KR102220751B1 - Eccentric calibration coonecting unit for vertical pipeline installation - Google Patents

Abstract

The present invention connects the upper pipe (1) and the lower pipe (2), but one end is fluidly connected to the upper pipe (1) and an upper connector 100 for discharging a fluid through the upper connector outlet 113, A cross-sectional area larger than the cross-sectional area of the lower connector through hole 201 and the upper connector through hole 201, which is disposed opposite to the upper connector 100 and forms one end of the lower connector through hole 201 The lower connector funnel inlet 210 of the lower connector, and a lower connector having a smaller cross-sectional area than the lower connector funnel inlet 210 and connected to the lower pipe 2 to discharge the fluid and form the other end of the lower connector through hole 201 An eccentricity correction connector unit is provided when vertical piping including the lower connector 200 including the funnel outlet 220 is installed.

Description

Eccentricity correction connector unit for vertical piping installation {ECCENTRIC CALIBRATION COONECTING UNIT FOR VERTICAL PIPELINE INSTALLATION}

The present invention relates to a piping connector, and more particularly, to a piping connector unit for smoother connection between an upper pipe and a lower pipe.

Buildings following urbanization are increasingly focusing on high-rises with intensive structures. In accordance with the trend of these buildings, the structural technology of the building structure itself is developed, and at the same time, various R&D and production of facilities entering the building are being made.

In addition to the field of air conditioning facilities for maximizing heating and cooling power generation and thermal efficiency, research on water supply and piping facilities according to high rise of buildings are being actively conducted.

In particular, due to the large increase in the number of floors in the building due to the high rise of the building, there is considerable difficulty in installation and installation due to the mismatch of the central axis of the piping facility in connecting vertical piping, which leads to considerable difficulty in complying with the process schedule or possible defects after the process. It was considerable.

Accordingly, an object of the present invention is to provide a connector unit for correcting eccentricity when installing a vertical pipe having a structure that minimizes the occurrence of process defects due to eccentricity of the center axis when the center axis of the vertical pipe does not match and improves assembly performance.

The present invention for achieving the above object is to connect the upper pipe (1) and the lower pipe (2), but one end is fluidly connected to the upper pipe (1) and discharges the fluid through the upper connector outlet (113). An upper connector 100, a lower connector through hole 201 disposed therein, and disposed opposite to the upper connector 100, to form one end of the lower connector through hole 201, and the upper connector cap outlet ( The lower connector funnel inlet 210 having a cross-sectional area larger than the cross-sectional area of 113) and the lower connector funnel inlet 210 have a smaller cross-sectional area than that of the lower connector funnel inlet 210 and are connected to the lower pipe 2 to discharge the fluid and the lower connector through hole 201 Provides an eccentricity correction connector unit when installing a vertical pipe including the lower connector 200 including the lower connector funnel outlet 220 forming the other end of the.

In the eccentricity correction connector unit when the vertical pipe is installed, the cross-sectional area of the lower connector through-hole 201 may decrease as it goes from the lower connector funnel inlet 210 to the lower connector funnel outlet 220.

In the eccentricity correction connector unit when the vertical pipe is installed, the upper connector 100 is: connected to the upper pipe 1, receiving a fluid from the upper pipe 1, and communicating with the upper connector cap outlet 113. The upper connector caps 110 and 110a including the upper connector cap inlet 111 and the outer circumference of the end of the upper connector cap 110 toward the lower connector 200 are formed to extend in a radial direction, and the connector funnel outlet ( It may also include upper connector around (120, 120a) having a cross-sectional area larger than the effective cross-sectional area of 220).

In the eccentricity correction connector unit when the vertical pipe is installed, the upper connector 100 and the lower connector 200 may be fixedly mounted at a relative position.

In the eccentricity correction connector unit when the vertical pipe is installed, an upper connector under guide 130 having a length toward the lower connector 200 may be further provided in the upper connector around 120.

