KR102012760B1 - Water treatment system with foreign matter removal function - Google Patents

Abstract

The present invention relates to a water treatment apparatus having a foreign matter discharge function, the disclosed invention is installed in any one section of the pipe to which the fluid is moved, by the fluid moved along the pipe inside the housing connected between the two pipes In the water treatment apparatus is installed a rotary reaction tube so that the fluid is water treatment while rotating, at least one foreign material guide groove is formed along the inner surface from the inlet of the housing toward the bearing seat groove located in the lower portion of the rotary reaction tube And an annular foreign matter receiving groove forming a concentric circle outwardly of the bearing seat groove on the inner surface of the lower center of the housing, wherein the foreign substance receiving groove is connected to the foreign substance inducing groove, and a drain port is provided at the lower center of the housing. Is formed, the inlet of the drain port through the foreign matter receiving groove and the connection groove That through to features.

Description

Water treatment system with foreign matter removal function

The present invention relates to a water treatment device having a foreign matter discharge function to effectively discharge the precipitated foreign matter of the fluid passing through the water treatment device equipped with a rotary reaction tube.

In general, the water supply pipe is a stable supply of water to the faucet, such as homes by pressing the purified water in the water treatment plant in the pump station.

Immediately after the new installation of the water supply pipe, immediately after the repair of the water supply pipe, and immediately after the replacement of the old water pipe, it is difficult to supply water in a good water quality state.

In addition, the long-term use of water pipes causes scales due to corrosion in the pipes, ages due to oxidative corrosion, deposits accumulate, or adheres to bacterial microorganisms for long periods of time. do. For this reason, a separate water treatment device that is economically burdened such as a water purifier and a water heater is used.

In addition, a water treatment system for removing scales and the like is applied to a portion of the pipe to supply water of stable quality even when water is supplied to a power plant.

As a water treatment system for stabilizing water quality, a scale filter or scale buster may be configured together with a valve, and ionized fluid moving through the valve along a pipe may be discharged with impurities. It is configured for filtering.

In other words, inorganic and salt components are dissolved in the process cooling water (PCW) in the pipe. Therefore, there is water dissolved inorganic salts and ingredients, which exist as anions, such as positive and, HCO₃-, SO₄-, Cl-, such as ^{Ca 2 +, Mg 2 +,} Na 2 +.

Various components contained in these fluids are combined with cations and anions as the temperature changes to form scales, and are mainly adhered to a 7 μm needle structure in the pipe with CaCO₃, MgSO, SiO₂.

As described above, the water treatment system having a reaction tube such as a scale filter or scale booster is composed of zinc (Zn) in which the reaction means component in the casing generates anion (-), and a predetermined current reacts with the anion inside the reaction tube. A tourmaline (eg, iron tourmaline, etc.) for generating a value (0.06 mA) is provided.

Therefore, as zinc in the reaction tube is continuously activated by generating negative ions by electric current generated from tourmaline, impurities stuck to the inner surface of the pipe can be continuously decomposed by negative ions to remove scale.

For example, an example of a corrosion prevention and descaling process is represented by the chemical formula below.

First, the corrosion protection is explained: Zn = Zn2 + + 2e- Fe₂O₃ (rust) + 1 / 2e- = Fe₃O₄ (magnetite) Fe₃O₄ + 5/2 e- (zinc electron) = Fe + (stable iron) It is converted to magnetite (magnetite; Fe₃O₄) which does not corrode abnormally to prevent the occurrence of corrosion, and finally reduced to stable iron (Fe +) to remove the existing rust.

In addition, the descaling process is described as CaCO₃ (scale) + CO₂ + H₂O = Ca (HCO₃) ₂ (calcium bicarbonate). That is, the scale particles are not removed in the form of a solid calcium carbonate (CaCO₃), but can be removed by changing to calcium bicarbonate (Ca (HCO₃) ₂), which is soluble in water.

