KR101756439B1 - Liquid fertilizer pufification system - Google Patents

Abstract

The present invention relates to a liquid fertilizer purifying system for separating liquid manure into a sludge layer and a supernatant layer by a sedimentation facility and filtering the scum remaining in the supernatant separated by the filtration facility so as to be made into a liquid fertilizer.
The liquid fertilizer purifying system according to an embodiment of the present invention includes a first storage tank for storing composted liquid manure, a second storage tank for storing the liquid manure stored in the first storage tank, a first conveying pump for separating the liquid manure into a sludge layer and an upper water layer, A second storage tank for receiving the supernatant discharged from the sedimentation facility and storing therein the supernatant discharged from the sedimentation facility; and a second reservoir for storing the supernatant stored in the second reservoir by the second transfer pump and remaining in the supernatant And a third storage tank for receiving the supernatant filtered by the scum from the filtration system and storing the supernatant therein.

Description

Liquid fertilizer pufification system

The present invention relates to a liquid fertilizer purifying system, and more particularly, to a liquid fertilizer purifying system that separates a liquid manure into a sludge layer and a supernatant layer by a sedimentation facility, filters the scum remaining in the supernatant separated by the filtration facility, To a liquid fertilizer purification system.

Generally, when used as livestock manure in livestock farming to produce high quality compost or livestock for use in cultivated soil, it is possible to improve the chemical properties of soil and improve the soil properties of agricultural land in Korea, which is low in organic matter and aged with acid fertilizer It becomes a valuable resource to do.

If these livestock manures are discharged without being treated as livestock wastewater, it will be a high-concentration pollutant with a higher pollutant load than domestic wastewater. Therefore, not only will it become a source of water pollution, but also facilities and treatment costs Therefore, it is difficult.

As such, there is a growing concern about environmental pollution. Nowadays livestock manure is being produced as liquid fertilizer so that it can be recycled as a precious resource.

These liquid fertilizers are diluted powdery or granular fertilizers. They are also called liquid fertilizers, and they are often used for the management of lawns in golf courses.

However, if harmful substances generated from such liquid fertilizer are sprayed on the golf course without filtration, the harmful components are absorbed by the plants as they are, so odor is generated in the golf course, and the liquid fertilizer is not smoothly sprayed There is a problem.

In addition, since the liquid fertilizer is produced by fermenting / aging the various mixed raw materials for a long period of time, there is a problem that not only the time for removing the foreign substances is prolonged, but also equipment cost for producing the liquid fertilizer is high.

Korean Patent No. 0291855

The present invention provides a liquid fertilizer purifying system for separating liquid manure into a sludge layer and a supernatant layer by a sedimentation facility and filtering the scum remaining in the supernatant separated by the filtration facility to produce liquid fertilizer .

According to an aspect of the present invention, there is provided a liquid fertilizer purifying system including a first storage tank for storing composted liquid manure, a second storage tank for storing the liquid manure stored in the first storage tank, A second storage tank for receiving the supernatant discharged from the sedimentation facility and storing the supernatant therein, and a second storage tank for storing the supernatant stored in the second storage tank, And a third storage tank for receiving a scum filtered supernatant from the filtration system and storing the scum filtered from the filtration system.

The sedimentation facility includes a sedimentation tank formed at one side with a supply nozzle for introducing the liquid manure stored in the first storage tank and having a discharge nozzle for discharging the supernatant separated from the liquid manure, An induction guide part installed in the inner space of the sedimentation tank to reduce the flow rate of the liquid manure introduced through the supply nozzle; and a control unit, which, when liquid manure is stored in a predetermined amount in the sedimentation tank and is separated into a sludge layer and a supernatant layer by gravity, A manure separation unit for inducing sedimentation of sludge suspended in the supernatant layer and installed in the sedimentation tank internal space so that the separated supernatant is overflowed; and a manure separation unit installed at one side of the manure separation unit to communicate with the discharge nozzle, And a trough for guiding the discharged supernatant to be discharged through the discharge nozzle The.

In addition, the manure separation unit includes a support frame supported by the inner wall of the sedimentation tank, a supporting frame formed in a hexahedron shape having four sides opened at its both sides and fixed to the upper end of the fixed frame, And a swash plate coupled to one side of the overflow water channel so as to be disposed in the inner space of the support frame. The overflow water channel is fixed to the upper end of the support frame so that one end thereof is inserted into the trough.

In addition, the overflow water is characterized in that a plurality of V-shaped grooves formed at regular intervals along the longitudinal direction are formed.

In addition, the swash plate is formed by extending a hook having an inverted U shape at its upper end so as to be detachably connected to one side of the overflow water.

