KR101047376B1 - Soil pest control device using electric shock - Google Patents

Abstract

The present invention relates to a soil pest control device using an electric shock, while watering through a drip irrigation canal for cultivated crops planted on arable soil covered with mulch, The first direct current for controlling soil pests is flowed into the soil containing moisture while alternating the polarity of the pair of electrode members disposed on both sides in a specific cycle, or the polarity of the pair of electrode members is alternated at a specific cycle. To control soil pests while flowing a second direct current into the soil containing water, which is not absorbed by the cultivated crop and causes ionic bonding or ion exchange to the insoluble fertilizer components remaining in the soil, or the first direct current. The current and the second direct current are alternately flowed into the soil containing moisture, alternating with a specific period.

According to the present invention, by applying a DC current to a pair of electrode members in the arable soil while alternating its polarity, it is possible to easily control soil pests harming crops, and to the insoluble fertilizer component remaining in the arable soil. By promoting the absorption of the insoluble fertilizer component by the cultivation crop by causing a bond or ion exchange, it is possible to promote the growth of the cultivated crops while inexpensively and easily avoiding the conventional salt accumulation phenomenon.

Electric shock, soil, pest, extermination, insoluble fertilizer

Description

Apparatus for exterminating soil pests using an electric shock}

The present invention relates to a soil pest control technology, and more particularly to a soil pest control device using an electric shock.

Generally, when cultivating crops such as field crops (pepper, eggplant, tomatoes, beans, etc.) or horticultural crops (eg, vegetables, fruits, flowers, etc.) in open fields or houses, soil erosion prevention, soil water retention, geothermal control, weed control , Mulching that covers the surface of arable soil with vinyl or paper, etc. for the purpose of preventing soil infectious diseases and soil contamination, etc., and then planting seedlings of the crops (very planting). .

For example, when cultivating field crops in open fields or houses, first dig soil in the cultivated soil, and drop drip irrigation pipes in which water or fertilizers are drilled at specific intervals along the lengthwise direction. Buried or lined on the top of the field, cover the surface of the field with drip irrigation pipes with vinyl, and then sequentially drill the holes in the plastic along the length of the field at specific intervals, and then cultivate in these holes. Set seedlings of crops.

For reference, Figure 1 is an embodiment showing the state of covering the surface of the field with a mulch 100, such as vinyl, watering the cultivated crops through the drip irrigation pipe 200 lined on the upper ground of the field If fertilization is necessary, fertilized water can be added.

Covering the surface of the field with mulch 100 as described above and watering the crops through the drip irrigation pipe 200, the remaining fertilizer components, that is, insoluble fertilizer components are not absorbed by the crops soil When the groundwater or the groundwater evaporates in the state of accumulation, salt deposits are formed on the surface of the hard soil, and the root crops are grown by reverse osmosis due to the high salt concentration. Dehydration and eventually dry salt accumulation occurs.

For reference, inorganic materials such as ammonium sulfate (NH ₄ SO ₄ ), ammonium chloride (NH ₄ Cl), potassium sulfate (K ₂ SO ₄ ), potassium chloride (KCl), magnesium sulfate (MgSO ₄ ), calcium carbonate (CaCO ₃ ), and the like. When fertilizer has been fertilized or has been fertilized in arable soil, for example, ammonium (NH ₄ ), potassium (K) and magnesium (Mg) components are sufficiently absorbed into the crop in an ionic state, and sulfuric acid (SO ₄ ) and chlorine ( Calcium sulfate formed by chemical bonding of calcium (Ca) and sulfuric acid (SO ₄ ) or calcium (Ca) and chlorine (Cl) in the arable soil if Cl) and calcium (Ca) remain in the arable soil in an ionic state. Salts, such as (CaSO ₄ ) and calcium chloride (CaCl ₂ ), accumulate on the surface layer of arable soil when groundwater or groundwater evaporate.

As a way to avoid the salt accumulation phenomenon mainly due to the insoluble fertilizer component as described above, using a fertilizer that does not contain a fertilizer component that is difficult to use in the cultivated crop or does not contain a fertilizer component that is not absorbed by the cultivated crop It is known to use organic fertilizers, cetal salt salt by water, crop salt by cultivation of threshing crops, field soil, and soy sauce.

