KR19990046288A - Wastewater treatment apparatus - Google Patents

Abstract

The present invention relates to a wastewater treatment apparatus, and has proposed a wastewater treatment apparatus capable of purifying and filtering the wastewater with very good water quality in the post-treatment of various wastewaters, and allowing the wastewater supply amount and its throughput to proceed almost in proportion. Far-infrared radiation water treatment filtration filled with wick-filled far-infrared radiation water treatment filtration filler, mineral water reactor using radiation energy of far-infrared radiation water treatment filler, and far-infrared radiation water filtration in multi-stage wire mesh structure fixed wick It is to provide a wastewater treatment device consisting of a secondary filtration device made by filling the filler.

Description

Wastewater treatment apparatus

The present invention relates to a wastewater treatment apparatus, and more particularly, can be purified and filtered with very good water quality in the post-treatment of various wastewaters, and the amount of the influent and the amount of the treated water proceed in proportion to each other. The present invention relates to a wastewater treatment apparatus in which the water quality is purified and filtered very cleanly.

Generally, water consumed in modern society can be divided into domestic water used for real life and agricultural water and industrial water used in agricultural and industrial production.

As mentioned above, water consumed by different uses at each place of use is usually contaminated, but recently, the degree of pollution has reached a very serious state, which is the biggest cause of water pollution in recent years. There is leachate and living sewage of food waste, which is used in industrial production, and industrial water is discharged in a state containing heavy metals.

More specifically, the leachate of food waste generated from landfills such as Gimpo landfill has an average biochemical oxygen demand (BOD) of 1680.0 ppm, a chemical oxygen demand (COD) of 1030.0 ppm, and an SS of 70 mg / l, hydrogen ion concentration (pH) is 7.8 and the pollution is very serious situation.

Therefore, although the leachate of food waste and used industrial water are filtered by their own filtration device in the landfill and industrial factory, the degree of treatment does not reach the standard value and is very weak.

In addition, the conventional wastewater treatment apparatus has a disadvantage in that the amount of wastewater that can be purified and filtered is limited because the supply wastewater is overloaded in the supply portion, and the waste water component ratio is varied because of various kinds of waste such as food waste introduced according to the season. Since the turbidity and turbidity are very different, of course, the wastewater passing through the refinery filtration unit is very slow to be discharged to the discharge unit while the overload is overloaded from the supply unit. Moreover, the wastewater overload of the supply unit causes a deterioration of the wastewater treatment apparatus. Has been.

Accordingly, there is an urgent need for a wastewater treatment apparatus which can easily purify and filter the above-mentioned wastewater at an effective speed, and the condition of the treated water quality is also very good.

The present invention proposes a wastewater treatment apparatus which not only can be purified and filtered with very good water quality in the post-treatment of various wastewaters, but also the inflow water supply and its throughput proceed almost in proportion to each other. The primary filtration device made by filling the far-infrared radiation water treatment filtration filler, the mineral water reaction device using the radiation energy of the far-infrared radiation water treatment filler, and the secondary infrared ray made by filling the far-infrared radiation water treatment filtration filler in a multi-stage structured wire mesh structure. It is an object of the present invention to provide a wastewater treatment device consisting of a filtration device.

1 is a process diagram of a wastewater treatment apparatus according to the present invention;

Figure 2a, 2b is a cross-sectional view showing a mineral water reactor of the wastewater treatment apparatus according to the present invention,

3 is a cross-sectional view showing a primary filtration device of a wastewater treatment device according to the present invention;

4 is a cross-sectional view showing a secondary filtration device of the wastewater treatment apparatus according to the present invention;

5 is a perspective view showing a wire mesh frame including a wick of a primary filtration device and a secondary filtration device of a wastewater treatment device according to the present invention.

