KR20160101352A - Using a rain cycle possible use of the washing water generated by the water washing bath circulation treatment system - Google Patents

Abstract

The present invention relates to a circulation flushing toilet treatment system capable of cyclic use of washing water generated by using rainwater. The present invention maximally reduces mechanical devices and improves treating efficiency to reduce management costs and easily perform post management. More specifically, the present invention collects the rainwater to be purified and sterilized to be used as washing water and freshly stores the washing water without spoilage of the washing water to be used for a long period of time.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a circulating flush toilet treatment system capable of circulating flush water generated using rainwater,

The present invention can reduce the management cost by increasing the processing efficiency even if the mechanical device is omitted as much as possible, and also makes it easy to manage afterwards. Especially, it collects rainwater and purifies and disinfects it to use as cleaning water, The present invention relates to a circulating flush toilet treatment system capable of circulating flush water generated by using rainwater which is preserved freshly and can be used for a long time.

In the toilets such as parks and hiking trails, bad odors and pests are generated, and you can see the unsanitary toilet.

In addition, uncomfortable facilities cause many complaints. The problems of the existing toilet are mostly unsanitary and non-environmental in the form of the conventional toilet, and since the flush toilet can not be used in places where there is no water supply and sewage, It is inevitable to install a conventional toilet toilet as an alternative, and even in the case of a flush toilet in general, bad odor and environmental pollution have occurred due to insufficient control of the purified water tank.

In order to solve this problem, the inventor of the present invention increases the treatment efficiency even if the machine is omitted as much as possible, thereby reducing the management cost as well as facilitating post-management. Especially, collecting rainwater and purifying and disinfecting it as cleaning water And a circulating flush toilet treatment system capable of circulating flushing water generated by using rainwater which can be used for a long time by freshly storing the flushing water without damaging it.

Korean Patent Registration No. 10-1028516

The present invention can reduce the management cost by increasing the processing efficiency even if the mechanical device is omitted as much as possible, and also makes it easy to manage afterwards. Especially, it collects rainwater and purifies and disinfects it to use as cleaning water, It is an object of the present invention to provide a circulating flush toilet treatment system capable of circulating flush water generated by using rainwater which is preserved freshly and can be used for a long time.

According to an aspect of the present invention, there is provided a sanitary washing machine comprising: a washing water generator for generating washing water supplied to a sanitary ware of a toilet using rainwater; A storage tank in which wastewater discharged from a sanitary ware of the toilet is stored; An adjustment tank in which wastewater supplied from the storage tank is stored therein; A decomposition tank for decomposing organic matter contained in the wastewater through a wastewater treatment fluidized bed material suspended in the wastewater stored in the wastewater stored in the wastewater supplied from the adjustment tank; A treatment tank in which wastewater supplied from the decomposition tank is stored therein and removes the dye of the wastewater stored therein, through a solid carrier for treating wastewater; A sedimentation tank in which wastewater supplied from the treatment tank is stored therein and the sludge precipitated in the inner lower side is transported to the decomposition tank; A sterilizing filtration tank in which wastewater supplied from the settling tank is stored inside and sterilizing the wastewater stored therein and removing some organic matter contained in the wastewater through a fixed consulting body for wastewater treatment; And sterilizing filtration treatment water supplied from the sterilization filtration tank is stored in the inside and the treated water stored therein is supplied to the sanitary ware of the toilet. Which is capable of circulating the toilet water.

Preferably, the floating bonnet for floating the wastewater stored in the wastewater stored in the disassembly tank is composed of a filter medium containing a plurality of wood chips and a plurality of styrofoams, respectively, inside the microorganisms for purifying the wastewater.

An oxygen supply unit is provided at one inner lower side of the decomposition tank and a flow bonus material for the wastewater treatment floating in the wastewater is disposed in an upper direction of the oxygen supply unit. An inclined portion is formed in the lower inner side of the decomposition tank, The odor removing layer is formed in the other side of the decomposing vessel so as to be located in the upper direction of the inclined portion, and the odor removing layer is formed in the other side of the decomposing vessel so as to remove the odor of the wastewater, A partition wall is formed inside the decomposition tank so as to be positioned between the malodor removal layer and the fluidization bonnet for the wastewater treatment, vertically extending from the interior upper side of the decomposition tank toward the inclined portion vertically to partition the interior of the decomposition tank .

Here, it is preferable that the malodor removing layer is made of a plurality of wood chips.

In particular, it is preferable that 60 to 80 parts by weight of the wood chip and 20 to 40 parts by weight of the styrofoam are contained in the flowable bonnet for treating the wastewater.

The length of the wood chip is preferably 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.

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

In addition, it is preferable that the outer diameter of the flow bonus material for treating wastewater is 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.

Preferably, the flowable bonnet for treating the wastewater containing the styrofoam and the wood chip is filled in a volume ratio of 10 to 15 per 100 volume ratio of the wastewater.

In addition, an oxygen supply unit is provided on the inner lower side of one side of the treatment tank and is vertically extended inside the treatment tank so as to be positioned between the oxygen supply unit and the other side of the treatment tank, A partition wall for partitioning the inside of the treatment tank is formed, and the solid support for treating wastewater is disposed in the upper direction of the oxygen supply unit.

In addition, a supply pipe portion for supplying wastewater to the inside of the settling tank in the treatment tank is formed on the upper side of the settling tank, and the sludge settled in the lower side of the settling tank is preferably conveyed to the decomposition tank by the pump portion.

