KR20160102677A - Livestock manure aekbihwa facility structure - Google Patents

Abstract

The present invention relates to a structure of a livestock manure liquid fertilizer producing facility. Avoiding a method to store livestock manure for a long period of time, the structure of the present invention removes bad smell of the livestock manure and color of the urine generated on the day, and minimizes a storage period of a liquefied fertilizer. The structure of a livestock manure liquid fertilizer producing facility can treat the livestock manure generated on the day by producing a liquid fertilizer using the livestock manure. More particularly, the structure of a livestock manure liquid fertilizer producing facility comprises: a raw water tank; a contact precipitation tank; an aeration tank; a trickling filter tank; and a liquefied fertilizer storage tank.

Description

Livestock manure aekbihwa facility structure [0002]

The present invention relates to a method for removing livestock manure from a long-term storage method, eliminating the odor of the livestock manure produced on that day, removing the coloring matter of the urine, and minimizing the storage period of the liquid manure, The present invention relates to a livestock manure liquefaction facility structure.

In general, resource reclamation of livestock manure is the industry's and farm's biggest challenge for sustainable livestock industry.

Fortunately, many facilities and compost manufacturing techniques have been developed to reduce environmental pollution such as heavy metal pollution and odor.

In addition, as a result of product development and technology for storing and liquefying the product for a certain period of time in the unit of the farm, and the utilization rate of the farm is increased, it is becoming a new farming method for the livestock industry.

The method of livestock manure liquefaction includes the simple storage of manure for 6 months, the injection of microbial agent and air into the manure, and the separation of the liquid from the manure to separate only the liquid.

In any case, the problem is to fully ferment the liquid to reduce the odor and increase the effect.

If you simply feed livestock farming without proper fermentation to treat livestock manure, it will not only ruin the farming for one year but also cause bad effects on the soil, lowering the utilization rate and hindering the livestock industry.

In the meantime, it has been treated with marine dumping, etc. Now, as a problem of self-treatment, manure must be stored in a storage tank for 6 months. However, the facility capacity is large and the problem of odor is not solved.

In addition, there is a method of treating the manure by chemical treatment. This method is to save the malodor reducing agent to the housing slurry for 3 months after 3 months, and then the livestock farmers also need the liquid tank and the liquid spraying equipment.

In addition, there is a high-temperature aerobic treatment method, which is to add an odor control agent and a microorganism preparation to the feed, to feed livestock and to reduce the amount of the liquid production by using the fermentation tank and the aeration, Has been highlighted.

The good liquid has the problem of eliminating odor, minimizing the color of urine, and minimizing the storage period.

Korean Registered Utility Model Registration No. 20-0386512

The present invention relates to a method for removing livestock manure from a long-term storage method, eliminating the odor of the livestock manure produced on that day, removing the coloring matter of the urine, and minimizing the storage period of the liquid manure, The present invention relates to a livestock manure liquefaction facility structure.

To achieve the above object, according to the present invention, there is provided a liquefied petroleum gasifier comprising: a raw water tank in which raw water of an animal manure is stored therein, and an inner livestock manure is transferred to a solid-liquid separator through a feed unit for raw water; A contact sedimentation tank in which urine discharged from the solid-liquid separator is stored therein and which transports the sludge precipitated in the lower side to the source water tank; An aeration tank in which urine supplied from the contact settling tank is stored therein and which removes odor and pigment of urine stored therein through a fluidized bonus material for treating wastewater and a solid carrier for treating wastewater; A water spray water storage tank for storing urine supplied from the aeration tank and for removing odor and pigment of urine stored therein; And a liquid storage tank for storing liquid stored in the spray water storage tank and supplying liquid stored in the liquid storage tank to the aeration tank.

It is preferable that a pumping tank is provided between the aeration tank and the water spraying water storage tank and between the water spraying water storage tank and the liquid storage tank to supply urine to the inside of the water spraying water storage tank and to supply the liquid storage into the liquid storage tank.

The livestock manure is preferably supplied to the inside of the raw water tank through a raw water supply line formed at one side of the raw water tank.

The feed unit for the raw water supply may include a pump provided inside the raw water tank; And a transfer line provided between the pump and the solid-liquid separator.

It is also preferable that an inclined surface is formed on the inner lower side of the raw water tank and the inclined surface is inclined downward toward the inside of the raw water tank from the upper side of the inclined surface toward the lower side of the inclined surface.

Furthermore, it is preferable that a conveying unit including an air lift pump for conveying the sludge settled in the contact settling tank to the bottom of the contact settling tank to the raw water tank is further provided.

In addition, a partition wall is formed at an inner middle portion of the contact sedimentation tank and extends vertically inwardly of the contact sedimentation tank from the upper side of the contact sedimentation tank to a predetermined length to partition the interior of the contact sedimentation tank, It is preferable that the wood chip layer is provided on the other side space of the contact settling tank among the one side space and the other side space formed on the inner side and the inner side of the contact settling tank.