In addition, the filtration apparatus may include a supply nozzle for receiving supernatant stored in the second reservoir, the supernatant reservoir having a cylindrical shape with an upper side opened, a discharge nozzle for discharging the supernatant filtered by the scum is formed on the other side, A cover which is detachably coupled to the upper side of the housing so as to close the inner space of the housing; and a cover which is coupled to the support shaft at an inner side of the housing, And a microfilter for filtering the scum remaining in the supernatant supplied through the microfilter.

In addition, the filtration system transmits a control signal for operating the second transfer pump when the water level is equal to or higher than a preset level in the housing, and transmits a control signal for stopping the second transfer pump when the water level is below a preset water level And a water level sensor for detecting the level of the water.

The microfilter includes a core in which an upper portion and a lower portion are opened and a plurality of through holes are formed in an outer periphery of the microfilter, a yarn wound around the outer periphery of the core, .

As described above, according to the present invention, the liquid-phase manure is separated into the sludge layer and the supernatant layer by the sedimentation facility, and the scum remaining in the supernatant separated by the filtration facility is filtered so that the environment- And thus the manufacturing cost can be reduced.

1 is a schematic diagram of a liquid fertilizer purifying system according to an embodiment of the present invention;
2 is a plan view schematically showing a settling facility in a liquid fertilizer purifying system according to an embodiment of the present invention;
3 is a side cross-sectional view of AA of the settling apparatus shown in FIG. 2;
4 is a side cross-sectional view of the BB of the settling facility shown in FIG. 2;
Fig. 5 is a perspective view showing the relationship between the swirling plate and the swirling flow path of the manure separation unit in the settling apparatus shown in Fig. 2; Fig.
6 is a cross-sectional view schematically showing a filtration facility in a liquid fertilizer purifying system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, which are intended to illustrate the present invention in a manner that will be readily apparent to those skilled in the art, And this does not mean that the technical idea and scope of the present invention are limited.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and like parts are denoted by similar reference numerals throughout the specification.

Also, when a part is referred to as " including " an element, it does not exclude other elements unless specifically stated otherwise.

The upward-flow type liquid fertilizer purifying system according to an embodiment of the present invention includes a first storage tank 100 storing a composted liquid manure, and a second feed pump 200 supplying a liquid manure stored in the first storage tank 100 A second sludge storage tank 400 for receiving the supernatant discharged from the sedimentation equipment 300 and storing the same in the sludge storage tank 300, 2 receives the supernatant stored in the second storage tank 400 by the transfer pump 500 and receives the supernatant filtered by the scum from the filtration facility 600 and the filtration facility 600 for filtering out the scum remaining in the supernatant, And a third reservoir 700 for storing the liquid.

Here, the first storage tank 100 stores the liquid manure that is composted therein so that the liquid manure that has been composted is supplied to the settling facility 300 by the first transfer pump 200.

The sedimentation facility 300 receives the liquid manure stored in the first storage tank 100 by the power of the transfer pump 200 and separates it into a sludge layer and a supernatant layer by gravity and separates the supernatant into a second reservoir 400 The induction guide unit 320, the manure separation unit 330, and the trough 340.

Specifically, the upper part of the sedimentation tank 310 is opened, the upper side of one side wall is inclined downward toward the other side, and the lower side of the inner space has an inverted triangle shape so that the sludge separated from the liquid manure can be collected on the bottom side .

In the settling tank 310, a supply nozzle 311 is formed on one upper side so that the liquid manure flows into the inner space. When the liquid manure is filled in the inner space, the discharge nozzle 312 Are protruded from the upper side of the other side.

That is, when the liquid manure supplied through the supply nozzle 311 is filled up to the height at which the discharge nozzle 312 is located, the supply of the liquid manure and the discharge of the supernatant separated from the liquid manure are simultaneously performed, The liquid manure is not flooded but always maintained at a constant water level.

In addition, a drain 313 is formed in one side of the sedimentation tank 310 so that the sludge layer separated from the liquid manure submerged on the bottom surface can be discharged to the first storage tank 100.

That is, since the sludge layer separated from the liquid manure through the drain 313 is discharged to the first storage tank 100, the sludge layer can not be accumulated in the sedimentation tank 310 and the sludge can be reused as the liquid manure There is an advantage.

The induction guide part 320 is installed adjacent to the supply nozzle 311 in the inner space of the settling tank 310. The guide guide part 320 is introduced into the settling tank 310 through the supply nozzle 311 Thereby reducing the flow rate of the liquid manure.

Concretely, the induction guide unit 320 includes a curved plate 321 having a U-shaped curved surface, both ends of which are vertically fixed to the inner wall of the settling tank 310 having the supply nozzle 311, And a mesh member 322 which is formed so as to intersect in the vertical and horizontal directions and is disposed on both open sides of the curved plate 321.