However, in the conventional water treatment system, when the fluid is discharged from the inlet portion of the pipe in which the rotary reaction tube is installed to the discharge portion through the rotary reaction tube, relatively light foreign matter passes through the rotary reaction tube and is treated with water. In the case of heavy foreign matter, there is a problem that the efficiency of the water treatment is lowered as it is discharged through the discharge unit without passing through the rotary reaction tube through the lower side of the rotary reaction tube.

Korean Patent Publication No. 10-2013-0018230 (published Feb. 20, 2013)

The present invention has been made to solve the above-mentioned problems of the prior art, and induces the settled foreign matter passing through the housing in the interior of the housing installed between the pipes in a state in which the rotary reaction tube is embedded to discharge to the outside of the housing It is an object of the present invention to provide a water treatment device having a function of discharging foreign matters to improve water treatment management efficiency and further stabilize water quality.

The technical problem to be solved by the present invention does not need to be limited to the technical problem mentioned above, and other technical problems that are not mentioned are clearly to those skilled in the art from the following description. It can be understood.

The present invention according to a preferred embodiment is installed in any one section of the pipe to which the fluid is moved, so that the fluid can be treated while being rotated by the fluid moved along the pipe inside the housing connected between the two pipes In the water treatment apparatus is installed a rotary reaction tube,

At least one foreign matter induction groove is formed along an inner surface of the inlet of the housing toward the bearing seat groove located at the bottom of the rotary reaction tube, and an inner concentric circle of the bearing seat groove is formed at the inner center of the lower center of the housing. A foreign substance accommodating groove is formed, the foreign substance accommodating groove is connected to the foreign substance inducing groove, a drain port is formed at the lower center of the housing, and the inlet of the drain port is connected to each other through the foreign substance accommodating groove and the connecting groove. It is composed.

More preferably, the rotatable reaction tube may be configured such that a wing or a groove is formed at an outer circumference so that the fluid moving on the center of the housing is guided to the foreign substance receiving groove so that the foreign matter contained in the fluid is collected in the foreign substance receiving groove. have.

More preferably, the wing or groove may be configured in a continuous or discontinuous spiral form along the outer circumference of the rotary reaction tube.

More preferably, the surface of the wing may be provided with a plurality of through holes.

More preferably the housing is a see-through hole formed in a predetermined size on the front,

And protruding outward from the outer periphery of the see-through hole, the inner circumferential surface and the mounting portion is formed in the lower jaw,

Perspective window is inserted into the inner circumferential surface of the installation portion and the bottom surface of the outer shaft is seated on the locking jaw,

The bottom surface is in contact with the protruding front edge of the installation portion is fastened by a fastening member, the cover has a through hole formed in the center,

It is installed between the protruding front edge of the installation portion and the bottom of the cover, it may be configured to include a packing hole formed in the center.

More preferably, a coating layer capable of seeing the inside of the housing may be formed on the inner surface or both surfaces of the viewing window.

More preferably the coating layer has a size corresponding to that of the viewing window,

An optical silicone adhesive layer, a PET layer, a hard coating layer, an oleophobic coating layer or a superhydrophobic coating layer may be formed by combining these in sequence.

More preferably, the coating layer has a size corresponding to that of the see-through window, and may be configured by sequentially combining the optical silicon adhesive layer, the tempered glass film layer, the hard coating layer, the oleophobic coating layer or the superhydrophobic coating layer.

More preferably, the inside of the rotary reaction tube may include any one of tourmaline or guinea pig or higerion or loess or elvan or gansumite or germanium or charcoal.

More preferably, the rotary reaction tube may be made of any one material of zinc, magnesium, or copper.

A water treatment apparatus having a remote management system according to the present invention has the following advantages.

That is, in the water treatment apparatus provided inside the housing installed between the pipes and the fluid passing through the housing is purified through the rotary reaction tube, the foreign matter precipitated in the lower portion of the housing to guide the foreign matter receiving portion to settle and use the drain port By being configured to be discharged by, it is possible to effectively prevent the phenomenon that the purification ability of the fluid is deteriorated while the heavy foreign matter that does not go through the rotary reaction tube is discharged in an unpurified state.