<Explanation of symbols for main parts of the drawings>

10: wastewater treatment device 12: flow tank

14: filtration tank 16: upper wire mesh

18: lower wire mesh 20: support frame

22: wire mesh frame 24: iron core

26: vegetable wick 28: far infrared radiation water treatment filtration filler

30: 1 Primary filtration device 32: Outer housing

34: fluid flow pipe 36: heater pipe

38: far-infrared radiation water treatment filler 40: mineral water reactor

50: secondary filtration device 52: aeration

54: stainless steel plate 56: inlet pipe

58: discharge valve 60: locking jaw

62: uneven bending portion 64: square ball

66: nonwoven fabric 68: outflow pipe

70: thermocouple

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

The present invention provides a flow tank 12 for storing pretreated wastewater; Inside the filtration tank 14 of a predetermined volume inside the wire mesh structure frame 22 made by fixing the upper wire mesh 16 and the lower wire mesh 18 with a plurality of support frames 20, the core of the upper wire mesh 16 ( 24) and a primary filtration device formed by connecting a plurality of vegetable wicks 26 between the iron cores of the lower wire mesh 18 opposite to each other to fill the space between the vegetable wicks 26 with far-infrared radiation water treatment filtration filler 28. 30; A fluid flow pipe 34 wound around a plurality of times in a predetermined size of the outer housing 32 and integrally connected up and down, and a heater pipe 36 installed adjacent to the fluid flow pipe 34, and the fluid flow A mineral water reactor (40) composed of a far-infrared radiation water treatment filler (38) filled in the space between the pipe (34) and the heater pipe (36); The wire mesh frame 22 to which the vegetable wick 26 of the primary filtration device 30 is fixed is stacked in a plurality of stages in a predetermined volume of the filtration tank 14, and the vegetation of each wire mesh frame 22 is stacked. The space between the wick 26 is characterized in that the secondary filtration device 50 made by filling the far-infrared radiation water treatment filtration filler 28 at different densities are installed in sequence.

Particularly, another mineral water reaction tank 40 through which a high quality fluid such as tap water passes is installed at the fluid inlet of the flow tank 12.

Therefore, an aeration 52 for mixing the pretreated wastewater and the fluid via the mineral water reaction tank 40 simultaneously supplied to the flow tank 12 is provided inside the flow tank 12.

On the other hand, the number of lamination stages of the wire mesh framework 22 provided in the filtration tank 14 of the secondary filtration device 50 is preferably 6 to 9 stages, and more preferably the number of lamination stages is 7 stages.

On the bottom of each wire mesh frame 22 of the secondary filtration device 50, a stainless plate 54 having a plurality of holes is installed on the locking jaw 60 formed on the inner diameter surface of the filtration tank 14 to guide the fluid. And to support the wire mesh frame 22.

Far-infrared radiation water treatment filtration filler 28 is 0.5 cm from above, 120 mesh (mesh), from the space between the vegetable wick 26 of each of the wire mesh structure 22 stacked in seven stages of the secondary filtration device 50, 0.2 cm, 120 mesh, 0.2 cm, 120 mesh, 0.3-0.5 cm in different particle order.

Hereinafter, the wastewater treatment apparatus according to the present invention will be described in more detail with reference to the accompanying drawings.

The pretreated wastewater is, for example, wastewater purified and filtered by a filtration device used in a landfill site or an industrial factory, and is a wastewater after being filtered, but its water quality is very poor.

Therefore, the wastewater treatment apparatus of the present invention can be purified by pretreatment of the wastewater pretreated as described above as a post-treatment, and can also be used independently to purify and filter wastewater that has not been pretreated.

First, the pretreated wastewater is supplied to the inlet of the flow tank 12 and stored therein as shown in the accompanying process diagram shown in FIG. 1, and another fluid inlet is formed in the flow tank 12. There, the mineral water reaction tank 40 is installed here.

Water introduced into the mineral water reaction tank 40 and receiving far-infrared radiation from the far-infrared radiation water treatment filler 38 therein is a first-class fluid such as tap water and groundwater.

Therefore, the fluid such as tap water which has passed through the mineral water reaction tank 40 is supplied to the flow tank.