On the other hand, if you cover the surface of the field with mulch 100, such as vinyl, if the pesticide is sprayed in order to control harmful pests on the crops, pests parasitic on the stems, leaves, flowers, fruits of the crops Although it may be able to control the soil pests such as soil nematodes, caterpillar larvae, ground dogs and so on harming while parasitic on the roots of crops in arable soil due to the mulch (100) has a disadvantage.

In addition, the conventional salt accumulation avoidance method mainly due to the insoluble fertilizer component is inconsistent with the current agricultural situation in which the agricultural population is solidified, labor costs are increased, and the cultivated area is gradually enlarged. And uncomfortable.

The present invention is to solve the conventional problems as described above, the object of the present invention is the water through the drip irrigation pipe for the cultivated crops formalized on the soil soil covered with a mulch, such as vinyl or paper During the giving, to control the soil pest while alternating the polarity of the pair of electrode members arranged in a state slightly buried in the upper ground of the arable soil side by side at a certain interval on the basis of the drip irrigation pipe at a specific cycle It is to provide a soil pest control device using an electric shock to flow the first direct current of a certain voltage level into the soil containing moisture.

Another object of the present invention is a constant on both sides of the drip irrigation pipe while watering through the drip irrigation pipe for the cultivated crops that are settled on the arable soil covered with mulch such as vinyl or paper. The fertilizer component, i.e., insoluble in the soil, is not absorbed by cultivated crops while controlling soil pests by alternating the polarity of a pair of electrode members arranged in a state slightly buried in the upper soil of arable soil side by side at intervals. It is to provide a soil pest control device using an electric shock to flow the second direct current of a specific voltage level causing ionic bonds or ion exchange to the fertilizer components into the soil containing moisture.

Another object of the present invention, while watering through the drip irrigation canal for the cultivated crops that are settled on the soil soil covered with mulch, such as vinyl or paper, on both sides of the drip irrigation canal The pair of electrodes and the first DC current at a specific voltage level for controlling soil pests while alternating the polarity of the pair of electrode members arranged in a state slightly buried in the upper ground of arable soil side by side at a predetermined interval. Alternating the polarity of the member at specific cycles to identify the second DC current at a specific voltage level that results in the removal of soil pests and is not absorbed by the crop and causes ionic bonding or ion exchange to the remaining fertilizer components, ie insoluble fertilizer components. Soil pest control field using electric shock that flows into moist arable soil alternating with cycle To provide.

In order to achieve the object of the present invention as described above, the first embodiment of the soil pest control device using the electric shock according to the present invention, with respect to the cultivated crops that are settled on arable soil covered with a mulch surface A pair of electrode members arranged side by side in arable soil at regular intervals on both sides of the drip irrigation pipe for watering; And during the watering of the cultivated crop through the drip irrigation pipe, the first soil current of a specific voltage level for controlling soil pests while alternating the polarity of the pair of electrode members at a specific cycle is contained in the soil soil containing moisture. Fertilizers remaining in the soil without being absorbed by the crops while controlling the pests of the soil while alternating the polarity of the pair of electrode members at specific intervals while flowing to the water or through the drip irrigation water. That is, the control device for flowing a second direct current of a specific voltage level causing ionic bonds or ion exchange to the insoluble fertilizer component into the arable soil containing water.

In order to achieve the object of the present invention as described above, the second embodiment of the soil pest control device using the electric shock according to the present invention, with respect to the cultivated crops that are formalized on arable soil covered with a mulch surface A pair of electrode members disposed in the arable soil side by side at regular intervals on both sides of the drip irrigation pipe for watering; And the first DC current at a specific voltage level and the pair of electrode members for controlling soil pests while altering the polarity of the pair of electrode members at specific cycles while watering the crops through the drip irrigation canals. Alternating the polarity in a specific cycle alternates the second DC current at a specific voltage level at a specific voltage level that prevents soil pests from being absorbed by the cultivation crop and causes ionic bonding or ion exchange to the insoluble fertilizer components. It is characterized by consisting of; a control device for flowing into the soil soil containing water.

According to the present invention, by applying a DC current to a pair of electrode members disposed in the arable soil while alternating its polarity, that is, the (+) and (-) poles, soil nematodes, which are harmful to the roots of crops, cause harm. It is possible to easily control soil pests such as fly larvae, ground puppies, etc., and additionally, by promoting ion absorption or ion exchange of insoluble fertilizer components remaining in the soil to promote absorption of insoluble fertilizer components by cultivated crops. It is possible to promote the growth of cultivated crops while inexpensively and easily avoiding salt accumulation.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is an embodiment showing a state in which the soil pest control device using the electric shock according to the present invention is installed on the field dug shown in FIG.