The inclined portion may be inclined downward toward the lower side of the settling tank as the inclined portion goes downward from the upper portion of the inclined portion toward the lower side of the bottom of the settling tank.

The sanitizing and filtering unit may include a sterilizing unit for sterilizing the wastewater supplied to the sterilizing and filtering unit at one side of the sterilizing and filtration tank. The sanitizing and filtering unit may include a fixing agent for treating the wastewater, The sterilizing filtration tank may include a partition wall extending vertically inwardly of the sterilizing filtration tank from the upper side of the sterilizing filtration tank to a predetermined length so as to be positioned between the circulating medium and the inside of the sterilizing filtration tank.

Particularly, it is preferable that the fixed backing body for treatment of wastewater, a charcoal layer or a granular activated carbon layer and a quartz gravel layer are sequentially laminated on the other side of the sterilization filtration tank.

The fixed admixture for wastewater treatment is manufactured by molding and drying a mixture of hydrated lime powder, granular activated carbon, oyster shell chips and wood chips in water, and the mixture in which microorganisms for purifying wastewater are inhaled is composed of calcium hydroxide powder 100 30 to 50 parts by weight of granular activated carbon, 30 to 50 parts by weight of oyster shell chips and 30 to 50 parts by weight of wood chips.

The mixture is preferably composed of 40 parts by weight of granular activated carbon, 40 parts by weight of oyster shell chips and 40 parts by weight of wood chips in 100 parts by weight of the slaked lime powder.

Here, it is preferable that the mixture is formed by shaping the mixture into a shape of a rectangular parallelepiped or a square having a through-hole and then drying it.

Particularly, it is preferable that the mixture is formed by forming through-holes in a rectangular parallelepiped shape having a length of 100 to 130 mm, a vertical height of 70 to 90 mm, and a thickness of 20 to 40 mm.

Alternatively, the mixture is preferably formed by forming a through-hole in a rectangular parallelepiped shape having a length of 120 mm, a height of 80 mm, and a thickness of 30 mm.

The inner diameter of the through-hole is preferably 10 to 30 mm.

Particularly, the inner diameter of the through-hole is preferably 20 mm.

It is preferable that two or more through-holes are formed.

It is preferable that the treated water stored in the water tank is supplied to the sanitary ware of the toilet by the pump unit.

The present invention is not only capable of generating cleaning water to be supplied to the sanitary ware of the toilet by collecting rainwater through the cleaning water producing unit and purifying and disinfecting it, and also can save the washing water freshly and freshly for a long time, It is possible to reduce the management cost by increasing the processing efficiency even if it is omitted.

FIG. 1 is a cross-sectional view schematically showing a circulating flush toilet treatment system capable of circulating flush water generated using rainwater, which is an embodiment of the present invention,
2 is a partially enlarged cross-sectional view showing an enlarged view of a washing water generating section and a storage tank,
3 is a partially enlarged cross-sectional view showing an enlarged view of an adjustment tank, a disassembling tank, a treatment tank, a sedimentation tank, a sterilizing filtration tank,
4 is a cross-sectional view schematically showing flows of the washing water and the treated water,
5 is a cross-sectional view schematically showing a flow bonus material for wastewater treatment,
6 is a partially enlarged perspective view showing an enlarged view of a wood chip accommodated in the fluidized bonus material for wastewater treatment,
7 is a perspective view schematically showing a fixed backing body 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.

FIG. 1 is a cross-sectional view schematically showing a circulating flush toilet processing system capable of circulating flush water generated using rainwater, which is an embodiment of the present invention.

As shown in FIG. 1, the circulating flush toilet system for circulating flush water generated using rainwater, which is one embodiment of the present invention, includes a flush water generating unit 10, a storage tank 20, an adjustment tank 30, A decomposition tank 40, a treatment tank 50, a sedimentation tank 60, a sterilizing filtration tank 70, and a water supply tank 80.

2 is a partially enlarged cross-sectional view showing an enlarged view of a washing water generating section and a storage tank.

First, the washing water generating section 10 generates washing water to be supplied to the sanitary ware 21 of the toilet 2 using rainwater. The washing water generating section 10 as described above is a domestic patent application No. 10 -2014-0025573, wherein the drinking water generated by the drinking water producing apparatus using the rainwater can be used as the washing water (3) supplied to the sanitary ware (21) of the toilet (2) have.

The sanitary ware 21 of the toilet 2 is a generic name of ceramics used for sanitary works and includes both sanitary devices such as a washstand 21a, a urinal 21b and a toilet 21c.

The washing water generating section 10 can supply the washing water 3 to the washstand 21a of the sanitary ware 21.

2, the washing water (3), which is stored in the storage tank of the washing water producing section (10), is supplied to the wash bowl (21a) between the washing water producing section (10) A supply unit 110 may be provided.

The washing water supply unit 110 may include a pump 111 and first and second washing water supply lines 112 and 113.

The pump 111 may be located at one side of the storage tank of the washing water supply unit 110.

The first and second wash water supply lines 112 and 113 may be formed of various types such as pipes and hoses.

One side of the first cleansing water supply line 112 is connected to the upper portion of the pump 111 and the other side of the first cleansing water supply line 112 is connected to the upper side of one side of the cleansing water supply unit 110 Can be drawn into the reservoir of the cleansing water supply unit 110 in a predetermined length and immersed in the cleansing water 3 stored in the reservoir of the cleansing water supply unit 110.

The upper part of the second rinse water supply line 113 is connected to the lower part of the pump 111 and the lower part of the second supply line 113 is connected to the upper part of the washstand 21a, , The cleansing water 3 forcedly pumped by the washing machine 1 can be supplied to the washstand 21a.