In addition, it is preferable that an inclined surface is formed inside the contact sedimentation tank, and the inclined surface is inclined downward toward the inside of the contact sedimentation tank from the upper side of the inclined surface toward the lower side of the inclined surface.

In addition, the aeration tank includes a first aeration tank in which urine supplied from the contact settling tank is stored therein, a floating bonnet for treating the wastewater is floated in urine stored therein, and an oxygen supply unit is provided in an inner lower side; A second aeration tank in which urine supplied from the first aeration tank is stored therein, floating wastewater treatment fluid is floated in urine stored therein, and an oxygen supply unit is provided in an inner lower side; And a third aeration tank in which the urine supplied from the second aeration tank is stored therein, the solid carrier for treating the wastewater is provided therein, and the oxygen supply unit is provided on the inner lower side.

Here, urine is sequentially supplied to the inside of the first, second and third aeration tanks through the supply line for the aeration tank provided in the first aeration tank, the inside of the second aeration tank and the inside of the third aeration tank desirable.

A partition wall is formed inside the third aeration tank and extends vertically inwardly from the upper side of the third aeration tank to a predetermined length in the downward direction of the third aeration tank to partition the interior of the third aeration tank, It is preferable that the solid carrier for treating wastewater is provided in one space of the third aeration tank among the one space and the other space formed on the inner side and the inner side of the third aeration tank, respectively.

The pumping tank may include a first pumping tank provided between the aeration tank and the water spraying water storage tank; And a second pumping tank provided between the water spraying water storage tank and the liquid storage tank, wherein urine stored inside the aeration tank through a supply line for a first pumping tank formed at an upper side of the inner side of the first pumping tank, Urine stored in the first pumping tank is supplied to the inside of the water spraying water bath through the first and second pumping tank feed units provided inside the first and second pumping baths, A first pumping tank pump provided inside the first pumping tank, the first pumping tank transferring unit being provided inside the liquid storage tank; And a transfer line for a first pumping tank for transferring urine forcedly pumped by the pump for the first pumping tank to the inside of the water spraying water tank, A pumping pump; And a second pumping tank transfer line for transferring the forced pumping liquid to the inside of the liquid storage tank by the pump for the second pumping tank.

Furthermore, the liquid stored in the liquid storage tank is supplied to the aeration tank through the liquid storage tank transfer unit, and the transfer unit for the liquid storage tank is provided in the lower side of the liquid storage tank; And a transfer line for a liquid storage tank for transferring the liquid pumped by the liquid storage tank pump to the aeration tank.

In addition, it is preferable that the floating bonnet for floating the wastewater stored in the aeration tank is a microorganism for purifying urine, and a plurality of wood chips and a plurality of styrofoam are contained therein.

It is preferable that 60 to 80 parts by weight of the wood chips and 20 to 40 parts by weight of the styrofoam are contained in the flowable bonnet for treating the wastewater.

It is preferable that the length of the wood chip is 3 to 5 mm, the length of the wood chip is 2 to 3 mm, and the thickness of the wood chip is 1 to 2 mm.

The outer diameter of the styrofoam is preferably 10 to 15 mm.

The outer diameter of the fluidized bonus material for treating the wastewater is preferably 50 to 100 mm.

In addition, it is preferable that the flow bonus material for the wastewater treatment comprises a mesh net formed with a plurality of cilia.

In addition, it is preferable that the flowable bonus material for treating the wastewater containing the styrofoam and the wood chip is filled in a volume ratio of 10 to 15 by volume based on 100 volume of urine.

The present invention relates to a method for removing livestock manure from a long-term storage method, eliminating the odor of the livestock manure produced on that day, removing the coloring matter of the urine, and minimizing the storage period of the liquid manure, There is an effect.

FIG. 1 is a cross-sectional view schematically showing a structure of an animal husbandry livestock pumping facility, which is an embodiment of the present invention,
2 is a cross-sectional view schematically showing the flow of urine,
3 is a cross-sectional view schematically showing a fluidized bonus material for wastewater treatment,
4 is a partially enlarged perspective view enlarging a wood chip accommodated in the fluidized bonus material for wastewater treatment.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

1 is a cross-sectional view schematically showing a structure of an animal husbandry livestock pumping facility, which is an embodiment of the present invention, and Fig. 2 is a cross-sectional view schematically showing a flow of urine.

As shown in FIGS. 1 and 2, the structure of an animal husbandry livestock pumping facility, which is one embodiment of the present invention, includes a raw water tank 10, a contact settling tank 20, an aeration tank 30, a sprinkling water storage tank 40, ).

First, the raw water 3 of the livestock manure is stored in the raw water tank 10 at a predetermined height.

The livestock manure stored in the raw water tank 10 is conveyed to the solid-liquid separator 120 located in the upper direction of the raw water tank 10 through the water feeding unit 110.

Next, the contact settling tank 20 is provided on the other side opposite to the one side of the raw water tank 10.

The urine (4) discharged from the solid-liquid separator (120) is stored inside the contact sedimentation tank (20) at a predetermined height.

