KR20100033828A - The lake apparatus for purifying use of clay-solid matter loaded with microorganism - Google Patents

Abstract

PURPOSE: A lake purification device using solid bodies made with soil including microorganism and a method thereof are provided to improve workability for inputting soil balls and water purification efficiency by evenly distributing the soil balls in a lake. CONSTITUTION: A lake purification device using solid bodies made with soil including microorganism includes a motor(111), a fan(112), a floating body(100) transferred by a rudder, and a soil ball supplying device(200) settled on the top of the floating body. The soil supplying device includes the following: a supply part supplying soil balls; a guide part formed on the bottom of the supply part; a dropping part dropping the soil balls; an intermittent feeding part supplying the soil balls to a plurality of the guide part sand the supply part.

Description

Lake purifying treatment apparatus and method using soil solids containing microorganisms {THE LAKE APPARATUS FOR PURIFYING USE OF CLAY-SOLID MATTER LOADED WITH MICROORGANISM}

The present invention relates to an apparatus and a method for improving and purifying water quality having a form accommodated in a lake or a pond, in particular, the soil containing microorganisms produced in the form of solids such as balls (hereinafter referred to as "soil ball for convenience" To the place of loading in the lake or pond (hereinafter referred to as lake) to facilitate identification of the administered location so as to have an even distribution of distribution over the entire area of the lake, etc. Apparatus and method for treating lakes using soil solids containing microorganisms for remarkably purifying the water quality of lakes by shortening the administration time of labor and eliminating labor shortages, and evenly distributing soil balls by uniform distribution will be.

In lakes and ponds, especially ecological lakes, water must be kept clean and clean at all times to ensure that ecology is maintained. For example, if the pollution of water quality is severe due to the occurrence of suspended matter in the lake for a suitable period of time, not only the destruction of the ecosystem of the lake, but also the surrounding environment may be greatly deteriorated, and thus, periodic water purification treatment is required.

In the conventional case, the method of managing the water quality of the lake or the like is only to remove the floating surface floating on the surface of the lake or periodically replace the water, and the stagnant water may decay over time or the surface It does not prevent the state of contamination caused by sedimentation of the form.

To this end, Korean Patent No. 840548 discloses a facility for water purification of a lake or a pond. The facility has a driving mechanism at the bottom of a lake, especially a slope, and a peak at a slope and a valley. By installing the facilities, and providing means such as windmills and dissolved oxygen supply means to provide a configuration that allows the water in the lake to be continuously circulated to purify the water in the lake.

However, the water purification apparatus or system, facilities, etc. in the lake according to such a configuration should be provided with a number of facilities in the periphery of the lake, the bottom, the slope, the peaks, etc., and a means such as a windmill should be provided separately. In addition, significant installation and maintenance costs are required, as well as the large-area water purification treatment of large lakes with dissolved oxygen supply is virtually impossible.

In addition, after solidifying soil containing microorganisms (which is commonly referred to as soil ball in the art), the water is injected into the lake to purify the water quality of the lake. Processing all of them leads to considerable problems in efficiency when comprehensively judging work time and workforce.

In addition, even if the worker directly throws the ball at the edge of the lake, the soil ball does not reach the central point of the lake, so it is impossible to evenly distribute and throw the ball in the entire area of the lake, and water purification efficiency is inevitably deteriorated.

Of course, the worker may administer the earth ball by using a float or a boat, but the soil ball is repeatedly placed on the ship or around the lake, and the worker repeatedly loads a certain amount of the float or boat on which the worker rides. Therefore, the time required for the administration of the earthen ball over the lake must take considerable time, and it is difficult to accurately classify the earthen ball administration area, and the range of dense and low concentrations of the earthen ball is always present. It is well known that within the range, the problem of worsening the water quality rather than the water purification effect has emerged.

Therefore, the present invention has been made to solve the above problems,

It is possible to purify the water quality in the lake by using the soil ball of the solid produced by using the microorganism, but the soil ball can be distributed evenly distributed over the entire range in the lake, water purification efficiency and earth ball administration workability The purpose is to increase.

