KR102218048B1 - Water to stabilize the water treatment device having means for reaction) - Google Patents

Abstract

The present invention relates to a water treatment device including a rotation-type reaction pipe so that a fluid can be treated with water while the rotation-type reaction pipe is rotated by the fluid moving along a pipe inside a housing installed in any one section of the pipe through which the fluid is moved. An inlet pipe is provided on one side surface of the housing, and a discharge pipe is provided on the other side surface thereof. A first installation groove is formed on the bottom surface inside the housing. The upper end of the interior is composed of a flat seating surface having an open inlet. A second installation groove is formed on the inner surface of a cover coupled to the seating surface. The upper end of the rotation-type reaction pipe erected and installed inside the housing is installed at the second installation groove to be directly rotated. Also, the bottom end thereof is installed at the first installation groove to be directly rotated.

Description

Water to stabilize the water treatment device having means for reaction}

The present invention relates to a water treatment device installed between pipes, and more particularly, to a water treatment device having a reaction means for stabilizing water quality capable of preventing corrosion of pipes and removing rust.

In general, a pipeline of a tap water supply pressurizes the water purified at a water purification plant at a pumping station to stably supply water to faucets such as households with good quality.

It is difficult to supply water with good water quality immediately after new installation of water pipes, immediately after repair of water pipes, and immediately after replacement of old water pipes.

In addition, when the water supply pipe is used for a long period of time, if scale is generated inside the pipe due to corrosion, aging due to oxidative corrosion, sediment accumulates, or bacterial microorganisms are attached and fixed for a long time, the water flow area decreases and water quality is severely contaminated. do.

For this reason, separate water treatment devices, such as water purifiers and water heaters, which are economically burdensome are used.

In addition, even when water is supplied to a power plant, a water treatment system for removing scale, etc. is applied to a part of a pipe in order to supply water of stable water quality.

As a water treatment system for stabilizing water quality, a scale filter or a corrosion inhibitor (I-Water), which is a reaction means, can be configured with a valve, and at the same time ionizing the fluid moving through the valve along the pipe. It is configured to filter impurities (foreign substances).

That is, inorganic substances and salt components are dissolved in the water in the pipe. Therefore, minerals and salts are dissolved in the water, which exist ^{as cations such as Ca 2} +, Mg ² +, Na ² +, and anions such as HCO ₃ -, SO ₄ -, and Cl-.

Various components contained in such fluid form scale by combining positive and negative ions according to temperature change, and mainly CaCO _3, MgSO, SiO ₂ are attached to the pipe in a 7㎛ needle-like structure.

As described above, in a water treatment system having a reaction means such as a scale filter or a scale booster, the reaction tube is composed of zinc (Zn) that generates anions (-), and a predetermined current value (006mA) reacting with anions inside the reaction means A tourmaline to generate (referring to an iron tourmaline as an example) is provided.

Accordingly, as the zinc in the reaction tube is activated by continuously generating anions by the electric current generated from the tourmaline, the scale can be removed by continuously decomposing impurities attached to the inner surface of the pipe by the anions.

For example, an example of the process of preventing corrosion and removing scale is expressed in a chemical formula as follows.

First of all, when explaining corrosion prevention, Zn = Zn2+ + 2e- Fe ₂ O ₃ (green) + 1/2e- = Fe ₃ O ₄ (magnetite) Fe ₃ O ₄ + 5/2 e- (zinc electron) = Fe+( _{Stable iron) It is converted into magnetite (magnetite; Fe 3} O ₄ ) that is not corroded any more by combining with molten electrons to prevent corrosion, and finally, it is reduced to stable iron (Fe+) to remove the existing rust. do.

In addition, when explaining the scale removal process, CaCO ₃ (scale) + CO ₂ + H ₂ O = Ca(HCO ₃ ) ₂ (calcium bicarbonate) That is, scale particles are removed in the form of _{solid calcium carbonate (CaCO 3 ). It is not, by changing to calcium bicarbonate (Ca(HCO 3} ) ₂ ) which is well soluble in water, the scale can be removed.

On the other hand, such a reaction means may be composed of a rotary type or a fixed type. In the case of a rotary type, it is not easy to manufacture as it is rotatably installed on both sides of the housing through parts such as bearings above and below the rotary reaction tube, There is a problem in that it is not easy to maintain and manage rotating parts such as bearings.

In addition, in the case of the fixed type, as the fixed reaction plate is installed in the transverse direction between the inlet and the outlet inside the housing, the fluid discharged from the inlet through the fixed reaction plate to the discharge portion receives the resistance of the fixed reaction plate and the flow velocity is reduced. There is a problem that noise is greatly generated during the contact process with the fixed reaction plate.

In addition, in the case of the housing, there is a problem in that the manufactureability according to the shape is not good, and the cost of maintenance and management is large.

Republic of Korea Patent Publication No. 10-2013-0018230 (published on February 20, 2013)

The present invention was conceived to solve the problems of the prior art described above, by simplifying the installation structure of the rotary reaction tube installed in the water treatment device to provide ease of installation and convenience of maintenance, and further double the efficiency of water treatment. One object is to provide a water treatment apparatus having a reaction means for stabilizing water quality so that it can be made.

In addition, the present invention provides a water treatment device having a reaction means for stabilizing water quality so as to prevent a decrease in flow rate and noise, and further double water treatment efficiency through a structural change of a fixed reaction plate installed in the water treatment device. There is one purpose.