On the other hand, the aeration 52 is installed inside the flow tank 12, the pre-treated waste water and the fluid such as tap water passed through the mineral water reaction tank 40 is mixed with each other and stored.

Each configuration of the mineral water reaction tank 40 will be described later.

Next, the flow tank 12 is installed with the primary filtration device 30 is connected, where the primary filter described with reference to Figure 3 attached as follows.

It is preferable that the primary filtration device 30 uses a wick filtration device for wastewater treatment of Application No. 99-2977 filed on January 29, 1999.

A hinged opening and closing door is mounted on the upper part of the filtration tank 14 of the primary filtration device, and an inlet pipe 56 into which wastewater flows is installed on one side of the upper outer surface, and a discharge valve at the lower center. 58 is mounted.

In addition, the outlet pipe 15 is mounted in a horizontal direction on one side of the lower outer surface, and a support for supporting the entire filtration tank 14 is formed on the bottom of the lower edge.

At this time, the locking jaw 60 is integrally formed at an inner diameter surface of the filtration tank 14 at a predetermined distance up and down, and the inner diameter surface between the locking jaws 60 is crushed into silicon and 120 mesh. A blocking material 38 made by mixing a far-infrared water treatment filtration filler and fiber wood fiber is attached.

Here, the wire mesh structure 22 as shown in FIG. 5 attached to the inside of the filtration tank 14 provided as described above is installed, and the installed state and its structure will be described as follows.

The wire mesh frame 22 is composed of an upper wire mesh 16, a lower wire mesh 18, and a support frame 20 for connecting and supporting the upper wire mesh 16 and the lower wire mesh 18.

The upper wire mesh 16 and the lower wire mesh 18 is composed of a fixing frame 33 forming a circular border, and an iron core 24 fixed to the fixing frame 33, wherein the iron core 24 having a constant diameter is horizontally and vertically. It is made of a network structure woven by crossing at equal intervals.

In this case, a plurality of square spheres having a constant size are formed in the network structure interwoven with the iron cores 24 in the lengthwise direction, and the size of the square spheres 64 is about 5 cm in length and width.

Therefore, the upper wire mesh 16 and the lower wire mesh 18 are manufactured by welding each end of the intersected iron core 24 to the inner surface of the fixing frame 33 by welding.

Thus, the upper wire mesh 16 and the lower wire mesh 18 provided as described above are supported by each other by the support frame 20, the support frame 20 is a long iron core shape, at equal intervals The concave-convex bent portion 62 is formed.

The reason why the uneven bending portion 62 is formed in the support frame 20 is to prevent the straight flow of the wastewater flowing from the top to the bottom, that is, the wastewater flowing through the uneven bending portion 62 is easily purified and filtered. To make it possible.

Accordingly, the upper end of the support frame 20 is fixed to the bottom surface of the fixing frame 33 of the upper wire mesh 16, the lower end is fixed to the upper surface of the fixing frame 33 of the lower wire mesh 18, the wire mesh structure frame 22 is It is made.

On the other hand, the support frame 20 is preferably fixed to about six at equal intervals.

Here, the vegetable wick 26 is fixed to the wire mesh structure 22 provided as described above. The vegetable wick 26 and its fixing method will be described below.

The vegetable wick 26 is made by selecting one of hemp, paper mulberry, and cotton thread as a material, and after weaving 100 strands of fine diameter obtained from one of the listed materials, the four strands woven into the 100 strands into one After weaving, these four strands are rewoven together into three strands.

At this time, the vegetable wick 26 made by weaving as described above is made to have a diameter of 1cm ~ 5cm according to the amount of the feed wastewater, the preferred diameter is 1cm.

Therefore, the upper end of the vegetable wick 26 is fixed to each vertex of the square sphere 64 of the upper wire mesh 16 by a wire or the like, and at the same time the lower end and the square sphere 64 of the upper wire mesh 16 It is fixed at each vertex of the square sphere 64 of the lower wire mesh 18 in the vertically opposite position.