In addition, the present invention, by precisely detecting the location of the earth ball administration and transmitting the data value to the central control room to determine the omni-directional earth ball administration position of the lake in the observation monitor, by the even distribution of the earth ball to the earth ball itself It is also aimed to suppress the occurrence of sediment and the like caused by a good purification efficiency of the water quality throughout the lake.

The present invention for achieving the above object,

The subsidiary body 100 which is conveyed forward by the motor 111, 휀 112, and rudder 113 to the rear side,

Including a soil ball supply device 200 is seated and fixed on the upper surface 100,

The earth ball supply device 100, a supply unit 210 for accommodating and supplying the earth ball 10, the guide portion 220 is configured to be spaced apart from the bottom surface side of the supply portion 210, and the guide portion 220 ) Is provided with a drop portion 230 for dropping the soil ball 10 is provided on the end side into the lake, each of the soil ball 10 to the front end of the supply portion 210 and the plurality of guide portion 220, respectively It is characterized by consisting of an intermittent supply unit 240 for supplying.

The earth ball supply device 200 is moved according to the position data of the earth ball 10 in the lake loaded by the GPS (GPS) in the central control panel 300 to drop the earth ball 10 to a predetermined position Include.

The administration position of the earth ball 10 is dropped by the earth ball supply device 200 is displayed on the terminal 310 of the central control panel 300 and includes the monitoring of the administration trajectory.

According to the present invention, by measuring the pollution degree of the water contained in a lake or pond having a wide range, and by using the microorganisms for the water purification process of the soil ball can be distributed evenly distributed throughout the entire range of the lake, Has the effect of maximizing the water purification efficiency of the water.

In addition, according to the present invention, by providing a device for administering the earth ball, unlike the person administers the earth ball by the manual operation, it is possible to administer the correct amount in the correct position as well as to improve the operation efficiency.

In addition, according to the present invention, using the GPS 400, which is one of the satellite communication, it is possible to control the movement path of the globules, as well as to track and monitor the administration position of the soil ball to which the globules are moved and a large amount of soil balls. Not only can it be overdosed, it can completely rule out the possibility of worsening the water quality of the water in the lake, and it is possible to efficiently manage the time, schedule, and capacity of the clay ball, thereby significantly reducing maintenance work and maintenance costs. You can expect the effect.

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

The present invention uses the earth ball as one of the means for purifying the water quality in the lake as described above, but provides an efficient dispensing device of the earth ball, the float 100 is configured to be transported floating on the water surface of the lake and It is fixed to the upper surface of the substructure 100 is made of a clay ball supply device 200 to allow the soil ball 10 to be administered dropping on a predetermined position of the lake.

The substructure 100 may be connected to a plurality of fixed pieces to be a unit piece, the rear end side is provided with a fin 112 is driven by a motor 111 to enable forward transfer and the direction of the substructure 100 A rudder 113 is configured to enable switching.

The rudder 113 is preferably controlled by the central control panel 300, which will be described later. When the path control path of the initial substructure 100 is set in the central control panel 300, By turning the rudder 113 of the substructure 100 according to the set data value it is possible to enable the transfer and direction change to the desired path.

Since such a wireless control method uses well-known technology, detailed description thereof will be omitted in the specification of the present invention.

The earth ball supply device 200 is divided into a supply unit 210 for supplying the earth ball 10 and the earth ball 10 supplied from the supply unit 210 to guide and discharge to be guided and discharged separately; The guide portion 220 is composed of a drop portion 230 to be administered to the end of the end of the earth ball 10 to the lake side, the earth ball 10 on the position where the supply portion 210 and the guide portion 220 in contact with ) Is made up of an intermittent supply unit 240 for supplying individual guides one by one.

Soil ball 10 in the present invention can be used that is usually manufactured, for example, the solids of such a lump is a mud microbial community, including the collection of microorganisms present in the reservoir, soil, air and other natural environments. Can be.

These microorganisms are mainly zoogloae, spaerotilus, nitrosomonas, nitroacter, hypohomecrobium, caulobacter , Bdelovibrio, pseudomonas, etc. This is similar to symbiotic species in lakes and ponds.

