RU2745916C1 - Locust killer - Google Patents

Abstract

FIELD: agriculture; machine building.

SUBSTANCE: invention relates to agricultural machine building, in particular to machines, in which electricity is used for pest destruction. A locust killer comprises a plurality of tillers connected in parallel to the front end of the support member and a plurality of downwardly extending shanks-pins attached to the rear end of the support member. Each of said shanks-pins is aligned with one of said cultivators and has at least one electrically conductive outer surface, generator for generating electric current supplied to said shanks-pins, a transformer connected to said generator and said shank ends for conversion of electric current supplied to said shank ends. Each shank tail has a generally flat cross-section, a sharpened front edge and a sharpened lower edge. Each of shanks-pins has wedge-shaped cross-section, width of which increases from front to rear edge of each such shank. Width of every said shanks-pins is adjustable. Generator provides electricity in three phases A, B and C, provided with seven shanks-pins, electricity is supplied by phase diagram A-B-C-A-B-C-A. Each of shanks-pins usually has shape of inverted letter U, having two downwards legs. Inner part of each leg has electrically conducting surface. Rippers are arranged in the form of installed on a horizontal axis perpendicular to direction of machine motion and flat discs electrically isolated from it and from each other with electrically connected current collectors. Flat disks installed in alignment with direction of movement of one longitudinal vertical plane of symmetry of shanks-pins have 25–30 % larger diameter and 2–2.5 times larger thickness than flat discs of smaller diameter installed between them and at machine edges. Electricity is supplied to all flat disks by phase diagram A-B-C-A-B-C-A-C-A-B-C-A-B-C-A.

EFFECT: higher efficiency of locust killing with electric discharges.

1 cl, 9 dwg

Description

The invention relates to agricultural engineering, in particular to machines that use electricity to destroy plant pests.

US Patent No. 2,429,412 describes a system for applying electrical soil tillage to destroy harmful organic matter and to sterilize and process the soil. This patent describes a device that includes a generator and a transformer connected to a box-like structure containing electrically conductive plates that penetrate the soil as the structure is pulled through the field. However, this device does not have a separate or lead cultivator, so the horizontally positioned electric cookers located at the bottom of the box structure must themselves break the soil. The box structure containing the electrical conductors is small and allows very shallow tillage, and the top of the box structure must be in contact with the soil surface to provide proper conductivity that is difficult to maintain.

US patent No. 2,588,561 supplies electricity to the soil using a series of cultivation discs having conductive rings that alternate alternately. However, the discs do not provide deep soil tillage, as less than half of their diameter penetrates the soil, and the conductive rings do not provide wide or complete electrical coverage, especially since they only come into contact with the loosened soil. In addition, the conductive rings must be constantly replaced because they are part of the tillage structure and also because they tend to deteriorate after prolonged contact with the soil. It should be noted that due to the location of the locust larvae on the surface of the field, it is important to prevent them from being covered with soil, which will significantly reduce the effect of electrical discharges on them.

Of all the known technical solutions, the closest in terms of the combination of features and the achieved positive effect (prototype) is US patent 2003O15O156A1.

A method and apparatus for removing soil pests, comprising a plurality of rippers connected in parallel to the front end of the support element, a plurality of downwardly located shank-tips attached to the rear end of the element of said support, each of said shank-tips is aligned with one of said rippers and has, along at least one electrically conductive outer surface, a generator for generating an electric current supplied to said shank-sting, a transformer connected to said generator and said shank-sting for converting an electric current supplied to said shank-sting, and each of said shanks is sting has a generally flat cross-section, a sharpened front edge and a sharpened bottom edge, while each of the mentioned shanks-sting has a wedge-shaped cross section, the width of which increases from the leading edge to the trailing edge of each such shank, and the width of each of said shanks is The tips are adjustable, with said generator providing electricity in three phases A, B and C, and providing seven tip shanks, as well as supplying electricity in an ABCABCA phase scheme, with each of said tip shanks usually having the shape of an inverted U having two downwardly extending legs, wherein the interior of each of said legs has an electrically conductive surface.

The disadvantages of the known device are its low efficiency in the destruction of locusts, since the rippers located in front mix the eggs of the locust with the soil, preventing the effective effect of electric charges on them in the future.

