KR100689343B1 - Pipe conduit assembly for preventing scale and Method of using the same - Google Patents

Abstract

The present invention relates to a pipe assembly capable of preventing the formation of scales and a method of using the same, by forming a plurality of plastic insulators in a common pipe assembly, and allowing the respective plastic insulators to be offset from each other. The fluid passage of the fluid causes the fluid (water) flowing therein to form turbulent flow due to the vortex phenomenon, and the zinc ions dissolved in the fluid (water) are mixed more efficiently by the turbulent flow. At this time, as a means for shifting the plastic insulator from each other, a plurality of misalignment protrusions and misalignment accommodating portions may be formed at the inlet and the outlet thereof, and misalignment slits are formed at the outer periphery of the fluid in the flow direction of the fluid. It may be combined with the slit fitting material, or may be assembled by forming a separate fluid path obstruction member.

The present invention can more effectively prevent the corrosion of the metallic piping material by such a pipe assembly, it is possible to effectively prevent the formation of the scale formed on the inner pipe wall.

Metal Piping, Piping Assemblies, Scale Protection, Inner Pipe Walls, Rust Removal, Corrosion Protection

Description

Pipe conduit assembly for preventing scale and method of using the same

1 is a schematic view of a conventional anti-scaling pipe material,

2 is an exploded perspective view of a pipe assembly according to the present invention;

3 is a conceptual diagram showing the relationship between the coupling state of the plastic insulators of the pipe assembly according to the invention and the resulting fluid passages,

4 is a cross-sectional view of the coupling state of the pipe assembly according to the present invention;

5 is a cross-sectional view showing a coupling state of another embodiment of the present invention;

6 is a conceptual view illustrating a case in which the pipe assembly according to the present invention includes a fluid passage obstruction member,

7 is a conceptual view illustrating a case in which the pipe assembly according to the present invention includes a fluid passage obstruction member and a plastic insulator alternately arranged one by one.

♠ Explanation of symbols for the main parts of the drawings.

100: pipe assembly (invention), 110: body portion,

120, 221, 222, 223, 224: plastic insulator,

122, 132: fluid passages, 124: misalignment projections,

125: misalignment housing, 126: misalignment slit,

128: slit fitting material, 130: zinc metal body,

150: fluid path obstruction member, 152: bottom plate,

154: euro blocking portion, 156: euro opening portion

The present invention relates to a pipe assembly capable of preventing the formation of scales and a method of using the same, and more particularly, to prevent corrosion of metallic piping materials more effectively and to prevent the formation of scales formed on the inner pipe walls thereof. It relates to a pipe assembly and a method of using the same.

Water is becoming an indispensable survival condition in our daily lives or industrial activities. In order to supply such water in large quantities and in a stable manner, most countries have a water management system as a national project.

Today's alternative water management systems obtain large amounts of water from the first source, then treat the water physicochemically, and send the treated water to the end users, between the first source and the end users. The piping system is used.

For example, in the case of a water supply system used in a general household, it is sent to the water purification plant from the first water source, and the water purification plant filters various suspended matters, deodorizes with activated carbon, sterilizes with chlorine, etc., and is suitable for drinking water. Processing is carried out. Water suitable for such drinking water is supplied to each household via water pipes, and each household uses it as needed.

This series of processes is the same for industrial water, where the raw materials are processed or unprocessed at the original water source and supplied to the final place of use.

By the way, in such a water treatment system, a problem that arises is the piping system to send water between the original water source and the final destination.

Commonly used piping systems are metal pipes that are adopted in consideration of the robustness and the simplicity of processing. Such metal pipes (particularly cast iron pipes) naturally contain iron, which has the disadvantage of causing corrosion of the water flowing therein. The corrosion caused by the metal tube, although weak, is caused by friction with water molecules flowing through it, and the friction causes a potential difference. In the process, the iron component is deprived of electrons and converted into iron ions. It is known that iron ions react with oxygen in water to produce iron oxide.

This is represented by the chemical formula below.