The urine drainage line 121, which may be a pipe or a hose for discharging the urine 4 discharged from the solid-liquid separator 120 to the inside of the contact sedimentation tank 20, .

The upper portion of the urine drainage line 121 is connected to the lower portion of the other side of the solid-liquid separator 120, and the lower portion of the urine drainage line 121 is connected to the contact- Can be drawn into the inside of the upper part of the upper portion of the body 20 at a certain depth.

The sludge settled in the lower portion of the contact settling tank 20 is returned to the inside of the raw water tank 10.

Next, the aeration tank (30) is provided on the other side opposite to the one side of the contact sedimentation tank (20).

In the aeration tank 30, the urine 4 supplied from the contact sedimentation tank 20 is stored at a predetermined height.

The aeration tank 30 is provided therein with a flow bonus material 31 for wastewater treatment for removing odors of the urine 4 stored in the aeration tank 30 and urine 4 The solid carrier 32 for treating wastewater for removing the coloring matter of the urine 4 stored in the aeration tank 30 is provided with a solid carrier 32 for wastewater treatment, Since it is a matter known through Registration No. 10-1261365, detailed description will be omitted.

Next, the water spray water storage tank 40 is provided in the other side opposite to the one side of the aeration tank 30.

An activated carbon layer or a char layer 410 and a wood chip layer 420 for sequentially removing malodor and coloring matter of the urine 4 stored in the water spraying water bath 40 are sequentially disposed inside the water spraying water bath 40, It can be stacked up and down.

In order to prevent the wood chip layer 420 from being damaged and deformed by the urine 4 over time, the wood chip layer 420 is preferably made of cedar resistant to moisture.

In order to prevent the wood chip layer 420 from floating, a support member, which may be formed of a net or the like, is horizontally provided on the upper part of the wood chip layer 420 and the lower part of the wood chip layer 420 .

Next, the liquid storage tank 50 is provided on the opposite side of one side of the water spray storage tank 40.

In the liquid storage tank 50, the liquid storage tank 5 supplied from the water spray storage tank 40 is stored at a predetermined height.

Although not shown in the drawing, a pipe, a hose, and the like for discharging the liquid pot 5 stored in the liquid pot storage tank 50 to the outside of the liquid pot storage tank 50 is provided at the other side of the other side of the liquid pot storage tank 50 A liquid discharge line which can be made of a liquid; And an on-off valve provided on the liquid discharge line to open and close the liquid discharge line.

The liquid pot (5) stored in the liquid pot storage tank (50) can be supplied to the inside of the aeration tank (30).

Next, as shown in FIGS. 1 and 2, between the aeration tank 30 and the water spraying water storage tank 40 and between the water spraying water storage tank 40 and the liquid storage tank 50, And a pumping tank 60 for supplying urine 4 and supplying the liquid mixture 5 into the liquid storage tank 50, respectively.

Next, the raw manure may be supplied to the inside of the raw water tank 10 through a raw water supply line 130 formed of a pipe, a hose, or the like formed on the inner side of the raw water tank 10.

The raw water supply line 130 may include a first raw water supply line 131 and a second raw water supply line 132.

The feed line 131 for the first water tank may be horizontally disposed on the upper side of the inner side of the source water tank 10 and the livestock manure may be supplied to the inside of the first water tank feed line 131.

The second water supply line 132 is communicated with the first water supply line 131 so that the second water supply line 132 has a predetermined length in the downward direction of the inside of the original water tank 10 from the inside of the original water tank 10 Can be vertically extended.

The solid component of the livestock manure can be more easily precipitated to the inner lower side of the raw water tank 10 through the second raw water supply line 132 of the raw water supply line 130.

The water feeding unit 110 includes a pump 111 and a transfer line 112 formed between the pump 111 and the solid-liquid separator 120, such as a pipe, a hose, .

The pump 111 is provided in an inner lower portion of the circulating water tank 10 so as to pump the livestock manure stored in the circulating water tank 10 forcibly.

The lower portion of the transfer line 112 may be connected to the upper portion of the pump 111 and the upper portion of the transfer line 112 may be connected to the upper portion of the circulating water tank 10, As shown in FIG.

Next, in order to more easily precipitate the solid component of the livestock manure under the inside of the raw water tank 10, an annular inclined surface 140 or an inner surface of the raw water tank 10, An inclined surface 140 may be formed on one inner lower side of the main body 10 and on the other inner lower side of the other side of the water tank 10.

The inclined surface 140 may be inclined downward toward the inside of the water tank 10 from the upper portion of the inclined surface 140 toward the lower portion of the inclined surface 140.

Next, the contact settling tank 20 may be provided with a carry section 210 for transferring the sludge settled in the contact settling tank to the inside of the raw water tank 10.

A structure having a mechanism for sending compressed air at the lower end of the pumping pipe 211 and generating a bubble in the pumping pipe 211 to pump the pumping pipe 210 due to the difference in specific gravity between the pumping water It is easy to use and there is no trouble, and a convenient air lift pump can be used.