The problem that the invention solves is to increase the efficiency of the destruction of locusts by electric discharges.

The problem is solved using a locust killing machine, which includes a plurality of rippers connected in parallel to the front end of the support element, a plurality of downward-pointing shanks attached to the rear end of the element of said support, each of said shank-stings aligned with one of said rippers, and has at least one electrically conductive outer surface, a generator for generating an electric current supplied to said shank-sting, a transformer connected to said generator and said shank-sting for converting electric current supplied to said shank-sting, and each of of said sting-shanks has a generally flat cross-section, a sharpened front edge and a sharpened lower edge, while each of said sting-shanks has a wedge-shaped cross-section, the width of which increases from the leading to trailing edge of each such shank, and the width of each of of said tip shank is adjustable, with said generator providing electricity in three phases A, B and C, and providing seven shank shanks, and also energizing in an ABCABCA phase scheme, with each of said shank shanks usually having the shape of an inverted letter U, having two legs located downward, and at the same time the inner part of each of said legs has an electrically conductive surface, where the rippers are made in the form of a horizontal axis installed with the possibility of rotation on a perpendicular to the direction of movement of the machine and electrically isolated from it and from each other flat discs with electrically with current collectors connected to them, while flat disks installed in the same direction of movement of one longitudinal vertical plane of symmetry of the shanks-stingers have a 25-30% larger diameter and 2-2.5 times greater thickness than those installed between them and along the edges of the machine flat discs of smaller diameter, and for all n flat disks are supplied with electricity according to the phase scheme A-B-C-A-B-C-A-C-A-B-C-A-B-C-A.

FIG. 1 is a perspective view of an embodiment of the present invention; in fig. 2 is an enlarged view taken along line 2-2 in FIG. one; in fig. 3 is an enlarged rear perspective view of one shank taken along line 3-3 in FIG. 1; Fig. 4 is an enlarged perspective side view of the bit shank of FIG. 3; in fig. 5 is a cross-section of the bit shank taken along line 5-5 in FIG. one; Fig. 6 is a schematic diagram of an embodiment of connecting the phases of electricity, having a series of seven shanks-sting; fig. 7 is a cross-sectional view of one bit shank taken along line 7-7 in FIG. four; in fig. 8 is a side view of the bit shank of FIG. 7; Fig. 9 shows a section along the axis of rotation mounted with the possibility of rotation on a horizontal axis perpendicular to the direction of movement of the machine and electrically isolated from it and from each other flat discs with electrically connected current collectors.

Referring to the drawings, in which like reference numbers refer to the same or corresponding structures in several views, and specifically referring to FIG. 1 and 2, it can be seen that the invention includes two rows of working bodies, adjustable with the possibility of attachment to the toolbar 19. On the axis 21 of the front row, the rippers are made in the form of a horizontal axis 21 installed with the possibility of rotation on a perpendicular to the direction of movement of the machine and electrically isolated from it and from each other using, for example, nylon bushings 42 and 43 of flat discs 44 and 45 with electrically connected current collectors 46, while flat discs 44 installed in the direction of movement of one longitudinal vertical plane of symmetry of the rear shanks-tips 32 have 25-30% larger diameter and 2-2.5 times greater thickness than flat discs of smaller diameter 45 installed at the same distance between them and along the edges of the machine, and on all flat discs through current collectors 46 and a conductive bushing 47, on which current collectors 46 and flat discs 44 or 45 are installed, electricity is supplied according to the ABCABCA phase scheme -C-A-B-C-A-B-C-A.

The back row shanks 32 are tip shanks designed to transmit electricity to the soil. Each of the shank-tips 32 is installed at a short distance directly behind the corresponding flat disc of a larger diameter 44. This arrangement of discs with a larger diameter 44 prolongs the life of the shank-tips 32, which go already along the slot formed by the discs of a larger diameter 44. Electric generator 28 and transformer 29 are designed to generate electricity for use with the tips-shanks 32 and discs 44 and 45. The generator 28 and transformer 29 can be installed together with the tips-tips and flat discs on a toolbox, on a trailer connected to the toolbox, on a tractor or on another vehicle pulling behind the instrument panel, or they can be installed separately on any of them. Appropriate insulated wiring is used to supply electrical power to the different outer conductive surfaces 39, 40 of the tips and collectors 46 of the discs 44 and 45 in different phases, as discussed in more detail below.