^{Fe 〓 Fe 2 + + 2 e} -

Fe ^{2 +} + O ₂ + H ₂ O = Fe ₂ O ₃

On the other hand, there is a case in which copper pipes are used in fear of corrosion problems such as cast iron pipes containing iron, which is mainly used in small pipes because copper pipes are more expensive than cast iron pipes. However, the copper tube can solve the problem of corrosion caused by iron, but can not fundamentally prevent the rust phenomena, and when the rust is generated, it is not only harmful to the human body, but also expensive. There are disadvantages not suitable for large piping systems.

In addition, since the copper tube does not corrode, its durability can be recognized, but scale and scale formed in the copper tube cannot be prevented. This is because various mineral components are dissolved in water, and calcium components are included in the water. Calcium ions (Ca ²⁺ ) dissolved in water are also dissolved in water and carbon dioxide (H ₂ CO ₃ ). This is because the combination forms an insoluble calcium carbonate (CaCO ₃ ), and the calcium carbonate (CaCO ₃ ) is attached to the wall surface of the piping material having the weakest flow rate in the piping material, thereby forming a so-called scale. This phenomenon occurs similarly in the case of scale.

When the scale is formed in the copper pipe, the scale becomes gradually larger and blocks the passage inside the pipe, thus acting as a factor that significantly lowers the flow velocity. Therefore, even when the piping material is made of copper, it is not possible to fundamentally solve the scale forming action.

On the other hand, it can be expected to use a plastic pipe as a piping material without using a metal iron pipe or a copper pipe. However, in the case of plastic pipes, there are advantages such as economy and processability, but they are not vulnerable to external pressure and cannot guarantee durability, and moreover, plastic resin components are eluted in flowing water. Since it is extremely harmful to the human body, it is not suitable as a general drain pipe for a specific purpose.

Taking these points together, the most common plumbing material to date is a metal pipe. As mentioned above, the metal pipe has the problem of corrosion and scale formation, but there is no substitute pipe material, so it is continuously used.

As such, metal pipe materials conventionally used do not solve the problem of corrosion and scale formation at all, and prior arts as improved products thereof also do not efficiently solve the problem of corrosion and scale formation. It is true.

For example, in order to solve the shortcomings of the metal pipe material, various types of products have appeared, and among them, the most efficient product is related to Korean Patent Registration No. 313778, "Fluid Treatment Apparatus and Method."

1 relates to the Korean Patent Registration No. 313778 "Fluid Treatment Apparatus and Method" which is used to prevent scale of piping materials, and the shape thereof is relatively well illustrated.

The conventional fluid treatment apparatus 50 includes a housing body 12 and a channel separator 24 made of a plastic material therein, the channel separator 24 forming a plurality of small holes 26. Doing. At this time, the channel separator 24 is formed in a radially concave radial section of one surface thereof, thereby changing the flow of the fluid. In addition, the conventional fluid treatment apparatus 50 further includes a metal channel separator 40 adjacent to the channel separator 24. Although the metal channel separator 40 described above is preferred to use zinc among metals, specific actions thereof are not mentioned. The metal channel separator 40 is also provided with a plurality of holes 42.

The conventional fluid treatment device 50 is installed in the middle of a metal pipe (not shown), and performs the following actions with water flowing therein, thereby preventing corrosion and scale formation of the pipe material. It is known.

In the conventional fluid treatment apparatus 50, water flowing from the piping material flows through the hole 42 of the metal channel separator 40, and the water causes friction to the wall surface of the hole 42 so that the metal channel The zinc component of the separator 40 is dissolved. Since zinc is very excellent in ionization tendency, especially since ionization tends to be very high compared to iron, zinc ions already dissolved in water prevent the iron component from being ionized from metal tubes such as cast iron tubes. Corrosion can be fundamentally prevented.

On the other hand, the zinc metal and iron components are very different in the ionization tendency, and when they are deposited in the same solvent, the potential difference is generated, the generation of microorganisms by this potential difference is suppressed, such as scale or scale It is assumed that contamination is prevented.

However, the conventional oil treatment apparatus 50 corresponds to a mechanism having such excellent performance, but the plastic channel separator 24 and the metal channel separator 40 are sequentially arranged inside the housing body 12. Alternatively, they are arranged alternately. This is because the water flowing therein is generally of a type close to or similar to the normal flow, and thus has a certain limit to sufficiently exhibit the performance of the conventional oil treatment apparatus 50.