When the error lift pump is used as the carry section 210, the upper part of the pumping pipe 211 of the air lift pump is connected to the upper part of the contact precipitating tank 20 through the upper part of one side of the contact sedimentation tank 20, And may be horizontally extended to a predetermined length in the direction of the raw water tank 10 while being exposed at a predetermined length.

One side of the upper part of the pumping water pipe 211 of the air lift pump can be drawn in a predetermined length into the water tank 10 through the upper part of the water tank 10 through a straight pipe.

Next, in the inner middle portion of the contact sedimentation tank 20, there is formed in the inner portion of the contact sedimentation tank 20 a section that vertically extends in the downward direction inside the contact sedimentation tank 20, A wall 220 may be formed.

The contact settling tank 20 and the contact settling tank 20 are formed in one side space 230 and the other side space 240 formed on one side of the contact settling tank 20 and the other side of the contact settling tank 20 on the partition wall 220, The transporting part 210 may be provided in one side space 230 and the wood chip layer 250 may be provided in the other side space 240 of the contact sedimentation bath 20,

Although not shown in the drawing, a support member, which may be formed of a mesh or the like, may be horizontally provided on the upper portion of the wood chip layer 250 and the lower portion of the wood chip layer 250.

The urine 4 that has passed through the lower part of the partition wall 220 can be raised while passing through the wood chip layer 250 and overflowed into the aeration tank 30. At this time, The individual particle size of the wood chip layer 250 is formed to be about 7 to 9 mm so that some of the sludge contained in the passing urine 4 is blocked by the wood chip layer 250 and can not pass through the wood chip layer 250 .

Next, an annular inclined surface 260 or an annular inclined surface 260 is formed on the inner lower side of the contact sedimentation tank 20, so that the sludge contained in the urine 4 can be more easily precipitated below the contact sedimentation tank 20 An inclined surface 260 may be formed on an inner lower side of the contact sedimentation tank 20 and an inner lower side of the other side of the contact sedimentation tank 20, respectively.

The inclined surface 260 may be inclined downward toward the inside of the contact sedimentation tank 20 from the upper portion of the inclined surface 260 toward the lower portion of the inclined surface 260.

Next, the aeration tank 30 may include a first aeration tank 310, a second aeration tank 320, and a third aeration tank 330.

The first aeration tank 310 may be provided on the other side of the contact sedimentation tank 20 opposite to the one side.

The urine (4) supplied from the contact settling tank (20) can be stored at a predetermined height in the first aeration tank (310).

A plurality of the flowable bonus materials 31 for treating wastewater can be floated in the urine 4 stored in the first aeration tank 310.

An oxygen supply unit 311 may be provided at an inner lower middle portion of the first aeration tank 310 to supply oxygen to the urine 4 stored in the first aeration tank 310 to aerate it .

The second aeration tank 320 may be provided on the opposite side of the first aeration tank 310.

The urine (4) supplied from the first aeration tank (310) can be stored in the second aeration tank (320) at a predetermined height.

A plurality of the flowable bonus materials 31 for treating wastewater can be floated in the urine 4 stored in the second aeration tank 320.

The second aeration tank 320 is provided at its lower middle portion with an acid disposal supplementary portion 321 which can be formed of an aerosol or the like which supplies oxygen to the urine 4 stored in the second aeration tank 320 to aeration .

The third aeration tank 330 may be provided on the other side opposite to the one side of the second aeration tank 320.

The urine (4) supplied from the second aeration tank (320) can be stored at a predetermined height in the third aeration tank (330).

The third aeration tank 330 may include a solid support 32 for treating the wastewater.

An oxygen supply unit 331 may be provided on the lower side of the third aeration tank 330 in order to supply oxygen to the urine 4 stored in the third aeration tank 330 to aerate it have.

The supply line 340 for the aeration tank, which may be a pipe, a hose, or the like, provided in the first aeration tank 310, the second aeration tank 320, and the third aeration tank 330, The urine 4 may be sequentially supplied into the first, second, and third aeration basins 310, 320,

The aeration tank supply line 340 may comprise supply lines 341, 342, 343, 344, 345, 346, 347 for the first, second, third, fourth, fifth, sixth and seventh aeration tanks.

The first aeration tank supply line 341 may extend laterally and horizontally with a predetermined length in one direction of the interior of the first aeration tank 310 while communicating with the upper side of the contact settling tank 20.

The second aeration tank supply line 342 is connected to the first aeration tank supply line 341 and is connected to the first aeration tank 310 through a first aeration tank 310, As shown in FIG.

The urine 4 inside the contact settling tank 20 rising while passing through the wood chip layer 250 overflows into the first aeration tank supply line 341 and flows into the second aeration tank supply line 342 And may be supplied to the inside of the second aeration tank 320.

The second wastewater treatment feed line 342 prevents the plurality of wastewater treatment fluidizing bonins 31 in the first aeration tank 310 from flowing out into the contact settling tank 20.

