KR20210023913A - Manifold fitting structure for pipe line - Google Patents

Abstract

The present invention relates to a manifold fitting structure for pipes and, more specifically, to a manifold fitting structure for pipes, wherein pipe composition can be simplified and fusion points can be reduced through thermal fusion of a connection part with an existing pipe at a direction switching spot and a branch pipe of a pipe having a flow path in which fluids flow, by using a plurality of manifold elbow tees, a manifold twin tee, an elbow reducer and the like. Thus, working hours can be shortened through convenient construction, and also efficiency and stability can be secured in regard to the design and composition of pipes through easy maintenance including a reduction in leak points, a reduction in workloads, a reduction in management points, and the like.

Description

Manifold fitting structure for pipe line}

The present invention relates to a structure of a manifold fitting of a pipe, and more particularly, a plurality of manifold elbow tee, manifold twin tee, elbow reducer, etc. are used to move fluid inside. Simplify the piping configuration by thermally fusing the connection part with the existing pipe at the branch pipe and direction change point of the pipe where the flow path is formed, and reduce the fusion point, thereby simplifying the construction and shortening the work time as well as reducing the leak point. It relates to a manifold fitting structure of a pipe that can improve efficiency and secure stability in designing and configuring a pipe due to easy maintenance such as reduction of work load and reduction of management points.

In general, in a semiconductor manufacturing process or an LCD manufacturing process, piping for various fluid supply facilities is essentially installed for stably and safely supplying various types of fluids to a process chamber in a clean room section in a constant quality state.

When manufacturing a substrate in such a semiconductor manufacturing process, various chemical solutions (Chemical) and ultrapure water (UPW) (ultrapure water containing hydrogen or ozone, i.e., so-called hydrogen water or ozone water) are used, and the fluid supply facility is a process device. It requires special piping equipment with sufficient cleanliness, corrosion resistance and strength to prevent contamination or leakage while keeping the fluid in high purity throughout the process.

PFA manifold fitting (also referred to as a special fitting) is a manifold type made of fluorine resin widely used in piping equipment of semiconductor and LCD manufacturing facilities, piping equipment of food manufacturing facilities, or piping equipment of chemical manufacturing facilities. As a fitting, it has excellent performance and chemical resistance from metal contamination and eluted ions, and is used as a piping material for supplying chemicals or gas transfer.

However, the conventional PFA fitting has a structure formed by forming a large number of fusion points, and thus has a problem in that safety is considerably weak and work efficiency is poor due to a large number of management sections and leak points. Accordingly, there is a need for an improved manifold fitting structure capable of solving this problem.

Korean Patent Registration No. 10-0770315 (2007.10.19) Korea Registration No. 10-0329582 (2002.03.09.)

As a result of intensive research in order to improve the problems associated with the conventional fitting as described above, and to develop an efficient piping connection structure, the present inventors have developed a manifold fitting including a manifold twin tee formed in various structures as described below. Accordingly, it was found that this problem can be solved by reducing the welding point of the pipe, and the present invention was completed.

The problem to be solved by the present invention is not limited thereto, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

Accordingly, an object of the present invention is to provide a pipe manifold fitting structure in which a welding point of a pipe is significantly reduced by a manifold fitting.

The object of the present invention as described above in the manifold fitting structure of the pipe,

At least one manifold twin tee in which two or more branch pipes are orthogonal to the horizontal type pipe but communicated so that the fluid flows;

One or more manifold elbow tees in which one or more branch pipes are orthogonal to the horizontal type pipe and an end portion thereof is formed as an elbow pipe to communicate with the fluid to flow; And

At least one branch pipe is orthogonal to the horizontal type pipe and the end is formed as an elbow pipe to communicate with the fluid to flow, and the branch pipe is at least one manifold elbow reducer whose diameter is reduced. It can be achieved by the manifold fitting structure of the pipe, characterized in that the heat fusion point is reduced by heat-sealing the connection part at the branch pipe and the direction change point of the pipe in which the flow passage through which the fluid moves is formed.