Accordingly, the wire mesh frame 22 to which the vegetable wick 26 is fixed is installed to be located between the upper and lower locking jaws 60 inside the filtration tank 14, between the physic wicks 26. The space is filled with far infrared radiation water treatment filtration filler 28.

The far-infrared radiation water treatment filtration filler preferably uses the composition of Application No. 10-1999-0002767, filed Jan. 28, 1999.

The previously applied far-infrared radiation water treatment composition has an inorganic composition ratio of 30 to 50% by weight of SiO ₂ , 5 to 25% by weight of Al ₂ O ₃ , 5 to 15% by weight of CaO, 5 to 15% by weight of MgO, Fe ₂ O ₃ 5-15 wt%, Na ₂ O 2.5-7.5 wt%, CoO ₃ 1-2 wt%, Ti 0.5-1.5 wt%, Y 0.001-0.01 wt%, La 0.005-0.02 wt%, Ce 0.005 A series of far-infrared emitter inorganic compositions of -0.02% by weight and 0.001% by weight of Nd, 1-5% by weight of CuO, 1-5% by weight of NiO, 1-5% by weight of biotite, and 1-5% by weight of pottery stone. Composition.

In more detail, the far-infrared radiation water treatment filtration filler 28 is filled with the same ratio of 1: 1: 1, which is finely crushed into particles having a diameter of 0.5 mm, 0.3 mm, and 0.2 mm, respectively.

Here, the infrared ray irradiated water treatment filtration filler 28 is filled in the filtration tank 14, and a stainless plate 54 having a plurality of holes is formed on the upper surface of the upper wire mesh 16 of the wire mesh structure 22 in which the filtration tank 14 is formed. Raised while being caught by the upper locking jaw (60) of the (), the nonwoven fabric 66 is placed on the upper surface of the stainless plate (54).

In addition, the nonwoven fabric 66 is in close contact with the bottom surface of the lower wire mesh 18 of the wire mesh structure 22 installed in the filtration tank 14, and the stainless steel plate 54 is attached to the bottom surface of the nonwoven fabric 66. It is mounted while hanging on the lower locking jaw (60) formed on the inner diameter surface of the).

At this time, the holes of the stainless plate 54 mounted on the upper and lower parts of the filtration tank 14 are holes penetrated into a plurality of holes of different diameters not evenly.

Therefore, the inflow water discharged to the outlet of the inlet pipe 14 of the primary filtration device 30 is filled with the upper space of the filtration tank 14 and the nonwoven fabric 66 placed on the top of the filtration tank 14. As it passes, large foreign objects are filtered out.

Subsequently, the inflow water passing through the nonwoven fabric 66 is introduced into the wire mesh framework 22 through a plurality of holes of the stainless plate 54 in close contact with the bottom surface of the nonwoven fabric 66.

More specifically, the influent flows through the upper wire mesh 16 of the wire mesh 22 and at the same time through the far-infrared radiation water treatment filtration filler 28 filled with the vegetable wick 26.

At this time, the wastewater is easily filtered by the far-infrared irradiated water filter filler 28 and at the same time flows downward through the vegetable wick 26 located between the far-infrared irradiated water filter filler 28.

That is, the wastewater is purified and filtered by the far-infrared radiation water treatment filtration filler 28 filled in close contact with the vegetable wick 26 while being easily guided along the vegetable wick 26.

On the other hand, the inflow of the inlet water supply portion, that is, the inlet pipe 56 of the filtration tank 14 of the primary filtration device 30 due to the downward flow guide of the vegetable wick 26 as described above is not overloaded. .

More specifically, the filtration rate of the inflow water passing through the far-infrared radiation water treatment filtration filler 28 proceeds rapidly because the inflow water is supplied to the inflow pipe 56 and guided by the flow of the vegetable wick 26.

The purified inflow water as described above is filled in the lower space of the filtration tank 14 and is discharged through the outlet pipe 68 installed on the lower side of the filtration tank 14.