The third aeration tank supply line 343 may extend vertically downward from the other upper side of the first aeration tank 310 toward the inner lower side of the first aeration tank 310.

The fourth aeration tank supply line 344 may be horizontally extended to the inside of the second aeration tank 320 by a predetermined length in a state of being communicated with the third aeration tank supply line 343.

The fifth aeration tank supply line 345 is communicated with the fourth aeration tank supply line 344 and is connected to the second aeration tank 320 in the inner lower side of the second aeration tank 320 As shown in FIG.

The urine 4 stored in the first aeration tank 310 sequentially passes through the inside of the supply lines 343, 344 and 345 for the aeration tanks of the third, fourth and fifth tanks, .

The third aeration tank supply line 343 prevents the plurality of flow boninets 31 for the wastewater treatment inside the first aeration tank 310 from flowing into the second aeration tank 320.

The fifth aeration tank supply line 345 prevents the plurality of wastewater treatment fluidizing bonins 31 in the second aeration tank 320 from flowing into the first aeration tank 310.

The sixth aeration tank supply line 346 may extend upward and downward from the other upper side of the second aeration tank 320 to a lower inner side of the second aeration tank 320 by a predetermined length.

The seventh aeration tank supply line 347 may be horizontally extended to a predetermined length to the upper side of one side of the third aeration tank 330 in a state of being communicated with the sixth aeration tank supply line 346.

The urine 4 stored in the second aeration tank 320 can be sequentially supplied to the inside of the third aeration tank 330 through the inside of the sixth and seventh aeration tank supply lines 346 and 347 .

The sixth aeration tank supply line 346 prevents the plurality of wastewater treatment fluidizing bonins 31 in the second aeration tank 320 from flowing into the third aeration tank 330.

The third aeration tank 330 is vertically extended from the upper side of the third aeration tank 330 to a downward direction inside the third aeration tank 330, A partition wall 350 for partitioning the inside can be formed.

A first space 332 and a second space 333 formed on one side of the inside of the third aeration tank 330 and the other side of the inside of the third aeration tank 330 on the basis of the partition wall 350, The solid support 32 for treating wastewater can be provided in the middle space 332 on one side.

Although not shown in the drawing, a support member, which may be formed of a net or the like, may be horizontally provided in the lower portion of the solid support 32 for treating wastewater.

The urine 4 in the third aeration tank 330 can be overflowed into the first pumping tank 610 of the pumping tank 60 through the lower portion of the partition wall 350 have.

Next, the pumping tank 60 may include a first pumping tank 610 and a second pumping tank 620.

The first pumping tank 610 may be provided between the third aeration tank 330 of the aeration tank 30 and the water spraying water storage tank 40.

The second pumping tank 620 may be provided between the spray water storage tank 40 and the liquid storage tank 50.

The lower part of the second pumping tank 620 may communicate with the lower part of the water spray water storage tank 40.

The third pumping tank 330 is connected to the first pumping tank 610 through a supply line 611 for supplying pumping water to the first pumping tank 610. The first pumping tank 610 may include a pipe, (4) may be fed into the first pumping tank (610).

The supply line 611 for the first pumping tank may extend to a predetermined length in the vertical direction of the first pumping tank 610. The upper portion of the supply line 611 for the first pumping tank may be formed in the aeration tank 30, The third aeration tank 330 may be horizontally bent in the direction of the third aeration tank 330 of the aeration tank 30 so as to communicate with the inside upper side of the third aeration tank 330 of the aeration tank 30.

The urine 4 inside the third aeration tank 330 may overflow into the supply line 611 for the first pumping tank 610 of the first pumping tank 610.

The urine 4 stored in the first pumping tank 610 is supplied into the water spraying water storage tank 40 through the first pumping tank transferring part 630 provided in the first pumping tank 610 .

The transfer unit 630 for the first pumping tank may include a pump 631 for the first pumping tank and a transfer line 632 for the first pumping tank, which may be a pipe, a hose, or the like.

The first pumping tank pump 631 is provided inside the first pumping tank 610 to forcibly pump the urine 4 stored in the first pumping tank 610.

The lower portion of the transfer line 632 for the first pumping tank may be connected to the upper portion of the pump 631 for the first pumping tank.

The upper portion of the transfer line 632 for the first pumping unit is horizontally extended horizontally to a length of the water spraying water tank 40 in the upward direction to form an upper portion of the wood chip layer 420 provided in the water spraying water storage tank 40 And the nozzle 633 may be connected to the nozzle 633.

The urine 4 stored in the first pumping tank 610 can be sprayed uniformly in the upward direction of the wood chip layer 420 through the nozzle 633, So that the urine 4 can be supplied to the inside of the urine 4. [

The urine 4 may be finally liquefied through the wood chip layer 420 and the activated carbon layer or the char layer 410 to be introduced into the second pumping tank 620.

The liquid 5 stored in the second pumping tank 620 is supplied to the inside of the liquid storage tank 50 through the pumping tank 640 provided in the second pumping tank 620 .