According to the manifold fitting structure of the pipe according to the present invention, the construction is simplified by simplifying the connection structure of the pipe and thus the work time is shortened, and maintenance is easy, such as reduction of leak points, reduction of work load, and reduction of management points. In designing and configuring piping, it is possible to achieve efficiency and secure stability.

1 is a diagram illustrating a structure of a manifold fitting of a pipe according to the present invention.
2 is a diagram illustrating various types of piping forming a manifold fitting structure for piping.
3 and 4 are views for explaining a manifold elbow tee used in the manifold fitting structure of the present invention.
5 is a diagram illustrating a manifold elbow reducer used in the manifold fitting structure of the present invention.
6 and 7 are views illustrating a manifold twin tee used in the manifold fitting structure of the present invention.
8 and 9 are views for explaining a manifold twin tee according to another embodiment used in the manifold fitting structure of the present invention.
10 is a diagram illustrating a manifold fitting structure according to an embodiment of the present invention.
11 is a diagram illustrating a manifold fitting structure according to another embodiment of the present invention.
12 is a diagram illustrating a manifold fitting structure according to another embodiment of the present invention.
13 is a diagram illustrating a manifold fitting structure according to another embodiment of the present invention.
14 is a perspective view showing a heat fusing machine for heat fusing of a pipe.

In one aspect, the present invention, in the manifold fitting structure of the pipe,

At least one manifold twin tee in which two or more branch pipes are orthogonal to the horizontal type pipe but communicated so that the fluid flows;

One or more manifold elbow tees in which one or more branch pipes are orthogonal to the horizontal type pipe and an end portion thereof is formed as an elbow pipe to communicate with the fluid to flow; And

At least one branch pipe is orthogonal to the horizontal type pipe and the end is formed as an elbow pipe to communicate with the fluid to flow, and the branch pipe is at least one manifold elbow reducer whose diameter is reduced. A manifold fitting structure of a pipe, characterized in that a heat fusion point is reduced by heat-sealing a connection part at a branch pipe and a direction change point of a pipe in which a flow passage through which a fluid moves is formed is provided.

The present invention, in a further aspect,

The material of the pipe is PFA resin or fluororesin,

The manifold twin tee, elbow tee, and manifold elbow reducer provide a pipe manifold fitting structure, characterized in that the diameter of the horizontal pipe and the diameter of the branch pipe are the same or different.

The present invention, in a further aspect,

The manifold elbow tee has an annular bulging portion 114, 115, 117 formed on an outer circumferential surface at a point where the horizontal pipes 111 and 118 and the branch pipes 112 and 113 are orthogonal to each other, and the annular bulging portion ( At points where 114, 115, 117 are orthogonal, support portions 116 are formed on both sides, and inner diameters of the horizontal pipes 111 and 118 and the branch pipes 112 and 113 are formed to have a constant size, and the horizontal pipe 111 The end of) is formed by an elbow tube,

The manifold elbow reducer has annular bulging portions 213 and 214 formed on an outer circumferential surface at a point where the horizontal pipe 211 and the branch pipe 212 are orthogonal, and the annular bulging portions 213 and 214 are orthogonal. The support part 215 is formed at the point where the horizontal pipe 211 and the branch pipe 212 have an inner diameter of a certain size, and the end of the horizontal pipe 211 is formed as an elbow pipe, and the branch pipe ( The diameter of 212) is reduced, and the elbow tube is formed in a structure in which the diameter is reduced while being rounded,

The manifold twin tee has an annular bulging portion 314 and 315 formed on an outer circumferential surface at a point where the horizontal pipes 311 and 317 and the branch pipes 312 and 313 are orthogonal to each other, and the annular bulging portion 314, Supports 316 are formed on both sides at a point where 315 is orthogonal to each other, and the horizontal pipe 311 and the branch pipes 312 and 313 have an inner diameter of a constant size. .

In another further aspect of the present invention,

The thermal fusion provides a pipe manifold fitting structure, characterized in that it is performed by ultrasonic vibration heating fusion or high frequency induction heating fusion.

Hereinafter, the present invention will be described in detail on the basis of the accompanying exemplary drawings.

Meanwhile, the present invention may be modified in various ways and may have various embodiments, and specific embodiments will be described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all changes, equivalents, or substitutes included in the spirit and scope of the present invention.