In the eccentricity correction connector unit when the vertical piping is installed, an upper connector gripper 140 for receiving and capturing at least a part of the lower connector 200 on one side of the upper connector around 120 facing the lower connector 200 It may also include.

In the eccentricity correction connector unit when the vertical piping is installed, the upper connector gripper 140: One end is fixed to the bottom surface of the upper connector around 120 and the other end is formed as a free end of the upper connector around 120 A plurality of gripper parts 141 forming a space for accommodating at least a portion of the lower connector 200 on the bottom surface, and a gripper cutout 143 for separating the other ends of the plurality of gripper pods 141 , It may include a gripper mounting hole 145 that is partitioned by the other ends of the plurality of gripper parts 141 and allows entry of the lower connector 200.

In the eccentricity correction connector unit when the vertical pipe is installed, the outer shapes of the upper connector around 120a and the lower connector 200 may be non-circular.

In the eccentricity correction connector unit when the vertical piping is installed, the upper connector around 120a and the lower connector 200a are of a rectangular type, and the long axis length of the lower connector funnel inlet 210a is the upper connector It may be less than the long axis length of the around 120a, and the short axis length of the lower connector funnel inlet 210a may be less than the short axis length of the upper connector around 120a.

In the eccentricity correction connector unit when the vertical piping is installed, half of the long axis length l120a of the upper connector around 120a is the long axis length of the lower connector funnel inlet 210a It may be substantially the same as the difference value between (l210a) and the radius R111 of the upper connector cap inlet 111.

In the eccentricity correction connector unit when the vertical piping is installed, the upper connector (100a) and the lower connector (200a) have a connector slider that enables a linear relative motion of the upper connector (100a) and the lower connector (200a) ( 300a) may be disposed.

In the eccentricity correction connector unit when the vertical piping is installed, the connector slider (300a) includes: an upper slider (310a) disposed toward the lower connector on a bottom surface of the upper connector around (120a), and the lower connector (200a) It may be provided with a lower slider (320a) that is disposed at the end of the upper slider (310a) and can engage with the relative movement.

In the eccentricity correction connector unit when the vertical pipe is installed, a slider stopper 140a for limiting relative motion with the lower connector 200a may be further provided at the lower end of the upper connector 100a.

In the eccentricity correction connector unit when the vertical pipe is installed, the slider stopper 140a may be made of a flexible material.

When installing a vertical pipe according to the present invention having the above configuration, the eccentricity correction connector unit has the following effects.

First, when installing a vertical pipe according to the present invention, the eccentricity correction connector unit enables smooth connection between the two even when the central axis of the upper and lower pipes are not coincident, so that the up and down flow of the flow can be smoothly performed.

Second, the eccentricity correction connector unit when installing vertical piping according to the present invention minimizes the possibility of leakage due to misassembly by facilitating the operator to recognize the limit line of the connection arrangement position of the upper connector and the lower connector through the upper connector under guide. You may.

Third, the eccentricity correction connector unit when vertical piping according to the present invention is installed, the upper connector and the lower connector have a non-circular type, and take a long-directional structure, so that manufacturing cost can be reduced by minimizing materials by optimizing the connection structure.

Fourth, the eccentricity correction connector unit in the vertical pipe installation according to the present invention may achieve a smoother assembly state by enabling relative movement of the upper connector and the lower connector through the connector slider structure.

Fifth, when installing a vertical pipe according to the present invention, the eccentricity correction connector unit, in addition to the horizontal movement of the vertical central axis on the plane in the vertical direction of the pipe through the upper connector gripper structure, crosses the central axis due to the rotational state or the vertical central axis direction. In the case of movement, the degree of freedom of assembly and connection of the upper and lower pipes may be improved by maintaining a predetermined smooth connection state.