Soil pest control device using the electric shock according to the present invention shown in Figure 2 is divided into different embodiments according to the control method of the control device (400,400a).

[First Embodiment]

In the soil pest control apparatus using the electric shock according to the first embodiment of the present invention, the control device 400 alternates the polarity of the pair of electrode members 300 and 300a at a specific cycle, and controls the soil pests at a specific voltage level. 1 Fertilizer component that is not absorbed by the cultivated crops while controlling the pests of the soil while direct current flows into the soil containing moisture, or alternating the polarity of the pair of electrode members 300 and 300a at specific cycles. In other words, the second direct current of a specific voltage level causing ionic bonds or ion exchange to the insoluble fertilizer component flows into the soil containing moisture.

Referring to FIG. 2, the pair of electrode members 300 and 300a are based on the drip irrigation pipe 200 that waters the cultivated crops that are settled on the soil covered with the mulch 100. It is arranged in arable soil side by side at regular intervals on both sides.

While the control device 400 waters the cultivated crop through the drip irrigation pipe 200, the control device 400 alternates the polarity of the pair of electrode members 300 and 300a at a specific cycle to control soil pests at a specific voltage level. While flowing the first direct current into the soil containing water, or watering the cultivated crop through the drip irrigation pipe 200, the polarity of the pair of electrode members (300, 300a) is specified Molecular soil containing moisture at a second voltage current at a certain voltage level that alternates with the cycle to control soil pests, which are not absorbed by the cultivated crop and remain in the soil, causing ionic bonding or ion exchange to the insoluble fertilizer. Let it flow through.

For reference, when the first direct current flows into the soil containing moisture, maintaining the voltage level of approximately 6V can sufficiently control the soil pests by electric shock. In addition, when the second direct current is flowed into the soil containing moisture, if the voltage level of approximately 20V is maintained, the soil pests are not absorbed by the cultivated crops while controlling the soil pests by electric shock, and the remaining insoluble fertilizers are left in the soil. It can cause sufficient ion bonding or ion exchange. The voltage level of the first DC current and the voltage level of the second DC current may be suitably set according to the type of cultivated crops, humidity in soil, soil pests, insoluble fertilizers, etc.

Referring to FIG. 3, the control device 400 includes a variable transformer 410, an AC / DC converter 420, a time relay 430, and a current supply control unit 440.

The variable transformer 410 may change the voltage of the commercial AC power supply (AC 220V or AC 110V) to a specific voltage level for controlling soil pests, for example, the specific voltage level for supplying the first DC current, or to control soil pests. While being absorbed by the cultivated crop and remaining in the soil, i.e., to a specific voltage level that causes ion bonding or ion exchange for insoluble fertilizer components, such as the second DC current supply.

The AC / DC converter 420 converts the output voltage of the variable transformer 410 into a DC voltage.

The time relay 430 supplies or cuts off the DC current at the output voltage level of the AC / DC converter 420 at a specific period. For example, a DC current is supplied for 10 seconds and a DC current is blocked for 10 seconds during a 20 second period.

The current supply control unit 440 applies a DC current output through the time relay 430 to the pair of electrode members 300 and 300a while alternating its polarity, that is, the (+) and (-) poles. Flow into moist soil. For example, after supplying DC currents of (+) and (-) poles for 10 seconds in a 20-second period and cutting off DC currents for 10 seconds, the DC current of (-) and (+) poles for 10 seconds during the next 20 seconds period. Repeat the alternating operation to supply current and cut off the DC current for 10 seconds.

The current supply control unit 440 and the variable transformer 410 when the manual operation switch 450 is turned on or when the detected humidity of the soil hygrometer 460 for detecting the humidity in the arable soil is determined to be above a predetermined reference value; The AC / DC converter 420 drives the pair of electrode members 300 and 300a while alternating the polarity, that is, the (+) and (-) poles, of the DC current output through the time relay 430 at a specific period. Is applied.

The manual operation switch 450 is operated by the user directly.

The soil hygrometer 460 is disposed in the arable soil side by side at regular intervals on both sides of the drip irrigation pipe 200 while the user waters the crops through the drip irrigation pipe 200. The humidity changes as water penetrates into the hard soil between the pair of electrode members 300 and 300a.