Next, the wastewater (4) discharged from the sanitary ware (21) of the toilet (2) is stored inside the storage tank (20).

The storage tank 20 may be located between the toilet 2 and the regulating tank 30. [

The storage tank 20 temporarily separates the solid matter contained in the wastewater 4 and prevents the excessive amount of BOD (biochemical oxygen demand) and solids from flowing into the decomposition tank 40, The wastewater 4 can be supplied.

2, the wastewater 4 discharged from the sanitary ware 21 of the toilet 2 is introduced into the storage tank 20 between the sanitary ware 21 of the toilet 2 and the storage tank 20, A wastewater supply line 22 which may be a pipe, a hose, or the like.

The wastewater supply line 22 may include first, second, third, and wastewater supply lines 221, 222, 223, and 224.

The upper portions of the first, second and third wastewater supply lines 221, 222 and 223 are connected to the lower portion of the toilet 21c of the sanitary ware 21, the lower portion of the urinal 21b and the lower portion of the toilet 21a, respectively .

The lower portions of the first, second and third wastewater supply lines 221, 222 and 223 may be connected to one side of the fourth wastewater supply line 224 at regular intervals so as to communicate with the fourth wastewater supply line 224 .

The other side of the fourth wastewater supply line 224 may be introduced into one side of the storage vessel 20 through the upper portion of one side of the storage vessel 20 at a predetermined length.

FIG. 3 is a partially enlarged cross-sectional view showing an enlarged enlarged view of the adjustment tank, decomposition tank, treatment tank, sedimentation tank, sterilizing filtration tank and deionization tank, and FIG. 4 is a sectional view schematically showing flows of the washing water and the treated water.

Next, the adjustment tank 30 stores the wastewater 4 supplied from the storage tank 20 at a constant interval in a small amount.

A wastewater supply unit 210 is provided between the storage tank 20 and the adjustment tank 30 to supply wastewater 4 stored in the storage tank 20 to the inside of the adjustment tank 30 at a predetermined interval .

2 to 4, the wastewater supply unit 210 may include a wastewater supply line 211 and a pump 212, which may be a pipe, a hose, or the like.

The lower part of the wastewater supply line 211 is drawn into the storage vessel 20 through the upper part of the storage vessel 20 in a predetermined length and stored in the wastewater 4 stored in the storage vessel 20 It can be immersed.

The upper portion of the wastewater supply line 211 may be introduced into the adjustment tank 30 through the upper portion of the adjustment tank 30 at a predetermined length.

The pump 212 is connected to the lower part of the wastewater supply line 211 and immersed in the wastewater 4 stored in the storage tank 20 in a state of being immersed in the wastewater 4) can be forcedly pumped.

Next, the decomposition tank 40 may be provided on the other side of the adjustment tank 30, and the wastewater supplied from the adjustment tank 30 is stored in the decomposition tank 40 therein.

The adjustment tank 30 may be provided with a wastewater supply unit 310 for supplying the wastewater 4 supplied to the inside of the adjustment tank 30 to the decomposition tank 40 at a predetermined interval.

3, the wastewater supply unit 310 may include a pump 311 and a wastewater supply line 312, which may be a pipe, a hose, or the like.

The pump 311 may be provided on the other side of the adjustment tank 30 while being immersed in the wastewater 4 supplied to the inside of the adjustment tank 30.

The lower part of the wastewater supply line 312 can be connected to the pump 311 and the upper part of the wastewater supply line 312 can pass through the upper part of the decomposition tank 40, As shown in Fig.

The wastewater 4 in the wastewater supply line 312 can flow down into the interior of the adjustment tank 30 along the wastewater supply line 312 by natural dropping when the pump 311 fails or is temporarily over- So that the ease of management of the wastewater supply unit 310 can be enhanced.

The organic matter contained in the wastewater 4 can be decomposed through the flowable bonnet material 41 for wastewater treatment floating on the wastewater 4 stored in the decomposition tank 40.

The treatment tank 50 may be disposed on the other side of the decomposition tank 40 and the upper portion of the other side of the decomposition tank 40 and the upper side of the treatment tank 50 may communicate with each other .

The wastewater (4) stored in the decomposition tank (40) can overflow and be supplied to the inside of the treatment tank (50).

The solid-liquid carrier 51 for treating wastewater can be provided in the treatment tank 50 to remove the dye of the wastewater 4 stored in the treatment tank 50. In this way, (51) is disclosed in Korean Patent Registration No. 10-1261365, and a detailed description thereof will be omitted.

In order to further improve the dyeing efficiency of the wastewater 4 through the solid carrier 51 for treating wastewater, the treatment tank 50 may be made of a single material, As shown in the figure, the first treatment tank 510 and the second treatment tank 520 may be two or more than two.

Next, the sedimentation tank (60) is provided on the other side of the treatment tank (50).

The wastewater (4) supplied from the treatment tank (50) is stored in the settling tank (60).

The sludge contained in the wastewater 4 can be set down in the bottom of the settling tank 60 and the sludge settled in the bottom of the settling tank 60 is returned to the settling tank 40.

The sterilization filtration tank 70 may be provided on the other side of the sedimentation tank 60 and the upper portion of the other side of the sedimentation tank 60 and the upper side of the inside of the sterilization filtration tank 70 may communicate with each other.

The wastewater (4) stored in the settling tank (60) may overflow and be supplied into the sterilization filtration tank (70).