The present invention has been described with reference to the exemplary embodiments shown in the drawings, but these are only exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1 is a schematic perspective view of an eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.
2 is a schematic exploded perspective view of an eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.
3 is a schematic partial cross-sectional view showing a geometric state of components of an eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.
4 and 5 are schematic exploded perspective views and partial cross-sectional state configuration diagrams of a modified example of an eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.
6 is a schematic exploded perspective view of another modified example of the eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.
7 is a schematic exploded perspective view of another modified example of the eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.
8 to 10 are schematic partial cross-sectional state configuration diagrams showing the structural state of another modified example of the eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.
11 is a schematic partial cross-sectional view of another modified example including a slider connector of the eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.
12 is a schematic exploded perspective view of another modified example of the eccentricity correction connector unit when vertical piping is installed according to an embodiment of the present invention.

Hereinafter, it will be described with reference to the drawings of the eccentricity correction connector unit when vertical piping is installed.

When installing the vertical pipe according to the present invention, the eccentricity correction connector units 10 and 10a are disposed between the upper pipe 1 and the lower pipe 2 to connect them. When installing the vertical pipe of the present invention, the eccentricity correction connector unit (10, 10a) includes an upper connector (100, 100a) and a lower connector (200, 200a).

When installing the vertical pipe of the present invention, the eccentricity correction connector unit (10, 10a) prevents disconnection of the connection between the upper pipe (1) and the lower pipe (2) in a state where the center line is inconsistent, and smoothly flows water such as rainwater and sewage It makes it possible to transfer from top to bottom.

More specifically, as shown in FIGS. 1 and 2, the eccentricity correction connector unit 10 includes an upper connector 100 and a lower connector 200 when vertical pipe installation according to an embodiment of the present invention.

The upper connector 100 has one end fluidly connected to the upper pipe 1 and discharges the fluid through the upper connector outlet 113. The lower connector 200 includes a lower connector through hole 201, a lower connector funnel inlet 210, and a lower connector funnel outlet 220, wherein the lower connector through hole 201 is disposed through the inside, and the lower connector funnel The inlet 210 is disposed opposite the upper connector 100 and forms one end of the lower connector through hole 201 and has a cross-sectional area larger than the cross-sectional area of the upper connector cap outlet 113, and the lower connector funnel outlet 220 Is smaller in cross-sectional area than the lower connector funnel inlet 210 and is connected to the lower pipe 2 to discharge fluid and form the other end of the lower connector through hole 201.

In this embodiment, the lower connector through hole 201 has a configuration in which the cross-sectional area decreases as it goes from the lower connector funnel inlet 210 to the lower connector funnel outlet 220. In this case, the cross-section of the lower connector through hole 201 may have various shapes, and the effective radius of the inner effective cross-sectional area of the lower connector through hole 201 may be discontinuously reduced, but the lower connector It is preferable that the cross-section of the through hole 201 is formed in a circular shape and the inner diameter of the lower connector through hole 201 is configured to minimize the flow resistance of the fluid flowing therein by taking a structure that continuously decreases.

More specifically, the upper connectors 100 and 100a of the present invention include upper connector caps 110 and 110a and upper connector around 120 and 120a.

The upper connector caps 110 and 110a are connected to the upper pipe 1 and include an upper connector cap inlet 111 and an upper connector cap outlet 113. The upper connector caps 110 and 110a receive the fluid from the upper pipe 1, and the upper connector cap inlet 111 communicates with the upper connector cap outlet 113 to collect the fluid flowing from the upper pipe 1 It makes it possible to transmit to the lower side.

The upper connector around (120, 120a) is disposed on the upper connector cap (110), more specifically, the upper connector around (120, 120a) is radial direction on the outer periphery of the end of the upper connector cap (110, 100a) toward the lower connector 200 Is formed to extend. The upper connector around 120 and 120a has a cross-sectional area larger than the effective cross-sectional area of the connector funnel outlet 220. In some cases, the upper connector around (120, 120a) has a predetermined stopping function that prevents upper movement of the lower connector (200, 200a) in the vertical direction and/or a predetermined guide function that guides the position movement in the horizontal direction. Can be accompanied by.