As shown in the drawing, the supply unit 210 for supplying the soil mass solid, that is, the soil ball 10 manufactured by including such microorganisms, is preferably manufactured in a form for accommodating a plurality of soil balls thereinto the lower side thereof. Each guide portion 220 is connected, so that the guide to each one of the soil ball 10 that can be supplied from the supply unit 210 is discharged one by one.

As shown in Figure 2 showing the cross-sectional shape of the supply portion 210, in order to ensure that the earth ball 10 is supplied to the guide portion 220 side to be described later smoothly, the bottom surface side of the supply portion 210 is tapered and The discharge hole 211 is formed on the end side so that the soil ball 10 is naturally discharged so that the soil ball 10 is supplied to the guide part 220 to be described later by the intermittent supply part 240.

On the other hand, the guide portion 220 which may be provided at both bottom of the supply portion 210 is formed at the bottom of both sides of the supply portion 210 to form a plurality of forms like a fan-shaped end of each individual guide portion 220 When the falling portion 230 is connected to the side to reach the set drop region 100, so that the soil ball 10 is located in each falling portion 230, respectively.

At this time, between the tip portion of the guide portion 220 and the supply portion 210 is provided with an intermittent supply portion 240, as described above, the soil ball 10 supplied from the supply portion 210 to each of the guide portion 220 side It is desirable to be supplied.

That is, the intermittent supply unit 240 has a function of allowing the soil ball 10 to be seated on the tip side of the guide unit 220 one by one from the supply unit 210 in which countless soil balls 10 are accommodated in a hopper form. To this end, as shown in FIG. 4, a supply plate 242 having a seating groove 243 for seating the soil ball 10 on the front side is positioned at the bottom end side of the supply unit 210 to the cylinder 241. To be rotated by, so that the soil ball 10 seated in the seating grooves 243 of the supply plate 242 is supplied to the guide unit 220 side as described above.

As shown in FIG. 1, the intermittent supply part 240 is provided according to the number of the guide parts 220 connected to the lower end of the supply part 210.

The guide part 220 receives the earth ball 10 accommodated in the supply part 210 by the intermittent supply part 240 as described above, and transports the earth ball 10 to the outside of the float 100. In such a configuration that the guide portion 220, the guide portion 220 has a shape in which the upper side is opened, and the guide portion 220 is preferably maintained in a state capable of pulling back and forth as shown in FIG.

That is, when the operation of the earth ball 10 to the inside of the lake is drawn out so that the end of the guide portion 220 is positioned outside the float 100, and when the operation is completed, the guide portion 220 is close to the supply portion 210 side It is desirable to be positioned.

In addition, the guide portion 220 is to be adjusted to the left and right spaced apart, it is preferable to adjust the separation distance between the soil ball 10 is administered to the side when the soil ball 10 is administered in the lake.

In addition, the drop section 220a is formed at the shortest side of the guide portion 220 so as to enable the easy dropping action of the earth ball 10 to the lake side in the drop portion 230.

The dropping portion 230 is located at the front end of the guide portion 220, the configuration for administering the earth ball 10 into the lake, the gripping-type falling method according to Figures 2, 3 and 6 The soil ball 10 can be administered into the lake by various methods, such as a closed-type drop method and a firing-type drop method according to FIG. 7, and the drop part 230 described in the specification, claims, and drawings of the present invention. It should not be limited to the configuration of), and similar technical concepts should be understood as the same technical concept.

For example, as shown in Figures 2 and 3 can be implemented with a gripping drop plate 232 to be rotated by the cylinder 231.

The gripping type falling plate 232 has a state where the upper side plate 232a and the lower side plate 232b are spread like a tong shape, and the lower end of the guide portion 220 is shown in FIG. When the gripping type falling plate 232 is rotated according to the operation of the cylinder 231 in the form where the side plate 232b is blocked, the lower side plate 232b is positioned downward as shown in FIG. 3B and the upper side plate ( 232a blocks the end side of the guide portion 220.

In addition, the earth ball 10 seated on the lower side plate 232b is dropped into the lake, and the other earth ball 10 is prevented from falling by the upper side plate 232a.

On the other hand, it is preferable to facilitate the rotation of the upper plate 232a, as well as to open one side of the shortest side dropping port 220a of the guide portion 220, that is, the cylinder 231 direction.