Referring to FIG. 3-5 and 7-8 it can be seen that each blade shank 32 is attached to the toolbox 19 using a center flange 33, preferably made of steel. The flange 33 is housed within two U-shaped insulated portions 34 and 35 (see FIG. 7). Conductive metal surfaces 39 and 40 are located outside of insulated portions 34 and 35. Surfaces 39 and 40 are attached to one of the outputs of generator 28 and transformer 29. As seen in FIG. 1 and 2, surfaces 39 and 40 come into direct contact with the soil to provide sterilizing electricity. The leading edge 37 of each bit shank 32 tapers to a point to facilitate easy movement through the ground behind the shank 32 of the ripper 21. Similarly, the bottom edge 38 of each bit shank 32 also tapers to a point. These sharpened edges typically act as a knife blade or plow as the shank blade 32 is driven through the soil.

Referring specifically to FIG. 7, it can be seen that the conductive sides 39, 40 of each bit shank 32 are mounted so that the total width of the bit shank 32 increases from the leading edge 37 to the trailing edge. Thus, each bit 32 forms a wedge that increases in size from front to back. This wedge-shaped design allows the soil to be compacted between the bit shanks 32, thus increasing soil density as the bit shank 32 is pulled through the soil. This compaction increases the conductivity of the electrical charge in the soil profile. The amount of increase in width can vary depending on things like 32 bit shank spacing, soil moisture and other conditions. Adjustment can be done with bolts 41.

A standard 3-phase generator 29 is used, although any suitable generator having different phases can be used with equal success. When using a 3-phase generator, at least 3 + 1 = 4 tip shanks 32 are required to deploy next to each other so that each phase can complete the electrical circuit through the ground (A-B-C-A). Current flows from the generator between each of the three phase pairs A-B, B-C, and C-A. Using the aforementioned 3 + 1 configuration, the generator can simultaneously provide current in all three phases, thereby continuously supplying electricity to the soil between each of the tips 32. Additional tips 32 can be added using a 3-phase generator in a 3 + pattern 3 + 1: ABCABCA (see diagram in FIG. 6 showing a 7 shank 15 disc system). It should be understood that the conductive panels 39, 40 on both sides of each tip shank 32 are charged in the same electrical phase and that only the soil between the charged tip shanks 32 will be electrified.

The lower part can have a more pronounced wedge shape compared to the upper blade shank 32, which can be adjusted according to soil conditions and similar to the use of bolts 41, which act as wedges.

Locust killing machine works as follows.

Soil cultivation using the machine of the present invention should be carried out prior to planting the crops and before the locust larvae develop wings. Electrical energy can potentially damage existing plants and root systems. Since the pest control is electricity, there are practically no harmful effects on the soil. There is a possibility that soil microbes will need to be replenished due to the destruction of natural organisms. Tillage using the machine of the present invention prefers the soil to be moist in order to better conduct electricity. Thus, it is preferable that the treatment is carried out within a sufficiently short time after rain or after irrigation. The more moisture in the soil, the more effective the treatment will be.

While any suitable dimensions may be used as another example and without limiting the scope of the appended claims, the flange 33 shown in FIG. 7 may be made of 1 "by 10" cold rolled steel enclosed in two C-pieces 34, 35 of ultra high molecular weight (UHMW) plastic or nylon for insulation purposes. The dimensions of the UHMW plastic that spans the 32 bit shank can be, for example, about 2 "thick and about 31.5" wide. The leading edge 37 of each bit shank 32 can be designed, for example, at an angle of about 45 degrees, although any suitable angle can be used. The leading edge can be made of cold rolled steel with a hard surface. The bottom edge 38 is also sloped. Silicone sealant can be applied on top of the seam between UHMW plastic 34, 35 and metal bit flange 33 to prevent moisture from reaching activated plates 39, 40 and to prevent shorting between bit shank 32 and toolbar 19. The lower part of the bit shank can be equipped with removable drains to prevent moisture accumulation.