In this embodiment, the upper connector 100 and the lower connector 200 may be fixedly mounted in a relative position. That is, the upper connector 100 and the lower connector 200 shown in FIGS. 1 and 2 may be connected to each other so as to be fixed in a relative position to prevent relative movement. The upper connector 100 and the lower connector 200 may take a structure that is fixedly connected to each other through fixing means such as adhesive or welding. Although not shown here, in some cases, it may take a configuration that is mutually fastened through a configuration such as a flange/bolt.

As described above, the lower connector funnel inlet 210 has a cross-sectional area larger than that of the upper connector cap outlet 113, and the lower connector funnel outlet 220 has a smaller cross-sectional area than the lower connector funnel inlet 210. This is an expression described on the premise that the thickness of each component is substantially the same, and the lower connector funnel inlet inner diameter 211 forming the inner diameter of the lower connector funnel inlet 210 more strictly is the upper connector The lower connector funnel outlet inner diameter portion 221 having a cross-sectional area larger than the cross-sectional area formed by the inner diameter surface of the cap outlet 113 and forming the outer diameter of the lower connector funnel outlet 220 is the inner diameter surface of the lower connector funnel inlet 210 This formation takes a configuration with a smaller cross-sectional area.

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That is, as shown in FIGS. 1 to 3, the radiuses of the upper connector cap inlet 111 and the upper connector cap outlet 113 provided in the upper connector cap 110, and more specifically, the inner diameter radiuses are R111 and R113, respectively. And, the radius of the lower connector funnel inlet inner diameter portion 211 and the lower connector funnel outlet inner diameter portion 221 of the lower connector funnel inlet 210 of the lower connector 200 is referred to as R211, R221, respectively, in this embodiment When the inner diameter radius of the upper connector cap inlet 111 and the upper connector cap outlet 113 are substantially the same, so that R111=R113 is a relationship, the relationship between R211>R111=R113 and R211>R221 forms a geometric relationship. Thus, the cross-section formed by the inner diameter radius of the upper connector cap outlet 113 is captured inside the cross-section formed by the lower connector funnel inlet inner diameter 211 of the lower connector funnel inlet 210, and the lower connector funnel inlet 210 A cross-sectional area formed by the inner diameter portion 211 of the lower connector funnel outlet of) has a value larger than the cross-sectional area formed by the radius of the inner diameter portion 221 of the lower connector funnel outlet.

Through this configuration, even when eccentricity of the central axis of the upper pipe 1 and the lower pipe 2 occurs, it is possible to seamlessly connect the upper and lower pipes through the eccentricity correction connector unit 10 when installing the vertical pipe of the present invention. You may.

In addition, the eccentricity correction connector unit 10 when installing the vertical pipe according to the present invention may further include a component for guiding the arrangement and connection positions of the upper connector 110 and the lower connector 120. That is, as shown in FIG. 4, when installing the vertical pipe, the eccentricity correction connector unit 10 may further include an upper connector under guide 130. The upper connector under guide 130 is disposed on the upper connector around 120, and the upper connector under guide 130 is formed in length toward the lower connector 200. The upper connector under guide 130 is disposed on the upper connector around 120 in a circumferential direction at a predetermined radial distance from the center, protrudes toward the lower connector 200 and extends in the longitudinal direction to have a predetermined length Formation

As shown in FIGS. 4 and 5, when the upper connector and the lower connector are connected, a guide or position limiting stopper functions so that the connection position of the lower connector is disposed inside the upper connector under guide 130. That is, the upper connector under guide 130 is a limiting point of the coupling position when the upper connector and the lower connector are fixedly connected to each of the upper pipe 1 and the lower pipe 2 in which the operator's central axes are inconsistent with each other through a protruding structure. By making it possible to recognize, it is possible to provide the speed, excellence, and efficiency of work.