In addition, terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate the existence of features, numbers, steps, actions, components, parts, or a combination thereof described in the specification, and one or more other features It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof does not preclude in advance.

1 is a diagram illustrating a structure of a manifold fitting of a pipe according to the present invention, FIG. 2 is a diagram illustrating various types of pipes forming a manifold fitting structure of a pipe, and FIGS. 3 and 4 are manifolds of the present invention. A diagram illustrating a manifold elbow tee used in a hold fitting structure, FIG. 5 is a diagram illustrating a manifold elbow reducer used in a manifold fitting structure of the present invention, and FIGS. 6 and 7 are a manifold fitting of the present invention. A diagram illustrating a manifold twin tee used in the structure, FIGS. 8 and 9 are diagrams illustrating a manifold twin tee used in the manifold fitting structure of the present invention, and FIG. 10 is a diagram illustrating a manifold twin tee used in the structure. FIG. 11 is a diagram illustrating a manifold fitting structure, FIG. 11 is a diagram illustrating a manifold fitting structure according to another embodiment of the present invention, and FIG. 12 is a diagram illustrating a manifold fitting structure according to another embodiment of the present invention. 13 is a view for explaining a manifold fitting structure according to another embodiment of the present invention, and FIG. 14 is a perspective view showing a heat fusion machine for heat fusion of a pipe.

As shown in Figs. 1 to 13, the manifold fitting structure of the pipe according to the present invention (hereinafter, may be used interchangeably with the term "pipe") is largely a plurality of manifold twin tee, manifold. It is characterized in that the heat fusion point is reduced by heat-sealing the connection at the branch pipe and the direction change point of the pipe in which the flow passage through which the fluid moves is formed using an elbow tee, an elbow reducer, etc. do.

As shown in Fig. 1, by fusing the fitting portion 101 and the pipe 102 or the fitting portion 101 and the elbow pipe 103 and the pipe reducer 104 according to the prior art (a) to reduce the used section In the present invention (b), by simplifying the connection structure of the pipe by simplifying the connection structure of the pipe by using only one manifold fitting, not only the work time is shortened due to the simple construction, but also maintenance such as reduction of leak points, reduction of work load, and reduction of management points is possible. It is easy to design and construct a pipe, thereby providing various advantages, such as being able to increase efficiency and secure stability.

The pipe used in the present invention may be a pipe that provides a path for the flow of various chemicals and ultrapure water (DIW) used in a semiconductor manufacturing apparatus, for example, a cleaning apparatus. In other semiconductor manufacturing apparatuses, their use is not limited, such as being applied to various pipes or ducts that provide a path to the flow of fluid. The material of the pipe may be made of a material including PFA, that is, perfluoroalkoxy, which is a kind of fluorine resin.

PFA is transparent, has excellent heat resistance and chemical resistance, and has excellent hot strength at high temperatures, so it is used in piping lines that require special high temperature characteristics. In addition, since the PFA is transparent, it has the advantage of observing the fluid flow inside. Meanwhile, the material of the pipe is not limited to PFA, and may be made of PTFE, another kind of fluororesin. PTFE is translucent, has excellent chemical and heat resistance, and can be used as a transport path for corrosive fluids.

The conditions of use of the piping should be configured to be durable at a maximum working pressure of 8 Kgf/㎠ and a maximum working temperature of 90℃.

2 shows a manifold unit (elbow, tee, reducer, etc.) having various shapes and diameters used in the manifold fitting structure of the present invention.

The manifold elbow tee (110, 120) has a structure in which one or more branch pipes are orthogonal to a horizontal type pipe and an end portion is formed as an elbow pipe to communicate with a fluid flow.

In more detail, the manifold elbow tee 110, as shown in Figure 3, the horizontal pipe (111, 118) and the same or different diameter branch pipes (112, 113) at orthogonal to the outer peripheral surface of the annular expansion. Protrusions 114, 115, 117 are formed, and at a point where the annular bulging parts 114, 115, 117 are orthogonal to each other, a support part 116 is integrally formed to be in close contact with both sides by connecting ends of the angular bulging part to each other, Inner diameters of the horizontal pipes 111 and 118 and the branch pipes 112 and 113 are formed to have a constant size, and the end of the horizontal pipe 111 may be formed as an elbow tube. This structure is also used when the diameter of the branch pipe 113 is reduced.