Soil pest control apparatus using an electric shock according to the first embodiment of the present invention configured as described above operates as follows.

While the user waters the cultivated crop through the drip irrigation pipe 200, the on state of the manual operation switch 450 is confirmed by the current supply control unit 440, or the soil hygrometer 460. When the detected humidity is determined to be equal to or greater than a preset reference value, the current supply controller 440 drives the variable transformer 410 and the AC / DC converter 420 to be output at a specific period through the time relay 430. DC current is applied to the pair of electrode members 300 and 300a while alternating their polarities, i.e., the (+) and (-) poles.

At this time, the variable transformer 410 changes the voltage of the commercial AC power supply (AC 220V or AC 110V) to the specific voltage level for supplying the first DC current set to control the soil pest, or while controlling the soil pest When the AC / DC converter 420 is changed to the specific voltage level for supplying the second DC current which is not absorbed by the cultivated crop and is set to cause ion bonding or ion exchange of the insoluble fertilizer component remaining in the soil. The output voltage of the transformer 410 is converted into a DC voltage, and then the time relay 430 supplies or blocks the first DC current or the second DC current of the output voltage level of the AC / DC converter 420 at a specific period. do. For example, a DC current is supplied for 10 seconds and a DC current is blocked for 10 seconds during a 20 second period.

Accordingly, the current supply control unit 440 is a pair of the first DC current or the second DC current output through the time relay 430 while alternating its polarity, that is, the (+) and (-) poles. It is applied to the electrode member (300, 300a) of the flow into the hard soil containing water. For example, after supplying DC currents of (+) and (-) poles for 10 seconds in a 20-second period and cutting off DC currents for 10 seconds, the DC current of (-) and (+) poles for 10 seconds during the next 20 seconds period. Repeat the alternating operation to supply current and cut off the DC current for 10 seconds. The alternating operation is the OFF state of the manual operation switch 450 is confirmed, or as the user cuts the water supply through the drip irrigation pipe 200, the detected humidity of the soil hygrometer 460 is less than the preset reference value If it is determined to be stopped.

As described above, when the first direct current flows into the soil containing moisture, soil pests such as soil nematodes, caterpillar larvae, and ground puppies, which are harmful to the roots of crops in the soil, are damaged by electric shock. It is easily remedied.

In addition, when the second direct current flows into the soil containing water as described above, soil pests in the soil are easily exterminated by electric shock, and ion binding or ion exchange with respect to the insoluble fertilizer component remaining in the soil. This causes the absorption of the insoluble fertilizer components by the cultivated crops, and as a result, it is possible to promote the growth of the cultivated crops while inexpensively and easily avoiding the conventional salt accumulation phenomenon.

Indeed, according to the present invention, insoluble fertilizer components remaining in arable soil, such as ammonium (NH ₄ ), potassium (K), magnesium (Mg), sulfuric acid (SO ₄ ), chlorine (Cl), calcium (Ca), etc. After supplying the DC current of the (+) and (-) poles for 10 seconds to the pair of electrode members (300,300a) for 10 seconds and cutting off the DC current for 10 seconds, for 10 seconds during the next 20 seconds period During the alternating operation of supplying the DC current of the (-) and (+) poles and cutting off the DC current for 10 seconds, while moving in the soil containing moisture between the pair of electrode members 300 and 300a Ion bonding or ion exchange promotes the absorption of insoluble fertilizer components by the cultivation crop, and as a result, it is possible to promote the growth of the cultivation crop at low cost and easily avoiding the conventional salt accumulation phenomenon.

[Second Embodiment]

In the soil pest control apparatus using the electric shock according to the second embodiment of the present invention, the control device 400a alternates the polarity of the pair of electrode members 300 and 300a at a specific cycle to control soil pests at a specific voltage level. Ion bonds or ions to fertilizer components, i.e., insoluble fertilizer components remaining in the soil that are not absorbed by the cultivation crops while controlling soil pests while alternating the first DC current and the polarity of the pair of electrode members 300 and 300a at specific cycles. The second direct current of a specific voltage level causing an exchange is flowed into the soil containing moisture while alternating at a specific cycle.

