshadi, M. D. (2011). The Importance of Turbulence Reduction in the Assessment of Wind Tunnel Flow Quality, In: Lemer, J. C., Boldes, U. (eds.). Wind Tummels and Experimental Fluid Dynamics Research, In. Tech. ISBN 978-953307-623-2, doi: 10.5772 / 17069

Van Pelt, R. S., Zobeck, T. M. (2013). Portable wind tunnels for field testing of soils and natural surfaces, In: Ahmed, N. A. (ed.). Wind Tunnel Designs and Their Diverse Engineering Applications Tech, ISBN 978-95351-1047-7, doi: 10.5772-54141

Claims (2)

PROTECTION REQUIREMENTS An apparatus for field measurement of real soil loss by wind erosion, characterized in that it consists of a fan (1) which is controlled by a control unit (6) and is provided with cover grilles (2) and (8) on the air inlet and outlet side. ), wherein the fan (1) is built into a movable structure in which stabilizing supports (4) are inserted, between which a spacer plate (5) is inserted during measurement and the front side of the fan (1) is formed by a circular flange (7), to which the flexible conduit (8a) extends into the measuring portion of the device (12a) through a transition conduit (9) mounted to the flange of the inlet transition conduit (10), wherein the transition conduit (9) is rigidly connected to the measuring part (12a) itself; which consists of a U-shaped tunnel whose open part delimits the area to be measured, the top of the measuring part (12a) being covered during measurement. plexiglass to form a viewing aperture (12) that is stabilized by clamping points (11), and the end portion of the measuring portion (12a) is provided with a flange (14), as well as an adjoining transition conduit (16) with a lower recessed edge (15) and the soil particulate collector, and the two flanges are bolted together, wherein the flange (14) on the transition conduit (16) has slotted passages and the flange on the measuring portion (12a) has point passages where the transition conduit (16) is connected to a flexible conduit (17) which is connected by a conduit transition (19) to a flange (18) of the cyclone separator (21) and tightened by a clamping sleeve (20), and the cyclone separator (21) is provided with a transport axle (22) for erection of the cyclone separator (21) in a vertical position, where the cyclone separator (21) is stabilized by supports (23), and a collecting vessel (26) is placed under its bottom outlet and the whole device is mobile. Device according to claim 1, characterized in that the fan (1) is electric axial.