After the wastewater (4) stored in the sterilization filtration tank (70) is sterilized, some organic matter contained in the wastewater (4) is supplied to the sterilizing filtration tank (70) Is removed.

The upper portion of the sterilizing filtration tank 70 and the upper portion of the inner side of the steam supply tank 80 may communicate with each other. have.

The sterilization filtration treated water 5 inside the sterilization filtration tank 70 can be overflowed and supplied to the inside of the water increasing tank 80.

The treated water 5 stored in the dehydration tank 80 can be supplied to the urinal 21b and the pailer 21c of the sanitary ware 21 of the toilet 2. [

A machine room 90 in which a mechanical device such as a control panel and an air pump is installed may be provided on the other side of the water supply tank 80.

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

Next, a plurality of floating bonus materials 41 for floating in a state of being immersed in the upper part of the wastewater 4 stored in the decomposition tank 40 are purified as shown in FIG. 5, And a plurality of wood chips 412 and a plurality of styrofoams 411 are accommodated in the interior of the microchip.

The filter material may be an HBC filter material for attaching a microorganism for purifying wastewater and purifying the organic contaminants by the microorganisms.

The plurality of wood chips 412 have a large surface area and are resistant to an impact load, and are excellent in deodorizing effect of wastewater.

In particular, in order to prevent a plurality of the wood chips 412 from being corrupted and deformed by the wastewater after a lapse of time, the plurality of wood chips 412 are preferably made of cedar resistant to moisture.

The plurality of the styrofoam 411 can be formed in various shapes such as a ball shape, has a large floating effect, is not harmful to the human body because it is not toxic, and has a closed bubble structure of 95% or more of its own volume.

As shown in FIG. 3, an oxygen supply unit 43 may be provided at an inner lower side of the decomposition tank 40 to supply air to the wastewater 4 to aerate it.

The fluidized bonus material 41 for wastewater treatment floating on the wastewater 4 may be positioned in the upper direction of the oxygen supply part 43.

An inclined portion 420, which may be formed in a plate shape or the like, may be formed on the inner lower side of the other side of the decomposition tank 40.

The inclined portion 420 may be inclined upwards toward the other side of the disassembly tank 40 as it goes from the lower portion of the inclined portion 420 toward the upper direction of the inclined portion 420.

A malodor removal layer 42 for removing malodor of the wastewater 4 may be formed in the other side of the decomposition tank 40 so as to be positioned in an upper direction of the slope section 420.

Although not shown in the drawing, the odor eliminating layer 42 and the odor eliminating layer 42 are formed of a mesh or the like to prevent the odor eliminating layer 42 from rising upward in the wastewater 4, And a support member for supporting and supporting the malodor removal layer 42 may be provided.

The malodor removing layer 42 may be formed of a plurality of wood chips or the like. In particular, it is possible to prevent the plurality of wood chips constituting the odor removing layer 42 from being damaged by the wastewater 4 It is preferable that a plurality of the wood chips are made of cedar or the like resistant to moisture.

The disposal tank 40 is disposed inside the decomposition tank 40 so as to be positioned between the odor eliminating layer 42 and the fluidized bonus material 41 for the wastewater treatment, A partition wall 410 may be formed which extends vertically to partition the interior of the decomposition tank 40.

The wastewater 4 inside the decomposition tank 40 can be moved to the odor removal layer 42 more easily through the lower portion of the partition wall 410 and through the inclined portion 420.

Next, 60 to 80 parts by weight of the wood chip 412 and 20 to 40 parts by weight of the styrofoam 411 are contained in the flowable bonus material 41 for treating wastewater.

If the wood chip 412 is less than 60 parts by weight, there is a problem that the deodorization efficiency of the wastewater 4 is lowered.

When the wood chip 412 is more than 80 parts by weight, the deodorization efficiency of the wastewater 4 can be increased. However, since the wood chip 412 is used in a larger amount than necessary, There is a problem that it takes time.

When the styrofoam 411 is less than 20 parts by weight, the floatability of the flowable bonnet material 41 for wastewater treatment is lowered and the flowable bonnet material 41 for treating the wastewater flows down to the bottom of the wastewater 4, ) Is lowered.

If the Styrofoam 412 is more than 40 parts by weight, the floatation force of the wastewater treatment fluidization bonnet material 41 is too large to allow a part of the wastewater treatment fluidization bonnet material 41 to be exposed on the water surface of the wastewater 4 So that the purification efficiency of the wastewater 4 is deteriorated.

6 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 412. As shown in Figure 6 is 3 ~ 5mm, and the left and right sides of the wood chip 412. The length (L ₁₎ is a 2 ~ 3mm, the wood chips It is preferable that the thickness T of the upper surface 412 is 1 to 2 mm.

More specifically, the length L _{2 of} the wood chip 412 is less than 3 mm, the length L _{1 of} the wood chip 412 is less than 2 mm, and the thickness T of the wood chip 412 is less than 2 mm. Is less than 1 mm, the surface area of the wood chip 412 is narrowed, and thus the deodorization efficiency of the wiping water of the wood chip 412 is lowered.

The longitudinal length L _{2 of} the wood chip 412 is greater than 5 mm, the lateral length L _{1 of} the wood chip 412 is greater than 3 mm, and the thickness T of the wood chip 412 is greater than 2 mm The surface area of the wood chip 412 is increased so that the deodorization efficiency of the wood chip 412 can be increased but the wood chip 412 is formed more than necessary, There is a problem in that it is costly.

Next, the outer diameter of the styrofoam 120 is preferably 10 to 15 mm.

