KR102117425B1 - Residual, environmentally friendly precision liquefaction support system - Google Patents

Abstract

The present invention relates to an eco-friendly precision liquid fertilizer support system without residue, and when the fertilizer is not stored for a long time in a diluted state, and when water is supplied to the soil, the type and amount of fertilizer are separately selected and precisely adjusted in each fertilizer raw material container to input liquid fertilizer. Since it can be mixed and diluted immediately before, the risk of spoilage due to long-term storage of liquid fertilizer, the problem of precipitation of mineral fertilizer components and waste due to the supply of unnecessary fertilizer and the occurrence of physiological disorders in crops, etc. The circulation line structure that eliminates the residual liquid manure by supplying and discharging only the supply water is simple, thereby reducing the manufacturing cost.

Description

Residual, environmentally friendly precision liquefaction support system

In the present invention, the fertilizer can be mixed and diluted immediately prior to liquid fertilization by separately selecting and precisely adjusting the type and amount of fertilizer in each fertilizer stock container when water is supplied to the soil without storing the fertilizer for a long time in a diluted state. The risk of spoilage due to long-term storage, precipitation of inorganic fertilizer components, and waste caused by the supply of unnecessary fertilizer and physiological disorders of crops are solved, and after supplying and discharging liquid fertilizer, only supply water is introduced and discharged to eliminate liquid fertilizer residue. It is related to an eco-friendly precision liquid manure support system that has no residual structure that can reduce manufacturing cost due to a simple line structure.

In general, when crops are cultivated, it is moisture that has the greatest influence on the growth of crops, and it is necessary to liquefy the fertilizer and supply it with moisture to prevent the occurrence of diseases caused by excess moisture, and separately supply liquid fertilizer to the soil after hydration It has the advantage of minimizing the waste of manpower, and in recent years, it can perform the function of promoting and inhibiting plant growth at the same time, so it can control the growth balance of plants, and it is possible for the biosynthesis of hormones and enzymes in plants. A method of manufacturing a liquid fertilizer composition that can be involved and promotes the physiological activity of plants has been proposed as Korean Patent Registration No. 10-1765438.

However, the existing method of supplying liquefied fertilizer proposed in Korean Patent Registration No. 10-1765438, etc., is diluted with 100 to 300 times water in advance according to the type and shape of the crop, stored in a tank, and when water is supplied. It is supplied with water supplied through the water supply pipe.

At this time, as the diluted liquefied fertilizer is stored in the tank for a long period of time, it is difficult to obtain a fertilizer effect due to the risk of spoilage and precipitation of inorganic fertilizer components, and there is a problem in that it is difficult to frequently dilute the liquefied fertilizer.

Korean Registered Patent Publication No. 10-1765438

The present invention was created to solve the above-described problems, and the present invention separately selects the type and amount of fertilizer in each fertilizer stock container and precisely controls it when water is supplied to the soil without storing the fertilizer for a long time in a diluted state. Therefore, it is possible to mix and dilute just before liquid fertilization, so that the risk of spoilage caused by long-term storage of liquid fertilizer, the problem of sedimentation of mineral fertilizer components and the supply of unnecessary fertilizer and the occurrence of crop physiological disorders are solved. Its purpose is to provide an eco-friendly precision liquid manure support system without residue that can reduce manufacturing cost because the circulation line structure that eliminates residual liquid manure is simple due to the inflow and discharge of only the supply water through liquid mixing and stirring.

The present invention for achieving the above object is a pump for supplying the supply water to the supply line by pumping through the inlet line; An auxiliary inflow line connected to the supply line and into which some supply water supplied to the supply line flows; A liquid comparison and stirring through which some supply water flowing through the auxiliary inflow line is accommodated; A fertilizer stock passage through which the fertilizer stock is accommodated; A fertilizer stock solution supply line for supplying the fertilizer stock solution accommodated in the fertilizer stock solution to the liquid fertilizer stir; Provides an environment-friendly precision liquid manure support system, characterized in that it comprises; a dilution liquid ratio supply line for supplying a dilution liquid ratio in which some of the supply water and fertilizer stock solution accommodated in the liquid mixing chamber is supplied to the inflow line.

Here, a guide line having one side and the other side respectively connected to the supply line and the inflow line; It is preferable that one side is connected to the liquid agitating cylinder and the other dilution liquid ratio supply line is connected to the other side of the guide line.