Accordingly, an object of the present invention is to provide a pipe assembly and a method of using the same, which can be provided more effectively and efficiently to the problems of corrosion and scale formation of the metal pipe material by mounting it between the metal pipe materials while using the conventional metal pipe material as it is. To provide.

The present invention relates to a pipe assembly and a method of using the same that can prevent corrosion and the formation of scale.

The present invention provides a pipe assembly including a body part having a connection part connected to a metal pipe member, a plastic insulator mounted inside the body part, and a zinc metal body tightly coupled to the plastic insulator. Is formed by assembling a plurality of plastic insulators, each plastic insulator having a plurality of fluid passageways, each of which separates the flow of water, each plastic insulator having a plurality of misalignments at the outer periphery of its inlet and outlet portions. It has a projection part and many misalignment accommodating parts engaging with it and it is characterized by the said fluid passage being mutually coupled mutually with respect to the moving direction of the fluid in the state fully assembled by one plastic assembly.

In the present invention, in the case of the above-described zinc metal body, it is preferable that the plastic assembly, their fluid passages, and the fluid passages are deviated from each other by the same method.

Further, in the present invention, the plastic insulator can form a misalignment slit recessed in the longitudinal direction at its outer periphery, and the misalignment slit is coupled to the front slit in a straight line. As a result, it is preferable that the fluid passage of the front plastic insulator and the fluid passage of the rear plastic insulator are mutually coupled to each other.

In addition, in the present invention, the plastic insulator may be coupled to the front or the rear thereof, and may further include a fluid passage obstruction member for blocking the straight running direction of water entering or exiting the fluid passage. . The fluid passage obstruction member includes a bottom plate which forms a bottom surface as a whole and is coupled to the inside of the plastic insulator, and a flow path blocking portion that is formed directly above the fluid passage and obstructs the linear traveling direction of the water; It is formed around the blocking portion and includes a flow path opening portion through which disturbed water flows.

Pipe assembly according to the present invention may include a plurality of fluid passage obstruction members.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in more detail. However, the accompanying drawings are only intended to describe the technical spirit of the present invention in more detail, and the technical spirit of the present invention is not limited thereto.

2 is an exploded perspective view of the pipe assembly 100 according to the present invention, and illustrates a form in which a plurality of plastic insulators 221, 222, and 223 are assembled.

FIG. 3 illustrates a correlation between the plastic insulators 221, 222, and 223 of the pipe assembly 100 and the resulting fluid passageway 122 according to the present invention.

4 is a cross-sectional view showing a coupling state of the pipe assembly 100 according to the present invention.

The pipe assembly 100 according to the present invention basically has a body portion 110 having a connection portion 112, a plastic insulator 120 mounted inside the body portion, and zinc that is tightly coupled to the plastic insulator. It is configured to include a metal body 130, which is not much different from a conventional product.

In the present invention, the zinc metal body 130 has a plurality of fluid passages 132, the water flows through the fluid passage 132, the material of the zinc metal body 130 in the process The zinc components that make up the water are dissolved in small amounts and mixed in the flowing water. At this time, since the zinc (Zn) component has a very high ionization tendency, and particularly has a high ionization tendency compared to the iron (Fe) component that forms the piping material, the zinc component dissolved in water is fundamentally responsible for the melting of the iron component in water. It can be prevented. Therefore, the water exiting the fluid passage 132 of the zinc metal body 130 is preferably mixed further in the subsequent process.

In the present invention, the plastic insulator 120 is formed by assembling a plurality of plastic insulators 221, 222, 223. This is because when the plurality of plastic insulators 221, 222, 223 are joined to each other, their fluid passages 122 are coupled to each other to allow the water flowing therein to form turbulent flows rather than normal flows. will be. In the case of steady flow, the mixing effect is not very high in the water flow process, whereas in turbulent flow, the mixing effect is relatively high.