The upper side plate 232a of the gripped drop plate 232 rotated according to the operation of the cylinder 231 by the dropping hole 220a opened as described above may open and close the end side of the dropping hole 220a without interference. It will be possible.

As described above, the earth ball 10 aligned with the guide part 220 by the repeated operation of the cylinder 231 may repeatedly perform a series of processes sequentially dropping into the lake.

Meanwhile, as shown in FIG. 6, the drop part 230 may be configured.

That is, provided with a means for opening and closing the drop opening (220a) of the guide portion 220, respectively up and down so that the earth ball 10 free fall into the lake by the sequential operation.

For example, as shown in the drawing, the first blocking plate 233 and the second blocking plate 234 for shielding the inside of the upper and lower drops 220a are spaced apart from each other by a distance such that one earth ball 10 is located. Next, the first and second blocking plates 233 and 234 are repeatedly shielded from each other.

Therefore, the earth ball 10 guided along the guide portion 220 reaches the shortest side of the guide portion 220 and is positioned by the second cylinder 231b in FIG. The second blocking plate 234 is in a state of blocking the lower end of the drop opening 230, and the earth ball 10 is seated on the upper surface of the second blocking plate 234, and the earth ball 10 is also seen from above in the drawing. As described above, the first blocking plate 233 is penetrated so that the falling hole 220a is blocked.

In this state, when the second blocking plate 234 is reversed by the second cylinder 231b, one earth ball 10 supported by the first and second blocking plates 233 and 234 at the drop opening 220a is opened. Administered into.

Thereafter, the second blocking plate 234 is moved forward by the operation of the second cylinder 231b, and at the same time, the first blocking plate 233 is moved backward and backward, and the upper surface of the first blocking plate 233 is The other earth ball 10 that was in the seated state falls on and is seated on the upper surface of the second blocking plate 234.

In the above state, the second blocking plate 234 repeats the above-described operation and the second blocking plate 234 is moved forward after the soil ball 10 drops to the lake side by opening the second blocking plate 234. Will be transferred.

When the first blocking plate 233 is moved backward by the operation of the first cylinder 231a, another earth ball 10 located on the upper surface of the first blocking plate 233 is dropped to drop the drop hole 220a. The first blocking plate 233 is forwardly transferred again to the upper surface of the second blocking plate 234 blocking the lower end, and the last soil ball 10 at the drop opening 220a is the first and second blocking plates ( 233, 234) and then isolated by the procedure described above, according to the opening of the second blocking plate 234, a series of processes that fall into the lake side is repeated.

On the other hand, Figure 7 is a view showing another embodiment of the drop unit 230, for example, is an exemplary diagram adopting a launch type drop method.

In the case of the firing type drop method according to FIG. 7, the first and second blocking plates 233 and 234 as described above are applied, but the soil ball 10 dropped by the opening of the second blocking plate 234 flows directly into the lake side. Instead of being loaded into the launching device, the earth ball 10 is fired by the operation of the third cylinder, so that the earth ball 10 is shot at a far distance from the float 100 so as to flow into the lake. .

In this type of firing-type dropping method, a cylindrical launch tube 235 connected to the lower end of the dropping hole 220a is formed to be inclined, and a third cylinder 231c is provided at the rear side of the launch tube 235, but the third cylinder ( A seating table 236 connected to the rod L of 231c to seat the earth ball 10 is elastically supported by a spring S surrounding the rod L outer circumferential surface and providing elastic force.

Therefore, as described above, the soil ball 10 dropped by the opening of the second blocking plate 234 is introduced into the launch tube 235 fixed in an inclined state as described above, and the soil ball 10 introduced therein. 7 is fixed to the rod (L) end side of the third cylinder (231c) to maintain a seated state on the seat 236 is introduced into the launch tube (235).

When the soil ball 10 is introduced into the launch tube 235 and seated on the seating table 236 as described above, the rod L is retracted backward according to the operation of the third cylinder 231c, and then the spring is momentarily moved forward. The earth ball 10 seated on the seating plate 236 by the elastic force of (S) is fired under the guidance of the launch tube 235, and the earth ball 10 is blown away to the position away from the float 100, It is entering the lake.