Here, since the effects of the present invention described above are naturally manifested by the configuration of the described contents irrespective of whether or not the inventor recognizes them, the above-described effects are only some effects according to the described contents, and all the effects grasped or actual by the inventors. It should not be accepted that it is listed.

In addition, the effects of the present invention should be further grasped by the entire description of the specification, even if not described in explicit sentences even those having ordinary skill in the art to which the description belongs belong Any effect that can be recognized as should be seen as an effect described herein.

1 is an exploded perspective view illustrating main parts of a water treatment system according to an exemplary embodiment of the present disclosure.
2 is a combined perspective view illustrating a water treatment system according to an embodiment of the present invention.
3 is a cross-sectional perspective view illustrating an internal configuration of a housing of a water treatment system according to an embodiment of the present invention.
Figure 4a is a front sectional view illustrating the internal configuration of the housing of the water treatment system according to an embodiment of the present invention.
Figure 4b is a front sectional view illustrating the internal configuration of the housing of the water treatment system according to another embodiment of the present invention.
FIG. 5 is a plan sectional view showing main parts of an installation part provided in a housing of a water treatment system according to an exemplary embodiment.
FIG. 6 is a cross-sectional plan view illustrating main parts of another installation part provided in a housing of a water treatment system according to an exemplary embodiment.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which is intended to explain in detail enough to enable those skilled in the art to easily practice the contents of the present invention. This does not mean that the technical spirit and scope of the present invention are limited.

In addition, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description, terms specifically defined in consideration of the configuration and operation of the present invention will vary depending on the intention or custom of the user or operator The definitions of these terms should be made based on the contents throughout the specification.

First, a water treatment apparatus having a foreign matter discharge function according to the present invention is a housing installed between a pipe having an inlet and an outlet, and a circuit for purifying the fluid while being rotated by the flow of the fluid passing through the pipe provided at the center of the housing. It comprises a typical reaction tube, the foreign matter induction groove is formed on the inner surface toward the lower center of the housing at the inlet side of the housing, the foreign matter induction groove is connected to the foreign matter receiving groove provided in the lower center of the housing, the lower center of the housing It is characterized in that it is provided with a drain port connected to the foreign matter receiving groove, look in more detail through the illustrated drawings as follows.

First, the housing 100,

Aluminum or brass, which is a diamagnetic material, preferably has a Teflon coating inside and outside to smoothly generate static electricity.

Opposite sides of the housing 100 are provided with an inlet 101 and an outlet 102 so that the fluid moved to the inlet 101 through one pipe is connected to the ends of both pipes, respectively. After passing through the interior of the discharge portion 102 is discharged through the other pipe.

A space having a predetermined size is formed inside the housing 100, and the fluid passing through the inside of the housing 100 is rotated as the reaction tube 200 is installed in the space to prevent scale and corrosion. Contact with the pipe 200 is suppressed from occurring scale, rust and corrosion in the pipe.

Here, the inside of the rotary reaction tube 200 may be provided with any one or more of tourmaline, gemstone, higerion, ocher, elvan, gansumite, germanium, charcoal to emit anions.

The rotating reaction tube 200 may be installed in a fixed form or a rotating form inside the housing 100 as shown in FIGS. 3 and 4A, and when installed in a rotating form, the upper and lower parts of the rotating reaction tube 200 may be used. Is rotatably installed through a bearing (not shown) in the bearing seat groove 106 positioned at the lower and upper portions of the center of the housing 100.

In the interior of the housing 100, the foreign material guide groove 105 recessed to a predetermined depth on the inner inner surface of the inlet portion 101 toward the bearing seat groove 106 located at the lower center of the housing 100 in a continuous form. Is formed, the foreign material guide groove 105 may be formed in the inlet 101, the one or more spaced apart toward the bearing seat groove 106 of the housing 100 described above, such foreign material guide groove 105 The width or depth of) can be variously modified without needing to be determined by any one.

Foreign matter receiving groove 103,

3 and 4a, the inner center of the housing 100 is formed to be recessed to a predetermined width and a predetermined depth inside the housing 100. Preferably, the bearing seat groove 106 and the concentric circle outside the bearing seat groove 106 are formed. It may be formed in a ring forming a.