In this embodiment, the upper connector around 120 has a structure that is continuously arranged in a circumferential direction on a predetermined radial distance from the center on the upper connector around 120, but the present invention is not limited thereto, and discontinuous to predetermined intervals Various implementations are possible, such as being able to take a discontinuous arrangement structure that is spaced apart from each other.

On the other hand, in the previous embodiment, it has been described focusing on the case of performing a connecting function in case of a mismatch between the center axis in the horizontal direction of the upper connector 100 and the lower connector 200, but the eccentricity correction connector when installing the vertical pipe of the present invention The unit may be configured to be able to cope with the case of mismatch of the central axis due to a vertical direction or a predetermined relative rotation. 6 shows a modified embodiment in which the lower connector 200 is configured to allow a predetermined relative movement to the upper connector 100 side. When vertical piping is installed, the eccentricity correction connector unit further includes an upper connector gripper 140, and the upper connector gripper 140 is disposed on one surface of the upper connector around 120 toward the lower connector 200. The upper connector gripper 140 accommodates and captures at least a portion of the lower connector 200. In this case, a predetermined relative motion occurs between the upper connector 100 and the lower connector 200, and the coupling through adhesive or welding is not performed, and the gripper part ( Various modifications are possible, such as being able to take a structure for maintaining a connected state through a configuration such as a ring or a coupling to prevent separation of 141).

The upper connector gripper 140 more specifically includes a plurality of gripper parts 141, a gripper cutout 143, and a gripper mounting hole 145.

One end of the plurality of gripper parts 141 is fixed to the bottom of the upper connector around 120 and the other end is formed as a free end. Through this configuration of the plurality of gripper parts 141, a space for accommodating at least a part of the lower connector 200 may be formed on the bottom surface of the upper connector around 120.

The plurality of gripper parts 141 may be formed of a flexible soft material having predetermined flexibility. However, it is preferable that the plurality of gripper parts 141 are selected from a material having flexibility or rigidity such that a predetermined level of flexibility allows smooth entry into the captured lower connector 200 but prevents unwanted separation and separation. Do.

The gripper cutout 143 separates the other ends of the plurality of gripper pods 141 apart, and the number, length and shape of the gripper cutouts 143 allow smooth entry of the lower connector 200 but are undesirably separated and separated. Various modifications are possible according to the design specifications to take the configuration enough to prevent it. In addition, the size of the gripper cutout 143 to prevent separation and separation of predetermined components, but to stably move to the lower connector without the fluid drawn out through the upper connector cap outlet. Selection of shape, etc. may be made.

The gripper mounting hole 145 is partitioned by the other ends of the plurality of gripper parts 141 and allows entry of the lower connector 200, the size of the gripper mounting hole 145, that is, the radius of the gripper mounting hole 145 It is preferable that the lower connector 200 is formed to take a configuration that allows a predetermined entry of the lower connector 200 but prevents unwanted withdrawal through the gripper mounting hole 145.

Through this configuration, a structure that allows a predetermined vertical or relative rotational angle of the central axis between the upper connector and the lower connector is possible, so that a stable connection structure can be achieved even when the central axis crosses the relative angle or a vertical reverberation gap occurs. May be.

Meanwhile, in the above embodiments, a configuration having a circular outer shape between the upper connector and the lower connector is taken, but the upper connector and the lower connector of the present invention are not limited thereto, and various modifications are possible.

That is, the outer shape of the upper connector around 120a and the lower connector 200 may take a non-circular structure, and through this configuration, the size of the upper connector and the lower connector can be rotated 360 degrees on a plane horizontal to the central axis. While securing area coverage (see FIG. 10), it is also possible to take a configuration that optimizes manufacturing cost by minimizing the required area.

When the upper connector and the lower connector are directly connected to the upper pipe (1) and the lower pipe (2), they can be rotated and connected in an angle-adjusted state, and the lower connector can be positioned along the entire length of the upper connector. In the previous embodiment, it is possible to secure the overall coverage of the area covered by the circular type upper connector and the lower connector.