On the other hand, the discharge valve 58 is mounted at a position deeper than the outlet pipe 68, that is, the bottom surface of the filtration tank 14, and deposits accumulated on the bottom surface of the filtration tank 14 for a long time. The discharge valve 58 can be opened and removed.

The inflow water exiting the outlet pipe 68 of the primary filtration device 30 passes through the mineral water reaction tank 40.

Herein, the configuration and operation state of the mineral water reaction tank 40 will be described with reference to FIGS. 2A and 2B.

It is preferable that the mineral water reaction tank 40 uses the mineral water reaction tank for water treatment of application No. 99-2976 filed on January 29, 1999.

Inside the outer housing 32 of the mineral water reaction tank 40, the fluid flow pipe 34 is wound 10 to 20 times in the center direction from the outside, and is bent vertically in the center direction again and then 2 to 4 times in the outer direction. As the number of the upper and lower stages is preferably increased, the two or more stages are preferred.

At this time, the upper end of the fluid flow pipe 34 is led to the upper one side of the outer housing 32 is formed as an inlet pipe of the fluid, the lower end of the fluid flow pipe 34 of the outer housing 32 Derived to one side of the lower is formed as an outlet of the fluid.

In addition, the inlet pipe of the fluid flow pipe 34 is provided with a pressure pump and a pressure gauge continuously, the fluid flows easily inside the fluid flow pipe 34 by the pressure pump, the flow pressure is It is measured by a pressure gauge.

On the other hand, the fluid flow pipe 34 is wound 10 to 20 times in a circle, and is in a state of 2 to 4 stages, and one heater pipe 36 in the central space thereof is provided with four heater pipes 36 in the outer circumferential surface space. ) Are installed at equal intervals.

At this time, the heater pipes 36 are disposed in a state in which power is connected to each other, and a fuse, a temperature sensor, a temperature controller, and a switch for operation of the heater pipes 36 are installed at one side and are automatically operated by a control panel. It is controlled.

Here, the far-infrared radiation water treatment filler 38 is filled in the space between the fluid flow pipe 34 and the heater pipe 36 in the outer housing 32 as described above, and the composition ratio of silver chloride (AgCl) 3 -5 wt%, biotite 3-5 wt%, nickel oxide (NiO) 1 wt%, 88-96 wt% of a far-infrared radiation water treatment composition, and these mixed together are used.

The far-infrared radiation water treatment composition preferably uses the composition of Application No. 10-1999-0002767 filed on January 28, 1999.

The previously applied far-infrared radiation water treatment composition has an inorganic composition ratio of 30 to 50% by weight of SiO ₂ , 5 to 25% by weight of Al ₂ O ₃ , 5 to 15% by weight of CaO, 5 to 15% by weight of MgO, Fe ₂ O ₃ 5-15 wt%, Na ₂ O 2.5-7.5 wt%, CoO ₃ 1-2 wt%, Ti 0.5-1.5 wt%, Y 0.001-0.01 wt%, La 0.005-0.02 wt%, Ce 0.005 A series of far-infrared emitter inorganic compositions of -0.02% by weight and 0.001% by weight of Nd, 1-5% by weight of CuO, 1-5% by weight of NiO, 1-5% by weight of biotite, and 1-5% by weight of pottery stone. Composition.

In addition, a thermocouple 70 is mounted to an external predetermined portion of the outer housing 32 of the mineral water reaction tank 40 through the far infrared radiation water treatment filler 38 therein.

Here, the operation state of the mineral water reaction tank 40 for water treatment produced as described above is as follows.

First, the fluid flows into the inlet pipe of the mineral water reaction tank 40 and the fluid easily flows along the inside of the fluid flow pipe 34 by the pressure pump.

The fluid flowing through the fluid flow pipe 34 receives the far-infrared radiation energy of the far-infrared radiation water treatment filler 38 to perform resonance motion.

Therefore, in addition to the material added to the filler has a bactericidal effect by the addition of AgCl in particular, the water passed through the mineral water reactor is activated.