That is, the curved plate 321 has a structure in which, when the liquid manure is introduced through the supply nozzle 311, the liquid manure hits the inner side and then the divided liquid is discharged to both sides, The sludge layer separated by the gravity and the supernatant layer can be smoothly supplied into the sedimentation tank 310 without flowing through the sludge layer.

And the net member 322 catches the sludge mixed in the liquid manure when the liquid manure is split on both sides by the curved plate 321, thereby inducing the sludge particles to be crushed. Thereby, there is an advantage that the sludge particles flow into the sedimentation tank 310 in a state where the sludge particles are smaller than the grid pattern formed on the mesh member 322, thereby facilitating the filtration treatment of the liquid manure.

The manure separation unit 330 is disposed above the inner space of the sedimentation tank 310. The manure separation unit 330 is provided in the sedimentation tank 310 with a predetermined amount of liquid manure being filled in the inner space of the sedimentation tank 310, And the supernatant layer, the sludge suspended in the supernatant layer is settled and the separated supernatant is floated over the trough 340.

Specifically, the manure separation unit 330 includes a supporter 331 disposed on the upper side of the inner space of the sedimentation tank 310, a supernatant water path 332 in which a plurality of supporters 331 are disposed, And an inclined plate 333 coupled to one side of each of the overflow channels 332 so as to be inclined downward in a direction in which the overflow channels 332 are formed.

The support frame 331 includes a fixed frame 331a fixed to both inner side walls of the settling tank 310 in which the supply nozzle 311 and the discharge nozzle 312 are not formed, And a support frame 331b which is fixed to the upper portion of the fixed frame 331a.

At this time, when the liquid manure is separated into the sludge layer and the supernatant layer by the gravity in the inner space of the sedimentation tank 310, the supporter 331 preferably supports the supernatant located at the uppermost end of the supporter 331 at a height overflowing the overflow water path 332.

The overflow channel 332 is disposed in the same direction as the longitudinal direction of the support platform 331 at the upper portion of the support frame 331b and serves to provide a path for supplying the liquid to the trough 340 when the supernumerary flow rate of the liquid manure overflows do.

A plurality of troughs 332a having a V-shape are formed at predetermined intervals along the longitudinal direction at one side of the overflow channel 332. The troughs 332a are formed in the inner space of the settling tank 310, And serves to guide the separated supernatant into the overflow channel 332 when it is continuously supplied.

It is preferable that one end of the overflow path 332 is arranged to be drawn into one side of the trough 340 to flow smoothly to the side of the trough 340 when a supernatant of the liquid manure flows through the throughflow groove 332a.

In addition, the swash plate 333 induces the sludge suspended in the supernatant layer to settle down to the bottom along the slope when the liquid manure is filled in the inner space of the sedimentation tank 310 and is separated into the sludge layer and the supernatant layer by gravity. And a ring 333a bent in an inverted U shape is formed in the upper part to open the lower side.

That is, the annular plate 333 is extended to the upper portion of the swash plate 333 so that the swash plate 333 can be coupled to one side of the overflow channel 332, preferably the side where the louver groove 332a is not formed And when the swash plate 333 is to be replaced or repaired, there is an advantage that it can be easily separated.

A trough 340 having a rectangular box shape with an open top is fixed to one side of the support frame 331b of the support table 331 so that the trough 340 can communicate with the discharge nozzle 312 And the longitudinal direction is arranged in a direction in which the supply nozzle 311 and the discharge nozzle 312 are formed.

That is, the trough 340 forms a path for transmitting the supernatant of the liquid manure supplied from the overflow water path 332 to discharge the supernatant of the liquid manure through the discharge nozzle 312.

The supernatant discharged from the settling facility 300 is stored in the second storage tank 400. The second storage tank 400 supplies the supernatant stored by the power of the second transfer pump 500 to the filtration facility 600 .

Meanwhile, the filtration facility 600 receives the supernatant stored in the second reservoir 400 by the power of the second transfer pump 500, and drains the scum remaining in the supernatant to the third reservoir 700 A housing 610, a cover 620, and a microfilter 630.

Specifically, the housing 610 serves to temporarily store the supernatant stored in the second reservoir 400 so that the scum remaining in the supernatant can be filtered by the micro-filter 630, .

In this housing 610, a supply nozzle 611 for receiving the supernatant stored in the second reservoir 400 is protruded outward and a supernatant filtered by the scum by the microfilter 630 is provided on the other side of the housing 610 A discharge nozzle 612 for discharging to the third reservoir 700 is formed on the other side and a support shaft 613 for fixing the micro filter 630 is formed in the inner space upward from the bottom surface.

A pressure gauge 614 for controlling the operation of the second transfer pump 500 is mounted on the housing 610.

The pressure gauge 614 transmits a control signal for stopping the second transfer pump 500 when the inner pressure of the housing 61 rises above a predetermined pressure because the supply amount of the equalizing water is greater than the capacity of the housing 61, And transmits a control signal for operating the second transfer pump 500 when the internal pressure of the housing 61 is lowered below a predetermined pressure.