More specifically, as shown in FIGS. 7 to 10, the upper connector around 120a and the lower connector 200 may be of a non-circular type and may be of a rectangular type. The long axis length (l210a) of the lower connector funnel inlet 210 is less than the long axis length (l20a) of the upper connector around 120, and the short axis length (l210a) of the lower connector funnel inlet 210 is the upper connector around It can take a structure less than the short axis length (lw120a) of (120).

More specifically, half of the long axis length l120a of the upper connector around 120a is the long axis length l210a of the lower connector funnel inlet 210 and the upper connector cap inlet 111 ) Is substantially the same as the difference value of the radius R111, that is, a relationship of l120a/2≒l210a-R111 is formed.

In addition, FIG. 9 shows a schematic diagram of a case where the centers are not matched. That is, compared to FIG. 8, even when the center of the upper connector cap inlet (O111) and the center of the inner diameter of the lower connector funnel outlet (O221) do not match, the lower connector funnel inlet inner diameter side of the lower connector funnel inlet takes a rectangular structure. However, it is possible to cover all of the upper connector cap inlets geometrically, and through a continuous cross-sectional area reduction structure, the inner diameter of the lower connector funnel inlet leads to the inner diameter of the lower connector funnel outlet, so that external leakage of fluid does not occur and a stable connection Structure can be achieved. In addition, the inner area of the line indicated by reference numeral T (refer to FIG. 9) represents the area covered by the component in this embodiment, which is substantially the same as the coverage provided in the embodiment shown in FIG. It can also increase the versatility of on-site installation by reducing cost, increasing mountability, and minimizing installation space.

That is, through such a configuration, the lower connector funnel inlet 210a and the upper connector cap inlet 111 are substantially radii and projection arrangement positions as in the previous embodiment shown in Fig. 1 and the like indicated by dotted lines (see Fig. 8). It is possible to secure coverage (T) for the entire area in which the same substantially identical upper connector cap outlet 113 is disposed, and at the same time, the structure may be minimized, resulting in a reduction in manufacturing cost through material reduction.

In this case, the eccentricity correction connector unit during vertical piping installation of the present invention may be configured to enable a more seamless connection structure construction when assembling on an actual field piping facility.

On the other hand, such a non-circular type, that is, when the vertical pipe of the present invention of the rectangular type is installed, the eccentricity correction connector unit may further include a component that facilitates relative movement. That is, as shown in FIG. 11, the connector slider 300a is disposed on the upper connector 100a and the lower connector 200a, and the connector slider 300a is a linear counterpart between the upper connector 100a and the lower connector 200a. Make exercise possible.

More specifically, the connector slider 300a includes an upper slider 310a and a lower slider 320a, and the upper slider 310a is disposed on the bottom surface of the upper connector around 120a toward the lower connector, and the lower slider ( 320a) is disposed at the end of the lower connector 200a, and takes a structure capable of engaging with the upper slider 310a to enable relative movement.

That is, the upper slider 310a and the lower slider 320a of the connector slider 300a extend their longitudinal axes to the bottom surface of the upper connector around 120a and the end of the lower connector inlet 210 of the lower connector 200a, respectively. It can be formed in the longitudinal direction to have. In this embodiment, the upper slider 310a of the connector slider 300a has a protrusion structure and the lower slider 320a has a corresponding concave groove structure, both of which are movably engaged with each other, It can be guided so that linear motion can be made smoothly.

Further, in the case of such a slider structure, a configuration may be further provided to prevent unwanted slider separation. That is, a slider stopper 140a is further provided at the lower end of the upper connector 100a, and the slider stopper 140a limits relative motion with the lower connector 200a. A slider stopper opening 141a is disposed at the front end of the slider stopper 140a to allow initial entry to form an assembled state.

The slider stopper 140a is formed in length toward the lower connector 200a to prevent the lower connector 200a from deviating from a predetermined position with respect to the upper connector 100a.