The transfer unit 640 for the first pumping tank may include a pump 641 for the second pumping tank and a transfer line 642 for the second pumping tank, which may be a pipe, a hose, or the like.

The second pumping tank pump 641 may be provided under the second pumping tank 620 to forcibly pump the liquid tank 5 stored in the second pumping tank 620.

The lower portion of the transfer line 642 for the second pumping tank may be connected to the upper portion of the pump 641 for the second pumping tank.

The upper portion of the transfer line 642 for the second pumping tank may be horizontally extended to a predetermined length in the upper direction of the liquid storage tank 50 so that the pump 641 for forced pumping So that the liquid 5 can be transferred into the liquid storage tank 50.

Next, the liquid pot 5 stored in the liquid pot storage tank 50 may be supplied to the inside of the aeration tank 30 through the liquid pot storage tank transfer unit 510.

The transfer unit 510 for the liquid storage reservoir may include a liquid storage reservoir pump 511 and a liquid storage reservoir transfer line 512 which may be a pipe, a hose, or the like.

The liquid storage tank pump 511 is provided inside the liquid storage tank 50 for forcibly pumping liquid stored in the liquid storage tank 50.

The transfer line 512 for the liquid storage tank is connected to the inside of the first, second, and third aeration tanks 310, 320, and 330 of the aeration tank 30 by a liquid pump 5 for which the liquid storage tank pump 511 forcibly pums Can be transported.

The transfer line 512 for the liquid storage reservoir may include transfer lines 512a, 512b, 512c, and 512d for the first, second, third, and fourth liquid storage reservoirs.

The lower part of the transfer line 512a for the first liquid storage reservoir may be connected to the upper part of the liquid storage reservoir pump 511. [

The upper part of the transfer line 512a for the first liquid storage reservoir is exposed to the outside of the upper part of the liquid storage tank 50 through the vertical pipe through the upper part of the liquid storage tank 50, And can be formed horizontally extending left and right.

The upper portions of the second, third and fourth liquid storage vessels 512b, 512c and 512d are connected to the first liquid storage vessel feed line 512a so as to communicate with one side of the first feed liquid storage vessel 512a, As shown in FIG.

The bottoms of the second, third and fourth liquid storage vessels 512b, 512c and 512d are connected to the first, second and third aeration basins 310, 320 and 330, respectively, Can be drawn into the inside of the three aeration tanks (310, 320, 330) with a predetermined length.

The liquid bins 5 are sprayed into the first, second, and third aeration tanks 310, 320, and 330 at the lower ends of the second, third, and fourth liquid storage vessels 512b, 512c, A nozzle 513 may be provided.

3 is a cross-sectional view schematically showing a fluidized bonus material for wastewater treatment.

Next, a plurality of floating bonus materials 31 for floating in a state of being immersed in the upper part of the urine 4 stored in the aeration tank 30 are inhabited by the microorganisms for purifying the urine 4 , As shown in FIG. 3, a plurality of wood chips 301 and a plurality of styrofoames 302 may be accommodated, respectively.

The plurality of flow boninets 31 for treating wastewater can be formed by attaching microorganisms for purifying the urine 4 and digesting the organic contaminants by the microorganisms to purify them.

The plurality of wood chips 301 have a large surface area, are strong against an impact load, and have excellent deodorizing effect on wastewater.

In particular, in order to prevent a plurality of the wood chips 301 from being corrupted and deformed by the urine 4 over time, the plurality of the wood chips 301 may be made of cedar resistant to moisture.

The plurality of styrofoames 302 may be formed in various shapes such as a ball shape, have a large floatation effect, are harmless to the human body due to their non-toxicity, and contain air with a closed cell structure of 95% or more of their own volume.

Next, 60 to 80 parts by weight of the wood chip 301 and 20 to 40 parts by weight of the styrofoam 302 are contained in the flowable bonus material 31 for wastewater treatment.

When the wood chip 301 is less than 60 parts by weight, there is a problem that the deodorization efficiency of the urine 4 is lowered.

When the wood chip 301 is more than 80 parts by weight, the deodorization efficiency of the urine 4 can be increased. However, since the wood chip 301 is used in a larger amount than necessary, There is a problem that it takes time.

If the amount of the styrofoam 302 is less than 20 parts by weight, the floatability of the wastewater treatment fluidized bedding material 31 is lowered so that the wastewater treatment fluidized bedding material 31 flows into the lower portion of the urine 4, ) Is lowered.

If the Styrofoam 302 is more than 40 parts by weight, the floatation force of the wastewater treatment fluidized bedding material 31 is so large that a portion of the wastewater treatment fluidized bedding material 31 is exposed on the surface of the urine 4 So that the purification efficiency of the urine 4 is deteriorated.

4 is a partially enlarged perspective view enlarging a wood chip accommodated in the fluidized bonus material for wastewater treatment.