And, a first valve for opening and closing the auxiliary inlet line; A second valve that opens and closes the fertilizer feedstock supply line; A third valve that opens and closes the dilution ratio supply line; A fourth valve that opens and closes the residual dilution ratio supply line; It is preferable to include; a control unit for controlling the first valve, the second valve, the third valve and the fourth valve.

Or, a first valve for opening and closing the auxiliary inlet line; A pump provided in the fertilizer feedstock supply line; A third valve that opens and closes the dilution ratio supply line; A fourth valve that opens and closes the residual dilution ratio supply line; It is preferable to include; a control unit for controlling the first valve, the pump, the third valve and the fourth valve.

Furthermore, it is preferable that a plurality of water level detecting units are provided at regular intervals in the vertical direction in the liquid stirring chamber.

Alternatively, a program for setting operating times of the first valve, the second valve, the third valve, and the fourth valve is provided, and the control unit controls the first valve, second valve, and second according to the operating time set in the program. It is preferable to control the 3 valve and the 4 valve.

Alternatively, a program for setting operating times of the first valve, the second valve, the third valve, and the fourth valve is provided, and the control unit controls the first valve, pump, and third valve according to the operating time set in the program. And it is preferable to control the fourth valve.

In the present invention, the fertilizer stock solution is mixed with and diluted with the feed water, and is not stored for a long time in a liquid fertilizer shaker, but when water is supplied to the soil, the type and amount of the fertilizer feedstock are separately selected and precisely controlled to precisely feed the fertilizer. Since it can be mixed and diluted immediately before, the risk of spoilage caused by long-term storage of liquid fertilizer, and problems such as waste caused by precipitation of inorganic fertilizer components and supply of unnecessary fertilizer and physiological disorders of crops are solved. The circulation line structure that eliminates the residual liquid manure by supplying and discharging only the supply water is simple, thereby reducing the manufacturing cost.

1 is a configuration diagram schematically showing an eco-friendly precision liquid manure support system without residue, which is a first embodiment of the present invention,
2 is a block diagram schematically showing a control unit for controlling the first, second and third valves according to the detection signal of the water level sensing unit,
3 is a partially cut configuration diagram schematically showing a state in which liquid fertilizer stock and some supply water are accommodated by liquid fertilization and stirring in the first embodiment,
FIG. 4 is a partial cutaway configuration diagram schematically showing a state in which a dilution ratio of a liquid agitation barrel of the first embodiment is supplied to an inflow line,
5 is a block diagram schematically showing a control unit for controlling the first, second, and third valves according to an operating time set in a program,
6 is a configuration diagram schematically showing an eco-friendly precision liquid manure support system without residue, which is a second embodiment of the present invention,
7 is a partially cut configuration diagram schematically showing a state in which a liquid fertilizer stock and a part of supply water are accommodated by liquid agitation of the second embodiment,
8 is a partially cut configuration diagram schematically showing a state in which a dilution ratio of a liquid agitation barrel of a second embodiment is supplied to an inflow line,
9 is a block diagram schematically showing the first and third valves of the second embodiment and a control unit for controlling the pump,
10 is a configuration diagram schematically showing an eco-friendly precision liquid manure support system without residue, which is a third embodiment of the present invention,
11 is a partially cut configuration diagram schematically showing a state in which a dilution ratio of a liquid agitation barrel of the third embodiment is supplied to an inflow line,
12 is a partially cut configuration diagram schematically showing a state in which some of the dilution liquid ratio remaining in the liquid comparison and stirring in the third embodiment is discharged to the residual dilution liquid ratio supply line together with some supply water.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and may be variously modified by those skilled in the art without departing from the technical gist of the present invention.

1 is a configuration diagram schematically showing an environment-friendly precision liquid manure support system without residue, which is a first embodiment of the present invention.

As shown in FIG. 1, the first embodiment of the present invention, the eco-friendly precision liquid support system without residue, is largely as shown in FIG. It comprises a fertilizer feedstock supply line 50 and a diluent feedstock supply line (60).

First, the pump 10, which can be made of various types, such as a water supply pump, forcibly pumps supply water that can be made of ground water or the like through the inlet line 110 connected to the suction port of the pump 10, thereby pumping the pump 10 It is supplied to the supply line 120 connected to the discharge port of the.