2 and 4, while the control device 400a waters the cultivated crop through the drip irrigation pipe 200, while alternating the polarity of the pair of electrode members 300 and 300a at a specific cycle. The fertilizer component that is not absorbed by the cultivation crops, that is insoluble in the crops while controlling the soil pests while alternating the polarity of the pair of electrode members 300 and 300a at a specific voltage level to control soil pests at a specific cycle The second direct current at a certain voltage level, causing ionic bonding or ion exchange to the fertilizer components, flows into the soil containing moisture, alternating at specific intervals.

For reference, when the first direct current flows into the soil containing moisture, maintaining the voltage level of approximately 6V can sufficiently control the soil pests by electric shock. In addition, when the second direct current is flowed into the soil containing moisture, if the voltage level of approximately 20V is maintained, the soil pests are not absorbed by the cultivated crops while controlling the soil pests by electric shock, and the remaining insoluble fertilizers are left in the soil. It can cause sufficient ion bonding or ion exchange.

The control device 400a includes a first transformer 410a and a second transformer 410b, a first AC / DC converter 420a, a second AC / DC converter 420b, a first time relay 430a, and a first transformer 410a. And a two time relay 430b and a current supply control unit 440.

The first transformer 410a may change the voltage of the commercial AC power supply (AC 220V or AC 110V) to a specific voltage level for controlling soil pests, for example, the specific voltage level for supplying the first DC current.

The second transformer 410b is ion-coupled or ion-exchanged with fertilizer components remaining in the soil, i.e., insoluble fertilizer components, which are not absorbed by the cultivated crops while controlling soil pests using a voltage of commercial AC power (AC 220V or AC 110V). It can be changed to a specific voltage level causing the voltage, for example the specific voltage level for supplying the second DC current.

The first AC / DC converter 420a converts the output voltage of the first transformer 410a into a DC voltage.

The second AC / DC converter 420b converts the output voltage of the second transformer 410b into a DC voltage.

The first time relay 430a supplies or blocks a first DC current of an output voltage level of the first AC / DC converter 420a at a specific cycle. For example, a DC current is supplied for 10 seconds and a DC current is blocked for 10 seconds during a 20 second period.

The second time relay 430b supplies or cuts off the second direct current of the output voltage level of the second AC / DC converter 420b in a specific period alternated with the supply period or the interruption period of the first direct current. For example, a DC current is cut off for 10 seconds and a DC current is supplied for 10 seconds in a 20 second period.

The current supply control unit 440a alternates the first direct current output through the first time relay 430a and the second direct current output through the second time relay 430b at specific cycles. By applying to the electrode member (300,300a) flows into the hard soil containing water. For example, after supplying the first direct current of the positive and negative poles for 10 seconds during the 20 second period and the second direct current of the positive and negative poles for 10 seconds, the next 20 second period The alternating operation of supplying the first direct current of the (-) and (+) poles for 10 seconds and the second direct current of the (-) and (+) poles for 10 seconds is repeated.

The current supply control unit 440a is configured to switch the first transformer 410a when the manual operation switch 450 is turned on or when the detected humidity of the soil hygrometer 460 for detecting humidity in arable soil is determined to be equal to or greater than a preset reference value. And a first DC current and the second DC current output through the first time relay 430a by driving the second transformer 410b, the first AC / DC converter 420a, and the second AC / DC converter 420b. The second DC current output through the two time relay 430b is applied to the pair of electrode members 300 and 300a while alternating at a specific cycle.

The manual operation switch 450 is operated by the user directly.

The soil hygrometer 460 is disposed in the arable soil side by side at regular intervals on both sides of the drip irrigation pipe 200 while the user waters the crops through the drip irrigation pipe 200. The humidity changes as water penetrates into the hard soil between the pair of electrode members 300 and 300a.

Soil pest control device using an electric shock according to a second embodiment of the present invention configured as described above operates as follows.

While the user waters the cultivated crop through the drip irrigation pipe 200, the on state of the manual operation switch 450 is confirmed by the current supply control unit 440a or the soil hygrometer 460. When the detected humidity of the control unit is determined to be equal to or greater than a preset reference value, the current supply control unit 440a may include the first transformer 410a, the second transformer 410b, the first AC / DC converter 420a, and the second. The AC / DC converter 420b is driven to alternate the first direct current output through the first time relay 430a and the second direct current output through the second time relay 430b at a specific cycle. It is applied to the pair of electrode members (300, 300a).