More specifically, when the outer diameter of the styrofoam 120 is less than 10 mm, the floating force of the wastewater treatment fluidizing entrainer 41 is lowered, and the fluidizing bonus material 41 for wastewater treatment is supplied to the wastewater 4 So that the purification efficiency of the wastewater 4 is lowered.

If the outer diameter of the styrofoam 120 is greater than 15 mm, the floatation force of the wastewater treatment fluidized bed material 41 is too large to allow a portion of the wastewater treatment fluidized bedding material 41 to flow into the wastewater 4 So that the cleaning efficiency of the wastewater 4 is lowered.

Next, the outer diameter of the flow bonus material 41 for treating wastewater is preferably 50 to 100 mm.

More specifically, in the case where the outer diameter of the flowable bonus material 41 for forming wastewater treatment is less than 50 mm, the number of the wastewater treated in the wastewater treatment is larger than the amount of wastewater 4 stored in the decomposition tank 40 The flowable bonus material 41 is floated on the wastewater 4, and the cost is increased.

When the outer diameter of the fluidizing bonus material 41 for forming the wastewater treatment is greater than 100 mm, the number of the fluidizing bonus materials 41 for the wastewater treatment is larger than the amount of the wastewater 4 stored in the decomposition tank 40 The efficiency of purifying wastewater through the microorganisms is deteriorated.

Next, as shown in FIG. 5, it is preferable that the flow bonus material 41 for wastewater treatment comprises a mesh net having a plurality of cilia 413 formed therein.

More specifically, the fluidized bonus material 41 for treating wastewater can be made of a mesh material such as cloth, nylon, or the like, but is not limited thereto. It can be made of various materials such as a cloth and paper .

In particular, a plurality of the cilia 413 may be formed on the surface of the mesh net made of a fiber material such as cloth, nylon or the like.

Due to the plurality of cilia (413), a greater number of microorganisms can be adhered to the mesh net.

A string member such as a wire, a rubber string, or a thread is bundled on the front side and rear side of the mesh net in a state where the wood chip 412 and the styrofoam 411 are accommodated in the mesh net in which the plurality of cilia 413 are formed. Can be fixed.

A plurality of the flowable bonus materials 41 for wastewater treatment filled with the wood chips 412 and the styrofoam 411 at the upper part of the wastewater 4 stored in the decomposition tank 40 flows more smoothly The flow of the wastewater treatment fluid filled with the foamed styfoam 120 and the wood chip 412 with respect to the volume ratio of the wastewater 4 stored in the decomposition tank 40 is adjusted so that the wastewater 4 can be purified. It is preferable that the bonus material 41 is filled in a volume ratio of 10 to 15.

Next, as shown in FIG. 3, an oxygen supply unit 51, which may be an oxidizer or the like, may be provided on the inner lower side of the treatment tank 50.

The inside of the treatment tank 50 is positioned inside the treatment tank 50 in the downward direction of the treatment tank 50 so as to be positioned between the oxygen supply unit 51 and the other side of the treatment tank 50, A partition wall 53 may be formed which extends vertically to the inside of the treatment tank 50 so as to partition the interior of the treatment tank 50.

And the solid carrier 51 for treating the wastewater can be positioned in the upper direction of the oxygen supply unit 51.

3, a supply pipe portion 610 for supplying the wastewater 4 to the interior of the settling tank 60 in the treatment tank 50 may be formed on the upper side of the settling tank 60 .

The supply pipe portion 610 may include a vertical supply pipe 611 and a horizontal supply pipe 612.

The vertical supply pipe 611 may be vertically extended from the upper side of the sedimentation tank 60 to a downward direction inside the sedimentation tank 60.

One side of the horizontal supply pipe 612 may be connected to the upper portion of the other side of the treatment tank 50 and the other side of the horizontal supply pipe 612 may be connected to the upper portion of one side of the vertical supply pipe 611.

The sludge contained in the wastewater (4) can be easily collected and settled in the lower part of the sedimentation tank (60) through the supply pipe part (610).

The sludge settled in the lower part of the settling tank (60) can be conveyed to the inside of the decomposition tank (40) by the pump part (630).

As the pump unit 630, compressed air is sent from the lower end of the pumping water pipe 631, and air bubbles are generated in the pumping water pipe 61 to pump the water by the difference in specific gravity between the water outside the pipe A simple structure with no breakdown, and a convenient air lift pump can be used.

When the air lift pump is used as the pump unit 630, the upper part of the water pipe 631 of the air lift pump is vertically drawn into the vertical supply pipe 611 of the supply pipe part 610, 612 and the upper part of the partition wall 53 of the treatment tank 50 and the upper part of the partition wall 410 of the decomposition tank 40 horizontally penetrate the upper part of the vertical supply pipe 611, And may be introduced into the decomposition tank 40 at a predetermined length.

3, in order to allow the sludge contained in the wastewater 4 to be gathered more easily, the sludge contained in the bottom side of the sedimentation tank 60 is separated from the inner bottom side of the sedimentation tank 60 An inclined portion 620, which may be formed in a plate shape or the like, may be formed on the lower inner side of the other side of the settling tank 60.

The inclined portion 620 may be inclined downward toward the lower portion of the sedimentation tank 60 from the upper portion of the inclined portion 620 toward the lower portion of the inclined portion 620.

3, a sterilizing unit 710 for sterilizing the wastewater 4 supplied to the sterilizing filtration tank 70 may be provided at one side of the sterilizing filtration tank 70. As shown in FIG.