The technical problems to be solved by the present invention need not be limited to the technical problems mentioned above, and other technical problems that are not mentioned are clearly to those of ordinary skill in the technical field to which the present invention belongs from the following description. It will be understandable.

The present invention according to a preferred embodiment is provided with a rotary reaction tube so that the fluid can be water treated while being rotated by the fluid moving along the pipe inside the housing installed in any one section of the pipe through which the fluid is moved. In the water treatment apparatus, an inlet pipe is provided on one side of the housing, a discharge pipe is provided on the other side, and a first installation groove is formed on the bottom surface of the housing, and the upper end of the housing has an open inlet. The branch is composed of a flat seating surface, and a second installation groove is formed on the inner surface of the cover coupled to the seating surface, and the upper end of the rotary reaction tube erected and installed inside the housing rotates directly to the second installation groove. It is installed to be possible, and the lower end is a configuration installed to be rotatable directly to the first installation groove.

The present invention according to another preferred embodiment of the present invention is a water treatment device provided with a fixed reaction plate so that the fluid moving along the pipe can be water treated inside a housing installed in any one section of a pipe through which the fluid moves, An inlet pipe is provided on one side, an outlet pipe is provided on the other side, and a first fitting groove is formed on the bottom surface of the housing, and the upper end of the housing is composed of a flat seating surface having an open inlet, A second fitting groove is formed on the inner surface of the cover coupled to the seating surface, and the fixed reaction plate erected and installed in the housing has an upper end inserted into the second fitting groove and fixed, and a lower end is inserted into the first fitting groove. It is a fixed configuration.

More preferably, the housing may be provided with at least one inspection window.

More preferably, the inlet pipe and the discharge pipe may be integrally formed on both sides of the housing.

More preferably, the inlet pipe and the outlet pipe may be coupled to both sides of the housing by screwing.

More preferably, the inlet pipe and the discharge pipe may be coupled to each other by a bolt to the housing.

More preferably, the housing may be made of aluminum, and the inner surface may be coated with a mixture of nickel and chromium or a mixture of charcoal and germanium.

More preferably, the housing may be injection molded of PVC (Poly Vinyl Chloride) material.

More preferably, the housing may be formed by compression molding a mixture of charcoal and germanium.

More preferably, tourmaline materials such as tourmaline or germanium or noble stone or hygerion or ocher or elvan or macsum stone or charcoal are included in a Teflon component in a powder form, and then coated on the inner surface of the housing. have.

More preferably, the upper end of the rotary reaction tube may have a shape corresponding to the second installation groove, and the lower end of the rotary reaction tube may have a shape corresponding to the first installation groove.

More preferably, the upper and lower ends of the rotary reaction tube may be configured by coating a Teflon component along the outer circumference.

More preferably, the upper and lower ends of the rotary reaction tube may be rotatably installed in the second installation groove and the first installation groove in a state in which a finishing member made of a Teflon material is coupled.

More preferably, the outer shape of the rotary reaction tube may be configured in any one of a circular shape, an oval shape, and a polygonal shape.

More preferably, the rotary reaction tube and the fixed reaction plate are made of a special zinc material in which zinc and bismuth or magnesium are mixed, and the bismuth may be configured to contain less than 2% by weight.

More preferably, the fixed reaction plate may be configured such that the center portion is recessed and protruded toward the rear while being configured in a curved shape.

More preferably, the fixed reaction plate may be configured such that the central portion is recessed and protruded toward the rear, but is protruded in a hemispherical or conical shape.

More preferably, the fixed reaction plate may have a vertical groove so that the through hole of the surface is connected in a vertical direction.

More preferably, the fixed reaction plate may have a horizontal groove through which the through hole of the surface is connected in a horizontal direction.

More preferably, the fixed reaction plate may be formed with a vertical groove and a horizontal groove so that the through hole of the surface is connected in a vertical direction and a horizontal direction.

More preferably, third fitting grooves may be formed on both inner side surfaces of the housing so that both ends of the fixed reaction plate can be fitted.

A water treatment apparatus having a reaction means for stabilizing water quality according to the present invention has the following effects.

That is, the present invention simplifies the shape of the housing to improve manufacturability and coupling power, and by configuring both inlet pipes and discharge pipes on both sides of the housing in a screw connection method or a coupling method using bolts as necessary, the water treatment device is installed It can be connected simply and effectively according to the shape, and has the effect of reducing the possibility of adhesion of foreign substances while maintaining the rigidity of the housing, improving the corrosion prevention, purification and sterilization functions.

In addition, it is possible to simplify the installation of the rotary reaction tube in the housing, which can double the assembly workability and ease of maintenance. By making the rotary reaction tube in a polygonal shape, water quality can be further improved through cavitation. have.

In addition, by depressing the center of the fixed reaction plate installed in the housing to the rear and protruding in a hemispherical or conical shape, it is possible to prevent a decrease in flow velocity while accelerating the flow of fluid toward the center, reduce noise, and improve water quality, As the through-holes on the surface are connected to each other with a vertical groove and a horizontal groove, the flow of the fluid can be induced to further increase the flow velocity, and the noise can be further reduced.

Here, the effects of the present invention described as described above are naturally exerted by the composition of the contents described regardless of whether the inventor recognizes or not, so the above-described effects are only a few effects according to the contents described, and all effects recognized or existed by the inventor. It should not be recognized as describing

In addition, the effect of the present invention will have to be further grasped by the overall description of the specification, and even if it is not described in an explicit sentence, a person having ordinary knowledge in the technical field to which the described content belongs will have such an effect through the present specification. If it is an effect that can be recognized, it should be seen as the effect described in this specification.