Next, the other side of the auxiliary inlet line 20 may be tightly connected to the middle of the supply line 120 so that the auxiliary inlet line 20 communicates with the supply line 120.

Some supply water supplied to the supply line 120 is introduced into the auxiliary inflow line 20.

Next, one side of the auxiliary inflow line 20 may be tightly connected to the other side of the upper side of the one side of the liquid comparison and agitation 30 so that the liquid agitation barrel 30 and the auxiliary inflow line 20 communicate. have.

Part of the supply water flowing through the auxiliary inflow line 20 is accommodated inside the liquid stirring container 30.

Next, the fertilizer stock container 40 may be disposed in one or more in the upward direction of the liquid fertilizer stirring container 30, the fertilizer stock solution is accommodated inside the fertilizer stock container 40.

Next, the fertilizer stock solution supply line 50 is the fertilizer stock solution 40 and the liquid mix container 30 so that the fertilizer stock solution can be more easily supplied into the liquid fertilizer shaker 30. The upper portion of the fertilizer stock solution supply line 50 may be tightly connected to the lower portion of the fertilizer stock solution 40 so as to communicate with each other. ) Can be tightly connected to the upper portion.

The fertilizer stock solution supply line 50 supplies the fertilizer stock solution accommodated in the fertilizer stock container 40 to the liquid fertilizer stirring container 30.

Next, one side of the dilution liquid supply line 60 is the other side of the liquid agitation container 40 so that the dilution solution supply line 60 communicates with the inlet line 110 and the liquid agitation container 30, respectively. It may be tightly connected to the lower portion, and the other side of the dilution ratio supply line 60 may be tightly connected to one side of the inflow line 110.

The dilution ratio supply line 60 supplies the dilution ratio in which some supply water and fertilizer stock contained in the liquid ratio agitation container 30 are mixed to the inflow line 110.

The inlet line 110, the supply line 120, the auxiliary inlet line 20, the fertilizer stock solution supply line 50, the dilution solution ratio supply line 60 and the drain line 310 are pipes, hoses It can be made of various types.

2 is a block diagram schematically showing a control unit for controlling the first, second, and third valves according to the detection signal of the water level sensing unit, and FIG. 3 is a schematic diagram showing a state in which the fertilizer stock solution and some supply water are accommodated by liquid agitation of the first embodiment. It is a partial cut-out configuration diagram.

Next, as shown in FIGS. 2 and 3, first, second, and third valves 210, 510, and 610 and a control unit 70, which may be made of solenoid valves, and the like, may be further provided.

The first valve 210 is provided on the auxiliary inlet line 20 to receive power from the power supply 80 under the control of the control unit 70 to open and close the auxiliary inlet line 20.

The second valve 510 is provided in the fertilizer stock solution supply line 50 to receive power from the power supply 80 under the control of the control unit 70 to open and close the fertilizer stock solution supply line 50. have.

The third valve 610 is provided on the dilution ratio supply line 60 to receive power from the power supply 80 under the control of the control unit 70 to open and close the dilution ratio supply line 60. have.

Next, as shown in FIG. 3, a plurality of water level detecting units 410 may be provided at a predetermined interval in the vertical direction of the liquid comparison and agitation 30 on one side or the other side of the liquid agitation and agitation 30. .

The plurality of water level detection units 410 may be formed of various types such as a ball tap, a water level sensor, and the like.

The control unit 70 may control the first, second, and third valves 210, 510, and 610 according to the detection signals of the plurality of water level detection units 410.

The plurality of water level detection units 410 may be composed of first, second, and third water level detection units 411, 412, and 413 formed at regular intervals from the lower portion of the liquid agitating cylinder 30 to the upper direction.

For example, the second valve 510 under the control of the control unit 70 while the pump 10 is forcibly pumping the supply water to the inflow line 110 and supplying it to the supply line 120. The fertilizer stock solution supply line 50 is opened for a predetermined period of time to allow the fertilizer stock solution to be supplied first to the interior of the liquid fertilizer agitator 30.

When the first and second water level detecting units 411 and 412 sequentially detect the fertilizer raw material supplied to the inside of the liquid mixing and stirring container 30, the control unit 70 quantifies the liquid mixing and stirring container 30. The second valve 510 may be closed by determining that the fertilizer raw material is contained.