The foreign matter receiving groove 103 may be accommodated by any one of the foreign matter that is in communication with the above-described foreign matter induction groove 105 to move the foreign matter induction groove 105 is moved to the foreign matter receiving groove (103).

The foreign material guide groove 105 or the foreign material receiving groove 103 may be the same width, may be different widths, the foreign material guide groove 105 or the foreign material receiving groove 103 is a hemispherical recessed form. It may be, or may be configured as a polygonal recessed shape as needed.

A drain port 180 penetrating an outer surface and an inner surface may be provided at a lower center of the housing 100, and a drain port 180 may be provided at an outlet 182 of the drain port 180 located at an outer surface of the housing 100. ), A drain member such as a valve or a cap may be installed.

The inlet 181 of the drain port 180 located on the inner surface of the housing 100 is positioned below the bearing seat groove 106, and the inlet 181 crosses the center of the foreign matter receiving groove 103 described above. Is connected to the connection groove 107 of the form, both sides of the connection groove 107 may be configured to communicate with the foreign matter receiving groove (103).

Therefore, the precipitated foreign matter that is guided through the foreign matter induction groove 105 and moved toward the bearing seat groove 106 is received into the foreign matter receiving groove 103 connected to one end of the foreign matter inducing groove 105, and then, the foreign matter receiving groove. The drain member may exit to the outlet 182 of the drain port 180 which is separated through the inlet 181 of the drain port 180 through the connection groove 107 communicating with the 103.

Here, the connecting groove 107 is located at a position higher than the center on both sides of the inlet 181 of the drain port 180 so that the connecting groove 107 is downward toward the center toward the inlet 181 on both sides. It is preferably configured to be inclined.

In the present invention configured as described above, the fluid containing the foreign matter is introduced through the inlet 101 of the housing 100 and then the water treatment through the rotary reaction tube 200 through the discharge portion 102 of the housing 100. In the discharged to, in the case of heavy foreign matter, precipitates down the inlet 101 and moves along the lower inner surface below the rotary reaction tube 200, wherein the foreign matter is formed on the inner surface of the inlet 101 Guided to the guide groove 105 is received in the foreign matter receiving groove 103, the foreign matter received in the foreign matter receiving groove 103 in the lower center of the housing 100 through the connection groove 107 connected to the foreign matter receiving groove 103. Gathered toward the inlet 181 of the drain port 180 is located toward the outlet 182 of the drain port 180.

In addition, when the drain member closing the outlet 182 of the drain port 180 is removed from the outlet 182 of the drain port 180 to remove the foreign matter, the foreign matter precipitated in the drain port 180 may be formed in the housing 100. It can be discharged to the outside.

On the other hand, when the foreign matter of the fluid passing through the housing 100 is light, it may not move to the inside of the rotary reaction tube 200, may pass through the outside, in this case, it moves to the outside of the rotary reaction tube 200 In order to be moved to the foreign matter receiving groove 103 located in the lower housing 100, the foreign material is inclined at a predetermined angle with a predetermined interval along the longitudinal direction on the outer circumference of the rotary reaction tube 200 as shown in Figure 4a To form a plurality of wings 210 is formed, or as shown in Figure 4b to form a recessed groove 220 is formed at a predetermined angle with a constant interval on the outer periphery of the rotary reaction tube 200 is formed at an angle By configuring to tilt from the top to the bottom, the rotary reaction in the process of the fluid drawn into the housing 100 through the inlet 101 is discharged to the discharge unit 102 via the rotary reaction tube 200 Under the influence of the wings 210 or the groove 220 of the 200, the foreign matter is moved to the bottom, which may be configured to capture the foreign matter receiving recess 103.

Here, by installing a skirt (not shown in the figure) that is inclined inwardly on the upper side of the foreign matter receiving groove 103, the foreign matter moved to the foreign matter receiving groove 103 to escape to the outside of the foreign matter receiving groove 103. It can also be prevented.