When the diameter of the branch pipe 113 is reduced, the elbow pipe is preferably formed in a structure in which the diameter is reduced while being rounded.

Another type of manifold elbow tee 120 is, as shown in FIG. 4, at a point where the horizontal pipes 121 and 128 and the branch pipes 122 and 123 are orthogonal to each other, the annular bulging portions 124, 125 and 127 on the outer circumferential surface thereof. ) Is formed, and at least one support portion 126, 129 is formed at a point where the annular bulging portions 124, 125, 127 are orthogonal, and the inner diameter of the horizontal pipe 121 and the branch pipes 122, 123 is constant. It is formed in size, and the end of the horizontal pipe 121 may be formed as an elbow tube. This structure is used when the diameter of the branch pipes 122 and 123 need not be reduced.

These annular bulging portions and support portions function to increase the physical strength of the piping and increase the durability of the piping structure to further increase the stability of the piping structure.

The manifold elbow reducer (210, 220) has one or more branch pipes orthogonal to the horizontal type pipe and the end is formed as an elbow pipe to communicate with the fluid to flow, and the branch pipe has a structure with a reduced diameter.

In the manifold elbow reducer, as shown in FIG. 5, annular bulging portions 213 and 214 are formed on the outer circumferential surface at a point where the horizontal pipe 211 and the branch pipe 212 are orthogonal to each other, and the annular bulging portion 213 A support part 215 is formed at a point where 214 is orthogonal to each other, the inner diameter of the horizontal pipe 211 and the branch pipe 212 is formed to have a certain size, and the end of the horizontal pipe is formed as an elbow pipe, The diameter of the trachea 212 is reduced.

When the diameter of the branch pipe 212 is reduced, it may be preferable in terms of the natural flow of the fluid that the elbow pipe is formed in a structure in which the diameter is reduced while being rounded.

The manifold twin tee (310, 320) is made of a structure in which two or more branch pipes are orthogonal to the horizontal type pipe but communicated so that a fluid flows.

In the manifold twin tee, as shown in FIG. 6, annular bulging portions 314 and 315 are formed on the outer circumferential surface at a point where the horizontal pipes 311 and 317 and the branch pipes 312 and 313 are orthogonal to each other, At the point where the annular bulging portions 314 and 315 are orthogonal to each other, support portions 316 on both left and right sides are integrally formed so as to be in close contact with both surfaces of the annular bulging portion by connecting ends of the annular bulging portion to each other, and horizontal pipes 311 and 317 The inner diameters of the and branch pipes 312 and 313 are formed to have a certain size. This structure is used when the diameter of the branch pipes 312 and 313 need not be reduced.

As another form, the manifold twin tee, as shown in FIG. 7, has annular bulging portions 324 and 325 on the outer circumferential surface at a point where the horizontal pipes 321 and 327 and the branch pipes 322 and 323 are orthogonal to each other. Is formed, the support portion 326 is formed at both sides at the point where the annular bulging portions 324 and 325 are orthogonal, and the inner diameters of the horizontal pipe 321 and the branch pipes 322 and 323 are formed to have a constant size. do. This structure is used when the diameter of the branch pipes 322 and 323 needs to be reduced.

The manifold twin tee (tee, 330) of the present invention according to another embodiment, as shown in Figure 8, the horizontal pipes (331, 337) and the branch pipes (332, 333) at a point orthogonal to the outer peripheral surface of the annular expansion. The protruding portions 334 and 335 are formed, and at the point where the annular bulging parts 334 and 335 are orthogonal, the support parts 336 on both left and right sides connect the ends of the angular bulging part to each other so as to be in close contact with both surfaces of the annular bulging part. It is formed, and the inner diameters of the horizontal pipes 331 and 337 and the branch pipes 332 and 333 are formed to have a certain size. This structure is used when the diameter of the branch pipes 332 and 333 is not required to be reduced. In addition, in this structure, the annular bulging portion 335 is continuously formed on the horizontal pipes 331 and 337 in the entire region of the branch pipes 332 and 333 to achieve a more stable structure.