On the other hand, by providing a plurality of the launch tube 235 can adjust the firing distance of the earth ball 10 to be launched from each launch tube 235, for example, to form a plurality of launch tubes 235 and the cylinder of each launch tube 235 By adjusting the hydraulic pressure so that the firing distance of the earth ball 10 to be launched from the launch tube 235 can be different from each other, it is possible to have different points to be put into the lake, so that the earth ball 10 is the appropriate position of the lake by multiple shots It will be able to be put into.

This point of course can be appropriately modified in the present invention, and of course, it will be apparent that it does not depart from the technical spirit of the present invention.

On the other hand, the globules 100 having the above configuration is to move along the lake having a predetermined area and to administer the earth ball 10, it is necessary to accurately observe the location and quantity of the earth ball 10, and the like.

To this end, in the present invention, it is preferable to have a communication network by a wireless network to enable communication between the sub-structure 100 and the central control panel 300.

In addition, the central control panel 300 grasps the transport path of the sub-sphere 100 in real time, and accurately calculates the position and quantity of the earth ball 10 administered in the lake along the transport path, which is most suitable for the purification of water in the lake. Work can be made according to suitable conditions.

That is, the central control panel 300 to enable the wireless control and mutual communication for the position control of the substructure 100, and control the transfer path of the substructure 100 using the GPS 400 and at the same time the specified position When reaching, the earth ball 10 to be administered through the earth ball supply device 200 of the substructure 100, the quantity and position of the earth ball 10 is the terminal 310 of the central control panel 300 It is displayed in real time and can be confirmed.

For example, the central control panel 300 transmits the designed earth ball 10 administration position and the transfer path of the substructure 100 at the time of starting the subsphere 100, and loads the program into the substructure 100, and then wirelessly connects to the state. When maintaining the trajectory of the transport path from the starting point of the substructure 100 is displayed on the terminal 310 of the central control panel 300, the substructure 100 is moved in accordance with the signal according to a given set value In the drop portion 230 in the earth ball supply device 200 is applied to the point that the earth ball 10 is administered into the lake to be displayed on the terminal 310.

In this way, the transport path of the substructure 100 and the administration position of the earth ball 10 to be displayed on the terminal 310 of the central control panel 300 in the form of dots to calculate the efficiency of the earth ball 10 currently working, etc., Allow for inspection and automatically back up the data.

In addition, by installing a separate ultrasonic device, turbidity measurement device, pollution measurement device, inspection sensor, camera, etc. in the sub-sphere 100 to apply a signal from the sub-sphere 100 received in real time from the central control panel 300 Thus, it is desirable to enable real-time inspection of the turbidity, pollution degree, etc. of the current lake.

According to the present invention having the above-described configuration, a purification treatment method using an earth ball, which is one of the methods for purifying contaminated water in a lake, and a working procedure and operation relationship thereof will be described.

First, the worker loads the preset value set in advance by the central control panel 300 to the floating sphere 100, the floating sphere 100 is the trajectory of the operation in the lake and the soil ball 10 during operation A value, such as a location to administer, is input, and the current navigation position and the administration position of the earth ball 10 of the float 100 are displayed on the terminal 310 of the central control panel 300 through a real-time GPS system. .

The earth ball 10 accommodated in the supply portion 210 of the earth ball supply device 200 provided in the substructure 100 is intermittent soil ball 10 passing through the discharge port 211 provided on each side of the lower The guide ball 220 is guided along the plurality of guides 220 arranged in a plurality arranged through the supply unit 240 is supplied individually, the soil ball 10 is supplied individually through each guide unit 220, the respective guide unit 220 The soil ball 10 discharged through the dropping hole (220a) leading to the end of the end is subjected to a series of processes to be administered into the lake by the above-described dropping portion 230.

Here, the point where the soil ball 10 is administered into the lake through the dropping portion 230 is already transferred along the transfer path of the substructure 100 according to the contents set by the central control panel 300 and the predetermined drop. So that the fall of the earth ball 10 is made at the point.