At this time, the first transformer 410a changes the voltage of the commercial AC power supply (AC 220V or AC 110V) to the specific voltage level for supplying the first DC current set to control soil pests, and the second transformer 410b. The second direct current is set to cause the ionic bond or ion exchange of the commercial AC power (AC 220V or AC 110V) to the soil crops while controlling the pests and not absorbed by the cultivation crops. When the voltage is changed to a specific voltage level for supplying current, the first AC / DC converter 420a and the second AC / DC converter 420b respectively change the output voltages of the first transformer 410a and the second transformer 410b. Convert to voltage.

Subsequently, the first time relay 430a supplies or blocks the first direct current of the output voltage level of the first AC / DC converter 420a at a specific period. For example, a DC current is supplied for 10 seconds and a DC current is blocked for 10 seconds during a 20 second period.

In addition, the second time relay 430b supplies or cuts off the second direct current of the output voltage level of the second AC / DC converter 420b in a specific period alternated with the supply period or the interruption period of the first direct current. do. For example, a DC current is cut off for 10 seconds and a DC current is supplied for 10 seconds in a 20 second period.

Accordingly, the current supply control unit 440a alternates between the first direct current output through the first time relay 430a and the second direct current output through the second time relay 430b at specific cycles. It is applied to the pair of electrode members 300 and 300a to flow into the hard soil containing moisture. For example, after supplying the first direct current of the positive and negative poles for 10 seconds during the 20 second period and the second direct current of the positive and negative poles for 10 seconds, the next 20 second period The alternating operation of supplying the first direct current of the (-) and (+) poles for 10 seconds and the second direct current of the (-) and (+) poles for 10 seconds is repeated. The alternating operation is the OFF state of the manual operation switch 450 is confirmed, or as the user cuts the water supply through the drip irrigation pipe 200, the detected humidity of the soil hygrometer 460 is less than the preset reference value If it is determined to be stopped.

As described above, when the first DC current and the second DC current flow alternately into the soil containing moisture, soil nematodes, caterpillar larvae, and ground puppies, which are harmful to the roots of crops in the soil, As soil pests are easily extinguished by electric shocks, ionic bonding or ion exchange of insoluble fertilizer components remaining in arable soil is caused, so that the absorption of insoluble fertilizer components by cultivated crops is promoted. It is possible to promote the growth of cultivated crops while inexpensively and easily avoiding the phenomenon.

Indeed, according to the present invention, insoluble fertilizer components remaining in arable soil such as ammonium (NH ₄ ), potassium (K), magnesium (Mg), sulfuric acid (SO ₄ ), chlorine (Cl), calcium (Ca) and the like In the ion state, the pair of electrode members 300 and 300a supply the first direct current of the positive and negative poles for 10 seconds during the 20 second period, and the positive and negative poles of the positive and negative poles are applied for 10 seconds. After supplying 2 DC current, supply 1st DC current of (-) and (+) poles for 10 seconds during the next 20 seconds period and supply 2nd DC current of (-) and (+) poles for 10 seconds While the alternating operation is repeated, the ion bonding or ion exchange while moving in the soil containing moisture between the pair of electrode members 300 and 300a promotes the absorption of insoluble fertilizer components by the cultivated crops. As a result, it is possible to promote the growth of cultivated crops while inexpensively and easily avoiding the conventional salt accumulation phenomenon.

Soil pest control apparatus using the electric shock according to the present invention described above is not limited to the above-described embodiment, it is common knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the following claims. Anyone who has a technical spirit has the technical spirit to the extent that various changes can be made.

1 is an embodiment showing a state covered with a mulch surface of the field.

Figure 2 is an embodiment showing a state in which the soil pest control device using the electric shock according to the present invention is installed on the field dug shown in FIG.

Figure 3 is a block diagram showing the internal configuration of a control device according to the present invention.

Figure 4 is a block diagram showing the internal configuration of another control device according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: mulch 200: drip irrigation pipe

300,300a: electrode member 400,400a: control device

410: variable transformer 410a: first transformer

410b: second transformer 420: AC / DC converter

420a: first AC / DC converter 420b: second AC / DC converter

430: time relay 430a: first time relay

430b: second time relay 440, 440a: current supply control unit

450: manual operation switch 460: soil hygrometer

Claims (6)