On the other hand, due to the effect of the heating of the heater pipe 16 and the added additives, in particular, AgCl, the far-infrared radiation energy radiated from the far-infrared radiation water treatment filler 38 is radiated higher, so that the inside of the fluid flow pipe 34 The fluid flowing through is more easily activated and sterilized.

As described above, the inflow water passing through the mineral water reaction tank 40 is passed through the secondary filtration device 50, which is the last process, which will be described with reference to FIG. 4 attached to each configuration and operation of the secondary filtration device. Same as

The secondary filtration device 50 is laminated in a plurality of stages in a predetermined volume of the filter tank 14, the wire mesh framework 22 is fixed to the vegetable wick 26, such as installed in the primary filtration device (30).

The structure of the filtration tank 14 may be manufactured in the same structure as that of the filtration tank 14 of the primary filtration device 30, and may be manufactured in another form.

On the other hand, the number of lamination stages of the wire mesh framework 22 provided in the filtration tank 14 of the secondary filtration device 50 is preferably 6 to 9 stages, and more preferably the number of lamination stages is 7 stages.

On the bottom of each wire mesh frame 22 of the secondary filtration device 50, a stainless plate 54 having a plurality of holes is installed on the locking jaw 60 formed on the inner diameter surface of the filtration tank 14 to guide the fluid. And to support the wire mesh frame 22.

At this time, the space between the vegetable wick 26 of each wire mesh frame 22 stacked as described above is filled with far-infrared radiation water treatment filtration filler 28 at different densities.

More specifically, the far-infrared radiation water treatment filtration filler used for the primary filtration device 30 is located in the space between the vegetable wicks 26 of each of the wire mesh structures 22 stacked in seven stages of the secondary filtration device 50. 28 will be filled with different densities.

That is, the far-infrared radiation water treatment filtration filler 28 is 0.5 cm, 120 mesh (mesh) from above in the space between the vegetable wicks 26 of each of the wire mesh frames 22 stacked in seven stages of the secondary filtration device 50. ), 0.2 cm, 120 mesh, 0.2 cm, 120 mesh, 0.3-0.5 cm in different particle order.

On the other hand, the stainless steel plate 54 is also placed on the upper surface of the uppermost wire mesh frame 22 of the secondary filtration device 50, the nonwoven fabric 66 is laid on the upper surface of the stainless steel plate 54.

In addition, a discharge valve 58 is mounted on the bottom surface of the filtration tank 14 of the secondary filtration device 50, and a discharge port is formed at a lower side of the filtration tank 14 at a position higher than the discharge valve 58. Lose.

The wire core 24 woven into the upper wire mesh 16 and the lower wire mesh 18 of the wire mesh structure frame 22 of the secondary filtration device 50 is woven in a width of 3cm, bar of the primary filtration device 30 It is woven into a size smaller than 5cm applied to the wire frame.

Accordingly, the wastewater passing through the mineral water reaction tank 40 is finally passed through the secondary filtration device 50, the inlet pipe 56 of the filtration tank 14 of the secondary filtration device 50 Wastewater from the mineral water reactor 40 is supplied.

At the same time, the wastewater passes through the stacked seven-layer wire mesh 22, that is, the far-infrared radiation water treatment filtration filler 28 filled in different sizes in the vegetable wick 26 of each wire mesh 22. Receives far-infrared radiation and is easily purified and filtered.

In addition, since the inflow water is supplied to the inlet pipe 14 of the secondary filtration device 50 and receives the flow guidance of the vegetable wick 26 of the wire mesh structure 22 stacked in multiple stages, the far-infrared radiation water treatment filtration filler ( The rate of filtration of the influent passing through 32 is fast.

On the other hand, the secondary treatment device 50 is also mounted to the discharge valve 58 in the deeper position than the outlet pipe 68, that is, the bottom surface of the filtration tank 14, similar to the primary treatment device 30. As a result, it is possible to remove the deposit accumulated on the bottom surface of the filtration tank 14 for a long time by opening the discharge valve 58.