Accordingly, when the inner pressure of the housing 610 is increased, the supply of the supernatant is stopped, and when the inner pressure of the housing 610 is lowered, the supernatant is supplied.

The cover 620 is detachably coupled to the upper portion of the housing 610 to seal the inner space of the housing 610 so that the supernatant supplied to the inside of the housing 610 does not overflow the outer portion of the housing 610 .

The micro filter 630 filters the scum remaining in the supernatant in the housing 610 when the supernatant stored in the second reservoir 400 is supplied into the housing 610. The micro filter 630 filters the scum remaining in the supernatant in the housing 610, .

The core 631 is formed in a cylindrical shape having open ends at both ends and is coupled to be fitted to the support shaft 613. A plurality of through holes 631a are formed in the outer circumferential surface of the core 631 so as to freely flow the supernatant introduced into the housing 610, Are formed at regular intervals.

The yarn 632 is wound around the outer periphery of the core 631 to filter the scum remaining in the supernatant, and the winding interval is denser as it goes from the outside to the inside. Accordingly, when the upper portion of the housing 610 is filled with the supernatant, there is an advantage that it can be effectively filtered regardless of the particle size of the scum remaining in the supernatant.

At this time, the material of the yarn 632 is not particularly limited, but it is preferable to have a cotton fiber material so that the scum can be smoothly adsorbed.

The supernatant filtered by the filtration facility 600 is supplied to the third reservoir 700. The third reservoir 400 stores the supernatant supplied from the filtration facility 600 to be used as liquid fertilizer .

100: first storage tank
200: 1st feed pump
300: Settling facility
400: second storage tank
500: Second transfer pump
600: Filtration equipment
700: third storage tank

Claims (8)

A first reservoir for storing composted liquid manure;
A sedimentation facility for separating the liquid manure stored in the first storage tank by the first transfer pump into a sludge layer and a supernatant layer and discharging the supernatant to the outside;
A second reservoir for receiving the supernatant discharged from the sedimentation facility and storing the supernatant therein;
A filtration facility for receiving the supernatant stored in the second reservoir by the second transfer pump and filtering out scum remaining in the supernatant; And
A third reservoir for receiving supernatant filtered by the scum from the filtration facility and storing the supernatant therein; Lt; / RTI >
Wherein the sedimentation facility comprises a sedimentation tank formed at one side with a supply nozzle for introducing the liquid manure stored in the first storage tank and having a discharge nozzle for discharging the supernatant separated from the liquid manure, An induction guide part installed in the inner space of the settling tank to reduce the flow rate of the liquid manure introduced through the feed nozzle; and a control part which, when the liquid manure is stored in a predetermined amount in the settling tank and is separated into a sludge layer and an upper water layer by gravity, And an upper water level detector installed at one side of the lower side of the manure separation unit to communicate with the discharge nozzle, wherein the lower side of the upper side And a trough for guiding the gas to be discharged through the discharge nozzle,
Wherein the filtration device is formed in a cylindrical shape with an upper side opened and a supply nozzle for receiving supersonic water stored in the second reservoir is formed at a lower side of one side and a discharge nozzle for discharging the supersonic water filtered by the scum is formed on the other side, A cover which is detachably coupled to the upper side of the housing so as to close the inner space of the housing; and a cover which is coupled to the support shaft at the inside of the housing, And a microfilter for filtering the scum remaining in the supernatant.
delete The method according to claim 1,
Wherein the manure separation unit comprises a fixed frame supported by an inner wall of the sedimentation tank, a supporting frame formed in a hexahedron shape having four sides and having a support frame fixedly seated on an upper end of the fixed frame,
An overflow channel fixed to an upper end of the support frame so that one end thereof is drawn into the trough,
And a swash plate coupled to one side of the overflow water channel so as to be disposed in an inner space of the support frame.
The method of claim 3,
Wherein a plurality of V-shaped grooves formed in the V-shaped groove are formed at regular intervals along the length direction of the overflow water.
The method of claim 3,
Wherein the swash plate is formed by an elongated ring formed in an inverted U shape at an upper end so as to be detachably connected to one side of the overflow water.
delete The method according to claim 1,
A pressure gauge for transmitting a control signal for stopping the second feed pump when the supernatant is supplied at a predetermined pressure or higher and for transmitting a control signal for operating the second feed pump when the supernatant is supplied at a pressure lower than a predetermined pressure, Wherein the liquid fertilizer purification system comprises:
The method according to claim 1,
The microfilter includes a cylindrical core having an upper portion and a lower portion opened and having a plurality of through holes penetrating the outer periphery,
And a yarn wound around the outer periphery of the core, the yarn having a tight winding interval from the outer side to the inner side.

Images