A pair disposed in the arable soil side by side at regular intervals on both sides of the drip irrigation pipe 200 for watering the cultivated crops formalized on the arable soil covered with its mulch 100. Electrode members 300 and 300a; And While watering the cultivated crop through the drip irrigation pipe 200, the first DC current at a specific voltage level for controlling soil pests while alternating the polarity of the pair of electrode members 300 and 300a at a specific cycle is polluted. Soil pests while alternating the polarity of the pair of electrode members (300, 300a) in a specific cycle while flowing to the cultivated soil containing water, or watering the crops through the drip irrigation pipe (200) A control device that delivers a second direct current at a specific voltage level into the soil containing moisture that is not absorbed by the crop and remains in the soil, causing ionic bonding or ion exchange to the insoluble fertilizer. 400; Soil pest control device using an electric shock, characterized in that consisting of. The method of claim 1, wherein the control device 400 The voltage of a commercial AC power source can be changed to a specific voltage level, either to control soil pests or to control soil pests that are not absorbed by the cultivated crop and that remain in the soil, causing ionic bonding or ion exchange to insoluble fertilizers. A variable transformer 410; An AC / DC converter 420 for converting an output voltage of the variable transformer 410 into a DC voltage; A time relay 430 for supplying or blocking DC current of the output voltage level of the AC / DC converter 420 at a specific cycle; And The DC current output through the time relay 430 is applied to the pair of electrode members 300 and 300a while alternating the polarity, that is, the (+) and (-) poles, into the soil containing soil. Flowing current supply control unit 440; Soil pest control device using an electric shock, characterized in that comprising a. The method of claim 2, wherein the current supply control unit 440 is When the manual operation switch 450 is turned on or when the detected humidity of the soil hygrometer 460 for detecting humidity in the arable soil is determined to be higher than or equal to a preset reference value, the variable transformer 410 and the AC / DC converter 420 are turned off. An electric shock, characterized in that for driving the DC current output through the time relay 430 to the pair of electrode members (300, 300a) while alternating its polarity, that is, (+) and (-) poles. Soil pest control device using. A pair disposed in the arable soil side by side at regular intervals on both sides of the drip irrigation pipe 200 for watering the cultivated crops formalized on the arable soil covered with its mulch 100. Electrode members 300 and 300a; And While watering the cultivated crop through the drip irrigation pipe 200, the first direct current of a specific voltage level for controlling soil pests while alternating the polarity of the pair of electrode members 300 and 300a at a specific cycle and the A specific voltage altering the polarity of the pair of electrode members 300 and 300a at a specific cycle, controlling the pests of the soil and causing ionic bonding or ion exchange to the fertilizer component remaining in the soil, i.e., the insoluble fertilizer component, which is not absorbed by the cultivated crop. A control device 400a for flowing the second direct current of the level into the soil containing moisture while alternating at a specific cycle; Soil pest control device using an electric shock, characterized in that consisting of. The method of claim 4, wherein the control device (400a) A first transformer 410a capable of changing the voltage of the commercial AC power supply to a specific first voltage level for controlling soil pests; A second transformer that converts the voltage of a commercial AC power source to a specific second voltage level that is not absorbed by the cultivation crop while controlling soil pests and that causes ionic bonding or ion exchange to the remaining fertilizer components, ie, insoluble fertilizer components. 410b; A first AC / DC converter 420a for converting the output voltage of the first transformer 410a into a DC voltage; A second AC / DC converter 420b for converting the output voltage of the second transformer 410b into a DC voltage; A first time relay 430a for supplying or cutting off the first DC current of the output voltage level of the first AC / DC converter 420a at a specific period; A second time relay (430b) for supplying or interrupting a second direct current of the output voltage level of the second AC / DC converter (420b) at a specific period alternated with the supply period or the interruption period of the first direct current; And The first DC current output through the first time relay 430a and the second DC current output through the second time relay 430b are alternately applied to the pair of electrode members 300 and 300a. A current supply control unit 440a which flows into the arable soil containing water; Soil pest control device using an electric shock, characterized in that comprising a. The method of claim 5, wherein the current supply control unit 440a The first transformer 410a and the second transformer 410b when the manual operation switch 450 is turned on or when the detected humidity of the soil hygrometer 460 for detecting humidity in arable soil is determined to be equal to or greater than a preset reference value. Drive the first AC / DC converter 420a and the second AC / DC converter 420b to convert the first DC current and the second time relay 430b output through the first time relay 430a. Apparatus for controlling soil pests using an electric shock, characterized in that the second DC current output through the alternating cycle in a specific cycle applied to the pair of electrode members (300,300a).

Images