Then, under the control of the control unit 70, the first valve 210 opens the auxiliary inlet line 20, and some supply water flows into the liquid comparison and agitation 30 through the auxiliary inlet line 20. As the fertilizer raw liquid supplied to the liquid mixing and stirring container 30 can be diluted, the third valve 610 can keep the dilution liquid supply line 60 closed.

The water level of the dilution liquid inside the liquid agitating container 30 may be gradually increased, and the third water level detecting unit 413 may detect a dilution liquid ratio with an increased water level.

When the third water level sensing unit 413 detects the dilution ratio, the first valve 210 may close the auxiliary inflow line 20 under the control of the control unit 70.

As another example, the first valve 210 under the control of the control unit 70 in the state that the pump 10 is forcibly pumping supply water to the inflow line 110 and supplying it to the supply line 120. ) May open the auxiliary inlet line 20 for a certain period of time to allow some supply water to be supplied first to the interior of the liquid agitator 30.

When the first and second water level detecting units 411 and 412 sequentially detect some supply water supplied to the inside of the liquid mixing and stirring container 30, the control unit 70 may return to the liquid mixing and stirring container 30. The first valve 210 may be closed by determining that some supply water of the quantity is accommodated.

Then, by the control of the control unit 70, the second valve 510 opens the fertilizer stock solution supply line 50 so that the fertilizer stock solution to be diluted into the interior of the liquid fertilizer shaker 30 can be supplied. In addition, the third valve 610 may keep the dilution ratio supply line 60 closed.

The water level of the dilution liquid inside the liquid agitating container 30 may be gradually increased, and the third water level detecting unit 413 may detect a dilution liquid ratio with an increased water level.

When the third water level sensing unit 413 detects the dilution ratio, the second valve 510 may close the auxiliary inflow line 20 under the control of the control unit 70.

As another example, as shown in FIG. 3 in the state in which the pump 10 is forcibly pumping supply water to the inflow line 110 and supplying it to the supply line 120, the control unit 70 is controlled. By this, the first valve 210 and the second valve 510 each open the auxiliary inlet line 20 and the fertilizer feedstock supply line 50 to partially supply water to the inside of the liquid fertilizer stir 30. And fertilizer stock.

When the third water level sensing unit 413 detects the mixed dilution ratio by supplying some supply water and fertilizer stock to the interior of the liquid mixing chamber 30, the control unit 70 displays the liquid mixing chamber 30 As a result, the first and second valves 210 and 510 may be closed by determining that the quantitative dilution ratio is accommodated.

FIG. 4 is a partially cut configuration diagram schematically showing a state in which a dilution ratio of a liquid agitation barrel of the first embodiment is supplied to an inflow line.

In addition, as shown in FIG. 4, the third valve 610 opens the dilution ratio supply line 60 for a certain period of time under the control of the control unit 70, and the liquid ratio is stirred by the pump 10. The dilution ratio accommodated in (30) may be pumped together with the feed water to the inlet line 110 and supplied to the supply line 120, and this process may be continuously repeated.

In addition, for example, after the first water level detecting unit 411 does not detect a portion of the dilution liquid remaining inside the liquid mixing chamber 30 or after a certain period of time elapses, the control of the control unit 70 is performed. By this, the first valve 210 and the third valve 610 open the auxiliary inlet line 20 and the dilute liquid ratio supply line 60 for a predetermined period of time, respectively, and remain in the liquid agitation cylinder 30. The dilution solution ratio and the supply water can be supplied to the dilution solution supply line 60.

5 is a block diagram schematically showing a control unit for controlling the first, second, and third valves according to an operating time set in a program.

Next, in order to enable the control unit 70 to control the first, second, and third valves 210, 510, and 610 without the water level sensing unit 410, the first, as shown in FIG. A program 90 such as a timer program for setting the operation time of the 2 and 3 valves 210, 510, and 610 may be provided, and the control unit 70 may control the product according to the operation time set in the program 90. It is possible to control the 1, 2, 3 valves 210, 510, 610.

A program 90 that can be made of a timer program or the like can be provided in the control unit 70, and the first, second, and third valves 210, 510, and 610 respectively set operating times of the valves. It may be composed of three programs (910, 920, 930).