In addition, the wing 210 or the groove 220 installed on the outer circumference of the rotary reaction tube 200 is a linear reaction tube 200 along the longitudinal direction of the rotary reaction tube 200 in a state inclined in a straight line. It may be installed to face the front and rear or both sides of the front and rear, at this time, the wing 210 or the groove may be a curved shape rather than a straight line, in another embodiment the wing 210 is a rotary reaction It may be configured to wrap continuously or discontinuously while forming a spiral around the outer periphery of the pipe (200).

In addition, in the case of the wing 210, since the fluid passing through the interior of the housing 100 may be subjected to resistance, a problem may occur in the flow of the fluid. Preferably formed.

In addition, in the case of the wing 210, although it may be a fixed form by welding or the like on the outer periphery of the rotary reaction tube 200, a plurality of the lower end of the wing 210 in contact with the rotary reaction tube 200 A protrusion (not shown in the drawing) is formed and a fitting hole (not shown in the figure) is formed on the outer circumference of the rotary reaction tube 200 to fit the rotary reaction tube 200 using the protrusion of the wing 210. It may be a form to be assembled to fit in the ball, at this time can be installed in various forms by adjusting the angle of the wing 210, the distance between the wing 210, the number of wings 210, etc., depending on the position of the fitting hole. have.

On the other hand, when the inspection or cleaning time of the rotary reaction tube 200 is recognized, it is necessary to directly check the rotary reaction tube 200 located inside the housing 100, for this purpose, the inside of the housing 100 The cover 110 is fastened by a plurality of fastening means, such as bolts, to the upper portion of the housing 100 in a state in which the fluid passing through is interrupted by the operation of a valve (not shown) provided on one side of the housing 100. After opening, you can check the rotary reaction tube 200 located inside the housing 100.

However, this method takes a long time, and the work process is complicated, there is an inefficient problem.

Therefore, the present invention forms a see-through window 140 through which the inside of the housing 100 can see through, and through this see-through window 140 to quickly and accurately determine the state of the rotary reaction tube 200 with the naked eye. I would have to.

An embodiment of the see-through window 140 is as follows.

That is, as shown in FIG. 5, a through-hole 120 having a predetermined size penetrating inside and outside of the center 100 of the housing 100 may be formed. In this case, the through-hole 120 may be configured in various shapes such as a circle or a polygon. have.

The see-through hole 120 may be formed on the surface of the cover 110 located at the front, rear, or upper side of the housing 100, and may be formed in plural in a plurality of parts.

And the outer periphery of the through-hole 120 is provided with an installation unit 130 protruding and extending from the housing 100 to a predetermined length, the installation unit 130 is provided with a see-through window 140 and cover 150 to be described later do.

The installation unit 130 has a locking jaw 131 is formed along the inner circumferential surface for mounting and fixing the see-through window 140 installed therein, and the locking jaw 131 is spaced apart from each other on the inner circumferential surface of the mounting unit 130. It may be formed of a dog, or may be formed of a single body.

The front of the installation unit 130 is formed with a fastening hole to which the fastening member 152 is fastened so that the cover 150 to be described later is fastened through the fastening member 152.

The see-through window 140 is matched and installed in the installation unit 130, and the see-through window 140 may be made of tempered glass that can withstand high pressure, and a metal frame is wrapped and installed on the outer circumferential surface of the see-through window 140. May be

The see-through window 140 is configured to be transparent to check the fluid state inside the housing 100 through the see-through window 140, or check the state of the rotary reaction tube 200 located inside the housing 100.

The see-through window 140 is configured in a shape corresponding to the inner circumferential surface of the installation unit 130 so that the outer circumference of the see-through window 140 is hung on the engaging jaw 131 of the installation unit 130, the viewing window 140 is one It may be composed of a body, when the outer peripheral bottom surface of the see-through window 140 is seated on the engaging jaw 131 of the installation unit 130 is preferably installed with the sealing member 170 therebetween for confidentiality, It is preferable that the sealing member 170 is installed between the upper surface of the outer periphery of the see-through window 140 and the bottom of the cover 150 to be described later for airtightness.