These sting shanks 32, as well as discs 44 and 45, are connected to a generator and a transformer, and the generator has, for example, an output of 480 volts, which are passed through a multiplying transformer, for example, from 9.5 to 1, to obtain 4160 volts at maximum power. 200 amperes at 32 sting shanks. The transformer is connected to 7 individual sting shanks 32 by means of a high voltage wire. All electrical cables are enclosed in a PVC plastic pipe between the generator, transformer, junction box and tip shanks 32. In use, when the tractor 20 is operating and positioned in the field, the generator 28 is started, the flat discs 44, 45 and the tip shanks 32 are lowered into soil profile. Generator 29, flat discs 44, 45 and tip shanks 32 are activated from the operator's control panel in the cab. The generator is brought up to operating power and activated by a magnetic switch connected to the transformer. After reaching the working voltage, the tractor starts to move slowly across the field, approximately 2 to 3 km per hour, depending on the soil conditions. The flat discs 44, 45 and the bit shanks 32 penetrate the soil and receive electrical power. Electricity is emitted from each flat disc 44, 45 and tip 32 in a jet. Between each flat disc 44, 45 and the blade shank 32, the electric charge is continuous. Making flat discs 44 25-30% larger in diameter and 2-2.5 times thicker than flat discs of smaller diameter 45 installed between them and along the edges of the machine, allows flat discs of larger diameter and thickness to push a gap of greater depth in the soil and thickness, facilitating the work of shanks-tips 32.

At the same time, with such a design of adjacent disks, the possibility of turning the soil layer located between them upwards is excluded, since the adhesion forces of the soil with the side surfaces of adjacent disks 44 and 45 differ many times due to their different diameters and thicknesses. Thus, the locust larvae remain on the soil surface and do not submerge into it, which makes it possible, after exposure to jets of electricity between flat disks 44 and 45, to carry out on them an additional effective electric effect of jets of electricity between the lateral surfaces of the sting-tips 32, completely repeated impact, destroying the remains of locust larvae not destroyed by flat discs 44 and 45. The immersion depth of flat discs 44, 45 and blade shanks 32 is determined empirically based on the characteristics and moisture of the soil.

Used sources:

1. Moskvichev A.Yu., Karpova T.L., Generalov S.A., Kobyzev A.B. Locust control in the Volgograd region requires new approaches. Agronomy and forestry, no. 2, 2012, p. 1-7.

2. Zapevalov V.E. High power microwaves against locusts and other harmful animals. Copyright © 2017 for this paper by its authors. Copying permitted for private and academic purposes. Proceedings of the 27th International Conference "Microwave & Telecommunication Technology" (CriMiCo'2017) Sevastopol, Russian Federation, September 10-16, 2017, pp. 1459-1465.

Claims (1)

A locust killing machine comprising a plurality of rippers connected in parallel to the front end of the support member, a plurality of downwardly located blade shanks attached to the rear end of said support element, each of said blade shanks aligned with one of said rippers and has at least one an electrically conductive outer surface, a generator for generating electric current supplied to said shanks-tips, a transformer connected to said generator and said shanks-tips for converting an electric current supplied to said shanks-tips, and each of said shanks-tips has a whole a flat cross-section, a tapered front edge and a tapered bottom edge, with each of the said shank-tips having a wedge-shaped cross-section, the width of which increases from the front to the trailing edge of each such shank, and the width of each of said shank-tips is adjustable, while the specified generator provides electricity in three phases A, B and C and provides seven shanks-tips, as well as electricity in the ABCABCA phase scheme, with each of the specified shanks-tips usually in the shape of an inverted U with two downward legs, and the inner part of each of said legs has an electrically conductive surface, characterized in that the rippers are made in the form of a horizontal axis installed with the possibility of rotation on a perpendicular to the direction of movement of the machine and electrically isolated from it and from each other flat discs with electrically connected to them current collectors, while flat disks installed in the same direction of movement of one longitudinal vertical plane of symmetry of the shanks-stingers have a 25-30% larger diameter and 2-2.5 times greater thickness than flat disks of smaller size installed between them and along the edges of the machine diameter, and on all flat disks n Electricity is supplied according to the phase diagram A-B-C-A-B-C-A-C-A-B-C-A-B-C-A.

Images