1 is an exploded perspective view illustrating a water treatment device provided with a rotary reaction tube according to an embodiment of the present invention.
Figure 2 (a) is a front cross-sectional view showing a water treatment device equipped with a rotary reaction tube according to an embodiment of the present invention.
Figure 2 (b) is a cross-sectional plan view showing a water treatment device equipped with a rotary reaction tube according to an embodiment of the present invention.
3A is a view showing a configuration in which an inlet pipe and an outlet pipe are screwed to the housing according to another embodiment of the present invention.
3B is a view showing a configuration in which an inlet pipe and an outlet pipe are bolted to the housing according to another embodiment of the present invention.
4 is an exploded perspective view illustrating a water treatment device provided with a fixed reaction plate according to another embodiment of the present invention.
5 is a cross-sectional view showing a water treatment apparatus equipped with a fixed reaction plate according to another embodiment of the present invention.

Hereinafter, a configuration and operation according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

This is for explaining in detail enough that those of ordinary skill in the art to which the present invention pertains can easily implement the contents of the present invention, and this does not mean that the technical spirit and scope of the present invention are limited. .

In addition, in adding reference numerals to elements of each drawing, it should be noted that the same elements are marked with the same numerals as much as possible, even if they are indicated on different drawings, and consider the configuration and operation of the present invention. Therefore, specially defined terms may vary according to the intention or custom of users and operators, and definitions of these terms should be determined based on the contents throughout the present specification.

In addition, throughout the specification, when a certain part "includes" a certain component, this means that other components may be further included, not excluding other components unless otherwise stated.

First, the configuration of a water treatment device having a reaction means for stabilizing water quality according to an embodiment of the present invention can be largely divided into a housing and a rotary reaction tube, according to an embodiment of the present invention through the drawings exemplified below. Looking at each component in more detail is as follows.

First, the housing 100,

It may be made of aluminum or brass, which is a diamagnetic material, and the inside and outside may be coated with a Teflon component for smooth static electricity generation.

When the interior of the housing 100 is coated with a Teflon component, a tourmaline material capable of generating negative ions such as tourmaline or germanium may be formed in a powder form or the like, and may be coated with a Teflon component.

Here, the above-described tourmaline material may be noble stone, hygerion, loess, elvan stone, macsum stone, charcoal, etc. in addition to tourmaline or germanium.

In another embodiment, the housing 100 may be manufactured by including a tourmaline material when the housing 100 is manufactured, so that the tourmaline material is included, and after coating the tourmaline material on the inner surface of the housing 100 One surface can be coated with a Teflon component.

When a tourmaline material is provided in the housing 100 as described above, strong electrons are released from the tourmaline material when a fluid pressure or friction is applied inside the housing 100, and when these electrons meet the fluid, hydrogen decomposed into single molecules in the fluid. By bonding with ions, an anion of a surface-active substance called hydroxyl ion is generated, and the generated hydroxyl anion has excellent penetrating power, cleaning power, and decomposition power, converting the acicular structure, which is the particle structure of substances such as rust, into a spherical structure. According to this, rust attached to the inner wall of the pipe is removed.

In addition, the anion of the surface-active material reacts with the carbonate to convert the carbonate particle structure into an acicular structure, thereby suppressing the scale in the pipe and removing the already formed scale.

In another embodiment, the housing 100 is composed of an aluminum material and is coated with a mixture of nickel and chromium on the inner surface, or a mixture of charcoal and germanium, such as a material for a fire plate, is coated, thereby providing antibacterial and purification functions and functions of preventing corrosion. You can have it.

In another embodiment, the housing 100 may be injection-molded of a PVC material so as to improve convenience in manufacturing, improve strength, prevent corrosion, and do not require a separate coating operation.

The housing 100 is formed by compression molding charcoal and germanium, such as a fire plate or a meat plate, as another embodiment, thereby increasing stiffness, preventing corrosion, and eliminating the need for coating on the inner surface, thereby improving manufacturability. The function or sterilization function is improved, and the possibility of adhesion of foreign substances may be reduced.

The shape of the housing 100 does not need to be set to any one, but preferably, as shown in FIGS. 1 and 2, the housing 100 is configured to have a predetermined length while having a substantially rectangular cross section, and the upper surface has an open inlet 160. The branches form a flat seating surface 150, and the cover 140 is coupled to the seating surface 150 through bolts, thereby minimizing the bent portion in the manufacture of the housing 100 to improve fabrication, and the housing ( It is possible to improve the flow of the fluid passing through the inside of 100), it is possible to further improve the bonding force between the housing 100 and the cover 140 by the bolt.

Here, the shape of the housing 100 may be variously configured, such as a circular shape other than the square illustrated in the drawing, or a polygonal shape or an elliptical shape excluding a square when viewed in cross section.

Both sides of the housing 100 are provided with an inlet pipe 110 of a predetermined length and a discharge pipe 120 of a predetermined length so as to be connected to the pipe, so that the fluid moved to the inlet pipe 110 through one pipe is the housing After passing through the interior of 100, it is moved to the other pipe through the discharge pipe 120.

Here, the inlet pipe 110 and the discharge pipe 120 may be configured integrally with the housing 100 as illustrated in FIGS. 1 and 2, but in another embodiment, the housing 100 as shown in FIG. 3 (a) ) Can also be coupled by screwing.