In the present invention, the plastic insulators 221, 222, 223 each have a plurality of fluid passages 122 that separate the flow of water. In addition, each of the plastic insulators 221, 222, and 223 includes a plurality of misalignment protrusions 124 and a plurality of misalignment accommodating portions 125 that are misaligned with the plurality of misalignment protrusions 124 on the outer periphery of the inlet and outlet portions thereof. Have. The misalignment protrusion 124 and the misalignment accommodating portion 125 are formed in the plastic insulator 120 when they are assembled with each other, so that the fluid passage 122 is moved in the direction of movement of the fluid (water). To be coupled out of alignment with one another.

This relationship is described in more detail with reference to FIG. 3. In FIGS. 3A and 3B, the first plastic insulator 221, the second plastic insulator 222, the third plastic insulator 223, and the fourth plastic insulator 224 are described. Exemplarily illustrates the principle of coupling to each other through the misalignment protrusion 124 and the misalignment accommodating part 125. Therefore, the plastic insulator 120 may be formed of only the first plastic insulator 221 and the second plastic insulator 222, and a third plastic insulator 223 may be added thereto, and the plastic insulator 120 may be further added thereto. have.

In the present invention, in the case of the zinc metal body 130, it is preferable that the plastic insulator 120, their fluid passage 122 and the fluid passage 132 are coupled to each other in the same manner.

As shown in FIG. 4, the pipe assembly 100 according to the present invention is preferably arranged with a zinc metal body 130, a plastic insulator 120, and a zinc metal body 130, but is not necessarily limited thereto. In addition, the plastic insulator 120 may be alternately disposed after the zinc metal body 130.

As another embodiment, the pipe assembly 100 according to the present invention may include a misalignment slit 126 as a means for misaligning the fluid passage 122 of the plastic insulator 120. .

FIG. 5 illustrates an embodiment including a misalignment slit 126 recessed in the outer circumference of the plastic insulator 120 along its longitudinal direction. In the present invention, the misalignment slit 126 is coupled in a straight line with the front slit, as a result, the fluid passage 122 of the front plastic insulator 221 and the rear plastic insulator 222. Allow fluid passages 122 to be coupled to each other. This can be done by slightly differently forming positions of the fluid passage 122 of the plastic insulator 221 and the alignment slit 126. At this time, by using the slit fitting material 128 fitted in the straight line to the misalignment slit 126, the slit fitting material 128 is inserted into the misalignment slit 126 and closely adhered thereto. The fluid passages 122 are simply arranged to be offset from each other, and the fluid (water) flowing therein forms turbulent flow and is more efficiently mixed.

As another embodiment, the pipe assembly 100 according to the present invention may further include a fluid passage barrier member 150 that may be coupled to the front or rear side of the plastic insulator 120.

FIG. 6 illustrates a case in which the pipe assembly 100 according to the present invention includes the fluid passage obstruction member 150, wherein the fluid passage obstruction member 150 is located in front of the plastic insulator 120. It shows the case where they are arranged in combination.

FIG. 7 illustrates a case in which the fluid passage barrier members 150 are alternately arranged together with the plastic insulator 120.

Pipe assembly 100 according to the present invention includes a fluid passage obstruction member 150. In the present invention, the fluid passage obstruction member 150 may be coupled to the front or the rear of the plastic insulator 120, and the straight line of water entering or exiting the fluid passage 122 It blocks the direction of travel and then causes the flowing water to form a severe vortex and then proceed in the form of the vortex.

In the present invention, the fluid passage obstruction member 150 includes a bottom plate 152 that forms a bottom surface as a whole and is coupled to the inside of the plastic insulator 120. In addition, the fluid passage obstruction member 150 includes a flow path blocking portion 154 that is formed directly above or directly below the fluid passage 122 to obstruct the linear traveling direction of the water. The flow path blocking portion 154 causes the flowing water to interrupt the direction of travel, thereby converting the steady flow into turbulent flow. In addition, the fluid path obstruction member 150 includes a flow path opening part 156 formed around the flow path blocking part 154 and into which the blocked water flows. The flow path opening portion 156 performs a function as a passage through which the disturbed water is switched from a normal flow to a turbulent flow, and then the turbulent flows.

Pipe assembly 100 according to the present invention may be formed to include a plurality of the fluid passage obstruction member 150. For example, as shown in FIG. 6, the fluid path obstruction member 150 may be formed in front of the plastic insulator 120 as one, and the fluid path obstruction member 150 may be formed as shown in FIG. 7. It may be formed alternately with the plastic insulator 120 as a dog, in addition to it may be coupled directly to the front or the back of the zinc metal body 130.