As another form, the manifold twin tee is, as shown in FIG. 9, at a point where the horizontal pipes 341 and 347 and the branch pipes 342 and 343 are orthogonal to each other, an annular bulge on the outer circumferential surface of the pipe and the branch pipe. (344, 345) is formed with a constant thickness, the support portion 346 is formed on both sides at the point where the annular bulging portions (344, 345) are orthogonal, horizontal pipes (341, 347) and branch pipes (342, 343) ) Is characterized in that the inner diameter is formed to a certain size. In this structure, the annular bulging portion 345 is continuously formed on the horizontal pipes 341 and 347 so that the entire region of the branch pipes 342 and 343 can be formed to achieve a more stable structure.

This manifold structure is not formed by splicing, bonding or fusion of individual components, but is integrally formed by compound injection molding.Many-hold twin tee, elbow tee and mani-hold elbow reducer are divided by the diameter of the horizontal pipe. The diameters of the organs may be the same or may be different, which may be produced by known insert injection or composite injection by core insertion injection.

The manifold fitting structure of the pipe according to the present invention uses a plurality of manifold twin tee, manifold elbow tee, elbow reducer, etc. as described above, and the branch pipe and direction change point of the pipe The heat-sealing point can be significantly reduced by heat-sealing the connection parts of the pipes.

As such an example, as shown in FIG. 10, when the number of filters 105 is two, the number of existing fusion points can be reduced to seven by applying a manifold fitting.

Similarly, in a pipe having a similar structure, as shown in FIG. 11, when the number of filters is four, the conventional 17 fusion points can be reduced to eight.

In addition, as shown in FIG. 12, when the number of filters is 6, 25 fusion points are conventionally required, but only 11 are required in the manifold fitting structure of the present invention, and when the number of filters is 8, FIG. 13 As shown, 33 fusion points are required, whereas only 12 are required in the manifold fitting structure of the present invention.

Likewise, it is possible to reduce the fusion points applied to the POU pipe in a similar manner, and in this case, the seven fusion points can be reduced to four.

The reduction of the fusion point can obtain a reduction rate of 25 to 75% based on the number of filters, and accordingly, various advantages as described above can be provided by reducing a leak point, a management point, and a working time.

On the other hand, the heat fusion of the pipe according to the present invention can be performed by ultrasonic vibration heating fusion or high frequency induction heating fusion using a known heat fusion machine and method.

As an example, FIG. 14 is a perspective view showing a heat fusion machine for heat fusion of a pipe. Such a heat splicer may include a base plate 400, a first clamp 410, a second clamp 420, a heat fusion unit 430, and the like.

The base plate 400 is generally provided as a rectangular flat plate, and a first clamp 410, a heat fusion unit 430, and a second clamp 420 are sequentially disposed thereon. Further, pedestal 440 for supporting each of the first pipe P1 and the second pipe P2 are installed at both ends of the base plate 400.

The pedestal 440 may be provided on the base plate 400 to enable position adjustment along the length direction X. The first clamp 410 and the second clamp 420 are provided to firmly fix the first and second pipes P1 and P2 so as not to move during the fusing operation. The first clamp 410 is disposed on one side of the heating fusion unit 430 to clamp the first pipe P1, and the second clamp 420 is a heating fusion unit ( It is placed on the other side of 430). The first clamp 410 and the second clamp 420 have the same structure. The first clamp 410 is a semicircular lower clamper 411 supporting one side of the first pipe P1 and a semicircle hingedly coupled to the lower clamper 411 to support the other side of the first pipe P1. Includes a separable upper clamper 412 on the upper and a fastening member 413 for fixing the separable upper clamper 412 to the lower clamper 411 by being coupled to both sides of the lower clamper 411 and the separable upper clamper 412, respectively. can do. The heating and fusion part 430 is disposed between the first clamp 410 and the second clamp 420. The heating and fusion unit 430 includes a heater installed to surround the joint portion of the first pipe P1 and the second pipe P2 to apply heat to the joint portion. The heating and fusion part 430 is composed of a lower body 431 and an upper body 432, and a heater for applying heat to the bonding portion is installed on the inner side. One end of the lower body 410 and the upper body 420 is hinged to open and close the upper body 432 with respect to the lower body 431 around the hinge. Further, the other ends of the lower body 431 and the upper body 432 are fixed by the fastening member 440. Reference numeral 434 denotes a fastening member of the heated and fused portion.