For example, holes are formed on both sides of the housing 100, a female thread is formed in such a hole, and a male thread is formed at the ends of the inlet pipe 110a and the discharge pipe 120a, such that the male thread is formed in the hole of the housing 100. The inlet pipe 110a and the discharge pipe 120a may be screwed into the housing 100 while being screwed to the female thread of the.

In addition, in another embodiment, as shown in (b) of FIG. 3, the inlet pipe 110b and the discharge pipe 120b may be coupled to the housing 100 through bolts.

That is, a flange portion having a bolt hole formed in close contact with the surface of the housing 100 is formed at one end of the inlet pipe 110b and the discharge pipe 120b, and a bolt hole is formed around the outer circumference of the hole formed on the side of the housing 100. As this is formed, the bolt hole formed in the flange portion of the inlet pipe 110b and the outlet pipe 120b is matched with the bolt hole of the housing 100, so that the inlet pipe 110b and the outlet pipe 120b are connected as bolts to the housing 100. It can also be combined with.

At this time, between the flange portion and the outer circumference of the inlet of the housing 100 may further include an airtight holding member, the inside of the housing 100, the bolt hole and a nut that can be fastened to the bolt penetrating the bolt hole May be provided.

The housing 100 may be provided with a drain port communicating with the outside on an inner bottom surface, so that foreign substances accumulated on the bottom surface of the housing 100 may be discharged to the outside of the housing 100 through the drain port.

In addition, a guide groove may be further provided on the bottom surface of the housing 100 so that foreign substances can be effectively moved toward the drain port.

The housing 100 may be provided with at least one inspection window on either surface, a coating layer may be formed on the surface of the inspection window, and the coating layer may be formed on the inner surface of the inspection window or both the inner and outer surfaces when the inspection window is a single window. If the inspection window is a double-glazed window, it may be formed on the inner surface of the inspection window located inside and the outer surface of the inspection window located outside.

The coating layer of the above-described inspection window prevents contamination of the inspection window by a fluid, facilitates cleaning of the inspection window, and reinforces the strength of the inspection window, thereby improving durability.

Such a coating layer may consist of a plurality of layers, for example, an optical silicon layer adhered to an inspection window, a PET layer or tempered glass film layer bonded to the optical silicon layer, and such a PET layer or tempered glass film. A hard coating layer bonded to the layer, and an oleophobic coating layer or a superhydrophobic coating layer bonded to the hard coating layer may be sequentially combined.

The optical silicone adhesive layer is preferably configured to have a transmittance of about 142, the PET layer is preferably made of a transparent synthetic resin, the tempered glass film layer is preferably configured to have a high hardness of about 8 to 9H, and hard It is preferable that the coating layer is configured to have a hardness of approximately 3-4H.

On the other hand, the rotary reaction tube 200,

It is installed inside the housing 100 and serves to stabilize the water quality by preventing scale removal and corrosion of the moving fluid.

The rotary reaction tube 200 may be made of, for example, zinc or anodized aluminum, and an electrostatic generating coating layer in contact with a fluid may be included on the outer surface.

As another example, the rotary reaction tube 200 may be made of magnesium or copper.

The rotary reaction tube 200 may be made of a special zinc material as a preferred embodiment, and this is because zinc is constantly ionized by the galvanic ion exchange principle of zinc, so that zinc, which has a higher ionization tendency than iron, first combines with oxygen in water. Corrosion can be suppressed because iron and oxygen can no longer react.

Here, the special zinc material of the rotary reaction tube 200 may be composed of only 99% by weight zinc, but may be composed of 95% by weight zinc and 5% by weight bismuth, and 98% by weight zinc and 2% by weight. As bismuth may be included, preferably, a special zinc material is composed of zinc and bismuth, but bismuth may be composed of less than 2% by weight, and preferably, a special zinc material is composed of zinc and magnesium. However, magnesium may be comprised of less than 2% by weight.

The rotary reaction tube 200 has a plurality of through-holes 210 through which a fluid passes through an outer surface, and a reaction ball (not shown in the drawing) for water treatment may be provided therein.

Here, the size and number of the through-holes 210 may be variously modified depending on the design specifications of the housing 100 and the rotary reaction tube 200 and the moving conditions of the fluid or the installation environment and the water treatment design environment.

The reaction ball may be made of the same material as the rotary reaction tube 200, but may be made of different materials.

That is, when the rotary reaction tube 200 is made of a special zinc material, the reaction ball may consist of a plurality of zinc materials, tourmaline materials, charcoal and germanium composite materials, or only zinc materials. And, for the efficiency of the reaction, it may be composed of a tourmaline material different from the material of the rotary reaction tube 200.

As an example, the reaction ball may have a spherical shape so as to be less resistant to the flow of a fluid, and discharge a large amount of negative ions through full contact with the fluid.

As another example, the reaction ball may be configured to have a porous structure by sintering or powder metallurgical molding. When the reaction ball has a porous structure, the fluid may penetrate into the pores. It increases considerably compared to the smooth sphere, so a large amount of negative ions can be released into the fluid.

Therefore, in the case of a fluid with a large concentration of inorganic salts, the reaction ball having a porous structure repels a large amount of (-) electrons and diffuses into the fluid, thereby decomposing scale and corrosion caused by hydroxyl action or surface activity. Not only the removal ability is improved, but the overall water treatment capacity can be maximized, such as preventing corrosion on the inner wall of the pipe.