The pipe assembly 100 of the present invention configured as described above is operated as follows, and can be usefully used by using this phenomenon.

The pipe assembly 100 according to the present invention is basically used by cutting a part of a metallic pipe material (not shown) and then joining it therebetween. Therefore, water supplied from a source of water, such as a water purification plant, first flows into the metallic piping material, flows into the interior of the pipe assembly 100 of the present invention, and then flows to the final destination through the metallic piping material coupled thereto. .

At this time, the water flowing through the pipe assembly 100 of the present invention dissolves zinc ions from the zinc metal body 130, and the water in which zinc is dissolved flows inside the plastic insulator 120. Severe vortices during the process result in higher mixing efficiency. By this mixing efficiency, the zinc component reduces the iron ions dissolved in the previous metallic piping material to metallic iron, thereby making it adhere to the metallic piping material existing below, thus more effectively preventing the ongoing corrosion phenomenon. It becomes possible.

In addition, since the iron ions remaining in the water after the reduction of the iron ions have a greater tendency to ionize than the iron ions, it is possible to fundamentally prevent the iron component of the metallic piping material to be dissolved in water.

In addition, since the remaining zinc ions have a greater tendency to ionize than components such as calcium and magnesium, the zinc ions and magnesium ions can be prevented from forming insoluble calcium and the like as they are dissolved in water. As a result, it is possible to more effectively prevent the scale from being formed inside the piping material.

As described above, the pipe assembly according to the present invention intentionally changes the flow of the fluid (water) flowing therein or intentionally interrupts the flow of the fluid (water) as compared to the conventional product. It is possible to form a severe vortex, and in the process so that the zinc component dissolved in the zinc metal body 130 is more efficiently mixed with the fluid (water).

Therefore, when using the pipe assembly according to the present invention, there is an advantage that can effectively prevent the corrosion phenomenon of the metal pipe material by converting the metal iron ions to the metal iron component more effectively.

In addition, in the case of using the pipe assembly according to the present invention, it is possible to more effectively prevent the formation of insoluble components by reacting with other components in water by converting components such as calcium and magnesium dissolved therein into their original state. There are also advantages.

Since the piping assembly according to the present invention can be used for a piping system made of metallic piping materials, special facilities using large amounts of tap water, such as general water pipes, domestic water pipes, water pipes of large group facilities such as apartments, hotels and sauna facilities, It can be used in various ways such as water facilities of factories using industrial water.

 Although the pipe assembly according to the present invention and a method of using the same have been described in detail, this is only for describing the most preferred embodiment of the present invention, and the present invention is not limited thereto, and the scope is defined by the appended claims. Is determined and defined.

In addition, anyone of ordinary skill in the art will be able to make various modifications and imitations by the description of the specification of the present invention, but it will be apparent that this is also outside the scope of the present invention.

Claims (9)