Particularly, a plurality of the second fertilizer stock supply lines 50 are respectively provided in the plurality of fertilizer stock supply lines 50 in order to adjust the mixing ratio of each fertilizer stock solution supplied to the inside of the liquid fertilizer shaker 30 according to the growth state of the crop. The opening and closing times of the valves 510 may be different from each other.

As described above, the liquid fertilizer can be supplied when water is supplied to the soil at regular intervals without storing the diluted liquid ratio in which some supply water and fertilizer stock contained in the liquid fertilizer 30 are mixed for a long period of time. Problems such as the risk of corruption due to long-term storage and precipitation of inorganic comparative components are solved, and the structure is simple, thereby reducing manufacturing cost.

6 is a configuration diagram schematically showing an environment-friendly precision liquid manure support system without residue, which is a second embodiment of the present invention, and FIG. 7 is a partial incision schematically showing a state in which liquid manure stock and some supply water are received through liquid mixing and stirring in the second embodiment 8 is a partial cutaway configuration diagram schematically showing a state in which a dilution ratio of a liquid agitation cylinder of the second embodiment is supplied to an inflow line.

Next, the second embodiment of the present invention, the environment-free precision liquid fertilizer support system without residue, is configured in the same manner as in the first embodiment, but the fertilizer feedstock supply line 50 has a first embodiment as shown in FIGS. 6 to 8. Instead of the second valve 510, a pump 511 that can be made of various types, such as a metering pump, may be provided.

Further, the fertilizer raw liquid container 40 may be located around the outside of the liquid fertilizer container 30 while maintaining a predetermined interval from the liquid fertilizer container 30.

One side of the fertilizer stock solution supply line 50 may be tightly connected and fixed to one lower part or the other lower part of the fertilizer stock solution line 40, and the other side of the fertilizer stock solution supply line 50 may be the liquid fertilizer stirring tube 30 ) Can be tightly connected to the upper portion.

9 is a block diagram schematically showing the first and third valves of the second embodiment and a control unit for controlling the pump.

As shown in FIG. 9, the pump 511, which replaces the second valve 510 of the first embodiment, is applied to the detection signal of the water level sensor 410 and / or the operating time set in the program 90. Accordingly, the fertilizer stock solution inside the fertilizer stock container 40 is forcibly pumped in a quantitative manner under the control of the control unit 70 to be quantitatively supplied to the liquid fermentation container 30.

A plurality of pumps 511 provided in each of the plurality of fertilizer feedstock supply lines 50 to adjust the mixing ratio of each fertilizer feedstock supplied to the inside of the liquid fertilizer shaker 30 according to the growth state of the crop The operating times of may be different from each other.

10 is a configuration diagram schematically showing an environment-friendly precision liquid manure support system without residue, which is a third embodiment of the present invention, and FIG. 11 is a partial incision schematically showing a state in which the dilution liquid ratio of the liquid mixing and stirring in the third embodiment is supplied to the inflow line. It is a block diagram.

Next, the third embodiment of the present invention, an eco-friendly precision liquid manure support system without residue, is configured in the same manner as in the first and second embodiments, and as shown in FIG. 11, a guide line 101 that can be formed in various types such as pipes and hoses ) And residual dilution ratio supply line 102 may be provided.

One side and the other side of the guide line 101 may be tightly connected to the supply line 120 and the inflow line 110, respectively.

One side of the residual dilution liquid supply line 102 can be tightly connected and fixed to the lower portion of the liquid fertilizer stir 30, the other side of the residual dilution liquid supply line 102 is the other side of the guide line 101 It can be tightly connected to the lower part.

12 is a partially cut configuration diagram schematically showing a state in which some of the dilution liquid ratio remaining in the liquid comparison and stirring in the third embodiment is discharged to the residual dilution liquid ratio discharge line together with some supply water.

The outer diameter of the guide line 101 may be formed to be smaller than the outer diameter of the supply line 120, and a part of the supply water supplied to the supply line 120 is the guide line (as shown in FIG. 12). 101) may be introduced into the flow through the guide line 101 to the inflow line 110 at high speed.