The rotational reaction tube 200 may be spherical or non-spherical, and the spherical shape may have a circular cross-section when viewed in a flat cross-section, and the non-spherical shape may have a fluid flow other than a spherical shape such as an elliptical shape or a long hole shape. It includes all that have a shape such as a streamlined shape or a freeform surface that can receive less resistance against.

The rotary reaction tube 200 is rotated on the inner bottom surface of the housing 100 and the inner surface of the cover 140 so that the upper and lower ends of the rotary reaction tube 200 can be rotatably installed inside the housing 100 Can possibly be installed directly.

That is, a first installation groove 130 in a circular concave shape is formed on the bottom surface of the housing 100, and a second installation groove 141 in a circular concave shape is also formed on the inner surface of the cover 140 According to the stepped portions of the upper and lower ends of the rotary reaction tube 200 are fitted in correspondence with the shape of the second installation groove 141 and the first installation groove 130, the rotational reaction in the housing 100 The tube 200 can be installed simply and quickly so as to be rotatable.

Here, the housing 100 may have a shape in which the center of the bottom protrudes when viewed from the outside due to the first installation groove 130, and the center of the upper surface of the cover 140 also protrudes due to the second installation groove 141. It can also be a form.

The rotary reaction tube 200 is coated with a Teflon component on the outer periphery of the stepped portion so that the stepped portions at the top and the bottom can be smoothly rotated in the first installation groove 130 and the second installation groove 141. As shown in FIG. 1, a ring-shaped finishing member 220 composed of a Teflon component may be additionally coupled to the stepped portions at the upper and lower ends of the rotary reaction tube 200.

Alternatively, as another example, a Teflon component may be coated on the inner circumference of the first installation groove 130 and the second installation groove 141, or a ring-shaped finishing ring made of a Teflon component may be installed, and the top of the rotary reaction tube 200 The Teflon component may be coated on both the stepped portion of the and lower ends and the first installation groove 130 and the second installation groove 141, or the finishing member 220 of the Teflon component and the finishing ring of the Teflon component may be installed respectively. .

Preferably, the rotary reaction tube 200 may be formed in a hexagonal shape when viewed in a flat cross-sectional view as illustrated in FIGS. 1 and 2 (a) and (b), and it is not necessarily limited to this, and is formed in a circular oval shape. It may be, and it may be composed of a polygonal shape such as a quadrangle or an octagonal shape, such as a zigzag shape or an irregular shape, etc.

When the rotary reaction tube 200 is configured in a polygonal, zigzag, irregular shape, such as a quadrangular, hexagonal, or octagonal shape as shown in FIG. 2(b), when the fluid contacts the rotary reaction tube 200 As it collides with the angled part, it causes a cavitation effect and a eddy current phenomenon, forming natural fluid circulation and air bubbles, which can further improve the water quality improvement effect.

Here, the cavitation effect is that a vapor cavity is formed in the fluid to create a small area without liquid.This cavitation effect is a chemical reaction that generates strong oxidizing agents and reducing agents, and efficiently decomposes and eradicates not only contaminated organic compounds but also some inorganic substances. Can induce

That is, the cavitation effect physically destroys or ruptures cell walls or outer membranes of microorganisms and larvae, and also generates bactericidal compounds such as peroxides, hydroxyls, and radicals, thereby erasing microorganisms.

Therefore, as the fluid passing through the interior of the housing 100 collides with the angled portion of the rotary reaction tube 200 and moves, microbubbles are generated through pressure change. After these microbubbles grow, the pressure rise area As it decays in, it dissociates various molecules in the fluid along with the vortex phenomenon to form free radicals, which are powerful oxidizing agents or reducing agents, and organic and other pollutants are removed from the fluid through such physical and chemical reactions, thereby purifying the water quality. .

On the other hand, in the case of a water treatment device having a reaction means for stabilizing water quality according to another embodiment of the present invention, the configuration can be largely divided into a housing and a fixed reaction plate, and each of the components according to it will be described in more detail as follows. .

First, the housing 100,

As mentioned in the above-described embodiment of the housing 100, it may be made of aluminum or brass, which is a diamagnetic material, and the inside and outside may be coated with a Teflon component for smooth static electricity generation.

When the interior of the housing 100 is coated with a Teflon component, a tourmaline material capable of generating negative ions such as tourmaline or germanium may be formed in a powder form or the like, and may be coated with a Teflon component.

Here, the above-described tourmaline material may be noble stone, hygerion, loess, elvan stone, macsum stone, charcoal, etc. in addition to tourmaline or germanium.

In another embodiment, the housing 100 may be manufactured by including a tourmaline material when the housing 100 is manufactured, so that the tourmaline material is included, and after coating the tourmaline material on the inner surface of the housing 100 One surface can be coated with a Teflon component.

When a tourmaline material is provided in the housing 100 as described above, strong electrons are released from the tourmaline material when a fluid pressure or friction is applied inside the housing 100, and when these electrons meet the fluid, hydrogen decomposed into single molecules in the fluid. By bonding with ions, an anion of a surface-active substance called hydroxyl ion is generated, and the generated hydroxyl anion has excellent penetrating power, cleaning power, and decomposition power, converting the acicular structure, which is the particle structure of substances such as rust, into a spherical structure. According to this, rust attached to the inner wall of the pipe is removed.

In addition, the anion of the surface-active material reacts with the carbonate to convert the carbonate particle structure into an acicular structure, thereby suppressing the scale in the pipe and removing the already formed scale.