The sterilizing unit 710 may include an ultraviolet sterilizer that sterilizes and disinfects wastewater supplied to the sterilizing filtration tank 70 by irradiating ultraviolet rays. However, the present invention is not limited thereto, And a chlorine sterilizer for sterilizing the wastewater (4) supplied to the reactor (1).

A fixed consulting body 72 for treating the wastewater can be provided on the other side of the sterilization filtration tank 70 in order to remove residual organic matter of the wastewater 4 and to smooth the flow of the wastewater 4.

The sterilization filtration tank 70 is disposed inside the sterilization filtration tank 70 so as to be positioned between the sterilizing unit 710 and the fixed counseling body 72 for treating the wastewater, A partition wall 75 may be formed which extends vertically to a predetermined length and divides the inside of the sterilizing filter tank 70.

Next, in order to treat the wastewater 4 in a clear and transparent manner while removing the color of the wastewater 4 that has passed through the wastewater treatment fixed countersunk body 72, the wastewater treatment is performed on the other side of the sterilization filtration tank 70 A charcoal or granular activated carbon layer 73, and a pebble gravel layer 74 in the form of a soybean gravel may be sequentially stacked on top of each other.

It is possible to prevent floating of the charcoal layer or the granular activated carbon layer 73 through the granite gravel layer 74 and to neutralize the acidity of the treated water 5. [

7 is a perspective view schematically showing a fixed backing body for wastewater treatment.

Next, the stationary phase carrier 72 for wastewater treatment is manufactured by molding and drying a mixture of calcium hydroxide powder, granular activated carbon, oyster shell chips and wood chips in water.

First, the calcium hydroxide powder is used as a coagulant for purification of a water purification plant or for sewage and industrial wastewater, and this calcium hydroxide is used for purifying wastewater and stabilizing sludge. After the pH is elevated to at least 11 by addition of calcium hydroxide, ammonium ions present in the water are converted into ammonia molecules. Then, the ammonia molecules are removed from the degassing tower by blowing them into the air in contact with air to remove nitrogen, It is the most economical altitude treatment method as chemical adjustment occurs simultaneously when required.

In addition, when the slaked lime is kneaded with water and molded at high pressure and dried, it is hard like a cement block and does not melt in water, so there is no need to heat it with high heat, which is economical.

The granular activated carbon is produced through carbonization and activation processes using wood, sawdust, coconut husk, coal, etc. as raw materials, and is widely used for advanced treatment of treated water such as a water treatment process and a biological wastewater. The granular activated carbon is a black porous carbonaceous material having an inner surface area which is very high in adsorption performance and removes or adjusts discoloration and odorous substances.

In addition, the granular activated carbon has an advantage that microorganisms generated in activated carbon can be easily grown by adsorbing odor causing substances, various organic substances, ammonia nitrogen, and the like, which are dissolved in wastewater, into numerous micropores in the activated carbon.

The oyster shell chips are washed in clean water by picking oyster shells, aged for 1 or more years, and then calcined at high temperature and crushed to a proper size. This oyster shell increases the removal efficiency of phosphorus contained in the wastewater. Particularly, the oyster shell chip has an advantage that it is easy to adhere and grow microorganisms which are porous.

The wood chip has a honeycomb structure, and its surface area is extremely wide, so that adhesion and growth of microorganisms are easy. However, sawdust in general water is prone to decay or deformation when in water for a long time, so you should be careful in your choice. For this purpose, select woody species such as cedar, and then use appropriate methods to select wood chips that have a wider surface area.

Next, 30 to 50 parts by weight of the granular activated carbon, 30 to 50 parts by weight of the oyster shell chip, and 30 to 50 parts by weight of the wood chips are mixed in 100 parts by weight of the calcium hydroxide powder in the mixture in which microorganisms for wastewater are purified, .

More specifically, when the granular activated carbon is mixed with less than 30 parts by weight of 100 parts by weight of the slaked powder, the decolorization and deodorization efficiency of the wastewater decreases.

When the granular activated carbon is mixed in an amount of more than 50 parts by weight to 100 parts by weight of the slaked powder, the decolorization and deodorization efficiency of the wastewater can be increased. However, since the granular activated carbon is used in a larger amount than necessary, the material is wasted, There is a problem that it takes time.

When 100 parts by weight of the calcium hydroxide powder is mixed with less than 30 parts by weight of the oyster shell powder, the removal efficiency of phosphorus contained in the wastewater is lowered and the adhered growth ability of the microorganisms adhering to the mixture 10 is lowered There is a problem.

When the oyster shell chips are mixed in an amount of more than 50 parts by weight to 100 parts by weight of the calcium hydroxide powder, the removal efficiency of phosphorus contained in the wastewater is improved and the adhered growth power of microorganisms is increased. However, So that the material is wasted and a lot of cost is required.

When 100 parts by weight of the calcium hydroxide powder is mixed with less than 30 parts by weight of the wood chips, the adhered growth ability of the microorganisms adhered to the mixture is lowered.

When the wood chips are mixed in an amount of more than 50 parts by weight in 100 parts by weight of the calcium hydroxide powder, the adhered growth ability of the microorganisms adhering to the mixture is increased. However, since the wood chip is used in an amount larger than necessary, There is a problem in that it is costly as well as wasteful.

Particularly, in order to further improve the decolorization / deodorization efficiency of the wastewater and to allow the microorganisms to adhere to the mixture more easily, the mixture is prepared by mixing 40 parts by weight of the granular activated carbon, 100 parts by weight of the oyster shell chip 40 And 40 parts by weight of the wood chip.