That is, the operation of the cylinder 231 constituting the components of the drop unit 230 is interlocked according to the application of the signal from the central control panel 300, so that the substructure 100 is transferred after a predetermined distance in the coordinates of the programmed position. When it reaches, the ball 100 is guided along the respective guide portion 220 in the earth ball supply device 200 is stopped after the float 100 in the corresponding coordinates are introduced into the lake through the falling portion 230 When the input is completed, the substructure 100 is repeatedly performed a series of processes to be transferred to the coordinates of the position where the earth ball 10 is to be inserted.

At this time, the coordinates corresponding to the input position of the earth ball 10 is injected through the substructure 100, the transfer path of the substructure 100, etc. are transmitted in real time through the terminal 310 of the central control panel 300 After being displayed, it can of course be stored on a central server or output as required.

The present invention is not limited to the soil ball 10 is introduced into the lake using only one substructure 100.

For example, as shown in Figure 8 is connected to the sub-sphere 100 which is a bus bar on the front side, and the sub-structure 100, which is connected to the rear side of the sub-line or subordinate ships are connected to each other ( 100) On both sides, a plurality of launch tubes 235 are respectively formed to allow the earth ball 10 to be launched into the lake, and the earth ball 10 at the rear side of the float 100 which becomes the barge or the own ship is in the present invention. The dropping means having the respective configurations described by the detailed description is allowed to fall into the lake so that the water in the lake can be purified.

Such a technical configuration may be implemented by effectively combining the respective drop means in the present invention.

On the other hand, the present invention is mainly described in the process of purifying the water of the lake by putting in the lake using the earth ball 10, it will not need to be limited to the earth ball (10).

For example, by spraying each microorganism that is the material of the earth ball 10 in the liquid phase directly in the lake will be able to enable the purification of contaminated water in the lake.

For example, while the contents of the liquid containing the microorganisms are accommodated in a tank installed in the float 100, using a plurality of hoses connected from the tank, the contents of the liquid discharged from the tank is appropriate pressure It will be discharged by the can be injected to be introduced into the sludge accumulated on the bottom of the lake through the nozzle of the hose end side.

This is to prevent the hose from being rotated by the injection pressure at this time, by adopting a weight providing means on the hose end side can be eliminated the phenomenon that the hose bounces by the opposite pressure generated when the liquid microorganism discharged from the nozzle of the hose In addition, it may be implemented by adopting the center of gravity maintenance means to ensure that the nozzle of the hose always directed to the bottom of the lake.

As described above, the contaminated water in the lake can be purified using the liquid microorganisms, and the point where the liquid microorganisms are discharged from the hose and the discharge position thereof are controlled through the central control panel 300 as described above. By using GPS, which is a satellite communication means, the location of the globules, the point where the liquid microorganisms are discharged through the hose, and the discharge amount may be displayed through the terminal 310 of the real-time central control panel 300.

In addition, the data obtained by the input of the liquid microorganism or the data obtained by the input of the earthen ball as in the present invention, that is, the location of administration of the earth ball and the liquid microorganism, the movement path of the globules, the dose of the earth ball and the liquid microorganism, etc. After being displayed through the terminal 310 of 300, the user can output the desired data in a report format by the selection menu to store the document.

1 is a perspective view showing a state equipped with a lake purification treatment apparatus adopted by the present invention

2 is a schematic front cross-sectional view of FIG.

Figure 3 is an enlarged cross-sectional view showing an example of the dropping portion leading to the end side of the guide portion of the earth ball supply apparatus adopted in the present invention;

Figure 4 is an enlarged cross-sectional view showing the configuration of the intermittent supply unit for intermittently supplying the earth ball dropping to the discharge port side of the supply portion to the guide portion in the earth ball supply apparatus adopted in the present invention;

Figure 5 is a schematic cross-sectional view showing a state capable of extending the guide portion in the earth ball supply apparatus according to the present invention;

Figure 6 is a view showing another embodiment of the dropping portion for dropping the earth ball supplied to the end side of the guide portion adopted in the present invention, such as a lake

7 is a view showing another embodiment in which the dropping portion for dropping the earth ball supplied to the end side of the guide portion adopted in the present invention into a lake or the like has a firing form;

FIG. 8 is a view showing an example of using the present invention to form a parent subsphere on a front end side and to administer a clay ball in a lake using a magnetic subsphere connected to a rear end of the parent subsphere.