In another embodiment, the housing 100 is composed of an aluminum material and is coated with a mixture of nickel and chromium on the inner surface, or a mixture of charcoal and germanium, such as a material for a fire plate, is coated, thereby providing antibacterial and purification performance and the functionality of preventing corrosion. You can have it.

In another embodiment, the housing 100 may be injection-molded of a PVC material so as to improve convenience in manufacturing, improve strength, prevent corrosion, and do not require a separate coating operation.

The housing 100 is formed by compression molding charcoal and germanium, such as a fire plate or a meat plate, as another embodiment, thereby increasing stiffness, preventing corrosion, and eliminating the need for coating on the inner surface, thereby improving manufacturability. The function or sterilization function is improved, and the possibility of adhesion of foreign substances may be reduced.

The shape of the housing 100 does not need to be set to any one, but preferably, as shown in FIGS. 4 and 5, the housing 100 is configured to have a predetermined length while having a substantially rectangular cross section, and the upper surface has an open inlet 160. The branch forms a flat seating surface 150, and the cover 140 is coupled to the seating surface 150 through a bolt, thereby improving the flow of fluid passing through the interior of the housing 100, and the housing by the bolt It is possible to further improve the bonding force between the 100 and the cover 140.

Here, the shape of the housing 100 may be variously configured, such as a circular shape other than the square illustrated in the drawing, or a polygonal shape or an elliptical shape excluding a square when viewed in cross section.

Both sides of the housing 100 are provided with an inlet pipe 110 of a predetermined length and a discharge pipe 120 of a predetermined length so as to be connected to the pipe, so that the fluid moved to the inlet pipe 110 through one pipe is the housing After passing through the inside of (100), it is moved to the other pipe through the discharge pipe (120).

Here, the inlet pipe 110 and the discharge pipe 120 may be configured integrally with the housing 100 as illustrated in FIGS. 4 and 5, but in another embodiment, the housing as shown in FIG. 3 (a) described above. It may be coupled to 100 by a screw fastening method.

For example, holes are formed on both sides of the housing 100, and female threads are formed in such holes, and male threads are formed at the ends of the inlet pipe 110a and the discharge pipe 120a. While being screwed into the female thread, the inlet pipe 120a and the discharge pipe 120 may be screwed into the housing 110a.

In addition, as another embodiment, as shown in (b) of FIG. 3 described above, the inlet pipe 110b and the discharge pipe 120b may be coupled to the housing 100 through bolts.

That is, a flange portion having a bolt hole formed in close contact with the surface of the housing 100 is formed at one end of the inlet pipe 110b and the discharge pipe 120b, and a bolt hole is formed around the outer circumference of the hole formed on the side of the housing 100. As this is formed, the bolt hole formed in the flange portion of the inlet pipe 110b and the outlet pipe 120b is matched with the bolt hole of the housing 100, so that the inlet pipe 110b and the outlet pipe 120b are connected as bolts to the housing 100. It can also be combined with.

At this time, between the flange portion and the outer circumference of the inlet of the housing 100 may further include an airtight holding member, the inside of the housing 100, the bolt hole and a nut that can be fastened to the bolt penetrating the bolt hole May be provided.

The housing 100 may be provided with a drain port communicating with the outside on an inner bottom surface, so that foreign substances accumulated on the bottom surface of the housing 100 may be discharged to the outside of the housing 100 through the drain port.

In addition, a guide groove may be further provided on the bottom surface of the housing 100 so that foreign matter can be effectively moved toward the drain port.

The housing 100 may be provided with at least one inspection window on either surface, a coating layer may be formed on the surface of the inspection window, and the coating layer may be formed on the inner surface of the inspection window or both the inner and outer surfaces when the inspection window is a single window. If the inspection window is a double-glazed window, it may be formed on the inner surface of the inspection window located inside and the outer surface of the inspection window located outside.

The coating layer of the above-described inspection window prevents contamination of the inspection window by a fluid, facilitates cleaning of the inspection window, and reinforces the strength of the inspection window, thereby improving durability.

Such a coating layer may consist of a plurality of layers, for example, an optical silicon layer adhered to an inspection window, a PET layer or tempered glass film layer bonded to the optical silicon layer, and such a PET layer or tempered glass film. A hard coating layer bonded to the layer and an oleophobic coating layer or a superhydrophobic coating layer bonded to the hard coating layer may be sequentially combined.

The optical silicone adhesive layer is preferably configured to have a transmittance of about 142, the PET layer is preferably made of a transparent synthetic resin, the tempered glass film layer is preferably configured to have a high hardness of about 8 to 9H, and hard It is preferable that the coating layer is configured to have a hardness of approximately 3-4H.

On the other hand, the fixed reaction plate 200 ′,

It is installed inside the housing 100 and serves to stabilize the water quality by preventing scale removal and corrosion of the moving fluid.

The fixed reaction plate 200 ′ may be made of, for example, zinc or anodized aluminum, and an electrostatic generating coating layer in contact with a fluid may be included on an outer surface thereof.

The fixed reaction plate 200 ′ may be made of magnesium or copper as another example.

The fixed reaction plate 200 ′ may be made of a special zinc material as a preferred embodiment, and this is because zinc is constantly ionized by the galvanic ion exchange principle of zinc, so that zinc, which has a higher ionization tendency than iron, first binds with oxygen in water. Because iron and oxygen can no longer react, corrosion can be suppressed.