Next, the longitudinal length (L ₂₎ of said wood chips 301. As shown in Figure 4 is 3 ~ 5mm, and the left and right sides of the wood chip 301. The length (L ₁₎ is a 2 ~ 3mm, the wood chips It is preferable that the upper and lower thicknesses T of the upper and lower substrates 301 are 1 to 2 mm.

More specifically, the length L _{2 of} the wood chip 301 is less than 3 mm, the length L _{1 of} the wood chip 301 is less than 2 mm, and the thickness T of the wood chip 301 is less than 2 mm. The surface area of the wood chip 301 is narrowed, so that the deodorization efficiency of the urine 4 of the wood chip 412 is lowered.

The length L _{2 of} the wood chip 301 is more than 5 mm, the length L _{1 of} the wood chip 301 is more than 3 mm and the thickness T of the wood chip 301 is more than 2 mm The surface area of the wood chip 301 is widened so that the deodorization efficiency of the wood chip 301 can be increased but the wood chip 301 is formed more than necessary, There is a problem in that it is costly.

Next, the outer diameter of the styrofoam 302 is preferably 10 to 15 mm.

More specifically, when the outer diameter of the styrofoam 302 is less than 10 mm, the floating force of the wastewater treatment fluidized bed material 31 is lowered, so that the wastewater treatment fluidized bedding material 31 is separated from the urine 4 , The purification efficiency of the urine 4 is lowered.

When the outer diameter of the styrofoam 302 is greater than 15 mm, the floating force of the wastewater treatment fluid flow 31 is too large to allow a portion of the wastewater treatment fluidization bonnet 31 to flow into the urine 4 So that the purification efficiency of the urine 4 is lowered.

Next, it is preferable that the outer diameter of the flow bonus material 31 for treating wastewater is in the range of 50 to 100 mm.

More specifically, when the outer diameter of the flow bonus material 31 for forming wastewater treatment is less than 50 mm, the number of wastewater treatment wastewater treatment wastewater The flowable bonus material 31 is floated in the urine 4, and thus the flowable bonus material 31 is expensive.

When the outer diameter of the flowable bonus material 31 for forming wastewater treatment is greater than 100 mm, the number of flowable bonus materials 31 for the wastewater treatment is smaller than the amount of stored urine 4 stored in the aeration tank 30 There is a problem that the purification efficiency of the urine 4 through microorganisms is deteriorated.

Next, as shown in FIG. 3, it is preferable that the flow bonus material 31 for wastewater treatment is formed of a mesh net having a plurality of cilia 303 formed therein.

More specifically, the fluidized bonus material 31 for treating wastewater can be made of a mesh material such as cloth, nylon, or the like, but it is not limited thereto and may be made of various materials such as cloth and paper .

In particular, a plurality of the cilia 303 may be formed on the surface of the mesh net made of a fiber material such as cloth, nylon or the like.

A larger number of microorganisms can be attached to the mesh network due to the plurality of cilia (303).

A string member such as a wire, an elastic string, or a thread is bundled on the front side and the rear side of the mesh net while the wood chip 301 and the styrofoam 302 are accommodated in the mesh net in which the plurality of cilia 303 are formed Can be fixed.

A plurality of the flowable bonus materials 31 for filling the wood chip 301 and the styrofoam 301 float more smoothly at the upper part of the urine 4 stored in the aeration tank 30 The amount of urine 4 to be stored in the aeration tank 30 is controlled so that the styrofoam 302 and the wood chip 301 are filled with the flowable bonus material for the wastewater treatment (31) is filled in a volume ratio of 10 to 15.

The present invention having the above-described structure is a method for removing the odor of the livestock manure generated on the day by removing the method of storing the livestock manure for a long period of time, removing the coloring matter of the urine 4 and minimizing the storage period of the liquid manure 5 There is an advantage that the generated livestock manure can be treated by liquefaction.

10; Circulating water tank, 20; Contact settler,
30; Aeration tank, 40; Water spraying,
50; Liquid storage tank.

Claims (20)