The inner surface facing the inside of the housing 100 in the see-through window 140 needs to be configured in the same manner as the inner circumferential surface of the housing 100. That is, when the inner circumferential surface of the housing 100 is flat, the inner surface of the see-through window 140 may also be configured to be flat so that no step occurs with the inner circumferential surface of the housing 100, and the inner circumferential surface of the housing 100 may have a predetermined curvature. In the case of having, the inner surface of the see-through window 140 may also be configured with the same curvature so that a step does not occur with the inner peripheral surface of the housing 100.

When the same curvature or the same straight line as the inner circumferential surface of the housing 100 of the see-through window 140 is formed, the fluid moved inside the housing 100 can be naturally moved without resistance when moved in contact with the see-through window 140 so that the fluid flows. Sex can be improved.

In another embodiment, the viewing window 140 may include a first viewing window 141 and a second viewing window 142 spaced apart from each other as shown in FIG. 6.

When the see-through window 140 is composed of the first see-through window 141 and the second see-through window 142, a sealing member 170 may be installed therebetween for maintaining the gap and airtight therebetween.

The distance between the first see-through window 141 and the second see-through window 142 may be maintained through a separate gap holding hole, in which case the see-through of the housing 100 should not be disturbed by the gap holding hole.

If the see-through window 140 is configured in a double to prevent condensation, even if one is broken, the other can maintain the airtight inside the housing 100 as it may be helpful for safety.

Perspective window 140 is composed of one or a plurality, the cover 150 is installed on the front of the installation unit 130 so that such a viewing window 140 can be fixed to the installation unit 130, the cover 150 is the center It is preferable to configure the through-hole 151 formed to correspond to the shape of the see-through hole 120 and the see-through window 140.

That is, the state of the inside of the housing 100 must be visually confirmed through the through hole 151, the see-through window 140, and the see-through hole 120, and the shape of the through-hole 151 is the see-through window 140 and the see-through hole ( The shape of 120 may be the same as each other, or may be freely deformed within a range in which the inside of the housing 100 can be confirmed.

When the cover 150 is installed in the installation unit 130, the insertion hole formed at the edge of the cover 150 is matched with the fastening hole formed in the front of the installation unit 130, and then the fastening member is formed with the insertion hole and the fastening hole matched with each other. 152 can be fastened by fastening.

The packing 160 may be further provided between the installation unit 130 and the cover 150 to maintain airtightness.

Packing 160 is preferably a material having an elastic force, the central hole 161 has a feature that can visually check the state inside the housing 100 without covering the viewing window 140 and the viewing hole 120. .

The packing 160 may be fixed in a state of being fitted by a coupling force between the cover 150 and the front of the installation unit 130, and forms a fitting hole corresponding to the fastening hole provided at the front of the installation unit on the outer circumference to fasten the member 152. ) May be fastened to the fastening hole of the installation unit 130 through the fitting hole of the packing 160, so that the packing 160 may be fixed by the fastening member 152.

On the other hand, a transparent coating layer 143 through which the inside of the housing 100 may be viewed may be formed on the surface of the see-through window 140.

The coating layer 143 may be formed on an inner surface or both an inner surface and an outer surface in the case of one viewing window 140, and in the case of the plurality of first viewing windows 141 and the second viewing window 142, the first viewing window 141. It may be formed on the inner surface and the outer surface of the second viewing window 142.

The coating layer 143 prevents contamination of the see-through window 140 by water, and facilitates cleaning of the see-through window 140, thereby reinforcing the strength of the see-through window 140 to improve durability.

The coating layer 143 has a shape corresponding to that of the viewing window 140 and is attached to the viewing window 140.

The coating layer 143 may be composed of a plurality of layers, and examples thereof include an optical silicon layer adhered to the viewing window 140, a PET layer or a tempered glass film layer bonded to the optical silicon layer, and such PET layer. Alternatively, the hard coating layer bonded to the tempered glass film layer and the oleophobic coating layer or the superhydrophobic coating layer bonded to the hard coating layer may be configured to be sequentially combined.