Here, the special zinc material of the fixed reaction plate 200 ′ may be composed of 99% by weight zinc, but may be composed of 95% by weight zinc and 5% by weight bismuth, and 98% by weight zinc and 2% by weight. As bismuth may be included, preferably, a special zinc material is composed of zinc and bismuth, but bismuth may be composed of less than 2% by weight.

The fixed reaction plate 200 ′ is erected and installed inside the housing 100 as shown in FIGS. 4 and 5 to divide and divide the interior, and is moved from the inlet pipe 110 to the discharge pipe 120 through the inside. It not only removes foreign substances contained in the fluid, but also prevents corrosion of pipes.

The fixed reaction plate 200 ′ is installed across the inside of the housing 100 so as to form a right angle with respect to the virtual line connecting the inlet pipe 110 and the outlet pipe 120, so that the inside of the housing 100 It is divided into two spaces: 110) side and discharge pipe 120 side.

Therefore, the fluid introduced through the inlet pipe 110 is moved to the discharge pipe 120 through the fixed reaction plate 200 ′, and a plurality of fluids flow through the fixed reaction plate 200 ′ and block foreign substances. The through hole 210' is formed.

Here, the size and number of the through-holes 210 ′ may be variously modified depending on the design specifications of the housing 100 and the fixed reaction plate 200 ′, the moving conditions of the fluid, the installation environment, and the water treatment design environment. .

The fixed reaction plate 200 ′ may be configured to be fixed inside the housing 100 or detachable from the inside of the housing 100 as needed. In an embodiment of the present invention, the fixed reaction plate 200 ′ It is illustrated in a detachable form for cleaning or replacement.

An example in which the fixed reaction plate 200 ′ can be detached from the inside of the housing 100 is a housing in a direction perpendicular to the virtual line connecting the inlet pipe 110 and the discharge pipe 120 inside the housing 100 (100) A third fitting groove 170' is formed in a state opposite to the front and rear of the inner surface of the inside, and the fixed reaction plate 200' can be detached while sliding both ends through the third fitting groove 170'. In this case, both ends of the fixed reaction plate 200 ′ are directly moved along the third fitting groove 170 ′, or along the third fitting groove 170 ′ at both ends of the fixed reaction plate 200 ′. A guide protrusion (not shown in the drawing) may be configured to be movable.

In addition, the fixed reaction plate 200 ′ may be configured in a linear shape, but the discharge pipe () minimizes friction with the fluid moving from the inlet pipe 110 to the discharge pipe 120 and facilitates the flow of the fluid. It is preferable to have a curved arc shape protruding toward 120).

In addition, the lower and upper ends of the fixed reaction plate 200 ′ have a first fitting groove 130 ′ on the inner bottom surface of the housing 100 so that the lower and upper ends of the fixed reaction plate 200 ′ are respectively fixed to the inner surface of the housing 100 and the inner surface of the cover 140. ) Is formed, and a second fitting groove 141' is preferably formed on the inner surface of the cover 140.

In a preferred embodiment, the fixed reaction plate 200 ′ may be configured to protrude in a form in which the central portion 240 ′ is depressed toward the rear toward the discharge pipe 120, and the protruding form has a smaller internal space as the protrusion increases. The paper may be formed in various ways, such as polygonal, hemispherical, or conical.

In this way, when the central portion 240' of the fixed reaction plate 200' protrudes in a depressed shape, the flow of fluid may be accelerated toward the central portion 240', and the protruding shape is from the front to the rear of the central portion 240'. If the inner space becomes narrower as the direction increases, the flow of fluid can be further accelerated, congestion of fluid can be prevented, the passage rate can be improved, and noise can be reduced.

In an embodiment of the present invention, the protruding length of the central portion 240 ′ may be configured to protrude to various lengths as necessary in consideration of the internal design of the housing 100.

More preferably, a vertical groove 220 ′ is formed in the fixed reaction plate 200 ′ so that the front through holes 210 ′ are connected in a vertical direction, but is configured by connecting only the rest of the , It may be configured to be connected as a whole including the central portion 240'.

In addition, a horizontal groove 230 ′ is formed in the fixed reaction plate 200 ′ so that the front through holes 210 ′ are connected in a horizontal direction, but is configured by connecting only the remaining parts except for the central part 240 ′, It may be configured to be connected as a whole including the central part 240'.

In addition, in the fixed reaction plate 200 ′, a vertical groove 220 ′ is formed so that the front through holes 210 ′ are connected in the vertical direction, and a horizontal groove 230 ′ is formed so as to be connected in the horizontal direction. However, the configuration may be configured by connecting only the remaining parts except for the central portion 240 ′, or may be configured by connecting the central portion 240 ′ as a whole.

When vertical grooves 220' or horizontal grooves 230' or vertical grooves and horizontal grooves 230' are formed on the front surface of the fixed reaction plate 200', these vertical grooves 220' and horizontal grooves 230 ') induces the flow direction of the fluid to further increase the flow velocity, and further reduce the noise.

As described above, in the detailed description of the present invention, specific embodiments have been described, but, of course, various modifications may be made without departing from the scope of the described content. Therefore, the scope of the described content is not limited to the described embodiments and does not need to be determined, and should be determined by the claims and equivalents as well as the claims to be described later.