A raw water tank for storing the raw water of the livestock manure inside and transferring the inner livestock manure to the solid-liquid separator through the feeding unit for raw water;
A contact sedimentation tank in which urine discharged from the solid-liquid separator is stored therein and which transports the sludge precipitated in the lower side to the source water tank;
An aeration tank in which urine supplied from the contact settling tank is stored therein and which removes odor and pigment of urine stored therein through a fluidized bonus material for treating wastewater and a solid carrier for treating wastewater;
A water spray water storage tank for storing urine supplied from the aeration tank and for removing odor and pigment of urine stored therein;
And a liquid storage tank for storing the liquid stored in the water spraying water storage tank and supplying the liquid stored in the liquid storage tank to the aeration tank.
The method according to claim 1,
Characterized in that urine is supplied to the inside of the water spraying water storage tank between the aeration tank and the water spraying water storage tank, and between the water spraying water storage tank and the liquid storage tank, and a pumping tank for supplying liquid storage to the inside of the liquid storage tank, rescue.
The method according to claim 1,
Characterized in that livestock manure is supplied to the inside of the raw water tank through a raw water supply line formed at one side of the raw water tank.
The method according to claim 1,
Wherein the water feeding unit includes a pump disposed inside the raw water tank;
And a transfer line provided between the pump and the solid-liquid separator.
The method according to claim 1,
An inclined surface is formed on the inner lower side of the raw water tank,
Wherein the inclined surface is inclined downward toward the inside of the raw water tank from the upper side of the inclined surface toward the lower side of the inclined surface.
The method according to claim 1,
And an air lift pump for conveying the sludge settled in the lower portion of the contact settling tank to the raw water tank in the contact settling tank.
The method according to claim 1,
A partition wall is formed at an inner middle part of the contact settling tank so as to extend vertically from the upper side of the contact settling tank to a downward direction inside the contact settling tank and to define the inside of the contact settling tank,
And a wood chip layer is provided on the other side space of the contact sedimentation tank, one side space and the other side space formed on one side and the other side of the inside of the contact sedimentation tank with respect to the partition wall.
The method according to claim 1,
An inclined surface is formed on the inner lower side of the contact sedimentation tank,
Wherein the inclined surface is inclined downward toward the inside of the contact sedimentation tank from the upper portion of the slope toward the lower portion of the slope.
The method according to claim 1,
Wherein the aeration tank includes a first aeration tank in which urine supplied from the contact sedimentation tank is stored therein, a floating bonnet for floating the wastewater is floated in urine stored therein, and an oxygen supply unit is provided in an inner lower side;
A second aeration tank in which urine supplied from the first aeration tank is stored therein, floating wastewater treatment fluid is floated in urine stored therein, and an oxygen supply unit is provided in an inner lower side;
And a third aeration tank in which urine supplied from the second aeration tank is stored therein, the solid carrier for treating the wastewater is provided therein, and the oxygen supply unit is provided in an inner lower portion thereof. .
10. The method of claim 9,
Urine is sequentially supplied to the inside of the first, second and third aeration tanks through a supply line for the aeration tank provided in the first aeration tank, the inside of the second aeration tank and the inside of the third aeration tank, respectively Livestock manure liquefaction facility structure.
10. The method of claim 9,
A partition wall is formed inside the third aeration tank, which is vertically extended from the upper side of the third aeration tank to a downward direction inside the third aeration tank and which divides the inside of the third aeration tank,
Characterized in that the solid carrier for treating wastewater is provided in one side space of the third aeration tank, one side space and the other side space formed on one side and the other side of the inside of the third aeration tank with respect to the partition wall rescue.
3. The method of claim 2,
The pumping tank includes a first pumping tank provided between the aeration tank and the water spraying water storage tank;
And a second pumping tank provided between the water spraying water storage tank and the liquid storage tank,
Urine stored inside the aeration tank is supplied to the inside of the first pumping tank through a supply line for a first pumping tank formed at an upper side of the first pumping tank,
Urine stored in the first pumping tank is supplied to the inside of the water spraying water bath through the first and second pumping baths provided in the first and second pumping baths, Is supplied to the inside of the liquid storage tank,
Wherein the first pumping tank transfer unit comprises: a first pumping tank pump disposed inside the first pumping tank;
And a transfer line for a first pumping tank for transferring the forced pumped urine to the inside of the water spraying water tank,
The second pumping tank transfer unit includes a second pumping tank pump disposed inside the second pumping tank;
And a second pumping tank transfer line for transferring the forced pumping liquid to the inside of the liquid storage tank by the pump for the second pumping tank.
The method according to claim 1,
The liquid stored in the liquid storage tank is supplied to the aeration tank through the liquid storage tank,
The transfer unit for the liquid storage reservoir includes a liquid storage reservoir provided inside the reservoir;
And a transfer line for the liquid storage tank for transferring the liquid pumped by the liquid storage tank pump to the aeration tank.
The method according to claim 1,
Wherein the fluidized bonus material for treating the wastewater stored in the aeration tank is inhabited by a microorganism for purifying urine and a plurality of wood chips and a plurality of styrofoams are accommodated in the interior of the aeration tank. .
15. The method of claim 14,
Wherein 60 to 80 parts by weight of the wood chips and 20 to 40 parts by weight of the styrofoam are contained in the fluidized bonus material for treating wastewater.
15. The method of claim 14,
Wherein the length of the wood chip is 3 to 5 mm, the length of the wood chip is 2 to 3 mm, and the thickness of the wood chip is 1 to 2 mm.
15. The method of claim 14,
Wherein the styrofoam has an outer diameter of 10 to 15 mm.
15. The method of claim 14,
Wherein the outer diameter of the flow bonus material for treating wastewater is 50 to 100 mm.
15. The method of claim 14,
Wherein the fluidized bonus material for the wastewater treatment comprises a mesh net having a plurality of cilia formed therein.
15. The method of claim 14,
Wherein the fluidized bonus material for filling the styrofoam and the wood chip is filled at a volume ratio of 10 to 15 per 100 volume ratio of urine to the livestock manure liquid facility.

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