Preferably, the optical silicone adhesive layer is configured to have a transmittance of approximately 1.42, and the PET layer is preferably made of a transparent synthetic resin, and the tempered glass film layer is preferably configured to have a high hardness of approximately 8-9H, and hard The coating layer is preferably configured to have a hardness of approximately 3 ~ 4H, the oleophobic coating layer is not easily combined with oil through the Oleophobic coating treatment, the superhydrophobic coating layer is a superhydrophobic coating (Superhydrophobic) coating The treatment prevents the easy binding of water molecules.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the disclosed contents. Therefore, the scope of the contents described should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

100: housing 101: inlet
102: discharge portion 103: foreign matter receiving groove
105: foreign matter guide groove 106: bearing seat groove
107: connecting groove 110: cover
120: see-through construction 130: mounting portion
131: jam jaw 140: viewing window
141: first viewing window 142: second viewing window
143: coating layer 150: cover
151: through hole 160: packing
161: hole 170: sealing member
180: drain port 181: inlet
182: outlet 200: rotary reaction tube
210: wing 211: through-hole
220: home

Claims (10)

The water treatment device is installed in any one section of the pipe to which the fluid is moved, and a rotary reaction tube is installed in the housing connected between the two pipes so that the fluid can be treated while being rotated by the fluid moved along the pipe. To
At least one foreign material induction groove is formed along an inner surface of the inlet of the housing toward the bearing seat groove located in the lower portion of the rotary reaction tube.
An inner surface of the lower center of the housing is formed with an annular foreign matter receiving groove forming a concentric circle outward of the bearing seat groove, the foreign matter receiving groove is connected to the foreign matter induction groove,
A drain port is formed in the lower center of the housing, and the inlet of the drain port is connected to each other through the foreign matter receiving groove and the connection groove,
The rotatable reaction tube has a wing or groove formed on the outer circumference so that the fluid moving on the center of the housing is guided to the foreign matter receiving groove, and the foreign matter contained in the fluid is configured to be collected in the foreign matter receiving groove. Water treatment device with discharge function. delete The method of claim 1,
The wing or the groove is a water treatment device having a foreign material discharge function, characterized in that configured in a continuous or discontinuous spiral form along the outer periphery of the rotary reaction tube. The method of claim 1,
Water treatment device having a foreign material discharge function, characterized in that a plurality of through holes are provided on the surface of the wing. The method of claim 1,
The housing,
Perspective hole formed in a predetermined size on the front;
An installation part which protrudes outward from the outer circumference of the see-through hole and has a locking jaw formed at an inner circumferential surface thereof;
A see-through window inserted into the inner circumferential surface of the installation unit and having a bottom surface of the outer shaft circumference seated on the locking jaw;
A bottom surface is folded to a protruding front edge of the installation unit and fastened by a fastening member, and a cover having a through hole formed at a center thereof; And
A packing formed between the protruding front edge of the installation unit and the bottom of the cover, and having a hole formed at a center thereof;
Water treatment device having a foreign matter discharge function, characterized in that it is included. The method of claim 5,
Water treatment apparatus having a foreign matter discharge function, characterized in that the coating layer capable of seeing the inside of the housing on the inner surface or both sides of the viewing window. The method of claim 6,
The coating layer has a size corresponding to the viewing window,
Optical silicone adhesive layer;
PET layer;
Hard coating layer; And
Oleophobic coating layer or superhydrophobic coating layer;
Water treatment device having a foreign material discharge function, characterized in that the combination is configured sequentially. The method of claim 6,
The coating layer has a size corresponding to the viewing window,
Optical silicone adhesive layer;
Tempered glass film layer;
Hard coating layer; And
Oleophobic coating layer or superhydrophobic coating layer;
Water treatment device having a foreign material discharge function, characterized in that the combination is configured sequentially. The method of claim 1,
The inside of the rotary reaction tube is a water treatment device having a foreign material discharge function, characterized in that it comprises any one of tourmaline or guinea pig or higerion or loess or elvan or gansumite or germanium or charcoal. The method of claim 1,
The rotary reaction tube is a water treatment device having a foreign material discharge function, characterized in that composed of any one material of zinc, magnesium or copper.

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