Next, the mixture is formed into a shape of a rectangular parallelepiped or a square having a through-hole 721 as shown in FIG. 7, and then dried.

More specifically, since the through hole 721 is formed in the mixture, the contact area with the treated water such as wastewater can be widened, so that the removal efficiency of phosphorus and nitrogen can be improved and the pigment can be effectively removed.

In addition, when the mixture is molded into pellets, the treated water permeability of the wastewater and the like is poor, which results in poor treatment efficiency and a high possibility of occlusion.

Therefore, when a rectangular parallelepiped or a cubic shape as in the present invention is manufactured, it is easy to manufacture, and the water permeability of treated water such as wastewater is excellent and there is no fear of clogging.

Next, in order to further improve the permeability of the treated water such as wastewater and prevent the obstruction by the mixture, the through hole 721 is formed in the mixture as shown in FIG. 7, (L) of 100 to 130 mm, a vertical height (H) of 70 to 90 mm, and a back and forth thickness (T) of 20 to 40 mm, followed by drying.

Particularly, in order to further improve the transmittance of treated water such as wastewater and prevent the obstruction by the mixture more easily, the mixture has a through hole 721 formed therein, and has a left-right length L of 120 mm, (H) of 80 mm and a thickness T of 30 mm, and drying it.

Next, in order to improve the permeability of treated water such as wastewater, the inner diameter of the through-hole 721 is preferably 10 to 30 mm.

More specifically, when the inner diameter of the through-hole 721 is less than 10 mm, the treatment water permeability such as wastewater is poor and the treatment efficiency is deteriorated.

If the inner diameter of the through-hole 721 is larger than 30 mm, the mixture easily breaks.

Particularly, in order to further improve the transmittance of treated water such as wastewater and to prevent the mixture from easily breaking easily, the inner diameter of the through-hole 721 is preferably 20 mm.

Next, in order to further improve the transmittance of treated water such as wastewater, it is preferable that two or more through-holes 721 as shown in FIG. 7 are formed.

The treated water 5 stored in the water supply tank 80 is supplied to the urinal 21b and the urinal 21c of the sanitary ware 21 of the toilet 2 by the pump unit 810 .

The pump unit 810 may include first, second, third, and fourth treated water supply lines 812, 813, 814, and 815, which may include various types of pumps 811, pipes, and hoses.

The pump 811 may be located at the upper portion of the water supply tank 80.

The upper portion of the first treated water supply line 812 may be connected to the lower portion of the pump 811 through a vertical pipe of the elevation tank 80.

The lower portion of the first treated water supply line 812 may be immersed in the treated water 5 stored in the water tank 80.

The other side of the second treated water supply line 813 may be connected to one side of the pump 811.

The upper portion of the third treated water supply line 814 and the upper portion of the fourth treated water supply line 815 may be connected to one side of the second treated water supply line 814 .

The lower portion of the third and fourth treated water supply lines 814 and the lower portion of the fourth treated water supply line 815 may be connected to the upper portion of the pantry 21c and the upper portion of the urinal 21b, respectively.

In the present invention constructed as described above, not only the washing water 3 to be supplied to the sanitary ware of the toilet can be generated by collecting and purifying the rainwater through the washing water generating part 10, There is an advantage that it can be used for a long time by preserving it freshly and without damaging it, and further, the processing efficiency can be improved even if the mechanical device is omitted as much as possible and the management cost can be reduced.

10; A washing water generating section 20; Storage tank,
30; A control tank, 40; Decomposition tank,
50; Treatment tank, 60; The sedimentation tank,
70; Sterilization filtration tank, 80; An increase tank.

Claims (24)