9 is a schematic block diagram of a lake purification process according to the present invention;

※ Brief description of the main symbols in the drawings

10; Earth ball 100; Globular

111; Motor 112; 휀

113; Rudder 200; Earth ball feeder

210; Supply section 211; outlet

220; Guide part 220a; Drop

230; A drop 231; cylinder

232; Gripped falling plate 232a; Upper side plate

232b; Bottom plate 233; 1st blocking plate

234; Second blocking plate 235; Launch tube

S; Spring 236; Seating table

240; Intermittent supply section 241; cylinder

242; Feed plate 243; Home

244; Link 300; Central control panel

310; Terminal 400; GPS

Claims (9)

The subsidiary body 100 which is conveyed forward by the motor 111, 휀 112, and rudder 113 to the rear side, Including a soil ball supply device 200 is seated and fixed on the upper surface 100, The earth ball supply device 100, a supply unit 210 for accommodating and supplying the earth ball 10, the guide portion 220 is configured to be spaced apart from the bottom side of the supply portion 210, the guide portion 220 ) Is provided with a drop portion 230 for dropping the soil ball 10 is provided on the end side into the lake, each of the soil ball 10 to the front end of the supply portion 210 and the plurality of guide portion 220, respectively Lake purification treatment apparatus using a solid of soil containing microorganisms, characterized in that consisting of an intermittent supply unit 240 for supplying. The method of claim 1, The supply unit 210 has a form in which the inner bottom surface is tapered and forms outlets 211 on both sides of the lower side thereof, so that the solid body is made of soil containing microorganisms including connecting the plurality of guide units 220. Used lake purification treatment device. The method of claim 1, The intermittent supply part 240 is located at the lower end side of the side end of the supply part 210 and the supply plate 242 having a seating groove 243 for seating the soil ball 10 on the front side is provided to the cylinder 241. By using a solid body made of soil containing microorganisms, including the soil ball 10 seated in the seating grooves 243 of the supply plate 242 to be supplied to the guide portion 220 side by Lake purification treatment unit. The method of claim 1, The guide unit 220 is a lake purification treatment apparatus using a solid body made of soil containing microorganisms, including a plurality of forms that are open to the bottom of both sides of the supply unit 210, such as a fan shape, and has an open shape upwards. . The method of claim 1, The guide unit 220 is a lake purification treatment apparatus using a solid body made of soil, including allowing the extraction and storage. The method of claim 1, The dropping part 230 opens one side of the lowermost dropping port 220a of the guide part 220, and along the open part of the dropping hole 220a by an operation of the end portion of the guide part 220. An apparatus for purifying a lake using soil solids, including having upper and lower side plates (232a and 232b) in the form of forceps to rotate and open and close. The method of claim 1, The dropping unit 230 has a ground hole 10 in which the first blocking plate 233 and the second blocking plate 234 are respectively located to vertically shield the lowermost dropping hole 220a of the guide unit 220. After the separation by a distance of about, the first and the second blocking plates (233,234) by the first and second cylinders (231a, 231b), the lake purification using soil solids, including the cross-repetitive shielding mutually Processing unit. The method of claim 7, wherein The dropping unit 230 is formed to be inclined to form a cylindrical launch tube 235 connected to the dropping port 220a and provided with a third cylinder 231c at the rear side of the launch tube 235, the third cylinder 231c The seating rod 236 connected to the rod (L) of the earth to seat the earth ball (10) is made of soil comprising the elastic support by the spring (S) surrounding the rod (L) outer peripheral surface and providing an elastic force Lake purification treatment apparatus using solids. The ground plate 10 is provided with the GPS 400 on the central control panel 300 and the substructure 100, and the soil ball 10 in the soil ball supply device 200 of the transfer path and the substructure 100 in the substructure 100. By inputting the respective coordinates of the position to be administered into the lake through the drop unit 230, the transport path of the substructure 100 and the administration point of the earth ball 10 in real time terminal 310 of the central control panel 300 Lake purification method using a solid of the soil, characterized in that the control to be displayed through.

Images