Body portion 110 having a connection portion 112 connected to the metal pipe, a plastic insulator 120 mounted inside the body portion, and a zinc metal body 130 is in close contact and coupled to the plastic insulator In the pipe assembly, The plastic insulator 120 is formed by assembling a plurality of plastic insulators 221, 222, 223, Each plastic insulator 120 has a plurality of fluid passages 122 that each separate a flow of water, Each of the plastic insulators 221, 222, and 223 has a plurality of misalignment protrusions 124 and a plurality of misalignment accommodating portions 125 at the outer periphery of the inlet and outlet, and the plastic insulator 221. A plurality of misalignment protrusions 124 of the outlet portion of the outlet) and a plurality of misalignment accommodating portions 125 of the inlet portion of the plastic insulator 222 are coupled to each other, and a plurality of misalignment portions of the outlet portion of the plastic insulator 222. When the fitting protrusion 124 and the plurality of misalignment accommodating portions 125 of the inlet portion of the plastic insulator 223 are coupled to each other, the fluid passage 122 of the fitting protrusion 124 is completely assembled into one plastic assembly. Are coupled to each other with respect to the direction of fluid movement, As a result, the water flowing through the plastic insulator 120 forms a vortex, so that the zinc ions dissolved in the water are more efficiently mixed. The method of claim 1, The plastic insulator 120 includes a misalignment slit 126 recessed in its outer peripheral portion in the longitudinal direction thereof, and the misalignment slit 126 is linearly aligned with the front slit. And, as a result, the fluid passageway (122) of the front plastic insulator (221) and the fluid passageway (122) of the rear plastic insulator (222) are alternately coupled to each other. The method of claim 2, The plastic insulator 120 is fitted into the alignment slit 126 formed on the outer circumference of the plastic insulator 126 in a straight line by using a slit fitting material 128, and is brought into close contact with each other so that the fluid passages 122 are easily aligned with each other. Piping assembly characterized in that the arrangement. The method of claim 1, The plastic insulator 120 inserts and inserts a separate fluid passage obstruction member 150 instead of coupling the misalignment protrusion 124 and the misalignment accommodating portion 125. At this time, the fluid path obstruction member 150 is coupled to the front or rear of the plastic insulator 120, As a result, the water flowing through the plastic insulator 120 forms a vortex, so that the zinc ions dissolved in the water are more efficiently mixed. The method of claim 4, wherein The fluid passage obstruction member 150 forms a bottom surface as a whole and is formed on the bottom plate 152 which is coupled to the inside of the plastic insulator 120 and directly above the fluid passage so that the water flows in a straight line. And a flow path opening portion (156) formed around the flow path blocking portion (154) and formed in the periphery of the flow path blocking portion (154) to allow the blocked water to flow therein. The method according to any one of claims 1 to 5, The plastic insulator (120) is a pipe assembly, characterized in that its fluid passage (122) is coupled to the fluid passage (132) of the zinc metal body (130) to be offset from each other. Body portion 110 having a connection portion 112 connected to the metal pipe, a plastic insulator 120 mounted inside the body portion, and a zinc metal body 130 is in close contact and coupled to the plastic insulator In the method using the piping assembly, The plastic insulator 120 is formed by assembling a plurality of plastic insulators 221, 222, 223, Each plastic insulator 120 has a plurality of fluid passages 122 that each separate a flow of water, Each of the plastic insulators 221, 222, and 223 has a plurality of misalignment protrusions 124 and a plurality of misalignment accommodating portions 125 at outer periphery of the inlet and outlet thereof. The plurality of misalignment protrusions 124 of the outlet portion of the outlet 221 and the plurality of misalignment accommodating portions 125 of the inlet portion of the plastic insulator 222 are coupled to each other, and the plurality of misalignment accommodating portions 125 of the outlet portion of the plastic insulator 222. When the misalignment protrusion 124 and the plurality of misalignment accommodating portions 125 of the inlet portion of the plastic insulator 223 are coupled with each other, the fluid passage 122 is completely assembled in a single plastic assembly. Are coupled to each other with respect to the direction of movement of the fluid, As a result, the water flowing through the plastic insulator 120 forms a vortex so that zinc ions dissolved in the water are more efficiently mixed. The method of claim 7, wherein The plastic insulator 120 includes a misalignment slit 126 that is recessed in the outer circumferential portion thereof in the longitudinal direction, and the misalignment slit 126 is formed by the slit fitting material 128. The front slit is coupled in a straight line, and as a result, the fluid passage 122 of the front plastic insulator 221 and the fluid passage 122 of the rear plastic insulator 222 are engaged with each other so as to be offset from each other. A method of using a pipe assembly, characterized in that the water flowing through the vortex forms a vortex and the zinc ions dissolved in the water are more efficiently mixed. The method of claim 7, wherein The plastic insulator 120 further includes a fluid passage obstruction member 150, wherein the fluid passage obstruction member 150 forms a bottom surface as a whole and is coupled to the inside of the plastic insulator 120. A plate 152, a flow path blocking portion 154 formed just above the fluid passageway and obstructing the linear traveling direction of water, and a flow path opening portion 156 formed around the flow path blocking portion 154. It includes, the water flowing in the interior is interrupted by the flow direction of the flow path blocking portion 154, causing the vortex, the vortex flows through the flow path opening 156, A method of using a pipe assembly, wherein zinc ions dissolved in water are more efficiently mixed.

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