A washing water generating unit for generating wash water supplied to the sanitary ware of the toilet using rainwater;
A storage tank in which wastewater discharged from a sanitary ware of the toilet is stored;
An adjustment tank in which wastewater supplied from the storage tank is stored therein;
A decomposition tank for decomposing organic matter contained in the wastewater through a wastewater treatment fluidized bed material suspended in the wastewater stored in the wastewater stored in the wastewater supplied from the adjustment tank;
A treatment tank in which wastewater supplied from the decomposition tank is stored therein and removes the dye of the wastewater stored therein, through a solid carrier for treating wastewater;
A sedimentation tank in which wastewater supplied from the treatment tank is stored therein and the sludge precipitated in the inner lower side is transported to the decomposition tank;
A sterilizing filtration tank in which wastewater supplied from the settling tank is stored inside and sterilizing the wastewater stored therein and removing some organic matter contained in the wastewater through a fixed consulting body for wastewater treatment;
And sterilizing filtration treatment water supplied from the sterilization filtration tank is stored in the inside and the treated water stored therein is supplied to the sanitary ware of the toilet. Circulating wash toilet treatment system that can be used for circulation.
The method according to claim 1,
Wherein the floating bonnet for floating the wastewater stored in the wastewater stored in the disassembly tank is composed of a filter medium containing microorganisms for purifying wastewater and containing a plurality of wood chips and a plurality of styrofoams, Which is capable of circulating the generated washing water.
3. The method of claim 2,
An oxygen supply unit is provided on one inner side of the decomposition tank and a floating bonus material for the wastewater treatment floating on the wastewater is disposed in an upper direction of the oxygen supply unit,
Wherein the inclined portion is inclined upward toward the other side of the disassembling tank from the lower portion of the inclined portion toward the upper portion of the inclined portion,
A malodor removing layer for removing malodor of the wastewater is formed in the other side of the decomposition tank so as to be located in an upper direction of the slope,
A partition wall is formed inside the decomposition tank so as to be positioned between the malodor removal layer and the fluidization bonnet for the wastewater treatment, vertically extending from the interior upper side of the decomposition tank toward the inclined portion vertically to partition the interior of the decomposition tank Wherein the circulating water can be circulated by using the rainwater generated by the rainwater.
The method of claim 3,
Wherein the odor-removing layer is made of a plurality of wood chips, and the circulating wash water generated using the rainwater can be circulated.
3. The method of claim 2,
Wherein 60 to 80 parts by weight of the wood chip and 20 to 40 parts by weight of the styrofoam are accommodated in the fluidized bonus material for treating wastewater and water, .
3. The method of claim 2,
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. This is a possible circular wash toilet treatment system.
3. The method of claim 2,
Wherein the styrofoam has an outer diameter of 10 mm to 15 mm. The circulating flush toilet system according to claim 1,
3. The method of claim 2,
Wherein the fluidized bonus material for treating wastewater is 50 to 100 mm in outer diameter, and the circulating water generated by the rainwater can be circulated.
3. The method of claim 2,
Wherein the flow bonus material for the wastewater treatment comprises a mesh net having a plurality of cilia formed therein, wherein the circulating wash water generated by the rainwater can be circulated.
3. The method of claim 2,
And a flowable bonus material for treating the wastewater containing the styrofoam and the wood chip is filled in a volume ratio of 10 to 15 per 100 volume ratio of the wastewater. system.
The method according to claim 1,
And an oxygen supply unit provided on an inner lower side of one side of the treatment tank and extending vertically inwardly of the treatment tank from the inside of the treatment tank to a certain length inside the treatment tank so as to be positioned between the oxygen supply unit and the other side of the treatment tank, A partition wall for partitioning the inside of the treatment tank is formed,
And the solid carrier for treating the wastewater is disposed in an upper direction of the oxygen supply unit.
The method according to claim 1,
A supply pipe portion for supplying wastewater to the inside of the settling tank is formed in the upper side of the settling tank,
Wherein the sludge settled in the lower part of the sedimentation tank is conveyed to the decomposition tank by a pump unit.
The method according to claim 1,
A slope part is formed on the inner lower side of one side of the settling tank and the other side of the other side of the settling tank,
Wherein the inclined portion is inclined downwardly toward the lower side of the sedimentation tank from the upper portion of the inclined portion to the lower portion of the inclined portion.
The method according to claim 1,
A sterilizing unit for sterilizing the wastewater supplied to the sterilizing filtration tank is provided on one side of the sterilizing filtration tank,
A sterilization and filtration tank is provided with a fixing agent for treating the wastewater at the other side thereof,
Wherein the sterilizing filter is disposed inside the sterilizing filter tank so as to be positioned between the sterilizing unit and the fixed counseling body for treating the wastewater and vertically extending inwardly downwardly of the sterilizing filter tank from the upper side of the sterilizing filter tank, Wherein the partition wall is formed in the partition wall.
15. The method of claim 14,
Characterized in that the fixed coun- tilter for treating wastewater, a charcoal layer or a granular activated carbon layer, and a crushed stone gravel layer are sequentially laminated on the other side of the sterilization filtration tank, and a circulating flush toilet treatment capable of circulating the cleansing water produced by using rainwater system.
The method according to claim 1,
The fixed consulting body for treating wastewater is manufactured by molding and drying a mixture of water and calcium hydroxide, granular activated carbon, oyster shell chips and wood chips,
Wherein the mixture containing microbes for purifying wastewater is mixed with 100 parts by weight of calcium hydroxide powder, 30 to 50 parts by weight of granular activated carbon, 30 to 50 parts by weight of oyster shell chips and 30 to 50 parts by weight of wood chips. Circulating wash toilet treatment system capable of circulating the wash water generated by using the washing water.
17. The method of claim 16,
Wherein the mixture is prepared by mixing 40 parts by weight of granular activated carbon, 40 parts by weight of oyster shell chips and 40 parts by weight of wood chips in 100 parts by weight of the slaked lime powder, and circulating washable toilet treatment capable of circulating the cleansing water produced by using rainwater system.
17. The method of claim 16,
Wherein the mixture is formed into a shape of a rectangular parallelepiped or a square having a through-hole formed therein, and then dried. The circulating washable toilet treatment system according to claim 1,
19. The method of claim 18,
Wherein the mixture is formed into a rectangular parallelepiped shape having a through hole and a length of 100 to 130 mm and a vertical height of 70 to 90 mm and a front and rear thickness of 20 to 40 mm and then drying the mixture. Circulating wash toilet treatment system that can be used for circulation.
19. The method of claim 18,
The mixture is formed by forming through-holes in a rectangular parallelepiped shape having a length of 120 mm, a vertical height of 80 mm, and a front and rear thickness of 30 mm, followed by drying. The circulation cycle of the generated cleansing water using rainwater Wash Handling System.
21. The method according to any one of claims 18 to 20,
And the inner diameter of the through-hole is 10 to 30 mm. The circulating flush toilet system according to claim 1,
22. The method of claim 21,
And the inner diameter of the through-hole is 20 mm. The circulating flush toilet system according to claim 1,
22. The method of claim 21,
Wherein at least two through-holes are formed in the circulation flush toilet system, wherein the circulation flushing water generated using the rainwater can be circulated.
The method according to claim 1,
And the treated water stored in the water tank is supplied to the sanitary ware of the toilet by a pump unit. The circulating washable toilet treatment system according to claim 1, wherein the circulating wash water generated by the rainwater is circulated.

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