The outer diameter size of the portion (P ₁ ) of the guide line 101 to which the other side of the residual dilution liquid supply line 102 is connected and fixed is another first guide to which the other side of the residual dilution liquid supply line 102 is not connected. Line 101 may be formed smaller than the outer diameter of the portion (P ₂ ).

Although not shown in the drawing, as an example, the residual dilution ratio of the inside of the liquid mixing chamber 30 may be determined on one side of the residual dilution liquid supply line 102 according to the detection signal of the first water level detector 411. A pump that is forcibly pumped into the second guide line 102 and supplied into the guide line 101 may be provided.

When the first water level detecting unit 411 does not detect the residual dilution ratio inside the liquid mixing and stirring container 30, the residual dilution liquid ratio supply line 102 is provided under the control of the control unit 70 A pump may force pump the residual dilution ratio inside the liquid agitation cylinder 30 into the residual dilution ratio supply line 102.

On the other hand, as another example, in order to prevent waste of power required to drive the pump provided in the residual dilution liquid supply line 102, the residual dilution liquid ratio supply line on the other side of the residual dilution liquid supply line 102 A fourth valve 200 that may be formed of a solenoid valve or the like that opens and closes 102 by the control of the control unit 70 may be provided.

For example, after the first water level detecting unit 411 does not detect the residual dilution ratio inside the liquid mixing chamber 30 or after a certain time has elapsed, the first valve is controlled by the control unit 70. 210 and the fourth valve 200 may open the auxiliary inlet line 20 and the residual dilution ratio supply line 102 for a certain period of time, respectively.

The guide line 101 connected to the other side of the residual dilution liquid ratio supply line 102 is sucked into the residual dilution liquid ratio supply line 102 by Bernoulli's theorem along with the dilution liquid ratio remaining in the liquid agitation container 30 ) May be introduced into the other side of the inlet into the inlet line 110 together with some supply water and supplied to the supply line 120 by the pump 10.

10; Pump, 20; Auxiliary Inflow Line,
30; Liquid agitation pain, 40; Fertilizer stock,
50; Fertilizer stock supply line, 60; Diluent Ratio Supply Line.

Claims (7)

A pump pumping the supply water through the inflow line and supplying it to the supply line;
An auxiliary inflow line connected to the supply line and into which some supply water supplied to the supply line flows;
A fertilizer stock passage through which the fertilizer stock is accommodated;
A fertilizer stock solution supply line for supplying a fertilizer stock solution accommodated in the fertilizer stock container;
A liquid comparison and stirring in which some supply water flowing through the auxiliary inflow line and fertilizer raw material supplied through the fertilizer stock supply line are accommodated and mixed;
A dilution ratio supply line for supplying a dilution ratio in which some supply water and fertilizer stock contained in the liquid agitation barrel are mixed to the inflow line;
A guide line having one side and the other side respectively connected to the supply line and the inflow line;
Residual dilution liquid supply system that is connected to the liquid fertilizer and the other side is connected to the other side of the guide line; environmentally friendly precision liquid manure support system comprising a.
According to claim 1,
A first valve for opening and closing the auxiliary inlet line;
A second valve that opens and closes the fertilizer feedstock supply line;
A third valve that opens and closes the dilution ratio supply line;
A fourth valve that opens and closes the residual dilution ratio supply line;
And a control unit for controlling the first valve, the second valve, the third valve, and the fourth valve.
According to claim 1,
A first valve for opening and closing the auxiliary inlet line;
A pump provided in the fertilizer feedstock supply line;
A third valve that opens and closes the dilution ratio supply line;
A fourth valve that opens and closes the residual dilution ratio supply line;
And a control unit for controlling the first valve, the pump, the third valve, and the fourth valve.
According to claim 1,
An environment-friendly precision liquid manure support system without residue, characterized in that a plurality of water level detecting units are provided at regular intervals in the vertical direction inside the liquid mixing chamber.
According to claim 2,
A program for setting operation times of the first valve, the second valve, the third valve, and the fourth valve is provided,
The control unit controls the first valve, the second valve, the third valve, and the fourth valve according to the operating time set in the program, and the eco-friendly precision liquid manure support system without residue.
According to claim 3,
A program for setting operation times of the first valve, the third valve, and the fourth valve is provided,
The control unit controls the first valve, the pump, the third valve, and the fourth valve according to the operating time set in the program, and the eco-friendly precision liquid manure support system without residue. delete

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