In addition, sediment may be caught in the far-infrared radiation water treatment filtration filler 28 used for influent filtration over a long period of time, in which case the opening and closing door of the filtration tank 12 is opened and the far-infrared radiation water treatment together with the wire mesh frame 22. After removing the filter filler 28 to the outside, it may be washed with clean water 100% recyclable and then dry showered and heated to a high temperature to sterilize it again, or may be filled with a new far infrared radiation water treatment agent.

As seen above, according to the wastewater treatment apparatus according to the present invention,

The primary filtration system is equipped with a wire mesh frame filled with vegetable wick and filled with far-infrared radiation water treatment filtration filler, the mineral water reactor filled with far-infrared radiation water treatment filler, and the wire mesh frame filled with far-infrared radiation water treatment filtration filler is fixed. By arranging the secondary filtration device installed in multiple stages side by side and passing the inflow water, the inflow water supplied to the supply portion of the primary and secondary filtration device is guided through the vegetable wick and easily purified and filtered by the far-infrared radiation water treatment filtration filler. It has the effect of losing water, and the water is activated and sterilized by the far-infrared radiation by the far-infrared radiation treatment filler while passing through the mineral water reactor, and the flow guide of the vegetable wick of the primary and secondary filtration devices Inflow to the supply section There is an advantage that the overload does not occur at all, so that the feed amount and the filtration throughput proceed almost in proportion.

Claims (6)

A flow tank 12 in which pretreated wastewater is stored; Inside the filtration tank 14 of a predetermined volume, the upper wire mesh 16 and the lower wire mesh 18 are internally installed with a plurality of support frames 20 having a bent portion. 1 is formed by connecting a plurality of vegetable wicks 26 between the iron cores 24 and the iron cores of the lower wire mesh 18 opposite thereto to fill the space between the vegetable wicks 26 with the far-infrared radiation water treatment filtration filler 28. A tea filtration device 30; A fluid flow pipe 34 wound around a plurality of times in a predetermined size of the outer housing 32 and integrally connected up and down, and a heater pipe 36 installed adjacent to the fluid flow pipe 34, and the fluid flow A mineral water reactor (40) composed of a far-infrared radiation water treatment filler (38) filled in the space between the pipe (34) and the heater pipe (36); The wire mesh framework 22 to which the vegetable wick 26 of the primary filtration device 30 is fixed is stacked in a plurality of stages in a predetermined volume of the filtration tank 14, and the vegetation of each of the stacked mesh structures 22 is Wastewater treatment device, characterized in that the space between the wick (26) is made by connecting the secondary filtration device (50) made by filling the far-infrared radiation water treatment filtration filler 28 at different densities in turn. 2. The wastewater treatment apparatus according to claim 1, wherein another fluidized water reaction tank (40) through which a fluid of high quality, such as tap water, passes through the fluid inlet of the flow tank (12). According to claim 1, wherein the aeration 52 for mixing the pre-treated waste water and the fluid via the mineral water reaction tank 40 at the same time supplied to the flow tank 12 is installed inside the flow tank 12 Wastewater treatment device characterized in that. The number of stacked stages of the wire mesh framework 22 provided in the filtration tank 14 of the secondary filtration device 50 is preferably 6 to 9 stages, and more preferably, the number of stacked stages is 7 stages. Wastewater treatment device. The method of claim 1, wherein the bottom surface of each of the wire mesh frame 22 of the secondary filtration device 50 has a stainless plate 54 having a plurality of holes in the locking step 60 formed on the inner diameter surface of the filtration tank 14 Hanging and installed is the waste water treatment apparatus, characterized in that for supporting the guide of the fluid and the wire mesh frame (22). The space-infrared irradiated water treatment filtration filler 28 is 0.5 cm from above in the space between the vegetable wicks 26 of each of the wire mesh frames 22 stacked in seven stages of the secondary filtration device 50. 120 mesh, 0.2cm, 120 mesh, 0.2cm, 120 mesh, the wastewater treatment apparatus characterized in that the filling in the order of different particles.