100: housing 110,110a,110b: inlet pipe
120,120a,120b: discharge pipe 130: first installation groove
130': first fitting groove 140: cover
141: second installation groove 141': first fitting groove
150: seating surface 160: entrance
170' first fitting groove 200: rotary reaction tube
200': fixed reaction tube 210,210': through hole
220: finishing member 220' vertical groove
230': horizontal groove 240': center

Claims (21)

It is installed in a section of the pipe through which the fluid is moved, and is rotated by the fluid moving along the pipe inside the housing configured to have a constant length while having a square cross section, so that the fluid can be treated with water. In the water treatment device provided with a pipe,
An inlet pipe 110 is provided on one side of the housing 100, an outlet pipe 120 is provided on the other side, and a first installation groove 130 is formed on the bottom surface of the housing 100 , The inner upper end is composed of a flat seating surface 150 having an open inlet 160,
A second installation groove 141 is formed on the inner surface of the cover 140 coupled to the seating surface 150, and the upper end of the rotary reaction tube 200 is erected and installed inside the housing 100. It is directly rotatably installed in the second installation groove 141, the lower end is directly rotatably installed in the first installation groove 130,
The housing 100 is configured by compression molding a mixture of charcoal and germanium,
A water treatment apparatus having a reaction means for stabilizing water quality, characterized in that the outer shape of the rotary reaction tube 200 is formed in a polygonal shape. In the water treatment device provided with a fixed reaction plate so that the fluid moving along the pipe can be water treated inside the housing, which is installed in a section of the pipe through which the fluid is moved and has a square cross section and has a constant length. ,
An inlet pipe 110 is provided on one side of the housing 100, an outlet pipe 120 is provided on the other side, and a first fitting groove 130' is formed on the bottom surface of the housing 100 And, the upper end of the inside is composed of a flat seating surface 150 having an open inlet 160,
A second fitting groove 141 ′ is formed on the inner surface of the cover 140 coupled to the seating surface 150, and the fixed reaction plate 200 ′ erected and installed in the housing 100 has an upper end of the It is fitted and fixed in the second fitting groove (141'), the lower end is fitted and fixed in the first fitting groove (130'),
The housing 100 is configured by compression molding a mixture of charcoal and germanium,
The fixed reaction plate 200 ′,
A water treatment device having a reaction means for water quality stabilization, characterized in that it is configured in a curved shape and has a conical shape in which the central portion 240 ′ protrudes in a shape that is recessed toward the rear, but the internal space gradually narrows toward the end. The method according to claim 1 or 2,
The housing 100 is a water treatment apparatus having a reaction means for stabilizing water quality, characterized in that at least one inspection window is provided. The method according to claim 1 or 2,
The water treatment device having a reaction means for stabilizing water quality, characterized in that the inlet pipe 110 and the discharge pipe 120 are integrally formed on both sides of the housing 100. The method according to claim 1 or 2,
The water treatment device having a reaction means for stabilizing water quality, characterized in that the inlet pipe (110a) and the discharge pipe (120a) are coupled to both sides of the housing (100) by screwing. The method according to claim 1 or 2,
The water treatment device having a reaction means for stabilizing water quality, characterized in that the inlet pipe (110b) and the discharge pipe (120b) are coupled to each other by bolts to the housing (100). delete delete delete The method according to claim 1 or 2,
A tourmaline material consisting of tourmaline or germanium or noble stone or hygerion or ocher or elvan or macsum stone or charcoal in a powder form, including in a Teflon component, and coating the inner surface of the housing 100 A water treatment apparatus having a reaction means for stabilizing water quality. The method according to claim 1,
The stepped portion at the top of the rotary reaction tube 200 is configured and fitted in a shape corresponding to the second installation groove 141, and the stepped portion at the bottom of the rotary reaction tube 200 is the first installation A water treatment apparatus having a reaction means for stabilizing water quality, characterized in that the groove 130 is configured and fitted in a shape corresponding to the groove 130. The method of claim 11,
A water treatment apparatus having a reaction means for stabilizing water quality, characterized in that the rotary reaction tube 200 is configured by coating a Teflon component along an outer circumference of the stepped portion at the top and the stepped portion at the bottom. The method of claim 11,
A water treatment device having a reaction means for stabilizing water quality, characterized in that a ring-shaped finishing member 220 composed of a Teflon component is coupled to the outer circumference of the stepped portion at the top and the stepped portion at the bottom of the rotary reaction tube 200 . delete The method according to claim 1 or 2,
The rotary reaction tube 200 and the fixed reaction plate 200 ′ are made of a special zinc material in which zinc and bismuth are mixed, and the bismuth is used in an amount of less than 2% by weight. Water treatment device with means. delete delete The method according to claim 2,
The fixed reaction plate 200 ′,
A water treatment apparatus having a reaction means for stabilizing water quality, characterized in that vertical grooves 220 ′ are formed so that the through holes 210 ′ of the surface are connected to each other in a vertical direction. The method according to claim 2,
The fixed reaction plate 200 ′,
A water treatment apparatus having a reaction means for stabilizing water quality, characterized in that horizontal grooves 230 ′ are formed so that the through holes 210 ′ of the surface are connected to each other in a horizontal direction. The method according to claim 2,
The fixed reaction plate 200 ′,
Water treatment having a reaction means for stabilizing water quality, characterized in that vertical grooves 220' and horizontal grooves 230' are formed in a grid shape so that the through hole 210' of the surface is connected in the vertical and horizontal directions Device. The method according to claim 2,
A water treatment device having a reaction means for stabilizing water quality, characterized in that third fitting grooves 170 ′ are formed on both inner sides of the housing 100 so that both ends of the fixed reaction plate 200 ′ can be fitted.

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