When using such a device, the end of the first pipe (P1) and the end of the second pipe (P2) are arranged to face each other, and then the end of the first pipe (P1) and the second pipe (P2) are removed. It is firmly fixed to the first clamp 410 and the second clamp 420. Subsequently, after inserting the inner diameter expansion means near the joint area while the first pipe (P1) and the second pipe (P2) are butted to each other, heat is applied to the heater to fuse the joint area, and then cool to perform thermal fusion I can.

Although the embodiments of the present invention have been described in detail as described above, the scope of the present invention is not limited thereto, and the scope of the present invention is included to the extent substantially equal to the embodiments of the present invention. Of course.

101: pipe tee
102: pipe
110, 120: Manihold elbow tee
210. 220: Manihold elbow reducer
310, 320: Manihold Twin Tee
410: first clamp
420: second clamp
430: heating and fusion part

Claims (3)

In the pipe manifold fitting structure,
At least one integrated manifold twin tee in which two or more branch pipes are orthogonal to the horizontal type pipe but communicated so that fluid flows;
One or more integrated manifold elbow tees in which one or more branch pipes are orthogonal to the horizontal type pipe and the end is formed as an elbow pipe to communicate with the fluid; And
At least one branch pipe is orthogonal to the horizontal type pipe and the end is formed as an elbow pipe to communicate with the fluid to flow, and the branch pipe has a reduced diameter. The heat fusion point is reduced by heat-sealing the connection at the branch pipe and the direction change point of the pipe in which the flow passage through which the fluid moves is formed, and the reduction of this fusion point is 25~75% based on the number of filters. By obtaining the reduction rate, the piping configuration is simplified and the construction is simple, which not only shortens the work time, but also improves efficiency in designing and configuring the piping by easy maintenance, such as reduction of leak points, reduction of work load, and reduction of management points. And secure stability,
The material of the pipe and pipe is PFA resin or fluororesin,
The integrated manifold twin tee, elbow tee, and manifold elbow reducer are not formed by bonding, bonding, or fusion, but are integrally formed by composite injection molding, and the diameter of the horizontal pipe and the diameter of the branch pipe are the same, or Manihold fitting structure of the pipe, characterized in that different. The method according to claim 1,
In the integrated manifold twin tee, annular bulging portions 314 and 315 are formed on an outer circumferential surface at a point where horizontal pipes 311 and 317 and branch pipes 312 and 313 are orthogonal to each other, and the annular bulging portion 314 The support portions 316 are formed on both sides at the point where 315 is orthogonal, and the inner diameters of the horizontal pipe 311 and the branch pipes 312 and 313 are formed to have a certain size,
The integrated manifold elbow tee has an annular bulging portion 114, 115, 117 formed on an outer circumferential surface at a point where the horizontal pipes 111 and 118 and the branch pipes 112 and 113 are orthogonal to each other, and the annular bulging portion At the point where (114, 115, 117) is orthogonal to each other, the support part 116 is formed on both sides, the inner diameters of the horizontal pipes 111, 118 and the branch pipes 112, 113 are formed to have a constant size, and the horizontal pipe ( 111) is formed of an elbow tube,
The integrated manifold elbow reducer has annular bulging portions 213 and 214 formed on the outer circumferential surface at a point where the horizontal pipe 211 and the branch pipe 212 are orthogonal to each other, and the annular bulging portions 213 and 214 are A support part 215 is formed at a point perpendicular to each other, the inner diameter of the horizontal pipe 211 and the branch pipe 212 is formed to have a constant size, and the end of the horizontal pipe 211 is formed as an elbow pipe, and the branch pipe The diameter of (212) is reduced, and the elbow tube is formed in a structure in which the diameter is reduced while being rounded. The method according to claim 1,
The heat fusion is performed by ultrasonic vibration heating fusion or high frequency induction heating fusion.

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