At this time, the slider stopper 140a is made of a flexible material to secure a predetermined stopper function, but it is also possible to minimize the assembling property degradation due to interference when assembling the slider structure.

Through such a guide structure, the operator can smoothly adjust the relative position between the upper connector and the lower connector to improve workability and at the same time optimize the manufacturing cost through optimization of essential elements.

The above embodiments are examples for explaining the present invention, and the present invention is not limited thereto. Various modifications are possible within the range of taking a configuration that connects a pipe whose central axis of the upper pipe and the lower pipe is shifted.

10...Eccentricity correction connector unit when vertical piping is installed 100...upper connector
110...upper connector cap 120...upper connector around
130...upper connector under guide 200...lower connector
210...lower connector funnel inlet 220....lower connector funnel outlet
300a... connector slider 310a.... upper slider
320a... lower slider

Claims (14)

The upper connector (100a) is connected to the upper pipe (1) and the lower pipe (2), but one end is fluidly connected to the upper pipe (1) and discharges the fluid through the upper connector outlet (113) The lower connector through hole 201, which is disposed opposite to the upper connector 100a, forms one end of the lower connector through hole 201 and has a cross-sectional area larger than the cross-sectional area of the upper connector cap outlet 113 The inlet 210a and the lower connector funnel outlet 220a which have a smaller cross-sectional area than the lower connector funnel inlet 210a and are connected to the lower pipe 2 to discharge the fluid and form the other end of the lower connector through hole 201 Including a lower connector (200a) containing,
The lower connector through-hole 201 continuously decreases in cross-sectional area as it moves from the lower connector funnel inlet 210a to the lower connector funnel outlet 220a,
The upper connector 100a is: an upper connector including an upper connector cap inlet 111 connected to the upper pipe 1 and receiving a fluid from the upper pipe 1 and communicating with the upper connector cap outlet 113 The cap 110a and an upper connector around 120a extending on the outer periphery of an end of the upper connector cap 110a facing the lower connector 200a and having a cross-sectional area larger than the effective cross-sectional area of the connector funnel outlet 220a Including,
The outer shapes of the upper connector around 120a and the lower connector 200a are non-circular,
The upper connector around 120a and the lower connector 200a are of a rectangular type,
When the upper connector (100a) and the lower connector (200a) are directly connected to the upper pipe (1) and the lower pipe (2), they can be rotated and fastened in an angle-adjusted state, and the overall length of the upper connector 100a Accordingly, the upper connector 100a and the lower connector 200a have a connector that enables a linear relative movement of the upper connector 100a and the lower connector 200a so that the position of the lower connector 200a can be adjusted accordingly. The slider 300a is disposed,
The connector slider 300a includes: an upper slider 310a disposed at the bottom of the upper connector around 120a toward the lower connector, and an upper slider 310a disposed at an end of the lower connector 200a, Eccentricity correction connector unit for vertical piping installation, characterized in that it has a lower slider (320a) that can be engaged to enable relative movement.
delete delete delete delete delete delete delete The method of claim 1,
The length of the long axis of the lower connector funnel inlet 210a is less than the length of the long axis of the upper connector around 120a,
An eccentricity correction connector unit for vertical piping installation, characterized in that the shorter length of the lower connector funnel inlet 210a is less than or equal to the shorter length of the upper connector around 120a. The method of claim 9,
Half of the long axis length (l120a) of the upper connector around 120a is the long axis length (l210a) of the lower connector funnel inlet 210 and the upper connector cap inlet 111 Eccentricity correction connector unit when installing vertical piping, characterized in that substantially the same as the difference value of the radius (R111) of. delete delete The method of claim 1,
A slider stopper (140a) for limiting relative motion with the lower connector (200a) is further provided at a lower end of the upper connector (100a). The method of claim 13,
The slider stopper (140a) is an eccentricity correction connector unit when installing a vertical pipe, characterized in that made of a flexible material.

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